DarkflameServer/thirdparty/raknet/Source/DS_MemoryPool.h

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#ifndef __MEMORY_POOL_H
#define __MEMORY_POOL_H
#ifndef __APPLE__
// Use stdlib and not malloc for compatibility
#include <stdlib.h>
#endif
#include <assert.h>
#include "Export.h"
#include "RakMemoryOverride.h"
// DS_MEMORY_POOL_MAX_FREE_PAGES must be > 1
#define DS_MEMORY_POOL_MAX_FREE_PAGES 4
// #define _DISABLE_MEMORY_POOL
namespace DataStructures
{
/// Very fast memory pool for allocating and deallocating structures that don't have constructors or destructors.
/// Contains a list of pages, each of which has an array of the user structures
template <class MemoryBlockType>
class RAK_DLL_EXPORT MemoryPool : public RakNet::RakMemoryOverride
{
public:
struct Page;
struct MemoryWithPage
{
MemoryBlockType userMemory;
Page *parentPage;
};
struct Page
{
MemoryWithPage** availableStack;
int availableStackSize;
MemoryWithPage* block;
Page *next, *prev;
};
MemoryPool();
~MemoryPool();
void SetPageSize(int size); // Defaults to 16384
MemoryBlockType *Allocate(void);
void Release(MemoryBlockType *m);
void Clear(void);
int GetAvailablePagesSize(void) const {return availablePagesSize;}
int GetUnavailablePagesSize(void) const {return unavailablePagesSize;}
int GetMemoryPoolPageSize(void) const {return memoryPoolPageSize;}
protected:
int BlocksPerPage(void) const;
void AllocateFirst(void);
bool InitPage(Page *page, Page *prev);
// availablePages contains pages which have room to give the user new blocks. We return these blocks from the head of the list
// unavailablePages are pages which are totally full, and from which we do not return new blocks.
// Pages move from the head of unavailablePages to the tail of availablePages, and from the head of availablePages to the tail of unavailablePages
Page *availablePages, *unavailablePages;
int availablePagesSize, unavailablePagesSize;
int memoryPoolPageSize;
};
template<class MemoryBlockType>
MemoryPool<MemoryBlockType>::MemoryPool()
{
#ifndef _DISABLE_MEMORY_POOL
//AllocateFirst();
availablePagesSize=0;
unavailablePagesSize=0;
memoryPoolPageSize=16384;
#endif
}
template<class MemoryBlockType>
MemoryPool<MemoryBlockType>::~MemoryPool()
{
#ifndef _DISABLE_MEMORY_POOL
Clear();
#endif
}
template<class MemoryBlockType>
void MemoryPool<MemoryBlockType>::SetPageSize(int size)
{
memoryPoolPageSize=size;
}
template<class MemoryBlockType>
MemoryBlockType* MemoryPool<MemoryBlockType>::Allocate(void)
{
#ifdef _DISABLE_MEMORY_POOL
return new MemoryBlockType;
#endif
if (availablePagesSize>0)
{
MemoryBlockType *retVal;
Page *curPage;
curPage=availablePages;
retVal = (MemoryBlockType*) curPage->availableStack[--(curPage->availableStackSize)];
if (curPage->availableStackSize==0)
{
--availablePagesSize;
availablePages=curPage->next;
assert(availablePagesSize==0 || availablePages->availableStackSize>0);
curPage->next->prev=curPage->prev;
curPage->prev->next=curPage->next;
if (unavailablePagesSize++==0)
{
unavailablePages=curPage;
curPage->next=curPage;
curPage->prev=curPage;
}
else
{
curPage->next=unavailablePages;
curPage->prev=unavailablePages->prev;
unavailablePages->prev->next=curPage;
unavailablePages->prev=curPage;
}
}
assert(availablePagesSize==0 || availablePages->availableStackSize>0);
return retVal;
}
availablePages = (Page *) rakMalloc(sizeof(Page));
if (availablePages==0)
return 0;
availablePagesSize=1;
if (InitPage(availablePages, availablePages)==false)
return 0;
assert(availablePages->availableStackSize>1);
return (MemoryBlockType *) availablePages->availableStack[--availablePages->availableStackSize];
}
template<class MemoryBlockType>
void MemoryPool<MemoryBlockType>::Release(MemoryBlockType *m)
{
#ifdef _DISABLE_MEMORY_POOL
delete m;
return;
#endif
// Find the page this block is in and return it.
Page *curPage;
MemoryWithPage *memoryWithPage = (MemoryWithPage*)m;
curPage=memoryWithPage->parentPage;
if (curPage->availableStackSize==0)
{
// The page is in the unavailable list so move it to the available list
curPage->availableStack[curPage->availableStackSize++]=memoryWithPage;
unavailablePagesSize--;
// As this page is no longer totally empty, move it to the end of available pages
curPage->next->prev=curPage->prev;
curPage->prev->next=curPage->next;
if (unavailablePagesSize>0 && curPage==unavailablePages)
unavailablePages=unavailablePages->next;
if (availablePagesSize++==0)
{
availablePages=curPage;
curPage->next=curPage;
curPage->prev=curPage;
}
else
{
curPage->next=availablePages;
curPage->prev=availablePages->prev;
availablePages->prev->next=curPage;
availablePages->prev=curPage;
}
}
else
{
curPage->availableStack[curPage->availableStackSize++]=memoryWithPage;
if (curPage->availableStackSize==BlocksPerPage() &&
availablePagesSize>=DS_MEMORY_POOL_MAX_FREE_PAGES)
{
// After a certain point, just deallocate empty pages rather than keep them around
if (curPage==availablePages)
{
availablePages=curPage->next;
assert(availablePages->availableStackSize>0);
}
curPage->prev->next=curPage->next;
curPage->next->prev=curPage->prev;
availablePagesSize--;
rakFree(curPage->availableStack);
rakFree(curPage->block);
rakFree(curPage);
}
}
}
template<class MemoryBlockType>
void MemoryPool<MemoryBlockType>::Clear(void)
{
#ifdef _DISABLE_MEMORY_POOL
return;
#endif
Page *cur, *freed;
if (availablePagesSize>0)
{
cur = availablePages;
#ifdef _MSC_VER
#pragma warning(disable:4127) // conditional expression is constant
#endif
while (true)
// do
{
rakFree(cur->availableStack);
rakFree(cur->block);
freed=cur;
cur=cur->next;
if (cur==availablePages)
{
rakFree(freed);
break;
}
rakFree(freed);
}// while(cur!=availablePages);
}
if (unavailablePagesSize>0)
{
cur = unavailablePages;
while (1)
//do
{
rakFree(cur->availableStack);
rakFree(cur->block);
freed=cur;
cur=cur->next;
if (cur==unavailablePages)
{
rakFree(freed);
break;
}
rakFree(freed);
} // while(cur!=unavailablePages);
}
availablePagesSize=0;
unavailablePagesSize=0;
}
template<class MemoryBlockType>
int MemoryPool<MemoryBlockType>::BlocksPerPage(void) const
{
return memoryPoolPageSize / sizeof(MemoryWithPage);
}
template<class MemoryBlockType>
bool MemoryPool<MemoryBlockType>::InitPage(Page *page, Page *prev)
{
int i=0;
const int bpp = BlocksPerPage();
page->block=(MemoryWithPage*) rakMalloc(memoryPoolPageSize);
if (page->block==0)
return false;
page->availableStack=(MemoryWithPage**)rakMalloc(sizeof(MemoryWithPage*)*bpp);
if (page->availableStack==0)
{
rakFree(page->block);
return false;
}
MemoryWithPage *curBlock = page->block;
MemoryWithPage **curStack = page->availableStack;
while (i < bpp)
{
curBlock->parentPage=page;
curStack[i]=curBlock++;
i++;
}
page->availableStackSize=bpp;
page->next=availablePages;
page->prev=prev;
return true;
}
}
#endif