haiku/headers/private/kernel/util/DoublyLinkedList.h
Ingo Weinhold 5c99d63970 Merged branch haiku/branches/developer/bonefish/vm into trunk. This
introduces the following relevant changes:
* VMCache:
  - Renamed vm_cache to VMCache, merged it with vm_store and made it a
    C++ class with virtual methods (replacing the store operations).
    Turned the different store implementations into subclasses.
  - Introduced MergeStore() callback, changed semantics of Commit().
  - Changed locking and referencing semantics. A reference can only be
    acquired/released with the cache locked. An unreferenced cache is
    deleted and a mergeable cache merged when it is unlocked. This
    removes the "busy" state of a cache and simplifies the page fault
    code.
* Added VMAnonymousCache, which will implement swap support (work by
  Zhao Shuai). It is not integrated and used yet, though.
* Enabled the mutex/recursive lock holder asserts.
* Fixed DoublyLinkedList::Swap().
* Generalized the low memory handler to a low resource handler. And made
  semaphores and reserved memory handled resources. Made
  vm_try_resource_memory() optionally wait (with timeout), and used that
  feature to reserve memory for areas.
...


git-svn-id: file:///srv/svn/repos/haiku/haiku/trunk@26572 a95241bf-73f2-0310-859d-f6bbb57e9c96
2008-07-22 20:36:32 +00:00

589 lines
11 KiB
C++

/*
* Copyright 2005-2007, Ingo Weinhold, bonefish@users.sf.net. All rights reserved.
* Distributed under the terms of the MIT License.
*/
#ifndef KERNEL_UTIL_DOUBLY_LINKED_LIST_H
#define KERNEL_UTIL_DOUBLY_LINKED_LIST_H
#include <SupportDefs.h>
#ifdef _KERNEL_MODE
# include <debug.h>
# include <util/kernel_cpp.h>
# if !defined(_BOOT_MODE) && KDEBUG
# define DEBUG_DOUBLY_LINKED_LIST KDEBUG
# endif
#endif
#ifdef __cplusplus
// DoublyLinkedListLink
template<typename Element>
class DoublyLinkedListLink {
public:
DoublyLinkedListLink() : next(NULL), previous(NULL) {}
~DoublyLinkedListLink() {}
Element *next;
Element *previous;
};
// DoublyLinkedListLinkImpl
template<typename Element>
class DoublyLinkedListLinkImpl {
private:
typedef DoublyLinkedListLink<Element> DLL_Link;
public:
DoublyLinkedListLinkImpl() : fDoublyLinkedListLink() {}
~DoublyLinkedListLinkImpl() {}
DLL_Link *GetDoublyLinkedListLink()
{ return &fDoublyLinkedListLink; }
const DLL_Link *GetDoublyLinkedListLink() const
{ return &fDoublyLinkedListLink; }
private:
DLL_Link fDoublyLinkedListLink;
};
// DoublyLinkedListStandardGetLink
template<typename Element>
class DoublyLinkedListStandardGetLink {
private:
typedef DoublyLinkedListLink<Element> Link;
public:
inline Link *operator()(Element *element) const
{
return element->GetDoublyLinkedListLink();
}
inline const Link *operator()(const Element *element) const
{
return element->GetDoublyLinkedListLink();
}
};
// DoublyLinkedListMemberGetLink
template<typename Element,
DoublyLinkedListLink<Element> Element::* LinkMember = &Element::fLink>
class DoublyLinkedListMemberGetLink {
private:
typedef DoublyLinkedListLink<Element> Link;
public:
inline Link *operator()(Element *element) const
{
return &(element->*LinkMember);
}
inline const Link *operator()(const Element *element) const
{
return &(element->*LinkMember);
}
};
// DoublyLinkedListCLink - interface to struct list
template<typename Element>
class DoublyLinkedListCLink {
private:
typedef DoublyLinkedListLink<Element> Link;
public:
inline Link *operator()(Element *element) const
{
return (Link *)&element->link;
}
inline const Link *operator()(const Element *element) const
{
return (const Link *)&element->link;
}
};
// for convenience
#define DOUBLY_LINKED_LIST_TEMPLATE_LIST \
template<typename Element, typename GetLink>
#define DOUBLY_LINKED_LIST_CLASS_NAME DoublyLinkedList<Element, GetLink>
// DoublyLinkedList
template<typename Element,
typename GetLink = DoublyLinkedListStandardGetLink<Element> >
class DoublyLinkedList {
private:
typedef DoublyLinkedList<Element, GetLink> List;
typedef DoublyLinkedListLink<Element> Link;
public:
class Iterator {
public:
Iterator(List *list)
:
fList(list)
{
Rewind();
}
Iterator()
{
}
Iterator(const Iterator &other)
{
*this = other;
}
bool HasNext() const
{
return fNext;
}
Element *Next()
{
fCurrent = fNext;
if (fNext)
fNext = fList->GetNext(fNext);
return fCurrent;
}
Element *Current()
{
return fCurrent;
}
Element *Remove()
{
Element *element = fCurrent;
if (fCurrent) {
fList->Remove(fCurrent);
fCurrent = NULL;
}
return element;
}
Iterator &operator=(const Iterator &other)
{
fList = other.fList;
fCurrent = other.fCurrent;
fNext = other.fNext;
return *this;
}
void Rewind()
{
fCurrent = NULL;
fNext = fList->First();
}
private:
List *fList;
Element *fCurrent;
Element *fNext;
};
class ConstIterator {
public:
ConstIterator(const List *list)
:
fList(list)
{
Rewind();
}
ConstIterator(const ConstIterator &other)
{
*this = other;
}
bool HasNext() const
{
return fNext;
}
Element *Next()
{
Element *element = fNext;
if (fNext)
fNext = fList->GetNext(fNext);
return element;
}
ConstIterator &operator=(const ConstIterator &other)
{
fList = other.fList;
fNext = other.fNext;
return *this;
}
void Rewind()
{
fNext = fList->First();
}
private:
const List *fList;
Element *fNext;
};
class ReverseIterator {
public:
ReverseIterator(List *list)
:
fList(list)
{
Rewind();
}
ReverseIterator(const ReverseIterator &other)
{
*this = other;
}
bool HasNext() const
{
return fNext;
}
Element *Next()
{
fCurrent = fNext;
if (fNext)
fNext = fList->GetPrevious(fNext);
return fCurrent;
}
Element *Remove()
{
Element *element = fCurrent;
if (fCurrent) {
fList->Remove(fCurrent);
fCurrent = NULL;
}
return element;
}
ReverseIterator &operator=(const ReverseIterator &other)
{
fList = other.fList;
fCurrent = other.fCurrent;
fNext = other.fNext;
return *this;
}
void Rewind()
{
fCurrent = NULL;
fNext = fList->Last();
}
private:
List *fList;
Element *fCurrent;
Element *fNext;
};
class ConstReverseIterator {
public:
ConstReverseIterator(const List *list)
:
fList(list)
{
Rewind();
}
ConstReverseIterator(const ConstReverseIterator &other)
{
*this = other;
}
bool HasNext() const
{
return fNext;
}
Element *Next()
{
Element *element = fNext;
if (fNext)
fNext = fList->GetPrevious(fNext);
return element;
}
ConstReverseIterator &operator=(const ConstReverseIterator &other)
{
fList = other.fList;
fNext = other.fNext;
return *this;
}
void Rewind()
{
fNext = fList->Last();
}
private:
const List *fList;
Element *fNext;
};
public:
DoublyLinkedList() : fFirst(NULL), fLast(NULL) {}
~DoublyLinkedList() {}
inline bool IsEmpty() const { return (fFirst == NULL); }
inline void Insert(Element *element, bool back = true);
inline void Insert(Element *before, Element *element);
inline void Add(Element *element, bool back = true);
inline void Remove(Element *element);
inline void Swap(Element *a, Element *b);
inline void MoveFrom(DOUBLY_LINKED_LIST_CLASS_NAME *fromList);
inline void RemoveAll();
inline void MakeEmpty() { RemoveAll(); }
inline Element *First() const { return fFirst; }
inline Element *Last() const { return fLast; }
inline Element *Head() const { return fFirst; }
inline Element *Tail() const { return fLast; }
inline Element *RemoveHead();
inline Element *GetPrevious(Element *element) const;
inline Element *GetNext(Element *element) const;
inline int32 Size() const;
// O(n)!
inline Iterator GetIterator() { return Iterator(this); }
inline ConstIterator GetIterator() const { return ConstIterator(this); }
inline ReverseIterator GetReverseIterator()
{ return ReverseIterator(this); }
inline ConstReverseIterator GetReverseIterator() const
{ return ConstReverseIterator(this); }
private:
Element *fFirst;
Element *fLast;
static GetLink sGetLink;
};
// inline methods
// Insert
DOUBLY_LINKED_LIST_TEMPLATE_LIST
void
DOUBLY_LINKED_LIST_CLASS_NAME::Insert(Element *element, bool back)
{
if (element) {
#if DEBUG_DOUBLY_LINKED_LIST
ASSERT_PRINT(fFirst == NULL ? fLast == NULL : fLast != NULL,
"list: %p\n", this);
#endif
if (back) {
// append
Link *elLink = sGetLink(element);
elLink->previous = fLast;
elLink->next = NULL;
if (fLast)
sGetLink(fLast)->next = element;
else
fFirst = element;
fLast = element;
} else {
// prepend
Link *elLink = sGetLink(element);
elLink->previous = NULL;
elLink->next = fFirst;
if (fFirst)
sGetLink(fFirst)->previous = element;
else
fLast = element;
fFirst = element;
}
}
}
// Insert
DOUBLY_LINKED_LIST_TEMPLATE_LIST
void
DOUBLY_LINKED_LIST_CLASS_NAME::Insert(Element *before, Element *element)
{
if (before == NULL) {
Insert(element);
return;
}
if (element == NULL)
return;
#if DEBUG_DOUBLY_LINKED_LIST
ASSERT_PRINT(fFirst == NULL ? fLast == NULL : fLast != NULL,
"list: %p\n", this);
#endif
Link *beforeLink = sGetLink(before);
Link *link = sGetLink(element);
link->next = before;
link->previous = beforeLink->previous;
if (link->previous != NULL)
sGetLink(link->previous)->next = element;
beforeLink->previous = element;
if (fFirst == before)
fFirst = element;
}
// Add
DOUBLY_LINKED_LIST_TEMPLATE_LIST
void
DOUBLY_LINKED_LIST_CLASS_NAME::Add(Element *element, bool back)
{
Insert(element, back);
}
// Remove
DOUBLY_LINKED_LIST_TEMPLATE_LIST
void
DOUBLY_LINKED_LIST_CLASS_NAME::Remove(Element *element)
{
if (element) {
#if DEBUG_DOUBLY_LINKED_LIST
ASSERT_PRINT(fFirst != NULL && fLast != NULL
&& (fFirst != fLast || element == fFirst),
"list: %p, element: %p\n", this, element);
#endif
Link *elLink = sGetLink(element);
if (elLink->previous)
sGetLink(elLink->previous)->next = elLink->next;
else
fFirst = elLink->next;
if (elLink->next)
sGetLink(elLink->next)->previous = elLink->previous;
else
fLast = elLink->previous;
elLink->previous = NULL;
elLink->next = NULL;
}
}
// Swap
DOUBLY_LINKED_LIST_TEMPLATE_LIST
void
DOUBLY_LINKED_LIST_CLASS_NAME::Swap(Element *a, Element *b)
{
if (a && b && a != b) {
Element *aNext = sGetLink(a)->next;
Element *bNext = sGetLink(b)->next;
if (a == bNext) {
Remove(a);
Insert(b, a);
} else if (b == aNext) {
Remove(b);
Insert(a, b);
} else {
Remove(a);
Remove(b);
Insert(aNext, b);
Insert(bNext, a);
}
}
}
// MoveFrom
DOUBLY_LINKED_LIST_TEMPLATE_LIST
void
DOUBLY_LINKED_LIST_CLASS_NAME::MoveFrom(DOUBLY_LINKED_LIST_CLASS_NAME *fromList)
{
if (fromList && fromList->fFirst) {
if (fFirst) {
sGetLink(fLast)->next = fromList->fFirst;
sGetLink(fromList->fFirst)->previous = fLast;
fLast = fromList->fLast;
} else {
fFirst = fromList->fFirst;
fLast = fromList->fLast;
}
fromList->fFirst = NULL;
fromList->fLast = NULL;
}
}
// RemoveAll
DOUBLY_LINKED_LIST_TEMPLATE_LIST
void
DOUBLY_LINKED_LIST_CLASS_NAME::RemoveAll()
{
Element *element = fFirst;
while (element) {
Link *elLink = sGetLink(element);
element = elLink->next;
elLink->previous = NULL;
elLink->next = NULL;
}
fFirst = NULL;
fLast = NULL;
}
// RemoveHead
DOUBLY_LINKED_LIST_TEMPLATE_LIST
Element *
DOUBLY_LINKED_LIST_CLASS_NAME::RemoveHead()
{
Element *element = Head();
Remove(element);
return element;
}
// GetPrevious
DOUBLY_LINKED_LIST_TEMPLATE_LIST
Element *
DOUBLY_LINKED_LIST_CLASS_NAME::GetPrevious(Element *element) const
{
Element *result = NULL;
if (element)
result = sGetLink(element)->previous;
return result;
}
// GetNext
DOUBLY_LINKED_LIST_TEMPLATE_LIST
Element *
DOUBLY_LINKED_LIST_CLASS_NAME::GetNext(Element *element) const
{
Element *result = NULL;
if (element)
result = sGetLink(element)->next;
return result;
}
// Size
DOUBLY_LINKED_LIST_TEMPLATE_LIST
int32
DOUBLY_LINKED_LIST_CLASS_NAME::Size() const
{
int32 count = 0;
for (Element* element = First(); element; element = GetNext(element))
count++;
return count;
}
// sGetLink
DOUBLY_LINKED_LIST_TEMPLATE_LIST
GetLink DOUBLY_LINKED_LIST_CLASS_NAME::sGetLink;
#endif /* __cplusplus */
#endif // _KERNEL_UTIL_DOUBLY_LINKED_LIST_H