Paranoia2/utils/common/utlarray.h

771 lines
22 KiB
C++

//====== Copyright © 1996-2005, Valve Corporation, All rights reserved. =======//
//
// Purpose:
//
// $NoKeywords: $
//
// A growable array class that maintains a free list and keeps elements
// in the same location
//=============================================================================//
#ifndef UTLVECTOR_H
#define UTLVECTOR_H
#ifdef _WIN32
#pragma once
#endif
#include <assert.h>
#include <string.h>
#include "utlmemory.h"
#include "utlblockmemory.h"
#define FOR_EACH_VEC( vecName, iteratorName ) \
for ( int iteratorName = 0; iteratorName < vecName.Count(); iteratorName++ )
//-----------------------------------------------------------------------------
// The CUtlArray class:
// A growable array class which doubles in size by default.
// It will always keep all elements consecutive in memory, and may move the
// elements around in memory (via a PvRealloc) when elements are inserted or
// removed. Clients should therefore refer to the elements of the vector
// by index (they should *never* maintain pointers to elements in the vector).
//-----------------------------------------------------------------------------
template< class T, class A = CUtlMemory<T> >
class CUtlArray
{
typedef A CAllocator;
public:
typedef T ElemType_t;
// constructor, destructor
CUtlArray( int growSize = 0, int initSize = 0 );
CUtlArray( T* pMemory, int allocationCount, int numElements = 0 );
~CUtlArray();
// Copy the array.
CUtlArray<T, A>& operator=( const CUtlArray<T, A> &other );
// element access
T& operator[]( int i );
const T& operator[]( int i ) const;
T& Element( int i );
const T& Element( int i ) const;
T& Head();
const T& Head() const;
T& Tail();
const T& Tail() const;
// Gets the base address (can change when adding elements!)
T* Base() { return m_Memory.Base(); }
const T* Base() const { return m_Memory.Base(); }
// Returns the number of elements in the vector
// SIZE IS DEPRECATED!
int Count() const;
int Size() const; // don't use me!
// Is element index valid?
bool IsValidIndex( int i ) const;
static int InvalidIndex();
// Adds an element, uses default constructor
int AddToHead();
int AddToTail();
int InsertBefore( int elem );
int InsertAfter( int elem );
// Adds an element, uses copy constructor
int AddToHead( const T& src );
int AddToTail( const T& src );
int InsertBefore( int elem, const T& src );
int InsertAfter( int elem, const T& src );
// Adds multiple elements, uses default constructor
int AddMultipleToHead( int num );
int AddMultipleToTail( int num, const T *pToCopy=NULL );
int InsertMultipleBefore( int elem, int num, const T *pToCopy=NULL ); // If pToCopy is set, then it's an array of length 'num' and
int InsertMultipleAfter( int elem, int num );
// Calls RemoveAll() then AddMultipleToTail.
void SetSize( int size );
void SetCount( int count );
// Calls SetSize and copies each element.
void CopyArray( const T *pArray, int size );
// Fast swap
void Swap( CUtlArray< T, A > &vec );
// Add the specified array to the tail.
int AddVectorToTail( CUtlArray<T, A> const &src );
// Finds an element (element needs operator== defined)
int Find( const T& src ) const;
bool HasElement( const T& src ) const;
// Makes sure we have enough memory allocated to store a requested # of elements
void EnsureCapacity( int num );
// Makes sure we have at least this many elements
void EnsureCount( int num );
// Element removal
void FastRemove( int elem ); // doesn't preserve order
void Remove( int elem ); // preserves order, shifts elements
bool FindAndRemove( const T& src ); // removes first occurrence of src, preserves order, shifts elements
void RemoveMultiple( int elem, int num ); // preserves order, shifts elements
void RemoveAll(); // doesn't deallocate memory
// Memory deallocation
void Purge();
// Purges the list and calls delete on each element in it.
void PurgeAndDeleteElements();
// Compacts the vector to the number of elements actually in use
void Compact();
// Set the size by which it grows when it needs to allocate more memory.
void SetGrowSize( int size ) { m_Memory.SetGrowSize( size ); }
int NumAllocated() const; // Only use this if you really know what you're doing!
void Sort( int (__cdecl *pfnCompare)(const T *, const T *) );
#ifdef DBGFLAG_VALIDATE
void Validate( CValidator &validator, char *pchName ); // Validate our internal structures
#endif // DBGFLAG_VALIDATE
protected:
// Can't copy this unless we explicitly do it!
CUtlArray( CUtlArray const& vec ) { assert(0); }
// Grows the vector
void GrowVector( int num = 1 );
// Shifts elements....
void ShiftElementsRight( int elem, int num = 1 );
void ShiftElementsLeft( int elem, int num = 1 );
CAllocator m_Memory;
int m_Size;
// For easier access to the elements through the debugger
// it's in release builds so this can be used in libraries correctly
T *m_pElements;
inline void ResetDbgInfo()
{
m_pElements = Base();
}
};
// this is kind of ugly, but until C++ gets templatized typedefs in C++0x, it's our only choice
template < class T >
class CUtlBlockVector : public CUtlArray< T, CUtlBlockMemory< T, int > >
{
public:
CUtlBlockVector( int growSize = 0, int initSize = 0 )
: CUtlArray< T, CUtlBlockMemory< T, int > >( growSize, initSize ) {}
};
//-----------------------------------------------------------------------------
// The CUtlArrayFixed class:
// A array class with a fixed allocation scheme
//-----------------------------------------------------------------------------
template< class BASE_UTLVECTOR, class MUTEX_TYPE = CThreadFastMutex >
class CUtlArrayMT : public BASE_UTLVECTOR, public MUTEX_TYPE
{
typedef BASE_UTLVECTOR BaseClass;
public:
MUTEX_TYPE Mutex_t;
// constructor, destructor
CUtlArrayMT( int growSize = 0, int initSize = 0 ) : BaseClass( growSize, initSize ) {}
CUtlArrayMT( typename BaseClass::ElemType_t* pMemory, int numElements ) : BaseClass( pMemory, numElements ) {}
};
//-----------------------------------------------------------------------------
// The CUtlArrayFixed class:
// A array class with a fixed allocation scheme
//-----------------------------------------------------------------------------
template< class T, size_t MAX_SIZE >
class CUtlArrayFixed : public CUtlArray< T, CUtlMemoryFixed<T, MAX_SIZE > >
{
typedef CUtlArray< T, CUtlMemoryFixed<T, MAX_SIZE > > BaseClass;
public:
// constructor, destructor
CUtlArrayFixed( int growSize = 0, int initSize = 0 ) : BaseClass( growSize, initSize ) {}
CUtlArrayFixed( T* pMemory, int numElements ) : BaseClass( pMemory, numElements ) {}
};
//-----------------------------------------------------------------------------
// The CUtlArrayFixed class:
// A array class with a fixed allocation scheme
//-----------------------------------------------------------------------------
template< class T, size_t MAX_SIZE >
class CUtlArrayFixedGrowable : public CUtlArray< T, CUtlMemoryFixedGrowable<T, MAX_SIZE > >
{
typedef CUtlArray< T, CUtlMemoryFixedGrowable<T, MAX_SIZE > > BaseClass;
public:
// constructor, destructor
CUtlArrayFixedGrowable( int growSize = 0 ) : BaseClass( growSize, MAX_SIZE ) {}
};
//-----------------------------------------------------------------------------
// The CCopyableUtlVector class:
// A array class that allows copy construction (so you can nest a CUtlArray inside of another one of our containers)
// WARNING - this class lets you copy construct which can be an expensive operation if you don't carefully control when it happens
// Only use this when nesting a CUtlArray() inside of another one of our container classes (i.e a CUtlMap)
//-----------------------------------------------------------------------------
template< class T >
class CCopyableUtlVector : public CUtlArray< T, CUtlMemory<T> >
{
typedef CUtlArray< T, CUtlMemory<T> > BaseClass;
public:
CCopyableUtlVector( int growSize = 0, int initSize = 0 ) : BaseClass( growSize, initSize ) {}
CCopyableUtlVector( T* pMemory, int numElements ) : BaseClass( pMemory, numElements ) {}
virtual ~CCopyableUtlVector() {}
CCopyableUtlVector( CCopyableUtlVector const& vec ) { CopyArray( vec.Base(), vec.Count() ); }
};
//-----------------------------------------------------------------------------
// constructor, destructor
//-----------------------------------------------------------------------------
template< typename T, class A >
inline CUtlArray<T, A>::CUtlArray( int growSize, int initSize ) :
m_Memory(growSize, initSize), m_Size(0)
{
ResetDbgInfo();
}
template< typename T, class A >
inline CUtlArray<T, A>::CUtlArray( T* pMemory, int allocationCount, int numElements ) :
m_Memory(pMemory, allocationCount), m_Size(numElements)
{
ResetDbgInfo();
}
template< typename T, class A >
inline CUtlArray<T, A>::~CUtlArray()
{
Purge();
}
template< typename T, class A >
inline CUtlArray<T, A>& CUtlArray<T, A>::operator=( const CUtlArray<T, A> &other )
{
int nCount = other.Count();
SetSize( nCount );
for ( int i = 0; i < nCount; i++ )
{
(*this)[ i ] = other[ i ];
}
return *this;
}
//-----------------------------------------------------------------------------
// element access
//-----------------------------------------------------------------------------
template< typename T, class A >
inline T& CUtlArray<T, A>::operator[]( int i )
{
return m_Memory[ i ];
}
template< typename T, class A >
inline const T& CUtlArray<T, A>::operator[]( int i ) const
{
return m_Memory[ i ];
}
template< typename T, class A >
inline T& CUtlArray<T, A>::Element( int i )
{
return m_Memory[ i ];
}
template< typename T, class A >
inline const T& CUtlArray<T, A>::Element( int i ) const
{
return m_Memory[ i ];
}
template< typename T, class A >
inline T& CUtlArray<T, A>::Head()
{
assert( m_Size > 0 );
return m_Memory[ 0 ];
}
template< typename T, class A >
inline const T& CUtlArray<T, A>::Head() const
{
assert( m_Size > 0 );
return m_Memory[ 0 ];
}
template< typename T, class A >
inline T& CUtlArray<T, A>::Tail()
{
assert( m_Size > 0 );
return m_Memory[ m_Size - 1 ];
}
template< typename T, class A >
inline const T& CUtlArray<T, A>::Tail() const
{
assert( m_Size > 0 );
return m_Memory[ m_Size - 1 ];
}
//-----------------------------------------------------------------------------
// Count
//-----------------------------------------------------------------------------
template< typename T, class A >
inline int CUtlArray<T, A>::Size() const
{
return m_Size;
}
template< typename T, class A >
inline int CUtlArray<T, A>::Count() const
{
return m_Size;
}
//-----------------------------------------------------------------------------
// Is element index valid?
//-----------------------------------------------------------------------------
template< typename T, class A >
inline bool CUtlArray<T, A>::IsValidIndex( int i ) const
{
return (i >= 0) && (i < m_Size);
}
//-----------------------------------------------------------------------------
// Returns in invalid index
//-----------------------------------------------------------------------------
template< typename T, class A >
inline int CUtlArray<T, A>::InvalidIndex()
{
return -1;
}
//-----------------------------------------------------------------------------
// Grows the vector
//-----------------------------------------------------------------------------
template< typename T, class A >
void CUtlArray<T, A>::GrowVector( int num )
{
if (m_Size + num > m_Memory.NumAllocated())
{
m_Memory.Grow( m_Size + num - m_Memory.NumAllocated() );
}
m_Size += num;
ResetDbgInfo();
}
//-----------------------------------------------------------------------------
// Sorts the vector
//-----------------------------------------------------------------------------
template< typename T, class A >
void CUtlArray<T, A>::Sort( int (__cdecl *pfnCompare)(const T *, const T *) )
{
typedef int (__cdecl *QSortCompareFunc_t)(const void *, const void *);
if ( Count() <= 1 )
return;
if ( Base() )
{
qsort( Base(), Count(), sizeof(T), (QSortCompareFunc_t)(pfnCompare) );
}
else
{
assert( 0 );
// this path is untested
// if you want to sort vectors that use a non-sequential memory allocator,
// you'll probably want to patch in a quicksort algorithm here
// I just threw in this bubble sort to have something just in case...
for ( int i = m_Size - 1; i >= 0; --i )
{
for ( int j = 1; j <= i; ++j )
{
if ( pfnCompare( &Element( j - 1 ), &Element( j ) ) < 0 )
{
swap( Element( j - 1 ), Element( j ) );
}
}
}
}
}
//-----------------------------------------------------------------------------
// Makes sure we have enough memory allocated to store a requested # of elements
//-----------------------------------------------------------------------------
template< typename T, class A >
void CUtlArray<T, A>::EnsureCapacity( int num )
{
m_Memory.EnsureCapacity(num);
ResetDbgInfo();
}
//-----------------------------------------------------------------------------
// Makes sure we have at least this many elements
//-----------------------------------------------------------------------------
template< typename T, class A >
void CUtlArray<T, A>::EnsureCount( int num )
{
if (Count() < num)
AddMultipleToTail( num - Count() );
}
//-----------------------------------------------------------------------------
// Shifts elements
//-----------------------------------------------------------------------------
template< typename T, class A >
void CUtlArray<T, A>::ShiftElementsRight( int elem, int num )
{
assert( IsValidIndex(elem) || ( m_Size == 0 ) || ( num == 0 ));
int numToMove = m_Size - elem - num;
if ((numToMove > 0) && (num > 0))
memmove( &Element(elem+num), &Element(elem), numToMove * sizeof(T) );
}
template< typename T, class A >
void CUtlArray<T, A>::ShiftElementsLeft( int elem, int num )
{
assert( IsValidIndex(elem) || ( m_Size == 0 ) || ( num == 0 ));
int numToMove = m_Size - elem - num;
if ((numToMove > 0) && (num > 0))
{
memmove( &Element(elem), &Element(elem+num), numToMove * sizeof(T) );
#ifdef _DEBUG
memset( &Element(m_Size-num), 0xDD, num * sizeof(T) );
#endif
}
}
//-----------------------------------------------------------------------------
// Adds an element, uses default constructor
//-----------------------------------------------------------------------------
template< typename T, class A >
inline int CUtlArray<T, A>::AddToHead()
{
return InsertBefore(0);
}
template< typename T, class A >
inline int CUtlArray<T, A>::AddToTail()
{
return InsertBefore( m_Size );
}
template< typename T, class A >
inline int CUtlArray<T, A>::InsertAfter( int elem )
{
return InsertBefore( elem + 1 );
}
template< typename T, class A >
int CUtlArray<T, A>::InsertBefore( int elem )
{
// Can insert at the end
assert( (elem == Count()) || IsValidIndex(elem) );
GrowVector();
ShiftElementsRight(elem);
Construct( &Element(elem) );
return elem;
}
//-----------------------------------------------------------------------------
// Adds an element, uses copy constructor
//-----------------------------------------------------------------------------
template< typename T, class A >
inline int CUtlArray<T, A>::AddToHead( const T& src )
{
// Can't insert something that's in the list... reallocation may hose us
assert( (Base() == NULL) || (&src < Base()) || (&src >= (Base() + Count()) ) );
return InsertBefore( 0, src );
}
template< typename T, class A >
inline int CUtlArray<T, A>::AddToTail( const T& src )
{
// Can't insert something that's in the list... reallocation may hose us
assert( (Base() == NULL) || (&src < Base()) || (&src >= (Base() + Count()) ) );
return InsertBefore( m_Size, src );
}
template< typename T, class A >
inline int CUtlArray<T, A>::InsertAfter( int elem, const T& src )
{
// Can't insert something that's in the list... reallocation may hose us
assert( (Base() == NULL) || (&src < Base()) || (&src >= (Base() + Count()) ) );
return InsertBefore( elem + 1, src );
}
template< typename T, class A >
int CUtlArray<T, A>::InsertBefore( int elem, const T& src )
{
// Can't insert something that's in the list... reallocation may hose us
assert( (Base() == NULL) || (&src < Base()) || (&src >= (Base() + Count()) ) );
// Can insert at the end
assert( (elem == Count()) || IsValidIndex(elem) );
GrowVector();
ShiftElementsRight(elem);
CopyConstruct( &Element(elem), src );
return elem;
}
//-----------------------------------------------------------------------------
// Adds multiple elements, uses default constructor
//-----------------------------------------------------------------------------
template< typename T, class A >
inline int CUtlArray<T, A>::AddMultipleToHead( int num )
{
return InsertMultipleBefore( 0, num );
}
template< typename T, class A >
inline int CUtlArray<T, A>::AddMultipleToTail( int num, const T *pToCopy )
{
// Can't insert something that's in the list... reallocation may hose us
assert( (Base() == NULL) || !pToCopy || (pToCopy + num < Base()) || (pToCopy >= (Base() + Count()) ) );
return InsertMultipleBefore( m_Size, num, pToCopy );
}
template< typename T, class A >
int CUtlArray<T, A>::InsertMultipleAfter( int elem, int num )
{
return InsertMultipleBefore( elem + 1, num );
}
template< typename T, class A >
void CUtlArray<T, A>::SetCount( int count )
{
RemoveAll();
AddMultipleToTail( count );
}
template< typename T, class A >
inline void CUtlArray<T, A>::SetSize( int size )
{
SetCount( size );
}
template< typename T, class A >
void CUtlArray<T, A>::CopyArray( const T *pArray, int size )
{
// Can't insert something that's in the list... reallocation may hose us
assert( (Base() == NULL) || !pArray || (Base() >= (pArray + size)) || (pArray >= (Base() + Count()) ) );
SetSize( size );
for( int i=0; i < size; i++ )
{
(*this)[i] = pArray[i];
}
}
template< typename T, class A >
void CUtlArray<T, A>::Swap( CUtlArray< T, A > &vec )
{
m_Memory.Swap( vec.m_Memory );
swap( m_Size, vec.m_Size );
swap( m_pElements, vec.m_pElements );
}
template< typename T, class A >
int CUtlArray<T, A>::AddVectorToTail( CUtlArray const &src )
{
assert( &src != this );
int base = Count();
// Make space.
AddMultipleToTail( src.Count() );
// Copy the elements.
for ( int i=0; i < src.Count(); i++ )
{
(*this)[base + i] = src[i];
}
return base;
}
template< typename T, class A >
inline int CUtlArray<T, A>::InsertMultipleBefore( int elem, int num, const T *pToInsert )
{
if( num == 0 )
return elem;
// Can insert at the end
assert( (elem == Count()) || IsValidIndex(elem) );
GrowVector(num);
ShiftElementsRight(elem, num);
// Invoke default constructors
for (int i = 0; i < num; ++i)
Construct( &Element(elem+i) );
// Copy stuff in?
if ( pToInsert )
{
for ( int i=0; i < num; i++ )
{
Element( elem+i ) = pToInsert[i];
}
}
return elem;
}
//-----------------------------------------------------------------------------
// Finds an element (element needs operator== defined)
//-----------------------------------------------------------------------------
template< typename T, class A >
int CUtlArray<T, A>::Find( const T& src ) const
{
for ( int i = 0; i < Count(); ++i )
{
if (Element(i) == src)
return i;
}
return -1;
}
template< typename T, class A >
bool CUtlArray<T, A>::HasElement( const T& src ) const
{
return ( Find(src) >= 0 );
}
//-----------------------------------------------------------------------------
// Element removal
//-----------------------------------------------------------------------------
template< typename T, class A >
void CUtlArray<T, A>::FastRemove( int elem )
{
assert( IsValidIndex(elem) );
Destruct( &Element(elem) );
if (m_Size > 0)
{
memcpy( &Element(elem), &Element(m_Size-1), sizeof(T) );
--m_Size;
}
}
template< typename T, class A >
void CUtlArray<T, A>::Remove( int elem )
{
Destruct( &Element(elem) );
ShiftElementsLeft(elem);
--m_Size;
}
template< typename T, class A >
bool CUtlArray<T, A>::FindAndRemove( const T& src )
{
int elem = Find( src );
if ( elem != -1 )
{
Remove( elem );
return true;
}
return false;
}
template< typename T, class A >
void CUtlArray<T, A>::RemoveMultiple( int elem, int num )
{
assert( elem >= 0 );
assert( elem + num <= Count() );
for (int i = elem + num; --i >= elem; )
Destruct(&Element(i));
ShiftElementsLeft(elem, num);
m_Size -= num;
}
template< typename T, class A >
void CUtlArray<T, A>::RemoveAll()
{
for (int i = m_Size; --i >= 0; )
{
Destruct(&Element(i));
}
m_Size = 0;
}
//-----------------------------------------------------------------------------
// Memory deallocation
//-----------------------------------------------------------------------------
template< typename T, class A >
inline void CUtlArray<T, A>::Purge()
{
RemoveAll();
m_Memory.Purge();
ResetDbgInfo();
}
template< typename T, class A >
inline void CUtlArray<T, A>::PurgeAndDeleteElements()
{
for( int i=0; i < m_Size; i++ )
{
delete Element(i);
}
Purge();
}
template< typename T, class A >
inline void CUtlArray<T, A>::Compact()
{
m_Memory.Purge(m_Size);
}
template< typename T, class A >
inline int CUtlArray<T, A>::NumAllocated() const
{
return m_Memory.NumAllocated();
}
#endif // CCVECTOR_H