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656 lines
18 KiB
656 lines
18 KiB
//===== Copyright 1996-2005, Valve Corporation, All rights reserved. ======//
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//
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// Purpose:
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//
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// $Workfile: $
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// $Date: $
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//
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//-----------------------------------------------------------------------------
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// $Log: $
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//
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// $NoKeywords: $
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//===========================================================================//
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#ifndef MEMPOOL_H
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#define MEMPOOL_H
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#ifdef _WIN32
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#pragma once
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#endif
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#include "tier0/memalloc.h"
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#include "tier0/tslist.h"
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#include "tier0/platform.h"
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#include "tier1/utlvector.h"
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#include "tier1/utlrbtree.h"
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//-----------------------------------------------------------------------------
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// Purpose: Optimized pool memory allocator
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//-----------------------------------------------------------------------------
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typedef void (*MemoryPoolReportFunc_t)( PRINTF_FORMAT_STRING char const* pMsg, ... );
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class CUtlMemoryPool
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{
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public:
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// Ways the memory pool can grow when it needs to make a new blob.
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enum MemoryPoolGrowType_t
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{
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GROW_NONE=0, // Don't allow new blobs.
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GROW_FAST=1, // New blob size is numElements * (i+1) (ie: the blocks it allocates
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// get larger and larger each time it allocates one).
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GROW_SLOW=2 // New blob size is numElements.
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};
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CUtlMemoryPool( int blockSize, int numElements, int growMode = GROW_FAST, const char *pszAllocOwner = NULL, int nAlignment = 0 );
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~CUtlMemoryPool();
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void* Alloc(); // Allocate the element size you specified in the constructor.
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void* Alloc( size_t amount );
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void* AllocZero(); // Allocate the element size you specified in the constructor, zero the memory before construction
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void* AllocZero( size_t amount );
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void Free(void *pMem);
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// Frees everything
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void Clear();
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// Error reporting...
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static void SetErrorReportFunc( MemoryPoolReportFunc_t func );
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// returns number of allocated blocks
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int Count() const { return m_BlocksAllocated; }
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int PeakCount() const { return m_PeakAlloc; }
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int BlockSize() const { return m_BlockSize; }
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int Size() const;
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bool IsAllocationWithinPool( void *pMem ) const;
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protected:
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class CBlob
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{
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public:
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CBlob *m_pPrev, *m_pNext;
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int m_NumBytes; // Number of bytes in this blob.
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char m_Data[1];
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char m_Padding[3]; // to int align the struct
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};
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// Resets the pool
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void Init();
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void AddNewBlob();
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void ReportLeaks();
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int m_BlockSize;
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int m_BlocksPerBlob;
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int m_GrowMode; // GROW_ enum.
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int m_BlocksAllocated;
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int m_PeakAlloc;
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unsigned short m_nAlignment;
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unsigned short m_NumBlobs;
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// Group up pointers at the end of the class to avoid padding bloat
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// FIXME: Change m_ppMemBlob into a growable array?
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void *m_pHeadOfFreeList;
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const char * m_pszAllocOwner;
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// CBlob could be not a multiple of 4 bytes so stuff it at the end here to keep us otherwise aligned
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CBlob m_BlobHead;
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static MemoryPoolReportFunc_t g_ReportFunc;
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};
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//-----------------------------------------------------------------------------
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// Multi-thread/Thread Safe Memory Class
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//-----------------------------------------------------------------------------
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class CMemoryPoolMT : public CUtlMemoryPool
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{
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public:
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CMemoryPoolMT( int blockSize, int numElements, int growMode = GROW_FAST, const char *pszAllocOwner = NULL, int nAlignment = 0) : CUtlMemoryPool( blockSize, numElements, growMode, pszAllocOwner, nAlignment ) {}
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void* Alloc() { AUTO_LOCK( m_mutex ); return CUtlMemoryPool::Alloc(); }
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void* Alloc( size_t amount ) { AUTO_LOCK( m_mutex ); return CUtlMemoryPool::Alloc( amount ); }
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void* AllocZero() { AUTO_LOCK( m_mutex ); return CUtlMemoryPool::AllocZero(); }
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void* AllocZero( size_t amount ) { AUTO_LOCK( m_mutex ); return CUtlMemoryPool::AllocZero( amount ); }
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void Free(void *pMem) { AUTO_LOCK( m_mutex ); CUtlMemoryPool::Free( pMem ); }
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// Frees everything
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void Clear() { AUTO_LOCK( m_mutex ); return CUtlMemoryPool::Clear(); }
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private:
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CThreadFastMutex m_mutex; // @TODO: Rework to use tslist (toml 7/6/2007)
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};
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//-----------------------------------------------------------------------------
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// Wrapper macro to make an allocator that returns particular typed allocations
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// and construction and destruction of objects.
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//-----------------------------------------------------------------------------
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template< class T >
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class CClassMemoryPool : public CUtlMemoryPool
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{
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public:
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CClassMemoryPool(int numElements, int growMode = GROW_FAST, int nAlignment = 0 ) :
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CUtlMemoryPool( sizeof(T), numElements, growMode, MEM_ALLOC_CLASSNAME(T), nAlignment ) {}
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T* Alloc();
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T* AllocZero();
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void Free( T *pMem );
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void Clear();
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};
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//-----------------------------------------------------------------------------
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// Specialized pool for aligned data management (e.g., Xbox textures)
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//-----------------------------------------------------------------------------
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template <int ITEM_SIZE, int ALIGNMENT, int CHUNK_SIZE, class CAllocator, bool GROWMODE = false, int COMPACT_THRESHOLD = 4 >
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class CAlignedMemPool
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{
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enum
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{
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BLOCK_SIZE = COMPILETIME_MAX( ALIGN_VALUE( ITEM_SIZE, ALIGNMENT ), 8 ),
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};
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public:
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CAlignedMemPool();
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void *Alloc();
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void Free( void *p );
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static int __cdecl CompareChunk( void * const *ppLeft, void * const *ppRight );
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void Compact();
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int NumTotal() { AUTO_LOCK( m_mutex ); return m_Chunks.Count() * ( CHUNK_SIZE / BLOCK_SIZE ); }
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int NumAllocated() { AUTO_LOCK( m_mutex ); return NumTotal() - m_nFree; }
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int NumFree() { AUTO_LOCK( m_mutex ); return m_nFree; }
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int BytesTotal() { AUTO_LOCK( m_mutex ); return NumTotal() * BLOCK_SIZE; }
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int BytesAllocated() { AUTO_LOCK( m_mutex ); return NumAllocated() * BLOCK_SIZE; }
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int BytesFree() { AUTO_LOCK( m_mutex ); return NumFree() * BLOCK_SIZE; }
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int ItemSize() { return ITEM_SIZE; }
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int BlockSize() { return BLOCK_SIZE; }
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int ChunkSize() { return CHUNK_SIZE; }
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private:
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struct FreeBlock_t
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{
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FreeBlock_t *pNext;
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byte reserved[ BLOCK_SIZE - sizeof( FreeBlock_t *) ];
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};
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CUtlVector<void *> m_Chunks; // Chunks are tracked outside blocks (unlike CUtlMemoryPool) to simplify alignment issues
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FreeBlock_t * m_pFirstFree;
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int m_nFree;
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CAllocator m_Allocator;
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double m_TimeLastCompact;
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CThreadFastMutex m_mutex;
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};
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//-----------------------------------------------------------------------------
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// Pool variant using standard allocation
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//-----------------------------------------------------------------------------
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template <typename T, int nInitialCount = 0, bool bDefCreateNewIfEmpty = true >
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class CObjectPool
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{
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public:
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CObjectPool()
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{
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int i = nInitialCount;
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while ( i-- > 0 )
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{
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m_AvailableObjects.PushItem( new T );
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}
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}
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~CObjectPool()
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{
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Purge();
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}
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int NumAvailable()
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{
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return m_AvailableObjects.Count();
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}
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void Purge()
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{
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T *p = NULL;
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while ( m_AvailableObjects.PopItem( &p ) )
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{
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delete p;
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}
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}
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T *GetObject( bool bCreateNewIfEmpty = bDefCreateNewIfEmpty )
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{
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T *p = NULL;
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if ( !m_AvailableObjects.PopItem( &p ) )
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{
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p = ( bCreateNewIfEmpty ) ? new T : NULL;
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}
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return p;
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}
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void PutObject( T *p )
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{
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m_AvailableObjects.PushItem( p );
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}
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private:
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CTSList<T *> m_AvailableObjects;
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};
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//-----------------------------------------------------------------------------
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// Fixed budget pool with overflow to malloc
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//-----------------------------------------------------------------------------
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template <size_t PROVIDED_ITEM_SIZE, int ITEM_COUNT>
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class CFixedBudgetMemoryPool
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{
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public:
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CFixedBudgetMemoryPool()
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{
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m_pBase = m_pLimit = 0;
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COMPILE_TIME_ASSERT( ITEM_SIZE % 4 == 0 );
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}
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bool Owns( void *p )
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{
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return ( p >= m_pBase && p < m_pLimit );
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}
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void *Alloc()
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{
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MEM_ALLOC_CREDIT_CLASS();
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#ifndef USE_MEM_DEBUG
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if ( !m_pBase )
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{
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LOCAL_THREAD_LOCK();
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if ( !m_pBase )
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{
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byte *pMemory = m_pBase = (byte *)malloc( ITEM_COUNT * ITEM_SIZE );
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m_pLimit = m_pBase + ( ITEM_COUNT * ITEM_SIZE );
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for ( int i = 0; i < ITEM_COUNT; i++ )
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{
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m_freeList.Push( (TSLNodeBase_t *)pMemory );
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pMemory += ITEM_SIZE;
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}
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}
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}
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void *p = m_freeList.Pop();
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if ( p )
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return p;
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#endif
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return malloc( ITEM_SIZE );
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}
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void Free( void *p )
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{
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#ifndef USE_MEM_DEBUG
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if ( Owns( p ) )
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m_freeList.Push( (TSLNodeBase_t *)p );
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else
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#endif
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free( p );
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}
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void Clear()
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{
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#ifndef USE_MEM_DEBUG
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if ( m_pBase )
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{
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free( m_pBase );
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}
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m_pBase = m_pLimit = 0;
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Construct( &m_freeList );
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#endif
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}
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bool IsEmpty()
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{
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#ifndef USE_MEM_DEBUG
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if ( m_pBase && m_freeList.Count() != ITEM_COUNT )
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return false;
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#endif
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return true;
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}
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enum
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{
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ITEM_SIZE = ALIGN_VALUE( PROVIDED_ITEM_SIZE, TSLIST_NODE_ALIGNMENT )
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};
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CTSListBase m_freeList;
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byte *m_pBase;
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byte *m_pLimit;
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};
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#define BIND_TO_FIXED_BUDGET_POOL( poolName ) \
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inline void* operator new( size_t size ) { return poolName.Alloc(); } \
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inline void* operator new( size_t size, int nBlockUse, const char *pFileName, int nLine ) { return poolName.Alloc(); } \
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inline void operator delete( void* p ) { poolName.Free(p); } \
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inline void operator delete( void* p, int nBlockUse, const char *pFileName, int nLine ) { poolName.Free(p); }
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//-----------------------------------------------------------------------------
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template< class T >
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inline T* CClassMemoryPool<T>::Alloc()
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{
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T *pRet;
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{
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MEM_ALLOC_CREDIT_CLASS();
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pRet = (T*)CUtlMemoryPool::Alloc();
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}
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if ( pRet )
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{
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Construct( pRet );
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}
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return pRet;
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}
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template< class T >
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inline T* CClassMemoryPool<T>::AllocZero()
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{
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T *pRet;
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{
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MEM_ALLOC_CREDIT_CLASS();
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pRet = (T*)CUtlMemoryPool::AllocZero();
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}
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if ( pRet )
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{
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Construct( pRet );
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}
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return pRet;
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}
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template< class T >
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inline void CClassMemoryPool<T>::Free(T *pMem)
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{
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if ( pMem )
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{
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Destruct( pMem );
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}
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CUtlMemoryPool::Free( pMem );
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}
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template< class T >
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inline void CClassMemoryPool<T>::Clear()
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{
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CUtlRBTree<void *, int> freeBlocks;
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SetDefLessFunc( freeBlocks );
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void *pCurFree = m_pHeadOfFreeList;
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while ( pCurFree != NULL )
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{
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freeBlocks.Insert( pCurFree );
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pCurFree = *((void**)pCurFree);
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}
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for( CBlob *pCur=m_BlobHead.m_pNext; pCur != &m_BlobHead; pCur=pCur->m_pNext )
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{
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int nElements = pCur->m_NumBytes / this->m_BlockSize;
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T *p = ( T * ) AlignValue( pCur->m_Data, this->m_nAlignment );
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T *pLimit = p + nElements;
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while ( p < pLimit )
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{
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if ( freeBlocks.Find( p ) == freeBlocks.InvalidIndex() )
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{
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Destruct( p );
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}
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p++;
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}
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}
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CUtlMemoryPool::Clear();
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}
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//-----------------------------------------------------------------------------
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// Macros that make it simple to make a class use a fixed-size allocator
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// Put DECLARE_FIXEDSIZE_ALLOCATOR in the private section of a class,
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// Put DEFINE_FIXEDSIZE_ALLOCATOR in the CPP file
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//-----------------------------------------------------------------------------
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#define DECLARE_FIXEDSIZE_ALLOCATOR( _class ) \
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public: \
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inline void* operator new( size_t size ) { MEM_ALLOC_CREDIT_(#_class " pool"); return s_Allocator.Alloc(size); } \
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inline void* operator new( size_t size, int nBlockUse, const char *pFileName, int nLine ) { MEM_ALLOC_CREDIT_(#_class " pool"); return s_Allocator.Alloc(size); } \
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inline void operator delete( void* p ) { s_Allocator.Free(p); } \
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inline void operator delete( void* p, int nBlockUse, const char *pFileName, int nLine ) { s_Allocator.Free(p); } \
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private: \
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static CUtlMemoryPool s_Allocator
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#define DEFINE_FIXEDSIZE_ALLOCATOR( _class, _initsize, _grow ) \
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CUtlMemoryPool _class::s_Allocator(sizeof(_class), _initsize, _grow, #_class " pool")
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#define DEFINE_FIXEDSIZE_ALLOCATOR_ALIGNED( _class, _initsize, _grow, _alignment ) \
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CUtlMemoryPool _class::s_Allocator(sizeof(_class), _initsize, _grow, #_class " pool", _alignment )
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#define DECLARE_FIXEDSIZE_ALLOCATOR_MT( _class ) \
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public: \
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inline void* operator new( size_t size ) { MEM_ALLOC_CREDIT_(#_class " pool"); return s_Allocator.Alloc(size); } \
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inline void* operator new( size_t size, int nBlockUse, const char *pFileName, int nLine ) { MEM_ALLOC_CREDIT_(#_class " pool"); return s_Allocator.Alloc(size); } \
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inline void operator delete( void* p ) { s_Allocator.Free(p); } \
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inline void operator delete( void* p, int nBlockUse, const char *pFileName, int nLine ) { s_Allocator.Free(p); } \
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private: \
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static CMemoryPoolMT s_Allocator
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#define DEFINE_FIXEDSIZE_ALLOCATOR_MT( _class, _initsize, _grow ) \
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CMemoryPoolMT _class::s_Allocator(sizeof(_class), _initsize, _grow, #_class " pool")
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//-----------------------------------------------------------------------------
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// Macros that make it simple to make a class use a fixed-size allocator
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// This version allows us to use a memory pool which is externally defined...
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// Put DECLARE_FIXEDSIZE_ALLOCATOR_EXTERNAL in the private section of a class,
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// Put DEFINE_FIXEDSIZE_ALLOCATOR_EXTERNAL in the CPP file
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//-----------------------------------------------------------------------------
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#define DECLARE_FIXEDSIZE_ALLOCATOR_EXTERNAL( _class ) \
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public: \
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inline void* operator new( size_t size ) { MEM_ALLOC_CREDIT_(#_class " pool"); return s_pAllocator->Alloc(size); } \
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inline void* operator new( size_t size, int nBlockUse, const char *pFileName, int nLine ) { MEM_ALLOC_CREDIT_(#_class " pool"); return s_pAllocator->Alloc(size); } \
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inline void operator delete( void* p ) { s_pAllocator->Free(p); } \
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private: \
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static CUtlMemoryPool* s_pAllocator
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#define DEFINE_FIXEDSIZE_ALLOCATOR_EXTERNAL( _class, _allocator ) \
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CUtlMemoryPool* _class::s_pAllocator = _allocator
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template <int ITEM_SIZE, int ALIGNMENT, int CHUNK_SIZE, class CAllocator, bool GROWMODE, int COMPACT_THRESHOLD >
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inline CAlignedMemPool<ITEM_SIZE, ALIGNMENT, CHUNK_SIZE, CAllocator, GROWMODE, COMPACT_THRESHOLD>::CAlignedMemPool()
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: m_pFirstFree( 0 ),
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m_nFree( 0 ),
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m_TimeLastCompact( 0 )
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{
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// These COMPILE_TIME_ASSERT checks need to be in individual scopes to avoid build breaks
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// on MacOS and Linux due to a gcc bug.
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{ COMPILE_TIME_ASSERT( sizeof( FreeBlock_t ) >= BLOCK_SIZE ); }
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{ COMPILE_TIME_ASSERT( ALIGN_VALUE( sizeof( FreeBlock_t ), ALIGNMENT ) == sizeof( FreeBlock_t ) ); }
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}
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template <int ITEM_SIZE, int ALIGNMENT, int CHUNK_SIZE, class CAllocator, bool GROWMODE, int COMPACT_THRESHOLD >
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inline void *CAlignedMemPool<ITEM_SIZE, ALIGNMENT, CHUNK_SIZE, CAllocator, GROWMODE, COMPACT_THRESHOLD>::Alloc()
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{
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AUTO_LOCK( m_mutex );
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if ( !m_pFirstFree )
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{
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if ( !GROWMODE && m_Chunks.Count() )
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{
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return NULL;
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}
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FreeBlock_t *pNew = (FreeBlock_t *)m_Allocator.Alloc( CHUNK_SIZE );
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Assert( (unsigned)pNew % ALIGNMENT == 0 );
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m_Chunks.AddToTail( pNew );
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m_nFree = CHUNK_SIZE / BLOCK_SIZE;
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m_pFirstFree = pNew;
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for ( int i = 0; i < m_nFree - 1; i++ )
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{
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pNew->pNext = pNew + 1;
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pNew++;
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}
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pNew->pNext = NULL;
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}
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void *p = m_pFirstFree;
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m_pFirstFree = m_pFirstFree->pNext;
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m_nFree--;
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return p;
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}
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template <int ITEM_SIZE, int ALIGNMENT, int CHUNK_SIZE, class CAllocator, bool GROWMODE, int COMPACT_THRESHOLD >
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inline void CAlignedMemPool<ITEM_SIZE, ALIGNMENT, CHUNK_SIZE, CAllocator, GROWMODE, COMPACT_THRESHOLD>::Free( void *p )
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{
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AUTO_LOCK( m_mutex );
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// Insertion sort to encourage allocation clusters in chunks
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FreeBlock_t *pFree = ((FreeBlock_t *)p);
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FreeBlock_t *pCur = m_pFirstFree;
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FreeBlock_t *pPrev = NULL;
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while ( pCur && pFree > pCur )
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{
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pPrev = pCur;
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pCur = pCur->pNext;
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}
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pFree->pNext = pCur;
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if ( pPrev )
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{
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pPrev->pNext = pFree;
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}
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else
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{
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m_pFirstFree = pFree;
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}
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m_nFree++;
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if ( m_nFree >= ( CHUNK_SIZE / BLOCK_SIZE ) * COMPACT_THRESHOLD )
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{
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double time = Plat_FloatTime();
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double compactTime = ( m_nFree >= ( CHUNK_SIZE / BLOCK_SIZE ) * COMPACT_THRESHOLD * 4 ) ? 15.0 : 30.0;
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if ( m_TimeLastCompact > time || m_TimeLastCompact + compactTime < time )
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{
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Compact();
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m_TimeLastCompact = time;
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}
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}
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}
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template <int ITEM_SIZE, int ALIGNMENT, int CHUNK_SIZE, class CAllocator, bool GROWMODE, int COMPACT_THRESHOLD >
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inline int __cdecl CAlignedMemPool<ITEM_SIZE, ALIGNMENT, CHUNK_SIZE, CAllocator, GROWMODE, COMPACT_THRESHOLD>::CompareChunk( void * const *ppLeft, void * const *ppRight )
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{
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return size_cast<int>( (intp)*ppLeft - (intp)*ppRight );
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}
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template <int ITEM_SIZE, int ALIGNMENT, int CHUNK_SIZE, class CAllocator, bool GROWMODE, int COMPACT_THRESHOLD >
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inline void CAlignedMemPool<ITEM_SIZE, ALIGNMENT, CHUNK_SIZE, CAllocator, GROWMODE, COMPACT_THRESHOLD>::Compact()
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{
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FreeBlock_t *pCur = m_pFirstFree;
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FreeBlock_t *pPrev = NULL;
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m_Chunks.Sort( CompareChunk );
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#ifdef VALIDATE_ALIGNED_MEM_POOL
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{
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FreeBlock_t *p = m_pFirstFree;
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while ( p )
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{
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if ( p->pNext && p > p->pNext )
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{
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__asm { int 3 }
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}
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p = p->pNext;
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}
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for ( int i = 0; i < m_Chunks.Count(); i++ )
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{
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if ( i + 1 < m_Chunks.Count() )
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{
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if ( m_Chunks[i] > m_Chunks[i + 1] )
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{
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__asm { int 3 }
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}
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}
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}
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}
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#endif
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int i;
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for ( i = 0; i < m_Chunks.Count(); i++ )
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{
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int nBlocksPerChunk = CHUNK_SIZE / BLOCK_SIZE;
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FreeBlock_t *pChunkLimit = ((FreeBlock_t *)m_Chunks[i]) + nBlocksPerChunk;
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int nFromChunk = 0;
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if ( pCur == m_Chunks[i] )
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{
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FreeBlock_t *pFirst = pCur;
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while ( pCur && pCur >= m_Chunks[i] && pCur < pChunkLimit )
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{
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pCur = pCur->pNext;
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nFromChunk++;
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}
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pCur = pFirst;
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}
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while ( pCur && pCur >= m_Chunks[i] && pCur < pChunkLimit )
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{
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if ( nFromChunk != nBlocksPerChunk )
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{
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if ( pPrev )
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{
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pPrev->pNext = pCur;
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}
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else
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{
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m_pFirstFree = pCur;
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}
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pPrev = pCur;
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}
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else if ( pPrev )
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{
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pPrev->pNext = NULL;
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}
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else
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{
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m_pFirstFree = NULL;
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}
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pCur = pCur->pNext;
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}
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if ( nFromChunk == nBlocksPerChunk )
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{
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m_Allocator.Free( m_Chunks[i] );
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m_nFree -= nBlocksPerChunk;
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m_Chunks[i] = 0;
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}
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}
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for ( i = m_Chunks.Count() - 1; i >= 0 ; i-- )
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{
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if ( !m_Chunks[i] )
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{
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m_Chunks.FastRemove( i );
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}
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}
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}
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#endif // MEMPOOL_H
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