//===== Copyright � 1996-2005, Valve Corporation, All rights reserved. ======// // // Purpose: // // $NoKeywords: $ // // A growable memory class. //===========================================================================// #ifndef UTLFIXEDMEMORY_H #define UTLFIXEDMEMORY_H #ifdef _WIN32 #pragma once #endif #include "tier0/dbg.h" #include "tier0/platform.h" #include "tier0/memalloc.h" #include "tier0/memdbgon.h" #pragma warning (disable:4100) #pragma warning (disable:4514) //----------------------------------------------------------------------------- #ifdef UTLFIXEDMEMORY_TRACK #define UTLFIXEDMEMORY_TRACK_ALLOC() MemAlloc_RegisterAllocation( "Sum of all UtlFixedMemory", 0, NumAllocated() * sizeof(T), NumAllocated() * sizeof(T), 0 ) #define UTLFIXEDMEMORY_TRACK_FREE() if ( !m_pMemory ) ; else MemAlloc_RegisterDeallocation( "Sum of all UtlFixedMemory", 0, NumAllocated() * sizeof(T), NumAllocated() * sizeof(T), 0 ) #else #define UTLFIXEDMEMORY_TRACK_ALLOC() ((void)0) #define UTLFIXEDMEMORY_TRACK_FREE() ((void)0) #endif //----------------------------------------------------------------------------- // The CUtlFixedMemory class: // A growable memory class that allocates non-sequential blocks, but is indexed sequentially //----------------------------------------------------------------------------- template< class T > class CUtlFixedMemory { public: // constructor, destructor CUtlFixedMemory( int nGrowSize = 0, int nInitSize = 0 ); ~CUtlFixedMemory(); // Set the size by which the memory grows void Init( int nGrowSize = 0, int nInitSize = 0 ); // here to match CUtlMemory, but only used by ResetDbgInfo, so it can just return NULL T* Base() { return NULL; } const T* Base() const { return NULL; } protected: struct BlockHeader_t; public: class Iterator_t { public: Iterator_t( BlockHeader_t *p, int i ) : m_pBlockHeader( p ), m_nIndex( i ) {} BlockHeader_t *m_pBlockHeader; intp m_nIndex; bool operator==( const Iterator_t it ) const { return m_pBlockHeader == it.m_pBlockHeader && m_nIndex == it.m_nIndex; } bool operator!=( const Iterator_t it ) const { return m_pBlockHeader != it.m_pBlockHeader || m_nIndex != it.m_nIndex; } }; Iterator_t First() const { return m_pBlocks ? Iterator_t( m_pBlocks, 0 ) : InvalidIterator(); } Iterator_t Next( const Iterator_t &it ) const { Assert( IsValidIterator( it ) ); if ( !IsValidIterator( it ) ) return InvalidIterator(); BlockHeader_t * RESTRICT pHeader = it.m_pBlockHeader; if ( it.m_nIndex + 1 < pHeader->m_nBlockSize ) return Iterator_t( pHeader, it.m_nIndex + 1 ); return pHeader->m_pNext ? Iterator_t( pHeader->m_pNext, 0 ) : InvalidIterator(); } intp GetIndex( const Iterator_t &it ) const { Assert( IsValidIterator( it ) ); if ( !IsValidIterator( it ) ) return InvalidIndex(); return ( intp )( HeaderToBlock( it.m_pBlockHeader ) + it.m_nIndex ); } bool IsIdxAfter( intp i, const Iterator_t &it ) const { Assert( IsValidIterator( it ) ); if ( !IsValidIterator( it ) ) return false; if ( IsInBlock( i, it.m_pBlockHeader ) ) return i > GetIndex( it ); for ( BlockHeader_t * RESTRICT pbh = it.m_pBlockHeader->m_pNext; pbh; pbh = pbh->m_pNext ) { if ( IsInBlock( i, pbh ) ) return true; } return false; } bool IsValidIterator( const Iterator_t &it ) const { return it.m_pBlockHeader && it.m_nIndex >= 0 && it.m_nIndex < it.m_pBlockHeader->m_nBlockSize; } Iterator_t InvalidIterator() const { return Iterator_t( NULL, INVALID_INDEX ); } // element access T& operator[]( intp i ); const T& operator[]( intp i ) const; T& Element( intp i ); const T& Element( intp i ) const; // Can we use this index? bool IsIdxValid( intp i ) const; // Specify the invalid ('null') index that we'll only return on failure static const intp INVALID_INDEX = 0; // For use with COMPILE_TIME_ASSERT static intp InvalidIndex() { return INVALID_INDEX; } // Size int NumAllocated() const; int Count() const { return NumAllocated(); } // Grows memory by max(num,growsize), and returns the allocation index/ptr void Grow( int num = 1 ); // Makes sure we've got at least this much memory void EnsureCapacity( int num ); // Memory deallocation void Purge(); protected: // Fast swap - WARNING: Swap invalidates all ptr-based indices!!! void Swap( CUtlFixedMemory< T > &mem ); bool IsInBlock( intp i, BlockHeader_t *pBlockHeader ) const { T *p = ( T* )i; const T *p0 = HeaderToBlock( pBlockHeader ); return p >= p0 && p < p0 + pBlockHeader->m_nBlockSize; } struct BlockHeader_t { BlockHeader_t *m_pNext; intp m_nBlockSize; }; const T *HeaderToBlock( const BlockHeader_t *pHeader ) const { return ( T* )( pHeader + 1 ); } const BlockHeader_t *BlockToHeader( const T *pBlock ) const { return ( BlockHeader_t* )( pBlock ) - 1; } BlockHeader_t* m_pBlocks; int m_nAllocationCount; int m_nGrowSize; }; //----------------------------------------------------------------------------- // constructor, destructor //----------------------------------------------------------------------------- template< class T > CUtlFixedMemory::CUtlFixedMemory( int nGrowSize, int nInitAllocationCount ) : m_pBlocks( 0 ), m_nAllocationCount( 0 ), m_nGrowSize( 0 ) { Init( nGrowSize, nInitAllocationCount ); } template< class T > CUtlFixedMemory::~CUtlFixedMemory() { Purge(); } //----------------------------------------------------------------------------- // Fast swap - WARNING: Swap invalidates all ptr-based indices!!! //----------------------------------------------------------------------------- template< class T > void CUtlFixedMemory::Swap( CUtlFixedMemory< T > &mem ) { V_swap( m_pBlocks, mem.m_pBlocks ); V_swap( m_nAllocationCount, mem.m_nAllocationCount ); V_swap( m_nGrowSize, mem.m_nGrowSize ); } //----------------------------------------------------------------------------- // Set the size by which the memory grows - round up to the next power of 2 //----------------------------------------------------------------------------- template< class T > void CUtlFixedMemory::Init( int nGrowSize /* = 0 */, int nInitSize /* = 0 */ ) { Purge(); m_nGrowSize = nGrowSize; Grow( nInitSize ); } //----------------------------------------------------------------------------- // element access //----------------------------------------------------------------------------- template< class T > inline T& CUtlFixedMemory::operator[]( intp i ) { Assert( IsIdxValid(i) ); return *( T* )i; } template< class T > inline const T& CUtlFixedMemory::operator[]( intp i ) const { Assert( IsIdxValid(i) ); return *( T* )i; } template< class T > inline T& CUtlFixedMemory::Element( intp i ) { Assert( IsIdxValid(i) ); return *( T* )i; } template< class T > inline const T& CUtlFixedMemory::Element( intp i ) const { Assert( IsIdxValid(i) ); return *( T* )i; } //----------------------------------------------------------------------------- // Size //----------------------------------------------------------------------------- template< class T > inline int CUtlFixedMemory::NumAllocated() const { return m_nAllocationCount; } //----------------------------------------------------------------------------- // Is element index valid? //----------------------------------------------------------------------------- template< class T > inline bool CUtlFixedMemory::IsIdxValid( intp i ) const { #ifdef _DEBUG for ( BlockHeader_t *pbh = m_pBlocks; pbh; pbh = pbh->m_pNext ) { if ( IsInBlock( i, pbh ) ) return true; } return false; #else return i != InvalidIndex(); #endif } template< class T > void CUtlFixedMemory::Grow( int num ) { if ( num <= 0 ) return; int nBlockSize = m_nGrowSize; if ( nBlockSize == 0 ) { if ( m_nAllocationCount ) { nBlockSize = m_nAllocationCount; } else { // Compute an allocation which is at least as big as a cache line... nBlockSize = ( 31 + sizeof( T ) ) / sizeof( T ); Assert( nBlockSize ); } } if ( nBlockSize < num ) { int n = ( num + nBlockSize -1 ) / nBlockSize; Assert( n * nBlockSize >= num ); Assert( ( n - 1 ) * nBlockSize < num ); nBlockSize *= n; } m_nAllocationCount += nBlockSize; MEM_ALLOC_CREDIT_CLASS(); BlockHeader_t * RESTRICT pBlockHeader = ( BlockHeader_t* )malloc( sizeof( BlockHeader_t ) + nBlockSize * sizeof( T ) ); if ( !pBlockHeader ) { Error( "CUtlFixedMemory overflow!\n" ); } pBlockHeader->m_pNext = NULL; pBlockHeader->m_nBlockSize = nBlockSize; if ( !m_pBlocks ) { m_pBlocks = pBlockHeader; } else { #if 1 // IsIdxAfter assumes that newly allocated blocks are at the end BlockHeader_t * RESTRICT pbh = m_pBlocks; while ( pbh->m_pNext ) { pbh = pbh->m_pNext; } pbh->m_pNext = pBlockHeader; #else pBlockHeader = m_pBlocks; pBlockHeader->m_pNext = m_pBlocks; #endif } } //----------------------------------------------------------------------------- // Makes sure we've got at least this much memory //----------------------------------------------------------------------------- template< class T > inline void CUtlFixedMemory::EnsureCapacity( int num ) { Grow( num - NumAllocated() ); } //----------------------------------------------------------------------------- // Memory deallocation //----------------------------------------------------------------------------- template< class T > void CUtlFixedMemory::Purge() { if ( !m_pBlocks ) return; for ( BlockHeader_t *pbh = m_pBlocks; pbh; ) { BlockHeader_t *pFree = pbh; pbh = pbh->m_pNext; free( pFree ); } m_pBlocks = NULL; m_nAllocationCount = 0; } #include "tier0/memdbgoff.h" #endif // UTLFIXEDMEMORY_H