Paranoia2/utils/common/utlmemory.h

906 lines
26 KiB
C++

//===== Copyright © 1996-2005, Valve Corporation, All rights reserved. ======//
//
// Purpose:
//
// $NoKeywords: $
//
// A growable memory class.
//===========================================================================//
#ifndef UTLMEMORY_H
#define UTLMEMORY_H
#ifdef _WIN32
#pragma once
#endif
#include <string.h>
#include <malloc.h>
#include <new.h>
#define ALIGN_VALUE( val, alignment ) (( val + alignment - 1 ) & ~( alignment - 1 ))
#define stackalloc( _size ) _alloca( ALIGN_VALUE( _size, 16 ) )
#define stackfree( _p ) 0
// Swap two of anything.
template <class T>
_forceinline void swap( T& x, T& y )
{
T temp = x;
x = y;
y = temp;
}
//-----------------------------------------------------------------------------
// Methods to invoke the constructor, copy constructor, and destructor
//-----------------------------------------------------------------------------
template <class T>
inline void Construct( T* pMemory )
{
new( pMemory ) T;
}
template <class T>
inline void CopyConstruct( T* pMemory, T const& src )
{
new( pMemory ) T(src);
}
template <class T>
inline void Destruct( T* pMemory )
{
pMemory->~T();
#ifdef _DEBUG
memset( pMemory, 0xDD, sizeof(T) );
#endif
}
#pragma warning (disable:4100)
#pragma warning (disable:4514)
//-----------------------------------------------------------------------------
// The CUtlMemory class:
// A growable memory class which doubles in size by default.
//-----------------------------------------------------------------------------
template< class T, class I = int >
class CUtlMemory
{
public:
// constructor, destructor
CUtlMemory( int nGrowSize = 0, int nInitSize = 0 );
CUtlMemory( T* pMemory, int numElements );
CUtlMemory( const T* pMemory, int numElements );
~CUtlMemory();
// Set the size by which the memory grows
void Init( int nGrowSize = 0, int nInitSize = 0 );
class Iterator_t
{
public:
Iterator_t( I i ) : index( i ) {}
I index;
bool operator==( const Iterator_t it ) const { return index == it.index; }
bool operator!=( const Iterator_t it ) const { return index != it.index; }
};
Iterator_t First() const { return Iterator_t( IsIdxValid( 0 ) ? 0 : InvalidIndex() ); }
Iterator_t Next( const Iterator_t &it ) const { return Iterator_t( IsIdxValid( it.index + 1 ) ? it.index + 1 : InvalidIndex() ); }
I GetIndex( const Iterator_t &it ) const { return it.index; }
bool IsIdxAfter( I i, const Iterator_t &it ) const { return i > it.index; }
bool IsValidIterator( const Iterator_t &it ) const { return IsIdxValid( it.index ); }
Iterator_t InvalidIterator() const { return Iterator_t( InvalidIndex() ); }
// element access
T& operator[]( I i );
const T& operator[]( I i ) const;
T& Element( I i );
const T& Element( I i ) const;
// Can we use this index?
bool IsIdxValid( I i ) const;
static I InvalidIndex() { return ( I )-1; }
// Gets the base address (can change when adding elements!)
T* Base();
const T* Base() const;
// Attaches the buffer to external memory....
void SetExternalBuffer( T* pMemory, int numElements );
void SetExternalBuffer( const T* pMemory, int numElements );
void AssumeMemory( T *pMemory, int nSize );
// Fast swap
void Swap( CUtlMemory< T, I > &mem );
// Switches the buffer from an external memory buffer to a reallocatable buffer
// Will copy the current contents of the external buffer to the reallocatable buffer
void ConvertToGrowableMemory( int nGrowSize );
// Size
int NumAllocated() const;
int Count() const;
// Grows the memory, so that at least allocated + num elements are allocated
void Grow( int num = 1 );
// Makes sure we've got at least this much memory
void EnsureCapacity( int num );
// Memory deallocation
void Purge();
// Purge all but the given number of elements
void Purge( int numElements );
// is the memory externally allocated?
bool IsExternallyAllocated() const;
// is the memory read only?
bool IsReadOnly() const;
// Set the size by which the memory grows
void SetGrowSize( int size );
protected:
void ValidateGrowSize()
{
#ifdef _X360
if ( m_nGrowSize && m_nGrowSize != EXTERNAL_BUFFER_MARKER )
{
// Max grow size at 128 bytes on XBOX
const int MAX_GROW = 128;
if ( m_nGrowSize * sizeof(T) > MAX_GROW )
{
m_nGrowSize = max( 1, MAX_GROW / sizeof(T) );
}
}
#endif
}
enum
{
EXTERNAL_BUFFER_MARKER = -1,
EXTERNAL_CONST_BUFFER_MARKER = -2,
};
T* m_pMemory;
int m_nAllocationCount;
int m_nGrowSize;
};
//-----------------------------------------------------------------------------
// The CUtlMemory class:
// A growable memory class which doubles in size by default.
//-----------------------------------------------------------------------------
template< class T, size_t SIZE, class I = int >
class CUtlMemoryFixedGrowable : public CUtlMemory< T, I >
{
typedef CUtlMemory< T, I > BaseClass;
public:
CUtlMemoryFixedGrowable( int nGrowSize = 0, int nInitSize = SIZE ) : BaseClass( m_pFixedMemory, SIZE )
{
assert( nInitSize == 0 || nInitSize == SIZE );
m_nMallocGrowSize = nGrowSize;
}
void Grow( int nCount = 1 )
{
if ( IsExternallyAllocated() )
{
ConvertToGrowableMemory( m_nMallocGrowSize );
}
BaseClass::Grow( nCount );
}
void EnsureCapacity( int num )
{
if ( CUtlMemory<T>::m_nAllocationCount >= num )
return;
if ( IsExternallyAllocated() )
{
// Can't grow a buffer whose memory was externally allocated
ConvertToGrowableMemory( m_nMallocGrowSize );
}
BaseClass::EnsureCapacity( num );
}
private:
int m_nMallocGrowSize;
T m_pFixedMemory[ SIZE ];
};
//-----------------------------------------------------------------------------
// The CUtlMemoryFixed class:
// A fixed memory class
//-----------------------------------------------------------------------------
template< typename T, size_t SIZE, int nAlignment = 0 >
class CUtlMemoryFixed
{
public:
// constructor, destructor
CUtlMemoryFixed( int nGrowSize = 0, int nInitSize = 0 ) { assert( nInitSize == 0 || nInitSize == SIZE ); }
CUtlMemoryFixed( T* pMemory, int numElements ) { assert( 0 ); }
// Can we use this index?
bool IsIdxValid( int i ) const { return (i >= 0) && (i < SIZE); }
static int InvalidIndex() { return -1; }
// Gets the base address
T* Base() { if ( nAlignment == 0 ) return (T*)(&m_Memory[0]); else return (T*)AlignValue( &m_Memory[0], nAlignment ); }
const T* Base() const { if ( nAlignment == 0 ) return (T*)(&m_Memory[0]); else return (T*)AlignValue( &m_Memory[0], nAlignment ); }
// element access
T& operator[]( int i ) { assert( IsIdxValid(i) ); return Base()[i]; }
const T& operator[]( int i ) const { assert( IsIdxValid(i) ); return Base()[i]; }
T& Element( int i ) { assert( IsIdxValid(i) ); return Base()[i]; }
const T& Element( int i ) const { assert( IsIdxValid(i) ); return Base()[i]; }
// Attaches the buffer to external memory....
void SetExternalBuffer( T* pMemory, int numElements ) { assert( 0 ); }
// Size
int NumAllocated() const { return SIZE; }
int Count() const { return SIZE; }
// Grows the memory, so that at least allocated + num elements are allocated
void Grow( int num = 1 ) { assert( 0 ); }
// Makes sure we've got at least this much memory
void EnsureCapacity( int num ) { assert( num <= SIZE ); }
// Memory deallocation
void Purge() {}
// Purge all but the given number of elements (NOT IMPLEMENTED IN CUtlMemoryFixed)
void Purge( int numElements ) { assert( 0 ); }
// is the memory externally allocated?
bool IsExternallyAllocated() const { return false; }
// Set the size by which the memory grows
void SetGrowSize( int size ) {}
class Iterator_t
{
public:
Iterator_t( int i ) : index( i ) {}
int index;
bool operator==( const Iterator_t it ) const { return index == it.index; }
bool operator!=( const Iterator_t it ) const { return index != it.index; }
};
Iterator_t First() const { return Iterator_t( IsIdxValid( 0 ) ? 0 : InvalidIndex() ); }
Iterator_t Next( const Iterator_t &it ) const { return Iterator_t( IsIdxValid( it.index + 1 ) ? it.index + 1 : InvalidIndex() ); }
int GetIndex( const Iterator_t &it ) const { return it.index; }
bool IsIdxAfter( int i, const Iterator_t &it ) const { return i > it.index; }
bool IsValidIterator( const Iterator_t &it ) const { return IsIdxValid( it.index ); }
Iterator_t InvalidIterator() const { return Iterator_t( InvalidIndex() ); }
private:
char m_Memory[ SIZE*sizeof(T) + nAlignment ];
};
//-----------------------------------------------------------------------------
// constructor, destructor
//-----------------------------------------------------------------------------
template< class T, class I >
CUtlMemory<T,I>::CUtlMemory( int nGrowSize, int nInitAllocationCount ) : m_pMemory(0),
m_nAllocationCount( nInitAllocationCount ), m_nGrowSize( nGrowSize )
{
ValidateGrowSize();
assert( nGrowSize >= 0 );
if (m_nAllocationCount)
{
m_pMemory = (T*)malloc( m_nAllocationCount * sizeof(T) );
}
}
template< class T, class I >
CUtlMemory<T,I>::CUtlMemory( T* pMemory, int numElements ) : m_pMemory(pMemory),
m_nAllocationCount( numElements )
{
// Special marker indicating externally supplied modifyable memory
m_nGrowSize = EXTERNAL_BUFFER_MARKER;
}
template< class T, class I >
CUtlMemory<T,I>::CUtlMemory( const T* pMemory, int numElements ) : m_pMemory( (T*)pMemory ),
m_nAllocationCount( numElements )
{
// Special marker indicating externally supplied modifyable memory
m_nGrowSize = EXTERNAL_CONST_BUFFER_MARKER;
}
template< class T, class I >
CUtlMemory<T,I>::~CUtlMemory()
{
Purge();
}
template< class T, class I >
void CUtlMemory<T,I>::Init( int nGrowSize /*= 0*/, int nInitSize /*= 0*/ )
{
Purge();
m_nGrowSize = nGrowSize;
m_nAllocationCount = nInitSize;
ValidateGrowSize();
assert( nGrowSize >= 0 );
if (m_nAllocationCount)
{
m_pMemory = (T*)malloc( m_nAllocationCount * sizeof(T) );
}
}
//-----------------------------------------------------------------------------
// Fast swap
//-----------------------------------------------------------------------------
template< class T, class I >
void CUtlMemory<T,I>::Swap( CUtlMemory<T,I> &mem )
{
swap( m_nGrowSize, mem.m_nGrowSize );
swap( m_pMemory, mem.m_pMemory );
swap( m_nAllocationCount, mem.m_nAllocationCount );
}
//-----------------------------------------------------------------------------
// Switches the buffer from an external memory buffer to a reallocatable buffer
//-----------------------------------------------------------------------------
template< class T, class I >
void CUtlMemory<T,I>::ConvertToGrowableMemory( int nGrowSize )
{
if ( !IsExternallyAllocated() )
return;
m_nGrowSize = nGrowSize;
if (m_nAllocationCount)
{
int nNumBytes = m_nAllocationCount * sizeof(T);
T *pMemory = (T*)malloc( nNumBytes );
memcpy( pMemory, m_pMemory, nNumBytes );
m_pMemory = pMemory;
}
else
{
m_pMemory = NULL;
}
}
//-----------------------------------------------------------------------------
// Attaches the buffer to external memory....
//-----------------------------------------------------------------------------
template< class T, class I >
void CUtlMemory<T,I>::SetExternalBuffer( T* pMemory, int numElements )
{
// Blow away any existing allocated memory
Purge();
m_pMemory = pMemory;
m_nAllocationCount = numElements;
// Indicate that we don't own the memory
m_nGrowSize = EXTERNAL_BUFFER_MARKER;
}
template< class T, class I >
void CUtlMemory<T,I>::SetExternalBuffer( const T* pMemory, int numElements )
{
// Blow away any existing allocated memory
Purge();
m_pMemory = const_cast<T*>( pMemory );
m_nAllocationCount = numElements;
// Indicate that we don't own the memory
m_nGrowSize = EXTERNAL_CONST_BUFFER_MARKER;
}
template< class T, class I >
void CUtlMemory<T,I>::AssumeMemory( T* pMemory, int numElements )
{
// Blow away any existing allocated memory
Purge();
// Simply take the pointer but don't mark us as external
m_pMemory = pMemory;
m_nAllocationCount = numElements;
}
//-----------------------------------------------------------------------------
// element access
//-----------------------------------------------------------------------------
template< class T, class I >
inline T& CUtlMemory<T,I>::operator[]( I i )
{
assert( !IsReadOnly() );
assert( IsIdxValid(i) );
return m_pMemory[i];
}
template< class T, class I >
inline const T& CUtlMemory<T,I>::operator[]( I i ) const
{
assert( IsIdxValid(i) );
return m_pMemory[i];
}
template< class T, class I >
inline T& CUtlMemory<T,I>::Element( I i )
{
assert( !IsReadOnly() );
assert( IsIdxValid(i) );
return m_pMemory[i];
}
template< class T, class I >
inline const T& CUtlMemory<T,I>::Element( I i ) const
{
assert( IsIdxValid(i) );
return m_pMemory[i];
}
//-----------------------------------------------------------------------------
// is the memory externally allocated?
//-----------------------------------------------------------------------------
template< class T, class I >
bool CUtlMemory<T,I>::IsExternallyAllocated() const
{
return (m_nGrowSize < 0);
}
//-----------------------------------------------------------------------------
// is the memory read only?
//-----------------------------------------------------------------------------
template< class T, class I >
bool CUtlMemory<T,I>::IsReadOnly() const
{
return (m_nGrowSize == EXTERNAL_CONST_BUFFER_MARKER);
}
template< class T, class I >
void CUtlMemory<T,I>::SetGrowSize( int nSize )
{
assert( !IsExternallyAllocated() );
assert( nSize >= 0 );
m_nGrowSize = nSize;
ValidateGrowSize();
}
//-----------------------------------------------------------------------------
// Gets the base address (can change when adding elements!)
//-----------------------------------------------------------------------------
template< class T, class I >
inline T* CUtlMemory<T,I>::Base()
{
assert( !IsReadOnly() );
return m_pMemory;
}
template< class T, class I >
inline const T *CUtlMemory<T,I>::Base() const
{
return m_pMemory;
}
//-----------------------------------------------------------------------------
// Size
//-----------------------------------------------------------------------------
template< class T, class I >
inline int CUtlMemory<T,I>::NumAllocated() const
{
return m_nAllocationCount;
}
template< class T, class I >
inline int CUtlMemory<T,I>::Count() const
{
return m_nAllocationCount;
}
//-----------------------------------------------------------------------------
// Is element index valid?
//-----------------------------------------------------------------------------
template< class T, class I >
inline bool CUtlMemory<T,I>::IsIdxValid( I i ) const
{
return ( ((int) i) >= 0 ) && ( ((int) i) < m_nAllocationCount );
}
//-----------------------------------------------------------------------------
// Grows the memory
//-----------------------------------------------------------------------------
inline int UtlMemory_CalcNewAllocationCount( int nAllocationCount, int nGrowSize, int nNewSize, int nBytesItem )
{
if ( nGrowSize )
{
nAllocationCount = ((1 + ((nNewSize - 1) / nGrowSize)) * nGrowSize);
}
else
{
if ( !nAllocationCount )
{
// Compute an allocation which is at least as big as a cache line...
nAllocationCount = (31 + nBytesItem) / nBytesItem;
}
while (nAllocationCount < nNewSize)
{
#ifndef _X360
nAllocationCount *= 2;
#else
int nNewAllocationCount = ( nAllocationCount * 9) / 8; // 12.5 %
if ( nNewAllocationCount > nAllocationCount )
nAllocationCount = nNewAllocationCount;
else
nAllocationCount *= 2;
#endif
}
}
return nAllocationCount;
}
template< class T, class I >
void CUtlMemory<T,I>::Grow( int num )
{
assert( num > 0 );
if ( IsExternallyAllocated() )
{
// Can't grow a buffer whose memory was externally allocated
assert(0);
return;
}
// Make sure we have at least numallocated + num allocations.
// Use the grow rules specified for this memory (in m_nGrowSize)
int nAllocationRequested = m_nAllocationCount + num;
m_nAllocationCount = UtlMemory_CalcNewAllocationCount( m_nAllocationCount, m_nGrowSize, nAllocationRequested, sizeof(T) );
// if m_nAllocationRequested wraps index type I, recalculate
if ( ( int )( I )m_nAllocationCount < nAllocationRequested )
{
if ( ( int )( I )m_nAllocationCount == 0 && ( int )( I )( m_nAllocationCount - 1 ) >= nAllocationRequested )
{
--m_nAllocationCount; // deal w/ the common case of m_nAllocationCount == MAX_USHORT + 1
}
else
{
if ( ( int )( I )nAllocationRequested != nAllocationRequested )
{
// we've been asked to grow memory to a size s.t. the index type can't address the requested amount of memory
assert( 0 );
return;
}
while ( ( int )( I )m_nAllocationCount < nAllocationRequested )
{
m_nAllocationCount = ( m_nAllocationCount + nAllocationRequested ) / 2;
}
}
}
if (m_pMemory)
{
m_pMemory = (T*)realloc( m_pMemory, m_nAllocationCount * sizeof(T) );
ASSERT( m_pMemory );
}
else
{
m_pMemory = (T*)malloc( m_nAllocationCount * sizeof(T) );
ASSERT( m_pMemory );
}
}
//-----------------------------------------------------------------------------
// Makes sure we've got at least this much memory
//-----------------------------------------------------------------------------
template< class T, class I >
inline void CUtlMemory<T,I>::EnsureCapacity( int num )
{
if (m_nAllocationCount >= num)
return;
if ( IsExternallyAllocated() )
{
// Can't grow a buffer whose memory was externally allocated
assert(0);
return;
}
m_nAllocationCount = num;
if (m_pMemory)
{
m_pMemory = (T*)realloc( m_pMemory, m_nAllocationCount * sizeof(T) );
}
else
{
m_pMemory = (T*)malloc( m_nAllocationCount * sizeof(T) );
}
}
//-----------------------------------------------------------------------------
// Memory deallocation
//-----------------------------------------------------------------------------
template< class T, class I >
void CUtlMemory<T,I>::Purge()
{
if ( !IsExternallyAllocated() )
{
if (m_pMemory)
{
free( (void*)m_pMemory );
m_pMemory = 0;
}
m_nAllocationCount = 0;
}
}
template< class T, class I >
void CUtlMemory<T,I>::Purge( int numElements )
{
assert( numElements >= 0 );
if( numElements > m_nAllocationCount )
{
// Ensure this isn't a grow request in disguise.
assert( numElements <= m_nAllocationCount );
return;
}
// If we have zero elements, simply do a purge:
if( numElements == 0 )
{
Purge();
return;
}
if ( IsExternallyAllocated() )
{
// Can't shrink a buffer whose memory was externally allocated, fail silently like purge
return;
}
// If the number of elements is the same as the allocation count, we are done.
if( numElements == m_nAllocationCount )
{
return;
}
if( !m_pMemory )
{
// Allocation count is non zero, but memory is null.
assert( m_pMemory );
return;
}
m_nAllocationCount = numElements;
// Allocation count > 0, shrink it down.
m_pMemory = (T*)realloc( m_pMemory, m_nAllocationCount * sizeof(T) );
}
//-----------------------------------------------------------------------------
// The CUtlMemory class:
// A growable memory class which doubles in size by default.
//-----------------------------------------------------------------------------
template< class T, int nAlignment >
class CUtlMemoryAligned : public CUtlMemory<T>
{
public:
// constructor, destructor
CUtlMemoryAligned( int nGrowSize = 0, int nInitSize = 0 );
CUtlMemoryAligned( T* pMemory, int numElements );
CUtlMemoryAligned( const T* pMemory, int numElements );
~CUtlMemoryAligned();
// Attaches the buffer to external memory....
void SetExternalBuffer( T* pMemory, int numElements );
void SetExternalBuffer( const T* pMemory, int numElements );
// Grows the memory, so that at least allocated + num elements are allocated
void Grow( int num = 1 );
// Makes sure we've got at least this much memory
void EnsureCapacity( int num );
// Memory deallocation
void Purge();
// Purge all but the given number of elements (NOT IMPLEMENTED IN CUtlMemoryAligned)
void Purge( int numElements ) { assert( 0 ); }
private:
void *Align( const void *pAddr );
};
//-----------------------------------------------------------------------------
// Aligns a pointer
//-----------------------------------------------------------------------------
template< class T, int nAlignment >
void *CUtlMemoryAligned<T, nAlignment>::Align( const void *pAddr )
{
size_t nAlignmentMask = nAlignment - 1;
return (void*)( ((size_t)pAddr + nAlignmentMask) & (~nAlignmentMask) );
}
//-----------------------------------------------------------------------------
// constructor, destructor
//-----------------------------------------------------------------------------
template< class T, int nAlignment >
CUtlMemoryAligned<T, nAlignment>::CUtlMemoryAligned( int nGrowSize, int nInitAllocationCount )
{
CUtlMemory<T>::m_pMemory = 0;
CUtlMemory<T>::m_nAllocationCount = nInitAllocationCount;
CUtlMemory<T>::m_nGrowSize = nGrowSize;
ValidateGrowSize();
// Alignment must be a power of two
COMPILE_TIME_ASSERT( (nAlignment & (nAlignment-1)) == 0 );
assert( (nGrowSize >= 0) && (nGrowSize != CUtlMemory<T>::EXTERNAL_BUFFER_MARKER) );
if ( CUtlMemory<T>::m_nAllocationCount )
{
CUtlMemory<T>::m_pMemory = (T*)_aligned_malloc( nInitAllocationCount * sizeof(T), nAlignment );
}
}
template< class T, int nAlignment >
CUtlMemoryAligned<T, nAlignment>::CUtlMemoryAligned( T* pMemory, int numElements )
{
// Special marker indicating externally supplied memory
CUtlMemory<T>::m_nGrowSize = CUtlMemory<T>::EXTERNAL_BUFFER_MARKER;
CUtlMemory<T>::m_pMemory = (T*)Align( pMemory );
CUtlMemory<T>::m_nAllocationCount = ( (int)(pMemory + numElements) - (int)CUtlMemory<T>::m_pMemory ) / sizeof(T);
}
template< class T, int nAlignment >
CUtlMemoryAligned<T, nAlignment>::CUtlMemoryAligned( const T* pMemory, int numElements )
{
// Special marker indicating externally supplied memory
CUtlMemory<T>::m_nGrowSize = CUtlMemory<T>::EXTERNAL_CONST_BUFFER_MARKER;
CUtlMemory<T>::m_pMemory = (T*)Align( pMemory );
CUtlMemory<T>::m_nAllocationCount = ( (int)(pMemory + numElements) - (int)CUtlMemory<T>::m_pMemory ) / sizeof(T);
}
template< class T, int nAlignment >
CUtlMemoryAligned<T, nAlignment>::~CUtlMemoryAligned()
{
Purge();
}
//-----------------------------------------------------------------------------
// Attaches the buffer to external memory....
//-----------------------------------------------------------------------------
template< class T, int nAlignment >
void CUtlMemoryAligned<T, nAlignment>::SetExternalBuffer( T* pMemory, int numElements )
{
// Blow away any existing allocated memory
Purge();
CUtlMemory<T>::m_pMemory = (T*)Align( pMemory );
CUtlMemory<T>::m_nAllocationCount = ( (int)(pMemory + numElements) - (int)CUtlMemory<T>::m_pMemory ) / sizeof(T);
// Indicate that we don't own the memory
CUtlMemory<T>::m_nGrowSize = CUtlMemory<T>::EXTERNAL_BUFFER_MARKER;
}
template< class T, int nAlignment >
void CUtlMemoryAligned<T, nAlignment>::SetExternalBuffer( const T* pMemory, int numElements )
{
// Blow away any existing allocated memory
Purge();
CUtlMemory<T>::m_pMemory = (T*)Align( pMemory );
CUtlMemory<T>::m_nAllocationCount = ( (int)(pMemory + numElements) - (int)CUtlMemory<T>::m_pMemory ) / sizeof(T);
// Indicate that we don't own the memory
CUtlMemory<T>::m_nGrowSize = CUtlMemory<T>::EXTERNAL_CONST_BUFFER_MARKER;
}
//-----------------------------------------------------------------------------
// Grows the memory
//-----------------------------------------------------------------------------
template< class T, int nAlignment >
void CUtlMemoryAligned<T, nAlignment>::Grow( int num )
{
assert( num > 0 );
if ( IsExternallyAllocated() )
{
// Can't grow a buffer whose memory was externally allocated
assert(0);
return;
}
// Make sure we have at least numallocated + num allocations.
// Use the grow rules specified for this memory (in m_nGrowSize)
int nAllocationRequested = CUtlMemory<T>::m_nAllocationCount + num;
CUtlMemory<T>::m_nAllocationCount = UtlMemory_CalcNewAllocationCount( CUtlMemory<T>::m_nAllocationCount, CUtlMemory<T>::m_nGrowSize, nAllocationRequested, sizeof(T) );
if ( CUtlMemory<T>::m_pMemory )
{
CUtlMemory<T>::m_pMemory = (T*)_aligned_realloc( CUtlMemory<T>::m_pMemory, CUtlMemory<T>::m_nAllocationCount * sizeof(T), nAlignment );
assert( CUtlMemory<T>::m_pMemory );
}
else
{
CUtlMemory<T>::m_pMemory = (T*)_aligned_malloc( CUtlMemory<T>::m_nAllocationCount * sizeof(T), nAlignment );
assert( CUtlMemory<T>::m_pMemory );
}
}
//-----------------------------------------------------------------------------
// Makes sure we've got at least this much memory
//-----------------------------------------------------------------------------
template< class T, int nAlignment >
inline void CUtlMemoryAligned<T, nAlignment>::EnsureCapacity( int num )
{
if ( CUtlMemory<T>::m_nAllocationCount >= num )
return;
if ( IsExternallyAllocated() )
{
// Can't grow a buffer whose memory was externally allocated
assert(0);
return;
}
CUtlMemory<T>::m_nAllocationCount = num;
if ( CUtlMemory<T>::m_pMemory )
{
CUtlMemory<T>::m_pMemory = (T*)_aligned_realloc( CUtlMemory<T>::m_pMemory, CUtlMemory<T>::m_nAllocationCount * sizeof(T), nAlignment );
}
else
{
CUtlMemory<T>::m_pMemory = (T*)_aligned_malloc( CUtlMemory<T>::m_nAllocationCount * sizeof(T), nAlignment );
}
}
//-----------------------------------------------------------------------------
// Memory deallocation
//-----------------------------------------------------------------------------
template< class T, int nAlignment >
void CUtlMemoryAligned<T, nAlignment>::Purge()
{
if ( !IsExternallyAllocated() )
{
if ( CUtlMemory<T>::m_pMemory )
{
_aligned_free( CUtlMemory<T>::m_pMemory );
CUtlMemory<T>::m_pMemory = 0;
}
CUtlMemory<T>::m_nAllocationCount = 0;
}
}
#endif // UTLMEMORY_H