disposer()(pVal);
}
- static node_type * child( node_type * pNode, int nDir, atomics::memory_order order )
+ static node_type * child( node_type * pNode, int nDir, atomics::memory_order order = memory_model::memory_order_relaxed )
{
return pNode->child( nDir ).load( order );
}
- static node_type * parent( node_type * pNode, atomics::memory_order order )
+ static node_type * parent( node_type * pNode, atomics::memory_order order = memory_model::memory_order_relaxed )
{
return pNode->m_pParent.load( order );
}
template <typename Func>
bool check_consistency( Func f ) const
{
- node_type * pChild = child( m_pRoot, right_child, memory_model::memory_order_relaxed );
+ node_type * pChild = child( m_pRoot, right_child );
if ( pChild ) {
size_t nErrors = 0;
do_check_consistency( pChild, 1, f, nErrors );
size_t do_check_consistency( node_type * pNode, size_t nLevel, Func f, size_t& nErrors ) const
{
if ( pNode ) {
- size_t hLeft = do_check_consistency( child( pNode, left_child, memory_model::memory_order_relaxed ), nLevel + 1, f, nErrors );
- size_t hRight = do_check_consistency( child( pNode, right_child, memory_model::memory_order_relaxed ), nLevel + 1, f, nErrors );
+ key_comparator cmp;
+ node_type * pLeft = child( pNode, left_child );
+ node_type * pRight = child( pNode, right_child );
+ if ( pLeft && cmp( pLeft->m_key, pNode->m_key ) > 0 )
+ ++nErrors;
+ if ( pRight && cmp( pNode->m_key, pRight->m_key ) > 0 )
+ ++nErrors;
+
+ size_t hLeft = do_check_consistency( pLeft, nLevel + 1, f, nErrors );
+ size_t hRight = do_check_consistency( pRight, nLevel + 1, f, nErrors );
if ( hLeft >= hRight ) {
if ( hLeft - hRight > 1 ) {
// get right child of root
node_type * pChild = child( m_pRoot, right_child, memory_model::memory_order_acquire );
if ( pChild ) {
- version_type nChildVersion = pChild->version( memory_model::memory_order_relaxed );
+ version_type nChildVersion = pChild->version( memory_model::memory_order_acquire );
if ( nChildVersion & node_type::shrinking ) {
m_stat.onRemoveRootWaitShrinking();
pChild->template wait_until_shrink_completed<back_off>( memory_model::memory_order_relaxed );
);
return pExtracted;
}
-
//@endcond
private:
//@cond
+ static int height( node_type * pNode, atomics::memory_order order = memory_model::memory_order_relaxed )
+ {
+ assert( pNode );
+ return pNode->m_nHeight.load( order );
+ }
+ static void set_height( node_type * pNode, int h, atomics::memory_order order = memory_model::memory_order_relaxed )
+ {
+ assert( pNode );
+ pNode->m_nHeight.store( h, order );
+ }
+ static int height_null( node_type * pNode, atomics::memory_order order = memory_model::memory_order_relaxed )
+ {
+ return pNode ? height( pNode, order ) : 0;
+ }
+
template <typename Q, typename Compare, typename Func>
find_result try_find( Q const& key, Compare cmp, Func f, node_type * pNode, int nDir, version_type nVersion ) const
{
assert( pNode );
while ( true ) {
- node_type * pChild = child( pNode, nDir, memory_model::memory_order_relaxed );
+ node_type * pChild = child( pNode, nDir );
if ( !pChild ) {
if ( pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
m_stat.onFindRetry();
}
}
else if ( nChildVersion != node_type::unlinked ) {
-
if ( pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
m_stat.onFindRetry();
return find_result::retry;
if ( found != find_result::retry )
return found;
}
+
+ if ( pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
+ m_stat.onFindRetry();
+ return find_result::retry;
+ }
}
}
// get right child of root
node_type * pChild = child( m_pRoot, right_child, memory_model::memory_order_acquire );
if ( pChild ) {
- version_type nChildVersion = pChild->version( memory_model::memory_order_relaxed );
+ version_type nChildVersion = pChild->version( memory_model::memory_order_acquire );
if ( nChildVersion & node_type::shrinking ) {
m_stat.onUpdateRootWaitShrinking();
pChild->template wait_until_shrink_completed<back_off>( memory_model::memory_order_relaxed );
pNew->m_pValue.store( pVal, memory_model::memory_order_release );
m_pRoot->child( pNew, right_child, memory_model::memory_order_relaxed );
- m_pRoot->height( 2, memory_model::memory_order_relaxed );
+ set_height( m_pRoot, 2 );
}
++m_ItemCounter;
// get right child of root
node_type * pChild = child( m_pRoot, right_child, memory_model::memory_order_acquire );
if ( pChild ) {
- version_type nChildVersion = pChild->version( memory_model::memory_order_relaxed );
+ version_type nChildVersion = pChild->version( memory_model::memory_order_acquire );
if ( nChildVersion & node_type::shrinking ) {
m_stat.onRemoveRootWaitShrinking();
pChild->template wait_until_shrink_completed<back_off>( memory_model::memory_order_relaxed );
int result;
do {
- node_type * pChild = child( pNode, nCmp, memory_model::memory_order_relaxed );
+ node_type * pChild = child( pNode, nCmp );
if ( pNode->version(memory_model::memory_order_acquire) != nVersion ) {
m_stat.onUpdateRetry();
return update_flags::retry;
pChild->template wait_until_shrink_completed<back_off>( memory_model::memory_order_relaxed );
// retry
}
- else if ( pChild == child( pNode, nCmp, memory_model::memory_order_relaxed )) {
+ else if ( pChild == child( pNode, nCmp )) {
// this second read is important, because it is protected by nChildVersion
// validate the read that our caller took to get to node
- if ( pNode->version( memory_model::memory_order_relaxed ) != nVersion ) {
+ if ( pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
m_stat.onUpdateRetry();
return update_flags::retry;
}
result = try_update( key, cmp, nFlags, funcUpdate, pNode, pChild, nChildVersion, disp );
}
}
+
+ if ( result == update_flags::retry && pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
+ m_stat.onUpdateRetry();
+ return update_flags::retry;
+ }
} while ( result == update_flags::retry );
return result;
}
int result;
do {
- node_type * pChild = child( pNode, nCmp, memory_model::memory_order_relaxed );
+ node_type * pChild = child( pNode, nCmp );
if ( pNode->version(memory_model::memory_order_acquire) != nVersion ) {
m_stat.onRemoveRetry();
return update_flags::retry;
pChild->template wait_until_shrink_completed<back_off>( memory_model::memory_order_relaxed );
// retry
}
- else if ( pChild == child( pNode, nCmp, memory_model::memory_order_relaxed )) {
+ else if ( pChild == child( pNode, nCmp )) {
// this second read is important, because it is protected by nChildVersion
// validate the read that our caller took to get to node
- if ( pNode->version( memory_model::memory_order_relaxed ) != nVersion ) {
+ if ( pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
m_stat.onRemoveRetry();
return update_flags::retry;
}
result = try_remove( key, cmp, func, pNode, pChild, nChildVersion, disp );
}
}
+
+ if ( result == update_flags::retry && pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
+ m_stat.onRemoveRetry();
+ return update_flags::retry;
+ }
} while ( result == update_flags::retry );
return result;
}
int result;
do {
- node_type * pChild = child( pNode, nDir, memory_model::memory_order_relaxed );
+ node_type * pChild = child( pNode, nDir );
if ( pNode->version(memory_model::memory_order_acquire) != nVersion ) {
m_stat.onRemoveRetry();
return update_flags::retry;
pChild->template wait_until_shrink_completed<back_off>( memory_model::memory_order_relaxed );
// retry
}
- else if ( pChild == child( pNode, nDir, memory_model::memory_order_relaxed )) {
+ else if ( pChild == child( pNode, nDir )) {
// this second read is important, because it is protected by nChildVersion
// validate the read that our caller took to get to node
- if ( pNode->version( memory_model::memory_order_relaxed ) != nVersion ) {
+ if ( pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
m_stat.onRemoveRetry();
return update_flags::retry;
}
result = try_extract_minmax( nDir, func, pNode, pChild, nChildVersion, disp );
}
}
+
+ if ( result == update_flags::retry && pNode->version( memory_model::memory_order_acquire ) != nVersion ) {
+ m_stat.onRemoveRetry();
+ return update_flags::retry;
+ }
} while ( result == update_flags::retry );
return result;
}
if ( c_bRelaxedInsert ) {
if ( pNode->version( memory_model::memory_order_acquire ) != nVersion
- || child( pNode, nDir, memory_model::memory_order_relaxed ) != nullptr )
+ || child( pNode, nDir ) != nullptr )
{
m_stat.onInsertRetry();
return update_flags::retry;
assert( pNode != nullptr );
node_scoped_lock l( m_Monitor, *pNode );
- if ( pNode->version( memory_model::memory_order_relaxed ) != nVersion
- || child( pNode, nDir, memory_model::memory_order_relaxed ) != nullptr )
+ if ( pNode->version( memory_model::memory_order_acquire ) != nVersion
+ || child( pNode, nDir ) != nullptr )
{
if ( c_bRelaxedInsert ) {
mapped_type pVal = pNew->m_pValue.load( memory_model::memory_order_relaxed );
if ( !pNode->is_valued( atomics::memory_order_relaxed ) )
return update_flags::failed;
- if ( child( pNode, left_child, memory_model::memory_order_relaxed ) == nullptr
- || child( pNode, right_child, memory_model::memory_order_relaxed ) == nullptr )
- {
+ if ( child( pNode, left_child ) == nullptr || child( pNode, right_child ) == nullptr ) {
node_type * pDamaged;
mapped_type pOld;
{
node_scoped_lock lp( m_Monitor, *pParent );
- if ( pParent->is_unlinked( atomics::memory_order_relaxed ) || parent( pNode, memory_model::memory_order_relaxed ) != pParent )
+ if ( pParent->is_unlinked( atomics::memory_order_relaxed ) || parent( pNode ) != pParent )
return update_flags::retry;
{
node_scoped_lock ln( m_Monitor, *pNode );
pOld = pNode->value( memory_model::memory_order_relaxed );
- if ( !( pNode->version( memory_model::memory_order_relaxed ) == nVersion
+ if ( !( pNode->version( memory_model::memory_order_acquire ) == nVersion
&& pOld
&& try_unlink_locked( pParent, pNode, disp )))
{
{
node_scoped_lock ln( m_Monitor, *pNode );
pOld = pNode->value( atomics::memory_order_relaxed );
- if ( pNode->version( atomics::memory_order_relaxed ) == nVersion && pOld ) {
+ if ( pNode->version( atomics::memory_order_acquire ) == nVersion && pOld ) {
pNode->m_pValue.store( nullptr, atomics::memory_order_relaxed );
result = update_flags::result_removed;
}
// pParent and pNode must be locked
assert( !pParent->is_unlinked(memory_model::memory_order_relaxed) );
- node_type * pParentLeft = child( pParent, left_child, memory_model::memory_order_relaxed );
- node_type * pParentRight = child( pParent, right_child, memory_model::memory_order_relaxed );
+ node_type * pParentLeft = child( pParent, left_child );
+ node_type * pParentRight = child( pParent, right_child );
if ( pNode != pParentLeft && pNode != pParentRight ) {
// node is no longer a child of parent
return false;
}
assert( !pNode->is_unlinked( memory_model::memory_order_relaxed ) );
- assert( pParent == parent( pNode, memory_model::memory_order_relaxed));
+ assert( pParent == parent( pNode ));
- node_type * pLeft = child( pNode, left_child, memory_model::memory_order_relaxed );
- node_type * pRight = child( pNode, right_child, memory_model::memory_order_relaxed );
+ node_type * pLeft = child( pNode, left_child );
+ node_type * pRight = child( pNode, right_child );
if ( pLeft != nullptr && pRight != nullptr ) {
// splicing is no longer possible
return false;
//@cond
int estimate_node_condition( node_type * pNode )
{
- node_type * pLeft = child( pNode, left_child, memory_model::memory_order_relaxed );
- node_type * pRight = child( pNode, right_child, memory_model::memory_order_relaxed );
+ node_type * pLeft = child( pNode, left_child );
+ node_type * pRight = child( pNode, right_child );
if ( (pLeft == nullptr || pRight == nullptr) && !pNode->is_valued( memory_model::memory_order_relaxed ))
return unlink_required;
- int h = pNode->height( memory_model::memory_order_relaxed );
- int hL = pLeft ? pLeft->height( memory_model::memory_order_relaxed ) : 0;
- int hR = pRight ? pRight->height( memory_model::memory_order_relaxed ) : 0;
+ int h = height( pNode );
+ int hL = height_null( pLeft );
+ int hR = height_null( pRight );
int hNew = 1 + std::max( hL, hR );
int nBalance = hL - hR;
case nothing_required:
return nullptr;
default:
- pNode->height( h, memory_model::memory_order_relaxed );
- return parent( pNode, memory_model::memory_order_relaxed );
+ set_height( pNode, h );
+ return parent( pNode );
}
}
void fix_height_and_rebalance( node_type * pNode, rcu_disposer& disp )
{
- while ( pNode && parent( pNode, memory_model::memory_order_relaxed )) {
+ while ( pNode && parent( pNode )) {
int nCond = estimate_node_condition( pNode );
if ( nCond == nothing_required || pNode->is_unlinked( memory_model::memory_order_relaxed ) )
return;
if ( nCond != unlink_required && nCond != rebalance_required )
pNode = fix_height( pNode );
else {
- node_type * pParent = parent( pNode, memory_model::memory_order_relaxed );
+ node_type * pParent = parent( pNode );
assert( pParent != nullptr );
{
node_scoped_lock lp( m_Monitor, *pParent );
- if ( !pParent->is_unlinked( memory_model::memory_order_relaxed )
- && parent( pNode, memory_model::memory_order_relaxed ) == pParent )
- {
+ if ( !pParent->is_unlinked( memory_model::memory_order_relaxed ) && parent( pNode ) == pParent ) {
node_scoped_lock ln( m_Monitor, *pNode );
pNode = rebalance_locked( pParent, pNode, disp );
}
{
// pParent and pNode should be locked.
// Returns a damaged node, or nullptr if no more rebalancing is necessary
- assert( parent( pNode, memory_model::memory_order_relaxed ) == pParent );
+ assert( parent( pNode ) == pParent );
- node_type * pLeft = child( pNode, left_child, memory_model::memory_order_relaxed );
- node_type * pRight = child( pNode, right_child, memory_model::memory_order_relaxed );
+ node_type * pLeft = child( pNode, left_child );
+ node_type * pRight = child( pNode, right_child );
if ( (pLeft == nullptr || pRight == nullptr) && !pNode->is_valued( memory_model::memory_order_relaxed )) {
if ( try_unlink_locked( pParent, pNode, disp ))
}
}
- assert( child( pParent, left_child, memory_model::memory_order_relaxed ) == pNode
- || child( pParent, right_child, memory_model::memory_order_relaxed ) == pNode );
+ assert( child( pParent, left_child ) == pNode || child( pParent, right_child ) == pNode );
- int h = pNode->height( memory_model::memory_order_relaxed );
- int hL = pLeft ? pLeft->height( memory_model::memory_order_relaxed ) : 0;
- int hR = pRight ? pRight->height( memory_model::memory_order_relaxed ) : 0;
+ int h = height( pNode );
+ int hL = height_null( pLeft );
+ int hR = height_null( pRight );
int hNew = 1 + std::max( hL, hR );
int balance = hL - hR;
else if ( balance < -1 )
return rebalance_to_left_locked( pParent, pNode, pRight, hL );
else if ( hNew != h ) {
- pNode->height( hNew, memory_model::memory_order_relaxed );
+ set_height( pNode, hNew );
// pParent is already locked
return fix_height_locked( pParent );
node_type * rebalance_to_right_locked( node_type * pParent, node_type * pNode, node_type * pLeft, int hR )
{
- assert( parent( pNode, memory_model::memory_order_relaxed ) == pParent );
- assert( child( pParent, left_child, memory_model::memory_order_relaxed ) == pNode
- || child( pParent, right_child, memory_model::memory_order_relaxed ) == pNode );
+ assert( parent( pNode ) == pParent );
+ assert( child( pParent, left_child ) == pNode || child( pParent, right_child ) == pNode );
// pParent and pNode is locked yet
// pNode->pLeft is too large, we will rotate-right.
if ( pNode->m_pLeft.load( memory_model::memory_order_relaxed ) != pLeft )
return pNode; // retry for pNode
- int hL = pLeft->height( memory_model::memory_order_relaxed );
+ int hL = height( pLeft );
if ( hL - hR <= 1 )
return pNode; // retry
- node_type * pLRight = child( pLeft, right_child, memory_model::memory_order_relaxed );
- int hLR = pLRight ? pLRight->height( memory_model::memory_order_relaxed ) : 0;
- node_type * pLLeft = child( pLeft, left_child, memory_model::memory_order_relaxed );
- int hLL = pLLeft ? pLLeft->height( memory_model::memory_order_relaxed ) : 0;
+ node_type * pLRight = child( pLeft, right_child );
+ int hLR = height_null( pLRight );
+ node_type * pLLeft = child( pLeft, left_child );
+ int hLL = height_null( pLLeft );
if ( hLL > hLR ) {
// rotate right
if ( pLeft->m_pRight.load( memory_model::memory_order_relaxed ) != pLRight )
return pNode; // retry
- hLR = pLRight->height( memory_model::memory_order_relaxed );
+ hLR = height( pLRight );
if ( hLL > hLR )
return rotate_right_locked( pParent, pNode, pLeft, hR, hLL, pLRight, hLR );
- node_type * pLRLeft = child( pLRight, left_child, memory_model::memory_order_relaxed );
- int hLRL = pLRLeft ? pLRLeft->height( memory_model::memory_order_relaxed ) : 0;
+ int hLRL = height_null( child( pLRight, left_child ));
int balance = hLL - hLRL;
if ( balance >= -1 && balance <= 1 && !((hLL == 0 || hLRL == 0) && !pLeft->is_valued(memory_model::memory_order_relaxed))) {
// nParent.child.left won't be damaged after a double rotation
node_type * rebalance_to_left_locked( node_type * pParent, node_type * pNode, node_type * pRight, int hL )
{
- assert( parent( pNode, memory_model::memory_order_relaxed ) == pParent );
- assert( child( pParent, left_child, memory_model::memory_order_relaxed ) == pNode
- || child( pParent, right_child, memory_model::memory_order_relaxed ) == pNode );
+ assert( parent( pNode ) == pParent );
+ assert( child( pParent, left_child ) == pNode || child( pParent, right_child ) == pNode );
// pParent and pNode is locked yet
{
if ( pNode->m_pRight.load( memory_model::memory_order_relaxed ) != pRight )
return pNode; // retry for pNode
- int hR = pRight->height( memory_model::memory_order_relaxed );
+ int hR = height( pRight );
if ( hL - hR >= -1 )
return pNode; // retry
- node_type * pRLeft = child( pRight, left_child, memory_model::memory_order_relaxed );
- int hRL = pRLeft ? pRLeft->height( memory_model::memory_order_relaxed ) : 0;
- node_type * pRRight = child( pRight, right_child, memory_model::memory_order_relaxed );
- int hRR = pRRight ? pRRight->height( memory_model::memory_order_relaxed ) : 0;
+ node_type * pRLeft = child( pRight, left_child );
+ int hRL = height_null( pRLeft );
+ node_type * pRRight = child( pRight, right_child );
+ int hRR = height_null( pRRight );
if ( hRR > hRL )
return rotate_left_locked( pParent, pNode, hL, pRight, pRLeft, hRL, hRR );
if ( pRight->m_pLeft.load( memory_model::memory_order_relaxed ) != pRLeft )
return pNode; // retry
- hRL = pRLeft->height( memory_model::memory_order_relaxed );
+ hRL = height( pRLeft );
if ( hRR >= hRL )
return rotate_left_locked( pParent, pNode, hL, pRight, pRLeft, hRL, hRR );
- node_type * pRLRight = child( pRLeft, right_child, memory_model::memory_order_relaxed );
- int hRLR = pRLRight ? pRLRight->height( memory_model::memory_order_relaxed ) : 0;
+ node_type * pRLRight = child( pRLeft, right_child );
+ int hRLR = height_null( pRLRight );
int balance = hRR - hRLR;
if ( balance >= -1 && balance <= 1 && !((hRR == 0 || hRLR == 0) && !pRight->is_valued( memory_model::memory_order_relaxed )))
return rotate_left_over_right_locked( pParent, pNode, hL, pRight, pRLeft, hRR, hRLR );
static void begin_change( node_type * pNode, version_type version )
{
+ assert(pNode->version(memory_model::memory_order_acquire) == version );
+ assert( (version & node_type::shrinking) == 0 );
pNode->version( version | node_type::shrinking, memory_model::memory_order_release );
}
static void end_change( node_type * pNode, version_type version )
node_type * rotate_right_locked( node_type * pParent, node_type * pNode, node_type * pLeft, int hR, int hLL, node_type * pLRight, int hLR )
{
- version_type nodeVersion = pNode->version( memory_model::memory_order_relaxed );
- node_type * pParentLeft = child( pParent, left_child, memory_model::memory_order_relaxed );
+ version_type nodeVersion = pNode->version( memory_model::memory_order_acquire );
+ node_type * pParentLeft = child( pParent, left_child );
begin_change( pNode, nodeVersion );
// fix up heights links
int hNode = 1 + std::max( hLR, hR );
- pNode->height( hNode, memory_model::memory_order_relaxed );
- pLeft->height( 1 + std::max( hLL, hNode ), memory_model::memory_order_relaxed );
+ set_height( pNode, hNode );
+ set_height( pLeft, 1 + std::max( hLL, hNode ));
end_change( pNode, nodeVersion );
m_stat.onRotateRight();
node_type * rotate_left_locked( node_type * pParent, node_type * pNode, int hL, node_type * pRight, node_type * pRLeft, int hRL, int hRR )
{
- version_type nodeVersion = pNode->version( memory_model::memory_order_relaxed );
- node_type * pParentLeft = child( pParent, left_child, memory_model::memory_order_relaxed );
+ version_type nodeVersion = pNode->version( memory_model::memory_order_acquire );
+ node_type * pParentLeft = child( pParent, left_child );
begin_change( pNode, nodeVersion );
// fix up heights
int hNode = 1 + std::max( hL, hRL );
- pNode->height( hNode, memory_model::memory_order_relaxed );
- pRight->height( 1 + std::max( hNode, hRR ), memory_model::memory_order_relaxed );
+ set_height( pNode, hNode );
+ set_height( pRight, 1 + std::max( hNode, hRR ));
end_change( pNode, nodeVersion );
m_stat.onRotateLeft();
node_type * rotate_right_over_left_locked( node_type * pParent, node_type * pNode, node_type * pLeft, int hR, int hLL, node_type * pLRight, int hLRL )
{
- version_type nodeVersion = pNode->version( memory_model::memory_order_relaxed );
- version_type leftVersion = pLeft->version( memory_model::memory_order_relaxed );
+ version_type nodeVersion = pNode->version( memory_model::memory_order_acquire );
+ version_type leftVersion = pLeft->version( memory_model::memory_order_acquire );
- node_type * pPL = child( pParent, left_child, memory_model::memory_order_relaxed );
- node_type * pLRL = child( pLRight, left_child, memory_model::memory_order_relaxed );
- node_type * pLRR = child( pLRight, right_child, memory_model::memory_order_relaxed );
- int hLRR = pLRR ? pLRR->height( memory_model::memory_order_relaxed ) : 0;
+ node_type * pPL = child( pParent, left_child );
+ node_type * pLRL = child( pLRight, left_child );
+ node_type * pLRR = child( pLRight, right_child );
+ int hLRR = height_null( pLRR );
begin_change( pNode, nodeVersion );
begin_change( pLeft, leftVersion );
if ( pPL == pNode )
pParent->m_pLeft.store( pLRight, memory_model::memory_order_relaxed );
else {
- assert( child( pParent, right_child, memory_model::memory_order_relaxed ) == pNode );
+ assert( child( pParent, right_child ) == pNode );
pParent->m_pRight.store( pLRight, memory_model::memory_order_relaxed );
}
pLRight->m_pParent.store( pParent, memory_model::memory_order_relaxed );
// fix up heights
int hNode = 1 + std::max( hLRR, hR );
- pNode->height( hNode, memory_model::memory_order_relaxed );
+ set_height( pNode, hNode );
int hLeft = 1 + std::max( hLL, hLRL );
- pLeft->height( hLeft, memory_model::memory_order_relaxed );
- pLRight->height( 1 + std::max( hLeft, hNode ), memory_model::memory_order_relaxed );
+ set_height( pLeft, hLeft );
+ set_height( pLRight, 1 + std::max( hLeft, hNode ));
end_change( pNode, nodeVersion );
end_change( pLeft, leftVersion );
node_type * rotate_left_over_right_locked( node_type * pParent, node_type * pNode, int hL, node_type * pRight, node_type * pRLeft, int hRR, int hRLR )
{
- version_type nodeVersion = pNode->version( memory_model::memory_order_relaxed );
- version_type rightVersion = pRight->version( memory_model::memory_order_relaxed );
+ version_type nodeVersion = pNode->version( memory_model::memory_order_acquire );
+ version_type rightVersion = pRight->version( memory_model::memory_order_acquire );
- node_type * pPL = child( pParent, left_child, memory_model::memory_order_relaxed );
- node_type * pRLL = child( pRLeft, left_child, memory_model::memory_order_relaxed );
- node_type * pRLR = child( pRLeft, right_child, memory_model::memory_order_relaxed );
- int hRLL = pRLL ? pRLL->height( memory_model::memory_order_relaxed ) : 0;
+ node_type * pPL = child( pParent, left_child );
+ node_type * pRLL = child( pRLeft, left_child );
+ node_type * pRLR = child( pRLeft, right_child );
+ int hRLL = height_null( pRLL );
begin_change( pNode, nodeVersion );
begin_change( pRight, rightVersion );
// fix up heights
int hNode = 1 + std::max( hL, hRLL );
- pNode->height( hNode, memory_model::memory_order_relaxed );
+ set_height( pNode, hNode );
int hRight = 1 + std::max( hRLR, hRR );
- pRight->height( hRight, memory_model::memory_order_relaxed );
- pRLeft->height( 1 + std::max( hNode, hRight ), memory_model::memory_order_relaxed );
+ set_height( pRight, hRight );
+ set_height( pRLeft, 1 + std::max( hNode, hRight ));
end_change( pNode, nodeVersion );
end_change( pRight, rightVersion );
</ItemGroup>\r
<ItemGroup>\r
<ClCompile Include="..\..\..\tests\unit\map2\map_delodd.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_delodd_bronsonavltree.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_delodd_cuckoo.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_delodd_ellentree.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_delodd_michael.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_delodd_skip.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_delodd_split.cpp" />\r
+ </ItemGroup>\r
+ <ItemGroup>\r
+ <ClInclude Include="..\..\..\tests\unit\map2\map_delodd.h" />\r
</ItemGroup>\r
<PropertyGroup Label="Globals">\r
<ProjectGuid>{3C598F96-FB84-4d42-9B43-F697F53B0221}</ProjectGuid>\r
<ItemGroup>\r
<ClCompile Include="..\..\..\tests\unit\map2\map_insdelfind.cpp" />\r
<ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func.cpp" />\r
- <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func2.cpp" />\r
- <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func3.cpp" />\r
- <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func4.cpp" />\r
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- <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func7.cpp" />\r
- <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func8.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func_bronsonavltree.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func_cuckoo.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func_ellentree.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func_michael.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func_refinable.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func_skip.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func_split.cpp" />\r
+ <ClCompile Include="..\..\..\tests\unit\map2\map_insdel_func_striped.cpp" />\r
<ClCompile Include="..\..\..\tests\unit\map2\map_insdel_int.cpp" />\r
<ClCompile Include="..\..\..\tests\unit\map2\map_insdel_item_int.cpp" />\r
<ClCompile Include="..\..\..\tests\unit\map2\map_insdel_item_string.cpp" />\r
tests/unit/map2/map_find_int.cpp \
tests/unit/map2/map_find_string.cpp \
tests/unit/map2/map_insdel_func.cpp \
- tests/unit/map2/map_insdel_func2.cpp \
- tests/unit/map2/map_insdel_func3.cpp \
- tests/unit/map2/map_insdel_func4.cpp \
- tests/unit/map2/map_insdel_func5.cpp \
- tests/unit/map2/map_insdel_func6.cpp \
- tests/unit/map2/map_insdel_func7.cpp \
- tests/unit/map2/map_insdel_func8.cpp \
+ tests/unit/map2/map_insdel_func_michael.cpp \
+ tests/unit/map2/map_insdel_func_split.cpp \
+ tests/unit/map2/map_insdel_func_skip.cpp \
+ tests/unit/map2/map_insdel_func_ellentree.cpp \
+ tests/unit/map2/map_insdel_func_bronsonavltree.cpp \
+ tests/unit/map2/map_insdel_func_striped.cpp \
+ tests/unit/map2/map_insdel_func_refinable.cpp \
+ tests/unit/map2/map_insdel_func_cuckoo.cpp \
tests/unit/map2/map_insdel_int.cpp \
tests/unit/map2/map_insdel_item_int.cpp \
tests/unit/map2/map_insdel_string.cpp \
tests/unit/map2/map_insdel_item_string.cpp \
tests/unit/map2/map_insfind_int.cpp \
tests/unit/map2/map_insdelfind.cpp \
- tests/unit/map2/map_delodd.cpp
+ tests/unit/map2/map_delodd.cpp \
+ tests/unit/map2/map_delodd_michael.cpp \
+ tests/unit/map2/map_delodd_bronsonavltree.cpp \
+ tests/unit/map2/map_delodd_ellentree.cpp \
+ tests/unit/map2/map_delodd_split.cpp \
+ tests/unit/map2/map_delodd_skip.cpp \
+ tests/unit/map2/map_delodd_cuckoo.cpp \
//$$CDS-header$$
-#include "cppunit/thread.h"
-#include "map2/map_types.h"
-#include <algorithm> // random_shuffle
+#include "map2/map_delodd.h"
namespace map2 {
+ CPPUNIT_TEST_SUITE_REGISTRATION( Map_DelOdd );
-# define TEST_MAP(X) void X() { test<MapTypes<key_type, value_type>::X >(); }
-# define TEST_MAP_EXTRACT(X) void X() { test_extract<MapTypes<key_type, value_type>::X >(); }
-# define TEST_MAP_NOLF(X) void X() { test_nolf<MapTypes<key_type, value_type>::X >(); }
-# define TEST_MAP_NOLF_EXTRACT(X) void X() { test_nolf_extract<MapTypes<key_type, value_type>::X >(); }
-
- namespace {
- static size_t c_nMapSize = 1000000 ; // max map size
- static size_t c_nInsThreadCount = 4 ; // insert thread count
- static size_t c_nDelThreadCount = 4 ; // delete thread count
- static size_t c_nExtractThreadCount = 4 ; // extract thread count
- static size_t c_nMaxLoadFactor = 8 ; // maximum load factor
- static bool c_bPrintGCState = true;
- }
-
- namespace {
- struct key_thread
- {
- size_t nKey;
- size_t nThread;
-
- key_thread( size_t key, size_t threadNo )
- : nKey( key )
- , nThread( threadNo )
- {}
-
- key_thread()
- {}
- };
-
- //typedef MapTypes<key_thread, size_t>::key_val key_value_pair;
+ size_t Map_DelOdd::c_nMapSize = 1000000 ; // max map size
+ size_t Map_DelOdd::c_nInsThreadCount = 4 ; // insert thread count
+ size_t Map_DelOdd::c_nDelThreadCount = 4 ; // delete thread count
+ size_t Map_DelOdd::c_nExtractThreadCount = 4 ; // extract thread count
+ size_t Map_DelOdd::c_nMaxLoadFactor = 8 ; // maximum load factor
+ bool Map_DelOdd::c_bPrintGCState = true;
+
+ void Map_DelOdd::setUpParams( const CppUnitMini::TestCfg& cfg ) {
+ c_nMapSize = cfg.getULong("MapSize", static_cast<unsigned long>(c_nMapSize) );
+ c_nInsThreadCount = cfg.getULong("InsThreadCount", static_cast<unsigned long>(c_nInsThreadCount) );
+ c_nDelThreadCount = cfg.getULong("DelThreadCount", static_cast<unsigned long>(c_nDelThreadCount) );
+ c_nExtractThreadCount = cfg.getULong("ExtractThreadCount", static_cast<unsigned long>(c_nExtractThreadCount) );
+ c_nMaxLoadFactor = cfg.getULong("MaxLoadFactor", static_cast<unsigned long>(c_nMaxLoadFactor) );
+ c_bPrintGCState = cfg.getBool("PrintGCStateFlag", true );
+
+ if ( c_nInsThreadCount == 0 )
+ c_nInsThreadCount = cds::OS::topology::processor_count();
+ if ( c_nDelThreadCount == 0 && c_nExtractThreadCount == 0 ) {
+ c_nExtractThreadCount = cds::OS::topology::processor_count() / 2;
+ c_nDelThreadCount = cds::OS::topology::processor_count() - c_nExtractThreadCount;
+ }
+
+ m_arrData.resize( c_nMapSize );
+ for ( size_t i = 0; i < c_nMapSize; ++i )
+ m_arrData[i] = i;
+ std::random_shuffle( m_arrData.begin(), m_arrData.end() );
}
- template <>
- struct cmp<key_thread> {
- int operator ()(key_thread const& k1, key_thread const& k2) const
- {
- if ( k1.nKey < k2.nKey )
- return -1;
- if ( k1.nKey > k2.nKey )
- return 1;
- if ( k1.nThread < k2.nThread )
- return -1;
- if ( k1.nThread > k2.nThread )
- return 1;
- return 0;
- }
- int operator ()(key_thread const& k1, size_t k2) const
- {
- if ( k1.nKey < k2 )
- return -1;
- if ( k1.nKey > k2 )
- return 1;
- return 0;
- }
- int operator ()(size_t k1, key_thread const& k2) const
- {
- if ( k1 < k2.nKey )
- return -1;
- if ( k1 > k2.nKey )
- return 1;
- return 0;
- }
- };
-
-} // namespace map2
-
-namespace std {
- template <>
- struct less<map2::key_thread>
- {
- bool operator()(map2::key_thread const& k1, map2::key_thread const& k2) const
- {
- if ( k1.nKey <= k2.nKey )
- return k1.nKey < k2.nKey || k1.nThread < k2.nThread;
- return false;
- }
- };
-
- template <>
- struct hash<map2::key_thread>
- {
- typedef size_t result_type;
- typedef map2::key_thread argument_type;
-
- size_t operator()( map2::key_thread const& k ) const
- {
- return std::hash<size_t>()(k.nKey);
- }
- size_t operator()( size_t k ) const
- {
- return std::hash<size_t>()(k);
- }
- };
-} // namespace std
-
-namespace boost {
- inline size_t hash_value( map2::key_thread const& k )
+ void Map_DelOdd::myRun(const char *in_name, bool invert /*= false*/)
{
- return std::hash<size_t>()( k.nKey );
+ setUpParams( m_Cfg.get( "Map_InsDel_func" ));
+
+ run_MichaelMap(in_name, invert);
+ run_SplitList(in_name, invert);
+ run_SkipListMap(in_name, invert);
+ run_EllenBinTreeMap(in_name, invert);
+ run_BronsonAVLTreeMap(in_name, invert);
+ //run_StripedMap(in_name, invert);
+ //run_RefinableMap(in_name, invert);
+ run_CuckooMap(in_name, invert);
+ //run_StdMap(in_name, invert);
+
+ endTestCase();
}
- template <>
- struct hash<map2::key_thread>
- {
- typedef size_t result_type;
- typedef map2::key_thread argument_type;
-
- size_t operator()(map2::key_thread const& k) const
- {
- return boost::hash<size_t>()( k.nKey );
- }
- size_t operator()(size_t k) const
- {
- return boost::hash<size_t>()( k );
- }
- };
-} // namespace boost
-
-namespace map2 {
-
- class Map_DelOdd: public CppUnitMini::TestCase
- {
- std::vector<size_t> m_arrData;
-
- protected:
- typedef key_thread key_type;
- typedef size_t value_type;
- typedef std::pair<key_type const, value_type> pair_type;
-
- atomics::atomic<size_t> m_nInsThreadCount;
-
- // Inserts keys from [0..N)
- template <class Map>
- class InsertThread: public CppUnitMini::TestThread
- {
- Map& m_Map;
-
- virtual InsertThread * clone()
- {
- return new InsertThread( *this );
- }
-
- struct ensure_func
- {
- template <typename Q>
- void operator()( bool /*bNew*/, Q const& )
- {}
- template <typename Q, typename V>
- void operator()( bool /*bNew*/, Q const&, V& )
- {}
- };
- public:
- size_t m_nInsertSuccess;
- size_t m_nInsertFailed;
-
- public:
- InsertThread( CppUnitMini::ThreadPool& pool, Map& rMap )
- : CppUnitMini::TestThread( pool )
- , m_Map( rMap )
- {}
- InsertThread( InsertThread& src )
- : CppUnitMini::TestThread( src )
- , m_Map( src.m_Map )
- {}
-
- Map_DelOdd& getTest()
- {
- return reinterpret_cast<Map_DelOdd&>( m_Pool.m_Test );
- }
-
- virtual void init() { cds::threading::Manager::attachThread() ; }
- virtual void fini() { cds::threading::Manager::detachThread() ; }
-
- virtual void test()
- {
- Map& rMap = m_Map;
-
- m_nInsertSuccess =
- m_nInsertFailed = 0;
-
- std::vector<size_t>& arrData = getTest().m_arrData;
- for ( size_t i = 0; i < arrData.size(); ++i ) {
- if ( rMap.insert( key_type( arrData[i], m_nThreadNo )))
- ++m_nInsertSuccess;
- else
- ++m_nInsertFailed;
- }
-
- ensure_func f;
- for ( size_t i = arrData.size() - 1; i > 0; --i ) {
- if ( arrData[i] & 1 ) {
- rMap.ensure( key_type( arrData[i], m_nThreadNo ), f );
- }
- }
-
- getTest().m_nInsThreadCount.fetch_sub( 1, atomics::memory_order_acquire );
- }
- };
-
- struct key_equal {
- bool operator()( key_type const& k1, key_type const& k2 ) const
- {
- return k1.nKey == k2.nKey;
- }
- bool operator()( size_t k1, key_type const& k2 ) const
- {
- return k1 == k2.nKey;
- }
- bool operator()( key_type const& k1, size_t k2 ) const
- {
- return k1.nKey == k2;
- }
- };
-
- struct key_less {
- bool operator()( key_type const& k1, key_type const& k2 ) const
- {
- return k1.nKey < k2.nKey;
- }
- bool operator()( size_t k1, key_type const& k2 ) const
- {
- return k1 < k2.nKey;
- }
- bool operator()( key_type const& k1, size_t k2 ) const
- {
- return k1.nKey < k2;
- }
-
- typedef key_equal equal_to;
- };
-
- // Deletes odd keys from [0..N)
- template <class Map>
- class DeleteThread: public CppUnitMini::TestThread
- {
- Map& m_Map;
-
- virtual DeleteThread * clone()
- {
- return new DeleteThread( *this );
- }
- public:
- size_t m_nDeleteSuccess;
- size_t m_nDeleteFailed;
-
- public:
- DeleteThread( CppUnitMini::ThreadPool& pool, Map& rMap )
- : CppUnitMini::TestThread( pool )
- , m_Map( rMap )
- {}
- DeleteThread( DeleteThread& src )
- : CppUnitMini::TestThread( src )
- , m_Map( src.m_Map )
- {}
-
- Map_DelOdd& getTest()
- {
- return reinterpret_cast<Map_DelOdd&>( m_Pool.m_Test );
- }
-
- virtual void init() { cds::threading::Manager::attachThread() ; }
- virtual void fini() { cds::threading::Manager::detachThread() ; }
-
- virtual void test()
- {
- Map& rMap = m_Map;
-
- m_nDeleteSuccess =
- m_nDeleteFailed = 0;
-
- std::vector<size_t>& arrData = getTest().m_arrData;
- if ( m_nThreadNo & 1 ) {
- for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
- for ( size_t i = 0; i < arrData.size(); ++i ) {
- if ( arrData[i] & 1 ) {
- if ( rMap.erase_with( arrData[i], key_less() ))
- ++m_nDeleteSuccess;
- else
- ++m_nDeleteFailed;
- }
- }
- if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
- break;
- }
- }
- else {
- for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
- for ( size_t i = arrData.size() - 1; i > 0; --i ) {
- if ( arrData[i] & 1 ) {
- if ( rMap.erase_with( arrData[i], key_less() ))
- ++m_nDeleteSuccess;
- else
- ++m_nDeleteFailed;
- }
- }
- if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
- break;
- }
- }
- }
- };
-
- // Deletes odd keys from [0..N)
- template <class GC, class Map >
- class ExtractThread: public CppUnitMini::TestThread
- {
- Map& m_Map;
-
- virtual ExtractThread * clone()
- {
- return new ExtractThread( *this );
- }
- public:
- size_t m_nDeleteSuccess;
- size_t m_nDeleteFailed;
-
- public:
- ExtractThread( CppUnitMini::ThreadPool& pool, Map& rMap )
- : CppUnitMini::TestThread( pool )
- , m_Map( rMap )
- {}
- ExtractThread( ExtractThread& src )
- : CppUnitMini::TestThread( src )
- , m_Map( src.m_Map )
- {}
-
- Map_DelOdd& getTest()
- {
- return reinterpret_cast<Map_DelOdd&>( m_Pool.m_Test );
- }
-
- virtual void init() { cds::threading::Manager::attachThread() ; }
- virtual void fini() { cds::threading::Manager::detachThread() ; }
-
- virtual void test()
- {
- Map& rMap = m_Map;
-
- m_nDeleteSuccess =
- m_nDeleteFailed = 0;
-
- typename Map::guarded_ptr gp;
-
- std::vector<size_t>& arrData = getTest().m_arrData;
- if ( m_nThreadNo & 1 ) {
- for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
- for ( size_t i = 0; i < arrData.size(); ++i ) {
- if ( arrData[i] & 1 ) {
- gp = rMap.extract_with( arrData[i], key_less());
- if ( gp )
- ++m_nDeleteSuccess;
- else
- ++m_nDeleteFailed;
- gp.release();
- }
- }
- if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
- break;
- }
- }
- else {
- for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
- for ( size_t i = arrData.size() - 1; i > 0; --i ) {
- if ( arrData[i] & 1 ) {
- gp = rMap.extract_with( arrData[i], key_less());
- if ( gp )
- ++m_nDeleteSuccess;
- else
- ++m_nDeleteFailed;
- gp.release();
- }
- }
- if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
- break;
- }
- }
- }
- };
-
- template <class RCU, class Map >
- class ExtractThread< cds::urcu::gc<RCU>, Map > : public CppUnitMini::TestThread
- {
- Map& m_Map;
-
- virtual ExtractThread * clone()
- {
- return new ExtractThread( *this );
- }
- public:
- size_t m_nDeleteSuccess;
- size_t m_nDeleteFailed;
-
- public:
- ExtractThread( CppUnitMini::ThreadPool& pool, Map& rMap )
- : CppUnitMini::TestThread( pool )
- , m_Map( rMap )
- {}
- ExtractThread( ExtractThread& src )
- : CppUnitMini::TestThread( src )
- , m_Map( src.m_Map )
- {}
-
- Map_DelOdd& getTest()
- {
- return reinterpret_cast<Map_DelOdd&>( m_Pool.m_Test );
- }
-
- virtual void init() { cds::threading::Manager::attachThread() ; }
- virtual void fini() { cds::threading::Manager::detachThread() ; }
-
- virtual void test()
- {
- Map& rMap = m_Map;
-
- m_nDeleteSuccess =
- m_nDeleteFailed = 0;
-
- typename Map::exempt_ptr xp;
-
- std::vector<size_t>& arrData = getTest().m_arrData;
- if ( m_nThreadNo & 1 ) {
- for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
- for ( size_t i = 0; i < arrData.size(); ++i ) {
- if ( arrData[i] & 1 ) {
- if ( Map::c_bExtractLockExternal ) {
- {
- typename Map::rcu_lock l;
- xp = rMap.extract_with( arrData[i], key_less() );
- if ( xp )
- ++m_nDeleteSuccess;
- else
- ++m_nDeleteFailed;
- }
- }
- else {
- xp = rMap.extract_with( arrData[i], key_less() );
- if ( xp )
- ++m_nDeleteSuccess;
- else
- ++m_nDeleteFailed;
- }
- xp.release();
- }
- }
- if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
- break;
- }
- }
- else {
- for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
- for ( size_t i = arrData.size() - 1; i > 0; --i ) {
- if ( arrData[i] & 1 ) {
- if ( Map::c_bExtractLockExternal ) {
- {
- typename Map::rcu_lock l;
- xp = rMap.extract_with( arrData[i], key_less() );
- if ( xp )
- ++m_nDeleteSuccess;
- else
- ++m_nDeleteFailed;
- }
- }
- else {
- xp = rMap.extract_with( arrData[i], key_less() );
- if ( xp )
- ++m_nDeleteSuccess;
- else
- ++m_nDeleteFailed;
- }
- xp.release();
- }
- }
- if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
- break;
- }
- }
- }
- };
-
- protected:
- template <class Map>
- void do_test( size_t nLoadFactor )
- {
- Map testMap( c_nMapSize, nLoadFactor );
- do_test_with( testMap );
- }
-
- template <class Map>
- void do_test_extract( size_t nLoadFactor )
- {
- Map testMap( c_nMapSize, nLoadFactor );
- do_test_extract_with( testMap );
- }
-
- template <class Map>
- void do_test_with( Map& testMap )
- {
- typedef InsertThread<Map> insert_thread;
- typedef DeleteThread<Map> delete_thread;
-
- m_nInsThreadCount.store( c_nInsThreadCount, atomics::memory_order_release );
-
- CppUnitMini::ThreadPool pool( *this );
- pool.add( new insert_thread( pool, testMap ), c_nInsThreadCount );
- pool.add( new delete_thread( pool, testMap ), c_nDelThreadCount ? c_nDelThreadCount : cds::OS::topology::processor_count());
- pool.run();
- CPPUNIT_MSG( " Duration=" << pool.avgDuration() );
-
- size_t nInsertSuccess = 0;
- size_t nInsertFailed = 0;
- size_t nDeleteSuccess = 0;
- size_t nDeleteFailed = 0;
- for ( CppUnitMini::ThreadPool::iterator it = pool.begin(); it != pool.end(); ++it ) {
- insert_thread * pThread = dynamic_cast<insert_thread *>( *it );
- if ( pThread ) {
- nInsertSuccess += pThread->m_nInsertSuccess;
- nInsertFailed += pThread->m_nInsertFailed;
- }
- else {
- delete_thread * p = static_cast<delete_thread *>( *it );
- nDeleteSuccess += p->m_nDeleteSuccess;
- nDeleteFailed += p->m_nDeleteFailed;
- }
- }
-
- CPPUNIT_MSG( " Totals (success/failed): \n\t"
- << " Insert=" << nInsertSuccess << '/' << nInsertFailed << "\n\t"
- << " Delete=" << nDeleteSuccess << '/' << nDeleteFailed << "\n\t"
- );
- CPPUNIT_CHECK( nInsertSuccess == c_nMapSize * c_nInsThreadCount );
- CPPUNIT_CHECK( nInsertFailed == 0 );
-
- analyze( testMap );
- }
-
- template <class Map>
- void do_test_extract_with( Map& testMap )
- {
- typedef InsertThread<Map> insert_thread;
- typedef DeleteThread<Map> delete_thread;
- typedef ExtractThread< typename Map::gc, Map > extract_thread;
-
- m_nInsThreadCount.store( c_nInsThreadCount, atomics::memory_order_release );
-
- CppUnitMini::ThreadPool pool( *this );
- pool.add( new insert_thread( pool, testMap ), c_nInsThreadCount );
- if ( c_nDelThreadCount )
- pool.add( new delete_thread( pool, testMap ), c_nDelThreadCount );
- if ( c_nExtractThreadCount )
- pool.add( new extract_thread( pool, testMap ), c_nExtractThreadCount );
- pool.run();
- CPPUNIT_MSG( " Duration=" << pool.avgDuration() );
-
- size_t nInsertSuccess = 0;
- size_t nInsertFailed = 0;
- size_t nDeleteSuccess = 0;
- size_t nDeleteFailed = 0;
- size_t nExtractSuccess = 0;
- size_t nExtractFailed = 0;
- for ( CppUnitMini::ThreadPool::iterator it = pool.begin(); it != pool.end(); ++it ) {
- insert_thread * pThread = dynamic_cast<insert_thread *>( *it );
- if ( pThread ) {
- nInsertSuccess += pThread->m_nInsertSuccess;
- nInsertFailed += pThread->m_nInsertFailed;
- }
- else {
- delete_thread * p = dynamic_cast<delete_thread *>( *it );
- if ( p ) {
- nDeleteSuccess += p->m_nDeleteSuccess;
- nDeleteFailed += p->m_nDeleteFailed;
- }
- else {
- extract_thread * pExtract = dynamic_cast<extract_thread *>( *it );
- assert( pExtract );
- nExtractSuccess += pExtract->m_nDeleteSuccess;
- nExtractFailed += pExtract->m_nDeleteFailed;
- }
- }
- }
-
- CPPUNIT_MSG( " Totals (success/failed): \n\t"
- << " Insert=" << nInsertSuccess << '/' << nInsertFailed << "\n\t"
- << " Delete=" << nDeleteSuccess << '/' << nDeleteFailed << "\n\t"
- << " Extract=" << nExtractSuccess << '/' << nExtractFailed << "\n\t"
- );
- CPPUNIT_CHECK( nInsertSuccess == c_nMapSize * c_nInsThreadCount );
- CPPUNIT_CHECK( nInsertFailed == 0 );
-
- analyze( testMap );
- }
-
- template <class Map>
- void analyze( Map& testMap )
- {
- cds::OS::Timer timer;
-
- // All even keys must be in the map
- {
- size_t nErrorCount = 0;
- CPPUNIT_MSG( " Check even keys..." );
- for ( size_t n = 0; n < c_nMapSize; n +=2 ) {
- for ( size_t i = 0; i < c_nInsThreadCount; ++i ) {
- if ( !testMap.find( key_type(n, i) ) ) {
- if ( ++nErrorCount < 10 ) {
- CPPUNIT_MSG( "key " << n << "-" << i << " is not found!");
- }
- }
- }
- }
- CPPUNIT_CHECK_EX( nErrorCount == 0, "Totals: " << nErrorCount << " keys is not found");
- }
-
- check_before_cleanup( testMap );
-
- CPPUNIT_MSG( " Clear map (single-threaded)..." );
- timer.reset();
- testMap.clear();
- CPPUNIT_MSG( " Duration=" << timer.duration() );
- CPPUNIT_CHECK_EX( testMap.empty(), ((long long) testMap.size()) );
-
- additional_check( testMap );
- print_stat( testMap );
-
- additional_cleanup( testMap );
- }
-
-
- template <class Map>
- void test()
- {
- CPPUNIT_MSG( "Insert thread count=" << c_nInsThreadCount
- << " delete thread count=" << c_nDelThreadCount
- << " set size=" << c_nMapSize
- );
-
- for ( size_t nLoadFactor = 1; nLoadFactor <= c_nMaxLoadFactor; nLoadFactor *= 2 ) {
- CPPUNIT_MSG( "Load factor=" << nLoadFactor );
- do_test<Map>( nLoadFactor );
- if ( c_bPrintGCState )
- print_gc_state();
- }
- }
-
- template <class Map>
- void test_extract()
- {
- CPPUNIT_MSG( "Thread count: insert=" << c_nInsThreadCount
- << ", delete=" << c_nDelThreadCount
- << ", extract=" << c_nExtractThreadCount
- << "; set size=" << c_nMapSize
- );
-
- for ( size_t nLoadFactor = 1; nLoadFactor <= c_nMaxLoadFactor; nLoadFactor *= 2 ) {
- CPPUNIT_MSG( "Load factor=" << nLoadFactor );
- do_test_extract<Map>( nLoadFactor );
- if ( c_bPrintGCState )
- print_gc_state();
- }
- }
-
- template <class Map>
- void test_nolf()
- {
- CPPUNIT_MSG( "Insert thread count=" << c_nInsThreadCount
- << " delete thread count=" << c_nDelThreadCount
- << " set size=" << c_nMapSize
- );
-
- Map s;
- do_test_with( s );
- if ( c_bPrintGCState )
- print_gc_state();
- }
-
- template <class Map>
- void test_nolf_extract()
- {
- CPPUNIT_MSG( "Thread count: insert=" << c_nInsThreadCount
- << ", delete=" << c_nDelThreadCount
- << ", extract=" << c_nExtractThreadCount
- << "; set size=" << c_nMapSize
- );
-
- Map s;
- do_test_extract_with( s );
- if ( c_bPrintGCState )
- print_gc_state();
- }
-
- void setUpParams( const CppUnitMini::TestCfg& cfg ) {
- c_nMapSize = cfg.getULong("MapSize", static_cast<unsigned long>(c_nMapSize) );
- c_nInsThreadCount = cfg.getULong("InsThreadCount", static_cast<unsigned long>(c_nInsThreadCount) );
- c_nDelThreadCount = cfg.getULong("DelThreadCount", static_cast<unsigned long>(c_nDelThreadCount) );
- c_nExtractThreadCount = cfg.getULong("ExtractThreadCount", static_cast<unsigned long>(c_nExtractThreadCount) );
- c_nMaxLoadFactor = cfg.getULong("MaxLoadFactor", static_cast<unsigned long>(c_nMaxLoadFactor) );
- c_bPrintGCState = cfg.getBool("PrintGCStateFlag", true );
-
- if ( c_nInsThreadCount == 0 )
- c_nInsThreadCount = cds::OS::topology::processor_count();
- if ( c_nDelThreadCount == 0 && c_nExtractThreadCount == 0 ) {
- c_nExtractThreadCount = cds::OS::topology::processor_count() / 2;
- c_nDelThreadCount = cds::OS::topology::processor_count() - c_nExtractThreadCount;
- }
-
- m_arrData.resize( c_nMapSize );
- for ( size_t i = 0; i < c_nMapSize; ++i )
- m_arrData[i] = i;
- std::random_shuffle( m_arrData.begin(), m_arrData.end() );
- }
-
-# include "map2/map_defs.h"
- CDSUNIT_DECLARE_MichaelMap
- CDSUNIT_DECLARE_SplitList
- //CDSUNIT_DECLARE_StripedMap
- //CDSUNIT_DECLARE_RefinableMap
- CDSUNIT_DECLARE_CuckooMap
- CDSUNIT_DECLARE_SkipListMap
- CDSUNIT_DECLARE_EllenBinTreeMap
- CDSUNIT_DECLARE_BronsonAVLTreeMap
- //CDSUNIT_DECLARE_StdMap
-
- CPPUNIT_TEST_SUITE( Map_DelOdd )
- CDSUNIT_TEST_MichaelMap
- CDSUNIT_TEST_SplitList
- CDSUNIT_TEST_SkipListMap
- CDSUNIT_TEST_EllenBinTreeMap
- CDSUNIT_TEST_BronsonAVLTreeMap
- //CDSUNIT_TEST_StripedMap
- //CDSUNIT_TEST_RefinableMap
- CDSUNIT_TEST_CuckooMap
- //CDSUNIT_TEST_StdMap
- CPPUNIT_TEST_SUITE_END()
- };
-
- CPPUNIT_TEST_SUITE_REGISTRATION( Map_DelOdd );
} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "cppunit/thread.h"
+#include "map2/map_types.h"
+#include <algorithm> // random_shuffle
+
+namespace map2 {
+
+# define TEST_MAP(X) void X() { test<MapTypes<key_type, value_type>::X >(); }
+# define TEST_MAP_EXTRACT(X) void X() { test_extract<MapTypes<key_type, value_type>::X >(); }
+# define TEST_MAP_NOLF(X) void X() { test_nolf<MapTypes<key_type, value_type>::X >(); }
+# define TEST_MAP_NOLF_EXTRACT(X) void X() { test_nolf_extract<MapTypes<key_type, value_type>::X >(); }
+
+ namespace {
+ struct key_thread
+ {
+ size_t nKey;
+ size_t nThread;
+
+ key_thread( size_t key, size_t threadNo )
+ : nKey( key )
+ , nThread( threadNo )
+ {}
+
+ key_thread()
+ {}
+ };
+
+ //typedef MapTypes<key_thread, size_t>::key_val key_value_pair;
+ }
+
+ template <>
+ struct cmp<key_thread> {
+ int operator ()(key_thread const& k1, key_thread const& k2) const
+ {
+ if ( k1.nKey < k2.nKey )
+ return -1;
+ if ( k1.nKey > k2.nKey )
+ return 1;
+ if ( k1.nThread < k2.nThread )
+ return -1;
+ if ( k1.nThread > k2.nThread )
+ return 1;
+ return 0;
+ }
+ int operator ()(key_thread const& k1, size_t k2) const
+ {
+ if ( k1.nKey < k2 )
+ return -1;
+ if ( k1.nKey > k2 )
+ return 1;
+ return 0;
+ }
+ int operator ()(size_t k1, key_thread const& k2) const
+ {
+ if ( k1 < k2.nKey )
+ return -1;
+ if ( k1 > k2.nKey )
+ return 1;
+ return 0;
+ }
+ };
+
+} // namespace map2
+
+namespace std {
+ template <>
+ struct less<map2::key_thread>
+ {
+ bool operator()(map2::key_thread const& k1, map2::key_thread const& k2) const
+ {
+ if ( k1.nKey <= k2.nKey )
+ return k1.nKey < k2.nKey || k1.nThread < k2.nThread;
+ return false;
+ }
+ };
+
+ template <>
+ struct hash<map2::key_thread>
+ {
+ typedef size_t result_type;
+ typedef map2::key_thread argument_type;
+
+ size_t operator()( map2::key_thread const& k ) const
+ {
+ return std::hash<size_t>()(k.nKey);
+ }
+ size_t operator()( size_t k ) const
+ {
+ return std::hash<size_t>()(k);
+ }
+ };
+} // namespace std
+
+namespace boost {
+ inline size_t hash_value( map2::key_thread const& k )
+ {
+ return std::hash<size_t>()( k.nKey );
+ }
+
+ template <>
+ struct hash<map2::key_thread>
+ {
+ typedef size_t result_type;
+ typedef map2::key_thread argument_type;
+
+ size_t operator()(map2::key_thread const& k) const
+ {
+ return boost::hash<size_t>()( k.nKey );
+ }
+ size_t operator()(size_t k) const
+ {
+ return boost::hash<size_t>()( k );
+ }
+ };
+} // namespace boost
+
+namespace map2 {
+
+ class Map_DelOdd: public CppUnitMini::TestCase
+ {
+ static size_t c_nMapSize; // max map size
+ static size_t c_nInsThreadCount; // insert thread count
+ static size_t c_nDelThreadCount; // delete thread count
+ static size_t c_nExtractThreadCount; // extract thread count
+ static size_t c_nMaxLoadFactor; // maximum load factor
+ static bool c_bPrintGCState;
+
+ std::vector<size_t> m_arrData;
+
+ protected:
+ typedef CppUnitMini::TestCase Base;
+
+ typedef key_thread key_type;
+ typedef size_t value_type;
+ typedef std::pair<key_type const, value_type> pair_type;
+
+ atomics::atomic<size_t> m_nInsThreadCount;
+
+ // Inserts keys from [0..N)
+ template <class Map>
+ class InsertThread: public CppUnitMini::TestThread
+ {
+ Map& m_Map;
+
+ virtual InsertThread * clone()
+ {
+ return new InsertThread( *this );
+ }
+
+ struct ensure_func
+ {
+ template <typename Q>
+ void operator()( bool /*bNew*/, Q const& )
+ {}
+ template <typename Q, typename V>
+ void operator()( bool /*bNew*/, Q const&, V& )
+ {}
+ };
+ public:
+ size_t m_nInsertSuccess;
+ size_t m_nInsertFailed;
+
+ public:
+ InsertThread( CppUnitMini::ThreadPool& pool, Map& rMap )
+ : CppUnitMini::TestThread( pool )
+ , m_Map( rMap )
+ {}
+ InsertThread( InsertThread& src )
+ : CppUnitMini::TestThread( src )
+ , m_Map( src.m_Map )
+ {}
+
+ Map_DelOdd& getTest()
+ {
+ return reinterpret_cast<Map_DelOdd&>( m_Pool.m_Test );
+ }
+
+ virtual void init() { cds::threading::Manager::attachThread() ; }
+ virtual void fini() { cds::threading::Manager::detachThread() ; }
+
+ virtual void test()
+ {
+ Map& rMap = m_Map;
+
+ m_nInsertSuccess =
+ m_nInsertFailed = 0;
+
+ std::vector<size_t>& arrData = getTest().m_arrData;
+ for ( size_t i = 0; i < arrData.size(); ++i ) {
+ if ( rMap.insert( key_type( arrData[i], m_nThreadNo )))
+ ++m_nInsertSuccess;
+ else
+ ++m_nInsertFailed;
+ }
+
+ ensure_func f;
+ for ( size_t i = arrData.size() - 1; i > 0; --i ) {
+ if ( arrData[i] & 1 ) {
+ rMap.ensure( key_type( arrData[i], m_nThreadNo ), f );
+ }
+ }
+
+ getTest().m_nInsThreadCount.fetch_sub( 1, atomics::memory_order_acquire );
+ }
+ };
+
+ struct key_equal {
+ bool operator()( key_type const& k1, key_type const& k2 ) const
+ {
+ return k1.nKey == k2.nKey;
+ }
+ bool operator()( size_t k1, key_type const& k2 ) const
+ {
+ return k1 == k2.nKey;
+ }
+ bool operator()( key_type const& k1, size_t k2 ) const
+ {
+ return k1.nKey == k2;
+ }
+ };
+
+ struct key_less {
+ bool operator()( key_type const& k1, key_type const& k2 ) const
+ {
+ return k1.nKey < k2.nKey;
+ }
+ bool operator()( size_t k1, key_type const& k2 ) const
+ {
+ return k1 < k2.nKey;
+ }
+ bool operator()( key_type const& k1, size_t k2 ) const
+ {
+ return k1.nKey < k2;
+ }
+
+ typedef key_equal equal_to;
+ };
+
+ // Deletes odd keys from [0..N)
+ template <class Map>
+ class DeleteThread: public CppUnitMini::TestThread
+ {
+ Map& m_Map;
+
+ virtual DeleteThread * clone()
+ {
+ return new DeleteThread( *this );
+ }
+ public:
+ size_t m_nDeleteSuccess;
+ size_t m_nDeleteFailed;
+
+ public:
+ DeleteThread( CppUnitMini::ThreadPool& pool, Map& rMap )
+ : CppUnitMini::TestThread( pool )
+ , m_Map( rMap )
+ {}
+ DeleteThread( DeleteThread& src )
+ : CppUnitMini::TestThread( src )
+ , m_Map( src.m_Map )
+ {}
+
+ Map_DelOdd& getTest()
+ {
+ return reinterpret_cast<Map_DelOdd&>( m_Pool.m_Test );
+ }
+
+ virtual void init() { cds::threading::Manager::attachThread() ; }
+ virtual void fini() { cds::threading::Manager::detachThread() ; }
+
+ virtual void test()
+ {
+ Map& rMap = m_Map;
+
+ m_nDeleteSuccess =
+ m_nDeleteFailed = 0;
+
+ std::vector<size_t>& arrData = getTest().m_arrData;
+ if ( m_nThreadNo & 1 ) {
+ for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
+ for ( size_t i = 0; i < arrData.size(); ++i ) {
+ if ( arrData[i] & 1 ) {
+ if ( rMap.erase_with( arrData[i], key_less() ))
+ ++m_nDeleteSuccess;
+ else
+ ++m_nDeleteFailed;
+ }
+ }
+ if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
+ break;
+ }
+ }
+ else {
+ for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
+ for ( size_t i = arrData.size() - 1; i > 0; --i ) {
+ if ( arrData[i] & 1 ) {
+ if ( rMap.erase_with( arrData[i], key_less() ))
+ ++m_nDeleteSuccess;
+ else
+ ++m_nDeleteFailed;
+ }
+ }
+ if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
+ break;
+ }
+ }
+ }
+ };
+
+ // Deletes odd keys from [0..N)
+ template <class GC, class Map >
+ class ExtractThread: public CppUnitMini::TestThread
+ {
+ Map& m_Map;
+
+ virtual ExtractThread * clone()
+ {
+ return new ExtractThread( *this );
+ }
+ public:
+ size_t m_nDeleteSuccess;
+ size_t m_nDeleteFailed;
+
+ public:
+ ExtractThread( CppUnitMini::ThreadPool& pool, Map& rMap )
+ : CppUnitMini::TestThread( pool )
+ , m_Map( rMap )
+ {}
+ ExtractThread( ExtractThread& src )
+ : CppUnitMini::TestThread( src )
+ , m_Map( src.m_Map )
+ {}
+
+ Map_DelOdd& getTest()
+ {
+ return reinterpret_cast<Map_DelOdd&>( m_Pool.m_Test );
+ }
+
+ virtual void init() { cds::threading::Manager::attachThread() ; }
+ virtual void fini() { cds::threading::Manager::detachThread() ; }
+
+ virtual void test()
+ {
+ Map& rMap = m_Map;
+
+ m_nDeleteSuccess =
+ m_nDeleteFailed = 0;
+
+ typename Map::guarded_ptr gp;
+
+ std::vector<size_t>& arrData = getTest().m_arrData;
+ if ( m_nThreadNo & 1 ) {
+ for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
+ for ( size_t i = 0; i < arrData.size(); ++i ) {
+ if ( arrData[i] & 1 ) {
+ gp = rMap.extract_with( arrData[i], key_less());
+ if ( gp )
+ ++m_nDeleteSuccess;
+ else
+ ++m_nDeleteFailed;
+ gp.release();
+ }
+ }
+ if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
+ break;
+ }
+ }
+ else {
+ for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
+ for ( size_t i = arrData.size() - 1; i > 0; --i ) {
+ if ( arrData[i] & 1 ) {
+ gp = rMap.extract_with( arrData[i], key_less());
+ if ( gp )
+ ++m_nDeleteSuccess;
+ else
+ ++m_nDeleteFailed;
+ gp.release();
+ }
+ }
+ if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
+ break;
+ }
+ }
+ }
+ };
+
+ template <class RCU, class Map >
+ class ExtractThread< cds::urcu::gc<RCU>, Map > : public CppUnitMini::TestThread
+ {
+ Map& m_Map;
+
+ virtual ExtractThread * clone()
+ {
+ return new ExtractThread( *this );
+ }
+ public:
+ size_t m_nDeleteSuccess;
+ size_t m_nDeleteFailed;
+
+ public:
+ ExtractThread( CppUnitMini::ThreadPool& pool, Map& rMap )
+ : CppUnitMini::TestThread( pool )
+ , m_Map( rMap )
+ {}
+ ExtractThread( ExtractThread& src )
+ : CppUnitMini::TestThread( src )
+ , m_Map( src.m_Map )
+ {}
+
+ Map_DelOdd& getTest()
+ {
+ return reinterpret_cast<Map_DelOdd&>( m_Pool.m_Test );
+ }
+
+ virtual void init() { cds::threading::Manager::attachThread() ; }
+ virtual void fini() { cds::threading::Manager::detachThread() ; }
+
+ virtual void test()
+ {
+ Map& rMap = m_Map;
+
+ m_nDeleteSuccess =
+ m_nDeleteFailed = 0;
+
+ typename Map::exempt_ptr xp;
+
+ std::vector<size_t>& arrData = getTest().m_arrData;
+ if ( m_nThreadNo & 1 ) {
+ for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
+ for ( size_t i = 0; i < arrData.size(); ++i ) {
+ if ( arrData[i] & 1 ) {
+ if ( Map::c_bExtractLockExternal ) {
+ {
+ typename Map::rcu_lock l;
+ xp = rMap.extract_with( arrData[i], key_less() );
+ if ( xp )
+ ++m_nDeleteSuccess;
+ else
+ ++m_nDeleteFailed;
+ }
+ }
+ else {
+ xp = rMap.extract_with( arrData[i], key_less() );
+ if ( xp )
+ ++m_nDeleteSuccess;
+ else
+ ++m_nDeleteFailed;
+ }
+ xp.release();
+ }
+ }
+ if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
+ break;
+ }
+ }
+ else {
+ for ( size_t k = 0; k < c_nInsThreadCount; ++k ) {
+ for ( size_t i = arrData.size() - 1; i > 0; --i ) {
+ if ( arrData[i] & 1 ) {
+ if ( Map::c_bExtractLockExternal ) {
+ {
+ typename Map::rcu_lock l;
+ xp = rMap.extract_with( arrData[i], key_less() );
+ if ( xp )
+ ++m_nDeleteSuccess;
+ else
+ ++m_nDeleteFailed;
+ }
+ }
+ else {
+ xp = rMap.extract_with( arrData[i], key_less() );
+ if ( xp )
+ ++m_nDeleteSuccess;
+ else
+ ++m_nDeleteFailed;
+ }
+ xp.release();
+ }
+ }
+ if ( getTest().m_nInsThreadCount.load( atomics::memory_order_acquire ) == 0 )
+ break;
+ }
+ }
+ }
+ };
+
+ protected:
+ template <class Map>
+ void do_test( size_t nLoadFactor )
+ {
+ Map testMap( c_nMapSize, nLoadFactor );
+ do_test_with( testMap );
+ }
+
+ template <class Map>
+ void do_test_extract( size_t nLoadFactor )
+ {
+ Map testMap( c_nMapSize, nLoadFactor );
+ do_test_extract_with( testMap );
+ }
+
+ template <class Map>
+ void do_test_with( Map& testMap )
+ {
+ typedef InsertThread<Map> insert_thread;
+ typedef DeleteThread<Map> delete_thread;
+
+ m_nInsThreadCount.store( c_nInsThreadCount, atomics::memory_order_release );
+
+ CppUnitMini::ThreadPool pool( *this );
+ pool.add( new insert_thread( pool, testMap ), c_nInsThreadCount );
+ pool.add( new delete_thread( pool, testMap ), c_nDelThreadCount ? c_nDelThreadCount : cds::OS::topology::processor_count());
+ pool.run();
+ CPPUNIT_MSG( " Duration=" << pool.avgDuration() );
+
+ size_t nInsertSuccess = 0;
+ size_t nInsertFailed = 0;
+ size_t nDeleteSuccess = 0;
+ size_t nDeleteFailed = 0;
+ for ( CppUnitMini::ThreadPool::iterator it = pool.begin(); it != pool.end(); ++it ) {
+ insert_thread * pThread = dynamic_cast<insert_thread *>( *it );
+ if ( pThread ) {
+ nInsertSuccess += pThread->m_nInsertSuccess;
+ nInsertFailed += pThread->m_nInsertFailed;
+ }
+ else {
+ delete_thread * p = static_cast<delete_thread *>( *it );
+ nDeleteSuccess += p->m_nDeleteSuccess;
+ nDeleteFailed += p->m_nDeleteFailed;
+ }
+ }
+
+ CPPUNIT_MSG( " Totals (success/failed): \n\t"
+ << " Insert=" << nInsertSuccess << '/' << nInsertFailed << "\n\t"
+ << " Delete=" << nDeleteSuccess << '/' << nDeleteFailed << "\n\t"
+ );
+ CPPUNIT_CHECK( nInsertSuccess == c_nMapSize * c_nInsThreadCount );
+ CPPUNIT_CHECK( nInsertFailed == 0 );
+
+ analyze( testMap );
+ }
+
+ template <class Map>
+ void do_test_extract_with( Map& testMap )
+ {
+ typedef InsertThread<Map> insert_thread;
+ typedef DeleteThread<Map> delete_thread;
+ typedef ExtractThread< typename Map::gc, Map > extract_thread;
+
+ m_nInsThreadCount.store( c_nInsThreadCount, atomics::memory_order_release );
+
+ CppUnitMini::ThreadPool pool( *this );
+ pool.add( new insert_thread( pool, testMap ), c_nInsThreadCount );
+ if ( c_nDelThreadCount )
+ pool.add( new delete_thread( pool, testMap ), c_nDelThreadCount );
+ if ( c_nExtractThreadCount )
+ pool.add( new extract_thread( pool, testMap ), c_nExtractThreadCount );
+ pool.run();
+ CPPUNIT_MSG( " Duration=" << pool.avgDuration() );
+
+ size_t nInsertSuccess = 0;
+ size_t nInsertFailed = 0;
+ size_t nDeleteSuccess = 0;
+ size_t nDeleteFailed = 0;
+ size_t nExtractSuccess = 0;
+ size_t nExtractFailed = 0;
+ for ( CppUnitMini::ThreadPool::iterator it = pool.begin(); it != pool.end(); ++it ) {
+ insert_thread * pThread = dynamic_cast<insert_thread *>( *it );
+ if ( pThread ) {
+ nInsertSuccess += pThread->m_nInsertSuccess;
+ nInsertFailed += pThread->m_nInsertFailed;
+ }
+ else {
+ delete_thread * p = dynamic_cast<delete_thread *>( *it );
+ if ( p ) {
+ nDeleteSuccess += p->m_nDeleteSuccess;
+ nDeleteFailed += p->m_nDeleteFailed;
+ }
+ else {
+ extract_thread * pExtract = dynamic_cast<extract_thread *>( *it );
+ assert( pExtract );
+ nExtractSuccess += pExtract->m_nDeleteSuccess;
+ nExtractFailed += pExtract->m_nDeleteFailed;
+ }
+ }
+ }
+
+ CPPUNIT_MSG( " Totals (success/failed): \n\t"
+ << " Insert=" << nInsertSuccess << '/' << nInsertFailed << "\n\t"
+ << " Delete=" << nDeleteSuccess << '/' << nDeleteFailed << "\n\t"
+ << " Extract=" << nExtractSuccess << '/' << nExtractFailed << "\n\t"
+ );
+ CPPUNIT_CHECK( nInsertSuccess == c_nMapSize * c_nInsThreadCount );
+ CPPUNIT_CHECK( nInsertFailed == 0 );
+
+ analyze( testMap );
+ }
+
+ template <class Map>
+ void analyze( Map& testMap )
+ {
+ cds::OS::Timer timer;
+
+ // All even keys must be in the map
+ {
+ size_t nErrorCount = 0;
+ CPPUNIT_MSG( " Check even keys..." );
+ for ( size_t n = 0; n < c_nMapSize; n +=2 ) {
+ for ( size_t i = 0; i < c_nInsThreadCount; ++i ) {
+ if ( !testMap.find( key_type(n, i) ) ) {
+ if ( ++nErrorCount < 10 ) {
+ CPPUNIT_MSG( "key " << n << "-" << i << " is not found!");
+ }
+ }
+ }
+ }
+ CPPUNIT_CHECK_EX( nErrorCount == 0, "Totals: " << nErrorCount << " keys is not found");
+ }
+
+ check_before_cleanup( testMap );
+
+ CPPUNIT_MSG( " Clear map (single-threaded)..." );
+ timer.reset();
+ testMap.clear();
+ CPPUNIT_MSG( " Duration=" << timer.duration() );
+ CPPUNIT_CHECK_EX( testMap.empty(), ((long long) testMap.size()) );
+
+ additional_check( testMap );
+ print_stat( testMap );
+
+ additional_cleanup( testMap );
+ }
+
+
+ template <class Map>
+ void test()
+ {
+ CPPUNIT_MSG( "Insert thread count=" << c_nInsThreadCount
+ << " delete thread count=" << c_nDelThreadCount
+ << " set size=" << c_nMapSize
+ );
+
+ for ( size_t nLoadFactor = 1; nLoadFactor <= c_nMaxLoadFactor; nLoadFactor *= 2 ) {
+ CPPUNIT_MSG( "Load factor=" << nLoadFactor );
+ do_test<Map>( nLoadFactor );
+ if ( c_bPrintGCState )
+ print_gc_state();
+ }
+ }
+
+ template <class Map>
+ void test_extract()
+ {
+ CPPUNIT_MSG( "Thread count: insert=" << c_nInsThreadCount
+ << ", delete=" << c_nDelThreadCount
+ << ", extract=" << c_nExtractThreadCount
+ << "; set size=" << c_nMapSize
+ );
+
+ for ( size_t nLoadFactor = 1; nLoadFactor <= c_nMaxLoadFactor; nLoadFactor *= 2 ) {
+ CPPUNIT_MSG( "Load factor=" << nLoadFactor );
+ do_test_extract<Map>( nLoadFactor );
+ if ( c_bPrintGCState )
+ print_gc_state();
+ }
+ }
+
+ template <class Map>
+ void test_nolf()
+ {
+ CPPUNIT_MSG( "Insert thread count=" << c_nInsThreadCount
+ << " delete thread count=" << c_nDelThreadCount
+ << " set size=" << c_nMapSize
+ );
+
+ Map s;
+ do_test_with( s );
+ if ( c_bPrintGCState )
+ print_gc_state();
+ }
+
+ template <class Map>
+ void test_nolf_extract()
+ {
+ CPPUNIT_MSG( "Thread count: insert=" << c_nInsThreadCount
+ << ", delete=" << c_nDelThreadCount
+ << ", extract=" << c_nExtractThreadCount
+ << "; set size=" << c_nMapSize
+ );
+
+ Map s;
+ do_test_extract_with( s );
+ if ( c_bPrintGCState )
+ print_gc_state();
+ }
+
+ void setUpParams( const CppUnitMini::TestCfg& cfg );
+
+ void run_MichaelMap(const char *in_name, bool invert = false);
+ void run_SplitList(const char *in_name, bool invert = false);
+ //void run_StripedMap(const char *in_name, bool invert = false);
+ //void run_RefinableMap(const char *in_name, bool invert = false);
+ void run_CuckooMap(const char *in_name, bool invert = false);
+ void run_SkipListMap(const char *in_name, bool invert = false);
+ void run_EllenBinTreeMap(const char *in_name, bool invert = false);
+ void run_BronsonAVLTreeMap(const char *in_name, bool invert = false);
+ //void run_StdMap(const char *in_name, bool invert = false);
+
+ virtual void myRun(const char *in_name, bool invert = false);
+
+# include "map2/map_defs.h"
+ CDSUNIT_DECLARE_MichaelMap
+ CDSUNIT_DECLARE_SplitList
+ //CDSUNIT_DECLARE_StripedMap
+ //CDSUNIT_DECLARE_RefinableMap
+ CDSUNIT_DECLARE_CuckooMap
+ CDSUNIT_DECLARE_SkipListMap
+ CDSUNIT_DECLARE_EllenBinTreeMap
+ CDSUNIT_DECLARE_BronsonAVLTreeMap
+ //CDSUNIT_DECLARE_StdMap
+ };
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_delodd.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_DelOdd, run_BronsonAVLTreeMap )
+ CDSUNIT_TEST_BronsonAVLTreeMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_delodd.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_DelOdd, run_CuckooMap )
+ CDSUNIT_TEST_CuckooMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_delodd.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_DelOdd, run_EllenBinTreeMap )
+ CDSUNIT_TEST_EllenBinTreeMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_delodd.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_DelOdd, run_MichaelMap )
+ CDSUNIT_TEST_MichaelMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_delodd.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_DelOdd, run_SkipListMap )
+ CDSUNIT_TEST_SkipListMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_delodd.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_DelOdd, run_SplitList )
+ CDSUNIT_TEST_SplitList
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
endTestCase();
}
-
- CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_MichaelMap )
- CDSUNIT_TEST_MichaelMap
- CPPUNIT_TEST_SUITE_END_PART()
} // namespace map2
+++ /dev/null
-//$$CDS-header$$
-
-#include "map2/map_insdel_func.h"
-
-namespace map2 {
- CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_SplitList )
- CDSUNIT_TEST_SplitList
- CPPUNIT_TEST_SUITE_END_PART()
-} // namespace map2
-
+++ /dev/null
-//$$CDS-header$$
-
-#include "map2/map_insdel_func.h"
-
-namespace map2 {
- CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_SkipListMap )
- CDSUNIT_TEST_SkipListMap
- CPPUNIT_TEST_SUITE_END_PART()
-} // namespace map2
-
+++ /dev/null
-//$$CDS-header$$
-
-#include "map2/map_insdel_func.h"
-
-namespace map2 {
- CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_EllenBinTreeMap )
- CDSUNIT_TEST_EllenBinTreeMap
- CPPUNIT_TEST_SUITE_END_PART()
-} // namespace map2
-
+++ /dev/null
-//$$CDS-header$$
-
-#include "map2/map_insdel_func.h"
-
-namespace map2 {
- CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_BronsonAVLTreeMap )
- CDSUNIT_TEST_BronsonAVLTreeMap
- CPPUNIT_TEST_SUITE_END_PART()
-} // namespace map2
+++ /dev/null
-//$$CDS-header$$
-
-#include "map2/map_insdel_func.h"
-
-namespace map2 {
- CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_StripedMap )
- CDSUNIT_TEST_StripedMap
- CPPUNIT_TEST_SUITE_END_PART()
-} // namespace map2
+++ /dev/null
-//$$CDS-header$$
-
-#include "map2/map_insdel_func.h"
-
-namespace map2 {
- CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_RefinableMap )
- CDSUNIT_TEST_RefinableMap
- CPPUNIT_TEST_SUITE_END_PART()
-} // namespace map2
+++ /dev/null
-//$$CDS-header$$
-
-#include "map2/map_insdel_func.h"
-
-namespace map2 {
- CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_CuckooMap )
- CDSUNIT_TEST_CuckooMap
- CPPUNIT_TEST_SUITE_END_PART()
-} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_insdel_func.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_BronsonAVLTreeMap )
+ CDSUNIT_TEST_BronsonAVLTreeMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_insdel_func.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_CuckooMap )
+ CDSUNIT_TEST_CuckooMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_insdel_func.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_EllenBinTreeMap )
+ CDSUNIT_TEST_EllenBinTreeMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
+
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_insdel_func.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_MichaelMap )
+ CDSUNIT_TEST_MichaelMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_insdel_func.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_RefinableMap )
+ CDSUNIT_TEST_RefinableMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_insdel_func.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_SkipListMap )
+ CDSUNIT_TEST_SkipListMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
+
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_insdel_func.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_SplitList )
+ CDSUNIT_TEST_SplitList
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
+
--- /dev/null
+//$$CDS-header$$
+
+#include "map2/map_insdel_func.h"
+
+namespace map2 {
+ CPPUNIT_TEST_SUITE_PART( Map_InsDel_func, run_StripedMap )
+ CDSUNIT_TEST_StripedMap
+ CPPUNIT_TEST_SUITE_END_PART()
+} // namespace map2
static inline void check_before_cleanup( cc::BronsonAVLTreeMap<GC, Key, T, Traits>& m )
{
CPPUNIT_MSG( " Check internal consistency (single-threaded)..." );
- m.check_consistency([]( size_t nLevel, size_t hLeft, size_t hRight )
+ bool bOk = m.check_consistency([]( size_t nLevel, size_t hLeft, size_t hRight )
{
CPPUNIT_MSG( "Tree violation on level=" << nLevel << ": hLeft=" << hLeft << ", hRight=" << hRight )
});
+ CPPUNIT_CHECK_CURRENT_EX( bOk, "check_consistency failed");
}
template <typename K, typename V, typename Traits>