pkg/tcpip/stack/tuple_list.go - third_party/gvisor.dev/gvisor/netstack - Git at Google

 package stack

 // ElementMapper provides an identity mapping by default.
 //
 // This can be replaced to provide a struct that maps elements to linker
 // objects, if they are not the same. An ElementMapper is not typically
 // required if: Linker is left as is, Element is left as is, or Linker and
 // Element are the same type.
 type tupleElementMapper struct{}

 // linkerFor maps an Element to a Linker.
 //
 // This default implementation should be inlined.
 //
 //go:nosplit
 func (tupleElementMapper) linkerFor(elem *tuple) *tuple { return elem }

 // List is an intrusive list. Entries can be added to or removed from the list
 // in O(1) time and with no additional memory allocations.
 //
 // The zero value for List is an empty list ready to use.
 //
 // To iterate over a list (where l is a List):
 //      for e := l.Front(); e != nil; e = e.Next() {
 // 		// do something with e.
 //      }
 //
 // +stateify savable
 type tupleList struct {
 	head *tuple
 	tail *tuple
 }

 // Reset resets list l to the empty state.
 func (l *tupleList) Reset() {
 	l.head = nil
 	l.tail = nil
 }

 // Empty returns true iff the list is empty.
 //
 //go:nosplit
 func (l *tupleList) Empty() bool {
 	return l.head == nil
 }

 // Front returns the first element of list l or nil.
 //
 //go:nosplit
 func (l *tupleList) Front() *tuple {
 	return l.head
 }

 // Back returns the last element of list l or nil.
 //
 //go:nosplit
 func (l *tupleList) Back() *tuple {
 	return l.tail
 }

 // Len returns the number of elements in the list.
 //
 // NOTE: This is an O(n) operation.
 //
 //go:nosplit
 func (l *tupleList) Len() (count int) {
 	for e := l.Front(); e != nil; e = (tupleElementMapper{}.linkerFor(e)).Next() {
 		count++
 	}
 	return count
 }

 // PushFront inserts the element e at the front of list l.
 //
 //go:nosplit
 func (l *tupleList) PushFront(e *tuple) {
 	linker := tupleElementMapper{}.linkerFor(e)
 	linker.SetNext(l.head)
 	linker.SetPrev(nil)
 	if l.head != nil {
 		tupleElementMapper{}.linkerFor(l.head).SetPrev(e)
 	} else {
 		l.tail = e
 	}

 	l.head = e
 }

 // PushBack inserts the element e at the back of list l.
 //
 //go:nosplit
 func (l *tupleList) PushBack(e *tuple) {
 	linker := tupleElementMapper{}.linkerFor(e)
 	linker.SetNext(nil)
 	linker.SetPrev(l.tail)
 	if l.tail != nil {
 		tupleElementMapper{}.linkerFor(l.tail).SetNext(e)
 	} else {
 		l.head = e
 	}

 	l.tail = e
 }

 // PushBackList inserts list m at the end of list l, emptying m.
 //
 //go:nosplit
 func (l *tupleList) PushBackList(m *tupleList) {
 	if l.head == nil {
 		l.head = m.head
 		l.tail = m.tail
 	} else if m.head != nil {
 		tupleElementMapper{}.linkerFor(l.tail).SetNext(m.head)
 		tupleElementMapper{}.linkerFor(m.head).SetPrev(l.tail)

 		l.tail = m.tail
 	}
 	m.head = nil
 	m.tail = nil
 }

 // InsertAfter inserts e after b.
 //
 //go:nosplit
 func (l *tupleList) InsertAfter(b, e *tuple) {
 	bLinker := tupleElementMapper{}.linkerFor(b)
 	eLinker := tupleElementMapper{}.linkerFor(e)

 	a := bLinker.Next()

 	eLinker.SetNext(a)
 	eLinker.SetPrev(b)
 	bLinker.SetNext(e)

 	if a != nil {
 		tupleElementMapper{}.linkerFor(a).SetPrev(e)
 	} else {
 		l.tail = e
 	}
 }

 // InsertBefore inserts e before a.
 //
 //go:nosplit
 func (l *tupleList) InsertBefore(a, e *tuple) {
 	aLinker := tupleElementMapper{}.linkerFor(a)
 	eLinker := tupleElementMapper{}.linkerFor(e)

 	b := aLinker.Prev()
 	eLinker.SetNext(a)
 	eLinker.SetPrev(b)
 	aLinker.SetPrev(e)

 	if b != nil {
 		tupleElementMapper{}.linkerFor(b).SetNext(e)
 	} else {
 		l.head = e
 	}
 }

 // Remove removes e from l.
 //
 //go:nosplit
 func (l *tupleList) Remove(e *tuple) {
 	linker := tupleElementMapper{}.linkerFor(e)
 	prev := linker.Prev()
 	next := linker.Next()

 	if prev != nil {
 		tupleElementMapper{}.linkerFor(prev).SetNext(next)
 	} else if l.head == e {
 		l.head = next
 	}

 	if next != nil {
 		tupleElementMapper{}.linkerFor(next).SetPrev(prev)
 	} else if l.tail == e {
 		l.tail = prev
 	}

 	linker.SetNext(nil)
 	linker.SetPrev(nil)
 }

 // Entry is a default implementation of Linker. Users can add anonymous fields
 // of this type to their structs to make them automatically implement the
 // methods needed by List.
 //
 // +stateify savable
 type tupleEntry struct {
 	next *tuple
 	prev *tuple
 }

 // Next returns the entry that follows e in the list.
 //
 //go:nosplit
 func (e *tupleEntry) Next() *tuple {
 	return e.next
 }

 // Prev returns the entry that precedes e in the list.
 //
 //go:nosplit
 func (e *tupleEntry) Prev() *tuple {
 	return e.prev
 }

 // SetNext assigns 'entry' as the entry that follows e in the list.
 //
 //go:nosplit
 func (e *tupleEntry) SetNext(elem *tuple) {
 	e.next = elem
 }

 // SetPrev assigns 'entry' as the entry that precedes e in the list.
 //
 //go:nosplit
 func (e *tupleEntry) SetPrev(elem *tuple) {
 	e.prev = elem
 }
	package stack

	// ElementMapper provides an identity mapping by default.
	//
	// This can be replaced to provide a struct that maps elements to linker
	// objects, if they are not the same. An ElementMapper is not typically
	// required if: Linker is left as is, Element is left as is, or Linker and
	// Element are the same type.
	type tupleElementMapper struct{}

	// linkerFor maps an Element to a Linker.
	//
	// This default implementation should be inlined.
	//
	//go:nosplit
	func (tupleElementMapper) linkerFor(elem tuple) tuple { return elem }

	// List is an intrusive list. Entries can be added to or removed from the list
	// in O(1) time and with no additional memory allocations.
	//
	// The zero value for List is an empty list ready to use.
	//
	// To iterate over a list (where l is a List):
	// for e := l.Front(); e != nil; e = e.Next() {
	// // do something with e.
	// }
	//
	// +stateify savable
	type tupleList struct {
	head *tuple
	tail *tuple
	}

	// Reset resets list l to the empty state.
	func (l *tupleList) Reset() {
	l.head = nil
	l.tail = nil
	}

	// Empty returns true iff the list is empty.
	//
	//go:nosplit
	func (l *tupleList) Empty() bool {
	return l.head == nil
	}

	// Front returns the first element of list l or nil.
	//
	//go:nosplit
	func (l tupleList) Front() tuple {
	return l.head
	}

	// Back returns the last element of list l or nil.
	//
	//go:nosplit
	func (l tupleList) Back() tuple {
	return l.tail
	}

	// Len returns the number of elements in the list.
	//
	// NOTE: This is an O(n) operation.
	//
	//go:nosplit
	func (l *tupleList) Len() (count int) {
	for e := l.Front(); e != nil; e = (tupleElementMapper{}.linkerFor(e)).Next() {
	count++
	}
	return count
	}

	// PushFront inserts the element e at the front of list l.
	//
	//go:nosplit
	func (l tupleList) PushFront(e tuple) {
	linker := tupleElementMapper{}.linkerFor(e)
	linker.SetNext(l.head)
	linker.SetPrev(nil)
	if l.head != nil {
	tupleElementMapper{}.linkerFor(l.head).SetPrev(e)
	} else {
	l.tail = e
	}

	l.head = e
	}

	// PushBack inserts the element e at the back of list l.
	//
	//go:nosplit
	func (l tupleList) PushBack(e tuple) {
	linker := tupleElementMapper{}.linkerFor(e)
	linker.SetNext(nil)
	linker.SetPrev(l.tail)
	if l.tail != nil {
	tupleElementMapper{}.linkerFor(l.tail).SetNext(e)
	} else {
	l.head = e
	}

	l.tail = e
	}

	// PushBackList inserts list m at the end of list l, emptying m.
	//
	//go:nosplit
	func (l tupleList) PushBackList(m tupleList) {
	if l.head == nil {
	l.head = m.head
	l.tail = m.tail
	} else if m.head != nil {
	tupleElementMapper{}.linkerFor(l.tail).SetNext(m.head)
	tupleElementMapper{}.linkerFor(m.head).SetPrev(l.tail)

	l.tail = m.tail
	}
	m.head = nil
	m.tail = nil
	}

	// InsertAfter inserts e after b.
	//
	//go:nosplit
	func (l tupleList) InsertAfter(b, e tuple) {
	bLinker := tupleElementMapper{}.linkerFor(b)
	eLinker := tupleElementMapper{}.linkerFor(e)

	a := bLinker.Next()

	eLinker.SetNext(a)
	eLinker.SetPrev(b)
	bLinker.SetNext(e)

	if a != nil {
	tupleElementMapper{}.linkerFor(a).SetPrev(e)
	} else {
	l.tail = e
	}
	}

	// InsertBefore inserts e before a.
	//
	//go:nosplit
	func (l tupleList) InsertBefore(a, e tuple) {
	aLinker := tupleElementMapper{}.linkerFor(a)
	eLinker := tupleElementMapper{}.linkerFor(e)

	b := aLinker.Prev()
	eLinker.SetNext(a)
	eLinker.SetPrev(b)
	aLinker.SetPrev(e)

	if b != nil {
	tupleElementMapper{}.linkerFor(b).SetNext(e)
	} else {
	l.head = e
	}
	}

	// Remove removes e from l.
	//
	//go:nosplit
	func (l tupleList) Remove(e tuple) {
	linker := tupleElementMapper{}.linkerFor(e)
	prev := linker.Prev()
	next := linker.Next()

	if prev != nil {
	tupleElementMapper{}.linkerFor(prev).SetNext(next)
	} else if l.head == e {
	l.head = next
	}

	if next != nil {
	tupleElementMapper{}.linkerFor(next).SetPrev(prev)
	} else if l.tail == e {
	l.tail = prev
	}

	linker.SetNext(nil)
	linker.SetPrev(nil)
	}

	// Entry is a default implementation of Linker. Users can add anonymous fields
	// of this type to their structs to make them automatically implement the
	// methods needed by List.
	//
	// +stateify savable
	type tupleEntry struct {
	next *tuple
	prev *tuple
	}

	// Next returns the entry that follows e in the list.
	//
	//go:nosplit
	func (e tupleEntry) Next() tuple {
	return e.next
	}

	// Prev returns the entry that precedes e in the list.
	//
	//go:nosplit
	func (e tupleEntry) Prev() tuple {
	return e.prev
	}

	// SetNext assigns 'entry' as the entry that follows e in the list.
	//
	//go:nosplit
	func (e tupleEntry) SetNext(elem tuple) {
	e.next = elem
	}

	// SetPrev assigns 'entry' as the entry that precedes e in the list.
	//
	//go:nosplit
	func (e tupleEntry) SetPrev(elem tuple) {
	e.prev = elem
	}