source-engine/public/tier1/utlpriorityqueue.h

//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose: 
//
// $NoKeywords: $
//=============================================================================//

#ifndef UTLPRIORITYQUEUE_H
#define UTLPRIORITYQUEUE_H
#ifdef _WIN32
#pragma once
#endif

#include "utlvector.h"

// T is the type stored in the queue, it must include the priority
// The head of the list contains the element with GREATEST priority
// configure the LessFunc_t to get the desired queue order
template< class T > 
class CUtlPriorityQueue
{
public:
	// Less func typedef
	// Returns true if the first parameter is "less priority" than the second
	// Items that are "less priority" sort toward the tail of the queue
	typedef bool (*LessFunc_t)( T const&, T const& );

	typedef T ElemType_t;

	// constructor: lessfunc is required, but may be set after the constructor with
	// SetLessFunc
	CUtlPriorityQueue( int growSize = 0, int initSize = 0, LessFunc_t lessfunc = 0 );
	CUtlPriorityQueue( T *pMemory, int numElements, LessFunc_t lessfunc = 0 );

	// gets particular elements
	inline T const&	ElementAtHead() const { return m_heap.Element(0); }

	inline bool IsValidIndex(int index) { return m_heap.IsValidIndex(index); }

	// O(lgn) to rebalance the heap
	void		RemoveAtHead();
	void		RemoveAt( int index );

	// O(lgn) to rebalance heap
	void		Insert( T const &element );
	// Sets the less func
	void		SetLessFunc( LessFunc_t func );

	// Returns the count of elements in the queue
	inline int	Count() const { return m_heap.Count(); }
	
	// doesn't deallocate memory
	void		RemoveAll() { m_heap.RemoveAll(); }

	// Memory deallocation
	void		Purge() { m_heap.Purge(); }

	inline const T &	Element( int index ) const { return m_heap.Element(index); }

protected:
	CUtlVector<T>	m_heap;

	void		Swap( int index1, int index2 );

	// Used for sorting.
	LessFunc_t m_LessFunc;
};

template< class T >
inline CUtlPriorityQueue<T>::CUtlPriorityQueue( int growSize, int initSize, LessFunc_t lessfunc ) :
	m_heap(growSize, initSize), m_LessFunc(lessfunc)
{
}

template< class T >
inline CUtlPriorityQueue<T>::CUtlPriorityQueue( T *pMemory, int numElements, LessFunc_t lessfunc )	: 
	m_heap(pMemory, numElements), m_LessFunc(lessfunc)
{
}

template <class T>
void CUtlPriorityQueue<T>::RemoveAtHead()
{
	m_heap.FastRemove( 0 );
	int index = 0;

	int count = Count();
	if ( !count )
		return;

	int half = count/2;
	int larger = index;
	while ( index < half )
	{
		int child = ((index+1) * 2) - 1;	// if we wasted an element, this math would be more compact (1 based array)
		if ( child < count )
		{
			// Item has been filtered down to its proper place, terminate.
			if ( m_LessFunc( m_heap[index], m_heap[child] ) )
			{
				// mark the potential swap and check the other child
				larger = child;
			}
		}
		// go to sibling
		child++;
		if ( child < count )
		{
			// If this child is larger, swap it instead
			if ( m_LessFunc( m_heap[larger], m_heap[child] ) )
				larger = child;
		}
		
		if ( larger == index )
			break;

		// swap with the larger child
		Swap( index, larger );
		index = larger;
	}
}


template <class T>
void CUtlPriorityQueue<T>::RemoveAt( int index )
{
	Assert(m_heap.IsValidIndex(index));
	m_heap.FastRemove( index );

	int count = Count();
	if ( !count )
		return;

	int half = count/2;
	int larger = index;
	while ( index < half )
	{
		int child = ((index+1) * 2) - 1;	// if we wasted an element, this math would be more compact (1 based array)
		if ( child < count )
		{
			// Item has been filtered down to its proper place, terminate.
			if ( m_LessFunc( m_heap[index], m_heap[child] ) )
			{
				// mark the potential swap and check the other child
				larger = child;
			}
		}
		// go to sibling
		child++;
		if ( child < count )
		{
			// If this child is larger, swap it instead
			if ( m_LessFunc( m_heap[larger], m_heap[child] ) )
				larger = child;
		}
		
		if ( larger == index )
			break;

		// swap with the larger child
		Swap( index, larger );
		index = larger;
	}
}

template <class T>
void CUtlPriorityQueue<T>::Insert( T const &element )
{
	int index = m_heap.AddToTail();
	m_heap[index] = element;

	while ( index != 0 )
	{
		int parent = ((index+1) / 2) - 1;
		if ( m_LessFunc( m_heap[index], m_heap[parent] ) )
			break;

		// swap with parent and repeat
		Swap( parent, index );
		index = parent;
	}
}

template <class T>
void CUtlPriorityQueue<T>::Swap( int index1, int index2 )
{
	T tmp = m_heap[index1];
	m_heap[index1] = m_heap[index2];
	m_heap[index2] = tmp;
}

template <class T>
void CUtlPriorityQueue<T>::SetLessFunc( LessFunc_t lessfunc )
{
	m_LessFunc = lessfunc;
}

#endif // UTLPRIORITYQUEUE_H
1 5 years ago			`//========= Copyright Valve Corporation, All rights reserved. ============//`
			`//`
			`// Purpose:`
			`//`
			`// $NoKeywords: $`
			`//=============================================================================//`

			`#ifndef UTLPRIORITYQUEUE_H`
			`#define UTLPRIORITYQUEUE_H`
			`#ifdef _WIN32`
			`#pragma once`
			`#endif`

			`#include "utlvector.h"`

			`// T is the type stored in the queue, it must include the priority`
			`// The head of the list contains the element with GREATEST priority`
			`// configure the LessFunc_t to get the desired queue order`
			`template< class T >`
			`class CUtlPriorityQueue`
			`{`
			`public:`
			`// Less func typedef`
			`// Returns true if the first parameter is "less priority" than the second`
			`// Items that are "less priority" sort toward the tail of the queue`
			`typedef bool (*LessFunc_t)( T const&, T const& );`

			`typedef T ElemType_t;`

			`// constructor: lessfunc is required, but may be set after the constructor with`
			`// SetLessFunc`
			`CUtlPriorityQueue( int growSize = 0, int initSize = 0, LessFunc_t lessfunc = 0 );`
			`CUtlPriorityQueue( T *pMemory, int numElements, LessFunc_t lessfunc = 0 );`

			`// gets particular elements`
			`inline T const& ElementAtHead() const { return m_heap.Element(0); }`

			`inline bool IsValidIndex(int index) { return m_heap.IsValidIndex(index); }`

			`// O(lgn) to rebalance the heap`
			`void RemoveAtHead();`
			`void RemoveAt( int index );`

			`// O(lgn) to rebalance heap`
			`void Insert( T const &element );`
			`// Sets the less func`
			`void SetLessFunc( LessFunc_t func );`

			`// Returns the count of elements in the queue`
			`inline int Count() const { return m_heap.Count(); }`

			`// doesn't deallocate memory`
			`void RemoveAll() { m_heap.RemoveAll(); }`

			`// Memory deallocation`
			`void Purge() { m_heap.Purge(); }`

			`inline const T & Element( int index ) const { return m_heap.Element(index); }`

			`protected:`
			`CUtlVector<T> m_heap;`

			`void Swap( int index1, int index2 );`

			`// Used for sorting.`
			`LessFunc_t m_LessFunc;`
			`};`

			`template< class T >`
			`inline CUtlPriorityQueue<T>::CUtlPriorityQueue( int growSize, int initSize, LessFunc_t lessfunc ) :`
			`m_heap(growSize, initSize), m_LessFunc(lessfunc)`
			`{`
			`}`

			`template< class T >`
			`inline CUtlPriorityQueue<T>::CUtlPriorityQueue( T *pMemory, int numElements, LessFunc_t lessfunc ) :`
			`m_heap(pMemory, numElements), m_LessFunc(lessfunc)`
			`{`
			`}`

			`template <class T>`
			`void CUtlPriorityQueue<T>::RemoveAtHead()`
			`{`
			`m_heap.FastRemove( 0 );`
			`int index = 0;`

			`int count = Count();`
			`if ( !count )`
			`return;`

			`int half = count/2;`
			`int larger = index;`
			`while ( index < half )`
			`{`
			`int child = ((index+1) * 2) - 1; // if we wasted an element, this math would be more compact (1 based array)`
			`if ( child < count )`
			`{`
			`// Item has been filtered down to its proper place, terminate.`
			`if ( m_LessFunc( m_heap[index], m_heap[child] ) )`
			`{`
			`// mark the potential swap and check the other child`
			`larger = child;`
			`}`
			`}`
			`// go to sibling`
			`child++;`
			`if ( child < count )`
			`{`
			`// If this child is larger, swap it instead`
			`if ( m_LessFunc( m_heap[larger], m_heap[child] ) )`
			`larger = child;`
			`}`

			`if ( larger == index )`
			`break;`

			`// swap with the larger child`
			`Swap( index, larger );`
			`index = larger;`
			`}`
			`}`


			`template <class T>`
			`void CUtlPriorityQueue<T>::RemoveAt( int index )`
			`{`
			`Assert(m_heap.IsValidIndex(index));`
			`m_heap.FastRemove( index );`

			`int count = Count();`
			`if ( !count )`
			`return;`

			`int half = count/2;`
			`int larger = index;`
			`while ( index < half )`
			`{`
			`int child = ((index+1) * 2) - 1; // if we wasted an element, this math would be more compact (1 based array)`
			`if ( child < count )`
			`{`
			`// Item has been filtered down to its proper place, terminate.`
			`if ( m_LessFunc( m_heap[index], m_heap[child] ) )`
			`{`
			`// mark the potential swap and check the other child`
			`larger = child;`
			`}`
			`}`
			`// go to sibling`
			`child++;`
			`if ( child < count )`
			`{`
			`// If this child is larger, swap it instead`
			`if ( m_LessFunc( m_heap[larger], m_heap[child] ) )`
			`larger = child;`
			`}`

			`if ( larger == index )`
			`break;`

			`// swap with the larger child`
			`Swap( index, larger );`
			`index = larger;`
			`}`
			`}`

			`template <class T>`
			`void CUtlPriorityQueue<T>::Insert( T const &element )`
			`{`
			`int index = m_heap.AddToTail();`
			`m_heap[index] = element;`

			`while ( index != 0 )`
			`{`
			`int parent = ((index+1) / 2) - 1;`
			`if ( m_LessFunc( m_heap[index], m_heap[parent] ) )`
			`break;`

			`// swap with parent and repeat`
			`Swap( parent, index );`
			`index = parent;`
			`}`
			`}`

			`template <class T>`
			`void CUtlPriorityQueue<T>::Swap( int index1, int index2 )`
			`{`
			`T tmp = m_heap[index1];`
			`m_heap[index1] = m_heap[index2];`
			`m_heap[index2] = tmp;`
			`}`

			`template <class T>`
			`void CUtlPriorityQueue<T>::SetLessFunc( LessFunc_t lessfunc )`
			`{`
			`m_LessFunc = lessfunc;`
			`}`

			`#endif // UTLPRIORITYQUEUE_H`