Chat-O-Matic/libs/libdownload/ObjectList.h

/*
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/****************************************************************************
** WARNING WARNING WARNING WARNING WARNING WARNING WARNING WARNING WARNING **
**                                                                         **
**                          DANGER, WILL ROBINSON!                         **
**                                                                         **
** The interfaces contained here are part of BeOS's                        **
**                                                                         **
**                     >> PRIVATE NOT FOR PUBLIC USE <<                    **
**                                                                         **
**                                                       implementation.   **
**                                                                         **
** These interfaces              WILL CHANGE        in future releases.    **
** If you use them, your app     WILL BREAK         at some future time.   **
**                                                                         **
** (And yes, this does mean that binaries built from OpenTracker will not  **
** be compatible with some future releases of the OS.  When that happens,  **
** we will provide an updated version of this file to keep compatibility.) **
**                                                                         **
** WARNING WARNING WARNING WARNING WARNING WARNING WARNING WARNING WARNING **
****************************************************************************/

//
// ObjectList is a wrapper around BList that adds type safety,
// optional object ownership, search, insert operations, etc.
//

#ifndef __OBJECT_LIST__
#define __OBJECT_LIST__

#ifndef _BE_H
#include <List.h>
#endif

#include <SupportDefs.h>


template<class T> class BObjectList;

template<class T>
struct UnaryPredicate {

	virtual int operator()(const T*) const
	// virtual could be avoided here if FindBinaryInsertionIndex,
	// etc. were member template functions
	{
		return 0;
	}

private:
	static int _unary_predicate_glue(const void* item, void* context);

	friend class BObjectList<T>;
};

template<class T>
int
UnaryPredicate<T>::_unary_predicate_glue(const void* item, void* context)
{
	return ((UnaryPredicate<T> *)context)->operator()((const T*)item);
}


class _PointerList_ : public BList
{
public:
	_PointerList_(const _PointerList_ &list);
	_PointerList_(int32 itemsPerBlock = 20, bool owning = false);
	~_PointerList_();

	typedef void *(* GenericEachFunction)(void*, void*);
	typedef int (* GenericCompareFunction)(const void*, const void*);
	typedef int (* GenericCompareFunctionWithState)(const void*, const void*,
	        void*);
	typedef int (* UnaryPredicateGlue)(const void*, void*);

	void* EachElement(GenericEachFunction, void*);
	void SortItems(GenericCompareFunction);
	void SortItems(GenericCompareFunctionWithState, void* state);
	void HSortItems(GenericCompareFunction);
	void HSortItems(GenericCompareFunctionWithState, void* state);

	void* BinarySearch(const void*, GenericCompareFunction) const;
	void* BinarySearch(const void*, GenericCompareFunctionWithState, void* state) const;

	int32 BinarySearchIndex(const void*, GenericCompareFunction) const;
	int32 BinarySearchIndex(const void*, GenericCompareFunctionWithState, void* state) const;
	int32 BinarySearchIndexByPredicate(const void*, UnaryPredicateGlue) const;

	bool Owning() const;
	bool ReplaceItem(int32, void*);

protected:
	bool owning;

};

template<class T>
class BObjectList : private _PointerList_
{
public:

	// iteration and sorting
	typedef T *(* EachFunction)(T*, void*);
	typedef const T *(* ConstEachFunction)(const T*, void*);
	typedef int (* CompareFunction)(const T*, const T*);
	typedef int (* CompareFunctionWithState)(const T*, const T*, void* state);

	BObjectList(int32 itemsPerBlock = 20, bool owning = false);
	BObjectList(const BObjectList& list);
	// clones list; if list is owning, makes copies of all
	// the items

	virtual ~BObjectList();

	BObjectList& operator=(const BObjectList& list);
	// clones list; if list is owning, makes copies of all
	// the items

	// adding and removing
	// ToDo:
	// change Add calls to return const item
	bool AddItem(T*);
	bool AddItem(T*, int32);
	bool AddList(BObjectList*);
	bool AddList(BObjectList*, int32);

	bool RemoveItem(T*, bool deleteIfOwning = true);
	// if owning, deletes the removed item
	T* RemoveItemAt(int32);
	// returns the removed item

	void MakeEmpty(bool deleteIfOwning = true);

	// item access
	T* ItemAt(int32) const;

	bool ReplaceItem(int32 index, T*);
	// if list is owning, deletes the item at <index> first
	T* SwapWithItem(int32 index, T* newItem);
	// same as ReplaceItem, except does not delete old item at <index>,
	// returns it instead

	T* FirstItem() const;
	T* LastItem() const;

	// misc. getters
	int32 IndexOf(const T*) const;
	bool HasItem(const T*) const;
	bool IsEmpty() const;
	int32 CountItems() const;

	T* EachElement(EachFunction, void*);
	const T* EachElement(ConstEachFunction, void*) const;

	void SortItems(CompareFunction);
	void SortItems(CompareFunctionWithState, void* state);
	void HSortItems(CompareFunction);
	void HSortItems(CompareFunctionWithState, void* state);

	// linear search, returns first item that matches predicate
	const T* FindIf(const UnaryPredicate<T> &) const;
	T* FindIf(const UnaryPredicate<T> &);

	// list must be sorted with CompareFunction for these to work
	T* BinarySearch(const T&, CompareFunction) const;
	T* BinarySearch(const T&, CompareFunctionWithState, void* state) const;

	template<typename Key>
	T* BinarySearchByKey(const Key& key, int (*compare)(const Key*, const T*))
	const;

	template<typename Key>
	T* BinarySearchByKey(const Key& key,
	                     int (*compare)(const Key*, const T*, void*), void* state) const;

	int32 BinarySearchIndex(const T& item, CompareFunction compare) const;
	int32 BinarySearchIndex(const T& item, CompareFunctionWithState compare,
	                        void* state) const;

	template<typename Key>
	int32 BinarySearchIndexByKey(const Key& key,
	                             int (*compare)(const Key*, const T*)) const;

	// Binary insertion - list must be sorted with CompareFunction for
	// these to work

	// simple insert
	bool BinaryInsert(T*, CompareFunction);
	bool BinaryInsert(T*, CompareFunctionWithState, void* state);
	bool BinaryInsert(T*, const UnaryPredicate<T> &);

	// unique insert, returns false if item already in list
	bool BinaryInsertUnique(T*, CompareFunction);
	bool BinaryInsertUnique(T*, CompareFunctionWithState, void* state);
	bool BinaryInsertUnique(T*, const UnaryPredicate<T> &);

	// insert a copy of the item, returns new inserted item
	T* BinaryInsertCopy(const T& copyThis, CompareFunction);
	T* BinaryInsertCopy(const T& copyThis, CompareFunctionWithState, void* state);

	// insert a copy of the item if not in list already
	// returns new inserted item or existing item in case of a conflict
	T* BinaryInsertCopyUnique(const T& copyThis, CompareFunction);
	T* BinaryInsertCopyUnique(const T& copyThis, CompareFunctionWithState, void* state);

	int32 FindBinaryInsertionIndex(const UnaryPredicate<T> &, bool* alreadyInList = 0) const;
	// returns either the index into which a new item should be inserted
	// or index of an existing item that matches the predicate

	// deprecated API, will go away
	BList* AsBList() {
		return this;
	}
	const BList* AsBList() const {
		return this;
	}
private:
	void SetItem(int32, T*);
};

template<class Item, class Result, class Param1>
Result
WhileEachListItem(BObjectList<Item> *list, Result (Item::*func)(Param1), Param1 p1)
{
	Result result = 0;
	int32 count = list->CountItems();

	for (int32 index = 0; index < count; index++)
		if ((result = (list->ItemAt(index)->*func)(p1)) != 0)
			break;

	return result;
}

template<class Item, class Result, class Param1>
Result
WhileEachListItem(BObjectList<Item> *list, Result (*func)(Item*, Param1), Param1 p1)
{
	Result result = 0;
	int32 count = list->CountItems();

	for (int32 index = 0; index < count; index++)
		if ((result = (*func)(list->ItemAt(index), p1)) != 0)
			break;

	return result;
}

template<class Item, class Result, class Param1, class Param2>
Result
WhileEachListItem(BObjectList<Item> *list, Result (Item::*func)(Param1, Param2),
                  Param1 p1, Param2 p2)
{
	Result result = 0;
	int32 count = list->CountItems();

	for (int32 index = 0; index < count; index++)
		if ((result = (list->ItemAt(index)->*func)(p1, p2)) != 0)
			break;

	return result;
}

template<class Item, class Result, class Param1, class Param2>
Result
WhileEachListItem(BObjectList<Item> *list, Result (*func)(Item*, Param1, Param2),
                  Param1 p1, Param2 p2)
{
	Result result = 0;
	int32 count = list->CountItems();

	for (int32 index = 0; index < count; index++)
		if ((result = (*func)(list->ItemAt(index), p1, p2)) != 0)
			break;

	return result;
}

template<class Item, class Result, class Param1, class Param2, class Param3, class Param4>
Result
WhileEachListItem(BObjectList<Item> *list, Result (*func)(Item*, Param1, Param2,
                  Param3, Param4), Param1 p1, Param2 p2, Param3 p3, Param4 p4)
{
	Result result = 0;
	int32 count = list->CountItems();

	for (int32 index = 0; index < count; index++)
		if ((result = (*func)(list->ItemAt(index), p1, p2, p3, p4)) != 0)
			break;

	return result;
}

template<class Item, class Result>
void
EachListItemIgnoreResult(BObjectList<Item> *list, Result (Item::*func)())
{
	int32 count = list->CountItems();
	for (int32 index = 0; index < count; index++)
		(list->ItemAt(index)->*func)();
}

template<class Item, class Param1>
void
EachListItem(BObjectList<Item> *list, void (*func)(Item*, Param1), Param1 p1)
{
	int32 count = list->CountItems();
	for (int32 index = 0; index < count; index++)
		(func)(list->ItemAt(index), p1);
}

template<class Item, class Param1, class Param2>
void
EachListItem(BObjectList<Item> *list, void (Item::*func)(Param1, Param2),
             Param1 p1, Param2 p2)
{
	int32 count = list->CountItems();
	for (int32 index = 0; index < count; index++)
		(list->ItemAt(index)->*func)(p1, p2);
}

template<class Item, class Param1, class Param2>
void
EachListItem(BObjectList<Item> *list, void (*func)(Item*, Param1, Param2),
             Param1 p1, Param2 p2)
{
	int32 count = list->CountItems();
	for (int32 index = 0; index < count; index++)
		(func)(list->ItemAt(index), p1, p2);
}

template<class Item, class Param1, class Param2, class Param3>
void
EachListItem(BObjectList<Item> *list, void (*func)(Item*, Param1, Param2,
             Param3), Param1 p1, Param2 p2, Param3 p3)
{
	int32 count = list->CountItems();
	for (int32 index = 0; index < count; index++)
		(func)(list->ItemAt(index), p1, p2, p3);
}


template<class Item, class Param1, class Param2, class Param3, class Param4>
void
EachListItem(BObjectList<Item> *list, void (*func)(Item*, Param1, Param2,
             Param3, Param4), Param1 p1, Param2 p2, Param3 p3, Param4 p4)
{
	int32 count = list->CountItems();
	for (int32 index = 0; index < count; index++)
		(func)(list->ItemAt(index), p1, p2, p3, p4);
}

// inline code

inline bool
_PointerList_::Owning() const
{
	return owning;
}

template<class T>
BObjectList<T>::BObjectList(int32 itemsPerBlock, bool owning)
	:	_PointerList_(itemsPerBlock, owning)
{
}

template<class T>
BObjectList<T>::BObjectList(const BObjectList<T> &list)
	:	_PointerList_(list)
{
	owning = list.owning;
	if (owning) {
		// make our own copies in an owning list
		int32 count = list.CountItems();
		for	(int32 index = 0; index < count; index++) {
			T* item = list.ItemAt(index);
			if (item)
				item = new T(*item);
			SetItem(index, item);
		}
	}
}

template<class T>
BObjectList<T>::~BObjectList()
{
	if (Owning())
		// have to nuke elements first
		MakeEmpty();
}

template<class T>
BObjectList<T> &
BObjectList<T>::operator=(const BObjectList<T> &list)
{
	owning = list.owning;
	BObjectList<T> &result = (BObjectList<T> &)_PointerList_::operator=(list);
	if (owning) {
		// make our own copies in an owning list
		int32 count = list.CountItems();
		for	(int32 index = 0; index < count; index++) {
			T* item = list.ItemAt(index);
			if (item)
				item = new T(*item);
			SetItem(index, item);
		}
	}
	return result;
}

template<class T>
bool
BObjectList<T>::AddItem(T* item)
{
	// need to cast to void * to make T work for const pointers
	return _PointerList_::AddItem((void*)item);
}

template<class T>
bool
BObjectList<T>::AddItem(T* item, int32 atIndex)
{
	return _PointerList_::AddItem((void*)item, atIndex);
}

template<class T>
bool
BObjectList<T>::AddList(BObjectList<T> *newItems)
{
	return _PointerList_::AddList(newItems);
}

template<class T>
bool
BObjectList<T>::AddList(BObjectList<T> *newItems, int32 atIndex)
{
	return _PointerList_::AddList(newItems, atIndex);
}


template<class T>
bool
BObjectList<T>::RemoveItem(T* item, bool deleteIfOwning)
{
	bool result = _PointerList_::RemoveItem((void*)item);

	if (result && Owning() && deleteIfOwning)
		delete item;

	return result;
}

template<class T>
T *
BObjectList<T>::RemoveItemAt(int32 index)
{
	return (T*)_PointerList_::RemoveItem(index);
}

template<class T>
inline T *
BObjectList<T>::ItemAt(int32 index) const
{
	return (T*)_PointerList_::ItemAt(index);
}

template<class T>
bool
BObjectList<T>::ReplaceItem(int32 index, T* item)
{
	if (owning)
		delete ItemAt(index);
	return _PointerList_::ReplaceItem(index, (void*)item);
}

template<class T>
T *
BObjectList<T>::SwapWithItem(int32 index, T* newItem)
{
	T* result = ItemAt(index);
	_PointerList_::ReplaceItem(index, (void*)newItem);
	return result;
}

template<class T>
void
BObjectList<T>::SetItem(int32 index, T* newItem)
{
	_PointerList_::ReplaceItem(index, (void*)newItem);
}

template<class T>
int32
BObjectList<T>::IndexOf(const T* item) const
{
	return _PointerList_::IndexOf((void*)item);
}

template<class T>
T *
BObjectList<T>::FirstItem() const
{
	return (T*)_PointerList_::FirstItem();
}

template<class T>
T *
BObjectList<T>::LastItem() const
{
	return (T*)_PointerList_::LastItem();
}

template<class T>
bool
BObjectList<T>::HasItem(const T* item) const
{
	return _PointerList_::HasItem((void*)item);
}

template<class T>
bool
BObjectList<T>::IsEmpty() const
{
	return _PointerList_::IsEmpty();
}

template<class T>
int32
BObjectList<T>::CountItems() const
{
	return _PointerList_::CountItems();
}

template<class T>
void
BObjectList<T>::MakeEmpty(bool deleteIfOwning)
{
	if (owning && deleteIfOwning) {
		int32 count = CountItems();
		for (int32 index = 0; index < count; index++)
			delete ItemAt(index);
	}
	_PointerList_::MakeEmpty();
}

template<class T>
T *
BObjectList<T>::EachElement(EachFunction func, void* params)
{
	return (T*)_PointerList_::EachElement((GenericEachFunction)func, params);
}


template<class T>
const T *
BObjectList<T>::EachElement(ConstEachFunction func, void* params) const
{
	return (const T*)
	       const_cast<BObjectList<T> *>(this)->_PointerList_::EachElement(
	           (GenericEachFunction)func, params);
}

template<class T>
const T *
BObjectList<T>::FindIf(const UnaryPredicate<T> &predicate) const
{
	int32 count = CountItems();
	for (int32 index = 0; index < count; index++)
		if (predicate.operator()(ItemAt(index)) == 0)
			return ItemAt(index);
	return 0;
}

template<class T>
T *
BObjectList<T>::FindIf(const UnaryPredicate<T> &predicate)
{
	int32 count = CountItems();
	for (int32 index = 0; index < count; index++)
		if (predicate.operator()(ItemAt(index)) == 0)
			return ItemAt(index);
	return 0;
}


template<class T>
void
BObjectList<T>::SortItems(CompareFunction function)
{
	_PointerList_::SortItems((GenericCompareFunction)function);
}

template<class T>
void
BObjectList<T>::SortItems(CompareFunctionWithState function, void* state)
{
	_PointerList_::SortItems((GenericCompareFunctionWithState)function, state);
}

template<class T>
void
BObjectList<T>::HSortItems(CompareFunction function)
{
	_PointerList_::HSortItems((GenericCompareFunction)function);
}

template<class T>
void
BObjectList<T>::HSortItems(CompareFunctionWithState function, void* state)
{
	_PointerList_::HSortItems((GenericCompareFunctionWithState)function, state);
}

template<class T>
T *
BObjectList<T>::BinarySearch(const T& key, CompareFunction func) const
{
	return (T*)_PointerList_::BinarySearch(&key,
	                                       (GenericCompareFunction)func);
}

template<class T>
T *
BObjectList<T>::BinarySearch(const T& key, CompareFunctionWithState func, void* state) const
{
	return (T*)_PointerList_::BinarySearch(&key,
	                                       (GenericCompareFunctionWithState)func, state);
}


template<class T>
template<typename Key>
T *
BObjectList<T>::BinarySearchByKey(const Key& key,
                                  int (*compare)(const Key*, const T*)) const
{
	return (T*)_PointerList_::BinarySearch(&key,
	                                       (GenericCompareFunction)compare);
}


template<class T>
template<typename Key>
T *
BObjectList<T>::BinarySearchByKey(const Key& key,
                                  int (*compare)(const Key*, const T*, void*), void* state) const
{
	return (T*)_PointerList_::BinarySearch(&key,
	                                       (GenericCompareFunctionWithState)compare, state);
}


template<class T>
int32
BObjectList<T>::BinarySearchIndex(const T& item, CompareFunction compare) const
{
	return _PointerList_::BinarySearchIndex(&item,
	                                        (GenericCompareFunction)compare);
}


template<class T>
int32
BObjectList<T>::BinarySearchIndex(const T& item,
                                  CompareFunctionWithState compare, void* state) const
{
	return _PointerList_::BinarySearchIndex(&item,
	                                        (GenericCompareFunctionWithState)compare, state);
}


template<class T>
template<typename Key>
int32
BObjectList<T>::BinarySearchIndexByKey(const Key& key,
                                       int (*compare)(const Key*, const T*)) const
{
	return _PointerList_::BinarySearchIndex(&key,
	                                        (GenericCompareFunction)compare);
}


template<class T>
bool
BObjectList<T>::BinaryInsert(T* item, CompareFunction func)
{
	int32 index = _PointerList_::BinarySearchIndex(item,
	              (GenericCompareFunction)func);
	if (index >= 0) {
		// already in list, add after existing
		return AddItem(item, index + 1);
	}

	return AddItem(item, -index - 1);
}

template<class T>
bool
BObjectList<T>::BinaryInsert(T* item, CompareFunctionWithState func, void* state)
{
	int32 index = _PointerList_::BinarySearchIndex(item,
	              (GenericCompareFunctionWithState)func, state);
	if (index >= 0) {
		// already in list, add after existing
		return AddItem(item, index + 1);
	}

	return AddItem(item, -index - 1);
}

template<class T>
bool
BObjectList<T>::BinaryInsertUnique(T* item, CompareFunction func)
{
	int32 index = _PointerList_::BinarySearchIndex(item,
	              (GenericCompareFunction)func);
	if (index >= 0)
		return false;

	return AddItem(item, -index - 1);
}

template<class T>
bool
BObjectList<T>::BinaryInsertUnique(T* item, CompareFunctionWithState func, void* state)
{
	int32 index = _PointerList_::BinarySearchIndex(item,
	              (GenericCompareFunctionWithState)func, state);
	if (index >= 0)
		return false;

	return AddItem(item, -index - 1);
}


template<class T>
T *
BObjectList<T>::BinaryInsertCopy(const T& copyThis, CompareFunction func)
{
	int32 index = _PointerList_::BinarySearchIndex(&copyThis,
	              (GenericCompareFunction)func);

	if (index >= 0)
		index++;
	else
		index = -index - 1;

	T* newItem = new T(copyThis);
	AddItem(newItem, index);
	return newItem;
}

template<class T>
T *
BObjectList<T>::BinaryInsertCopy(const T& copyThis, CompareFunctionWithState func, void* state)
{
	int32 index = _PointerList_::BinarySearchIndex(&copyThis,
	              (GenericCompareFunctionWithState)func, state);

	if (index >= 0)
		index++;
	else
		index = -index - 1;

	T* newItem = new T(copyThis);
	AddItem(newItem, index);
	return newItem;
}

template<class T>
T *
BObjectList<T>::BinaryInsertCopyUnique(const T& copyThis, CompareFunction func)
{
	int32 index = _PointerList_::BinarySearchIndex(&copyThis,
	              (GenericCompareFunction)func);
	if (index >= 0)
		return ItemAt(index);

	index = -index - 1;
	T* newItem = new T(copyThis);
	AddItem(newItem, index);
	return newItem;
}

template<class T>
T *
BObjectList<T>::BinaryInsertCopyUnique(const T& copyThis, CompareFunctionWithState func,
                                       void* state)
{
	int32 index = _PointerList_::BinarySearchIndex(&copyThis,
	              (GenericCompareFunctionWithState)func, state);
	if (index >= 0)
		return ItemAt(index);

	index = -index - 1;
	T* newItem = new T(copyThis);
	AddItem(newItem, index);
	return newItem;
}

template<class T>
int32
BObjectList<T>::FindBinaryInsertionIndex(const UnaryPredicate<T> &pred, bool* alreadyInList)
const
{
	int32 index = _PointerList_::BinarySearchIndexByPredicate(&pred,
	              (UnaryPredicateGlue)&UnaryPredicate<T>::_unary_predicate_glue);

	if (alreadyInList)
		*alreadyInList = index >= 0;

	if (index < 0)
		index = -index - 1;

	return index;
}

template<class T>
bool
BObjectList<T>::BinaryInsert(T* item, const UnaryPredicate<T> &pred)
{
	return AddItem(item, FindBinaryInsertionIndex(pred));
}

template<class T>
bool
BObjectList<T>::BinaryInsertUnique(T* item, const UnaryPredicate<T> &pred)
{
	bool alreadyInList;
	int32 index = FindBinaryInsertionIndex(pred, &alreadyInList);
	if (alreadyInList)
		return false;

	AddItem(item, index);
	return true;
}

#endif	/* __OBJECT_LIST__ */