void PoolMemoryAllocator::incVectorSlot(PoolElement &pe)
{
if(pe.m_currentVector == 0 || ++pe.m_index == ePoolVectorLength) {
if(s_freeVectors == 0)
s_freeVectors = allocateBlock(sizeof(PoolVector));
PoolVector *pv = (PoolVector *)s_freeVectors;
s_freeVectors = MemElemPtr(pv)->m_next;
pe.m_currentVector = pv;
pe.m_index = 0;
}
}
PoolMemoryAllocator::MemElemPtr
PoolMemoryAllocator::allocateBlock(__uint16 nBytes)
{
if(nBytes < eMinBytes)
nBytes = eMinBytes;
MemElemPtr pBlock = (MemElemPtr) malloc(eBlockSize);
// we altogether create nSlices slices
int nWords;
int nSlices = slicesPerBlock(nBytes,nWords);
MemElemPtr pHead = MemElemPtr(pBlock);
BlockChainPtr(pBlock)->m_next = s_blocks;
s_blocks = BlockChainPtr(pBlock);
do {
pBlock = pBlock->m_next = pBlock+nWords;
} while(--nSlices > 1);
MemElemPtr(pBlock)->m_next = 0;
return pHead;
}
void PoolMemoryAllocator::flushPool(__uint16 nBytes)
{
#ifndef OGDF_MEMORY_POOL_NTS
if(nBytes >= sizeof(MemElemEx)) {
MemElemPtr pRestHead, pRestTail;
int nRest;
MemElemExPtr pStart = collectGroups(nBytes, pRestHead, pRestTail, nRest);
s_criticalSection->enter();
PoolElement &pe = s_pool[nBytes];
while(pStart != 0) {
incVectorSlot(pe);
pe.m_currentVector->m_pool[pe.m_index] = MemElemPtr(pStart);
pStart = pStart->m_down;
}
if(pRestHead != 0) {
int n = slicesPerBlock(nBytes);
pRestTail->m_next = pe.m_restTail;
int nTotal = nRest + pe.m_restCount;
if(nTotal >= n) {
MemElemPtr p = pe.m_restHead;
int i = n-nRest;
while(--i > 0)
p = p->m_next;
pe.m_restHead = p->m_next;
pe.m_restCount = nTotal-n;
incVectorSlot(pe);
pe.m_currentVector->m_pool[pe.m_index] = pRestHead;
} else {
pe.m_restHead = pRestHead;
pe.m_restCount = nTotal;
}
}
s_criticalSection->leave();
} else {
s_criticalSection->enter();
flushPoolSmall(nBytes);
s_criticalSection->leave();
}
#endif
}
