test/typeparam/listimp2.dir/a.go - go - Git at Google

 // Copyright 2021 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package a

 import (
 	"fmt"
 )

 // Element is an element of a linked list.
 type Element[T any] struct {
 	// Next and previous pointers in the doubly-linked list of elements.
 	// To simplify the implementation, internally a list l is implemented
 	// as a ring, such that &l.root is both the next element of the last
 	// list element (l.Back()) and the previous element of the first list
 	// element (l.Front()).
 	next, prev *Element[T]

 	// The list to which this element belongs.
 	list *List[T]

 	// The value stored with this element.
 	Value T
 }

 // Next returns the next list element or nil.
 func (e *Element[T]) Next() *Element[T] {
 	if p := e.next; e.list != nil && p != &e.list.root {
 		return p
 	}
 	return nil
 }

 // Prev returns the previous list element or nil.
 func (e *Element[T]) Prev() *Element[T] {
 	if p := e.prev; e.list != nil && p != &e.list.root {
 		return p
 	}
 	return nil
 }

 // List represents a doubly linked list.
 // The zero value for List is an empty list ready to use.
 type List[T any] struct {
 	root Element[T] // sentinel list element, only &root, root.prev, and root.next are used
 	len  int        // current list length excluding (this) sentinel element
 }

 // Init initializes or clears list l.
 func (l *List[T]) Init() *List[T] {
 	l.root.next = &l.root
 	l.root.prev = &l.root
 	l.len = 0
 	return l
 }

 // New returns an initialized list.
 func New[T any]() *List[T] { return new(List[T]).Init() }

 // Len returns the number of elements of list l.
 // The complexity is O(1).
 func (l *List[_]) Len() int { return l.len }

 // Front returns the first element of list l or nil if the list is empty.
 func (l *List[T]) Front() *Element[T] {
 	if l.len == 0 {
 		return nil
 	}
 	return l.root.next
 }

 // Back returns the last element of list l or nil if the list is empty.
 func (l *List[T]) Back() *Element[T] {
 	if l.len == 0 {
 		return nil
 	}
 	return l.root.prev
 }

 // lazyInit lazily initializes a zero List value.
 func (l *List[_]) lazyInit() {
 	if l.root.next == nil {
 		l.Init()
 	}
 }

 // insert inserts e after at, increments l.len, and returns e.
 func (l *List[T]) insert(e, at *Element[T]) *Element[T] {
 	e.prev = at
 	e.next = at.next
 	e.prev.next = e
 	e.next.prev = e
 	e.list = l
 	l.len++
 	return e
 }

 // insertValue is a convenience wrapper for insert(&Element[T]{Value: v}, at).
 func (l *List[T]) insertValue(v T, at *Element[T]) *Element[T] {
 	return l.insert(&Element[T]{Value: v}, at)
 }

 // remove removes e from its list, decrements l.len, and returns e.
 func (l *List[T]) remove(e *Element[T]) *Element[T] {
 	e.prev.next = e.next
 	e.next.prev = e.prev
 	e.next = nil // avoid memory leaks
 	e.prev = nil // avoid memory leaks
 	e.list = nil
 	l.len--
 	return e
 }

 // move moves e to next to at and returns e.
 func (l *List[T]) move(e, at *Element[T]) *Element[T] {
 	if e == at {
 		return e
 	}
 	e.prev.next = e.next
 	e.next.prev = e.prev

 	e.prev = at
 	e.next = at.next
 	e.prev.next = e
 	e.next.prev = e

 	return e
 }

 // Remove removes e from l if e is an element of list l.
 // It returns the element value e.Value.
 // The element must not be nil.
 func (l *List[T]) Remove(e *Element[T]) T {
 	if e.list == l {
 		// if e.list == l, l must have been initialized when e was inserted
 		// in l or l == nil (e is a zero Element) and l.remove will crash
 		l.remove(e)
 	}
 	return e.Value
 }

 // PushFront inserts a new element e with value v at the front of list l and returns e.
 func (l *List[T]) PushFront(v T) *Element[T] {
 	l.lazyInit()
 	return l.insertValue(v, &l.root)
 }

 // PushBack inserts a new element e with value v at the back of list l and returns e.
 func (l *List[T]) PushBack(v T) *Element[T] {
 	l.lazyInit()
 	return l.insertValue(v, l.root.prev)
 }

 // InsertBefore inserts a new element e with value v immediately before mark and returns e.
 // If mark is not an element of l, the list is not modified.
 // The mark must not be nil.
 func (l *List[T]) InsertBefore(v T, mark *Element[T]) *Element[T] {
 	if mark.list != l {
 		return nil
 	}
 	// see comment in List.Remove about initialization of l
 	return l.insertValue(v, mark.prev)
 }

 // InsertAfter inserts a new element e with value v immediately after mark and returns e.
 // If mark is not an element of l, the list is not modified.
 // The mark must not be nil.
 func (l *List[T]) InsertAfter(v T, mark *Element[T]) *Element[T] {
 	if mark.list != l {
 		return nil
 	}
 	// see comment in List.Remove about initialization of l
 	return l.insertValue(v, mark)
 }

 // MoveToFront moves element e to the front of list l.
 // If e is not an element of l, the list is not modified.
 // The element must not be nil.
 func (l *List[T]) MoveToFront(e *Element[T]) {
 	if e.list != l || l.root.next == e {
 		return
 	}
 	// see comment in List.Remove about initialization of l
 	l.move(e, &l.root)
 }

 // MoveToBack moves element e to the back of list l.
 // If e is not an element of l, the list is not modified.
 // The element must not be nil.
 func (l *List[T]) MoveToBack(e *Element[T]) {
 	if e.list != l || l.root.prev == e {
 		return
 	}
 	// see comment in List.Remove about initialization of l
 	l.move(e, l.root.prev)
 }

 // MoveBefore moves element e to its new position before mark.
 // If e or mark is not an element of l, or e == mark, the list is not modified.
 // The element and mark must not be nil.
 func (l *List[T]) MoveBefore(e, mark *Element[T]) {
 	if e.list != l || e == mark || mark.list != l {
 		return
 	}
 	l.move(e, mark.prev)
 }

 // MoveAfter moves element e to its new position after mark.
 // If e or mark is not an element of l, or e == mark, the list is not modified.
 // The element and mark must not be nil.
 func (l *List[T]) MoveAfter(e, mark *Element[T]) {
 	if e.list != l || e == mark || mark.list != l {
 		return
 	}
 	l.move(e, mark)
 }

 // PushBackList inserts a copy of an other list at the back of list l.
 // The lists l and other may be the same. They must not be nil.
 func (l *List[T]) PushBackList(other *List[T]) {
 	l.lazyInit()
 	for i, e := other.Len(), other.Front(); i > 0; i, e = i-1, e.Next() {
 		l.insertValue(e.Value, l.root.prev)
 	}
 }

 // PushFrontList inserts a copy of an other list at the front of list l.
 // The lists l and other may be the same. They must not be nil.
 func (l *List[T]) PushFrontList(other *List[T]) {
 	l.lazyInit()
 	for i, e := other.Len(), other.Back(); i > 0; i, e = i-1, e.Prev() {
 		l.insertValue(e.Value, &l.root)
 	}
 }

 // Transform runs a transform function on a list returning a new list.
 func Transform[TElem1, TElem2 any](lst *List[TElem1], f func(TElem1) TElem2) *List[TElem2] {
 	ret := New[TElem2]()
 	for p := lst.Front(); p != nil; p = p.Next() {
 		ret.PushBack(f(p.Value))
 	}
 	return ret
 }

 func CheckListLen[T any](l *List[T], len int) bool {
 	if n := l.Len(); n != len {
 		panic(fmt.Sprintf("l.Len() = %d, want %d", n, len))
 		return false
 	}
 	return true
 }

 func CheckListPointers[T any](l *List[T], es []*Element[T]) {
 	root := &l.root

 	if !CheckListLen(l, len(es)) {
 		return
 	}

 	// zero length lists must be the zero value or properly initialized (sentinel circle)
 	if len(es) == 0 {
 		if l.root.next != nil && l.root.next != root || l.root.prev != nil && l.root.prev != root {
 			panic(fmt.Sprintf("l.root.next = %p, l.root.prev = %p; both should both be nil or %p", l.root.next, l.root.prev, root))
 		}
 		return
 	}
 	// len(es) > 0

 	// check internal and external prev/next connections
 	for i, e := range es {
 		prev := root
 		Prev := (*Element[T])(nil)
 		if i > 0 {
 			prev = es[i-1]
 			Prev = prev
 		}
 		if p := e.prev; p != prev {
 			panic(fmt.Sprintf("elt[%d](%p).prev = %p, want %p", i, e, p, prev))
 		}
 		if p := e.Prev(); p != Prev {
 			panic(fmt.Sprintf("elt[%d](%p).Prev() = %p, want %p", i, e, p, Prev))
 		}

 		next := root
 		Next := (*Element[T])(nil)
 		if i < len(es)-1 {
 			next = es[i+1]
 			Next = next
 		}
 		if n := e.next; n != next {
 			panic(fmt.Sprintf("elt[%d](%p).next = %p, want %p", i, e, n, next))
 		}
 		if n := e.Next(); n != Next {
 			panic(fmt.Sprintf("elt[%d](%p).Next() = %p, want %p", i, e, n, Next))
 		}
 	}
 }
	// Copyright 2021 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package a

	import (
	"fmt"
	)

	// Element is an element of a linked list.
	type Element[T any] struct {
	// Next and previous pointers in the doubly-linked list of elements.
	// To simplify the implementation, internally a list l is implemented
	// as a ring, such that &l.root is both the next element of the last
	// list element (l.Back()) and the previous element of the first list
	// element (l.Front()).
	next, prev *Element[T]

	// The list to which this element belongs.
	list *List[T]

	// The value stored with this element.
	Value T
	}

	// Next returns the next list element or nil.
	func (e Element[T]) Next() Element[T] {
	if p := e.next; e.list != nil && p != &e.list.root {
	return p
	}
	return nil
	}

	// Prev returns the previous list element or nil.
	func (e Element[T]) Prev() Element[T] {
	if p := e.prev; e.list != nil && p != &e.list.root {
	return p
	}
	return nil
	}

	// List represents a doubly linked list.
	// The zero value for List is an empty list ready to use.
	type List[T any] struct {
	root Element[T] // sentinel list element, only &root, root.prev, and root.next are used
	len int // current list length excluding (this) sentinel element
	}

	// Init initializes or clears list l.
	func (l List[T]) Init() List[T] {
	l.root.next = &l.root
	l.root.prev = &l.root
	l.len = 0
	return l
	}

	// New returns an initialized list.
	func New[T any]() *List[T] { return new(List[T]).Init() }

	// Len returns the number of elements of list l.
	// The complexity is O(1).
	func (l *List[_]) Len() int { return l.len }

	// Front returns the first element of list l or nil if the list is empty.
	func (l List[T]) Front() Element[T] {
	if l.len == 0 {
	return nil
	}
	return l.root.next
	}

	// Back returns the last element of list l or nil if the list is empty.
	func (l List[T]) Back() Element[T] {
	if l.len == 0 {
	return nil
	}
	return l.root.prev
	}

	// lazyInit lazily initializes a zero List value.
	func (l *List[_]) lazyInit() {
	if l.root.next == nil {
	l.Init()
	}
	}

	// insert inserts e after at, increments l.len, and returns e.
	func (l List[T]) insert(e, at Element[T]) *Element[T] {
	e.prev = at
	e.next = at.next
	e.prev.next = e
	e.next.prev = e
	e.list = l
	l.len++
	return e
	}

	// insertValue is a convenience wrapper for insert(&Element[T]{Value: v}, at).
	func (l List[T]) insertValue(v T, at Element[T]) *Element[T] {
	return l.insert(&Element[T]{Value: v}, at)
	}

	// remove removes e from its list, decrements l.len, and returns e.
	func (l List[T]) remove(e Element[T]) *Element[T] {
	e.prev.next = e.next
	e.next.prev = e.prev
	e.next = nil // avoid memory leaks
	e.prev = nil // avoid memory leaks
	e.list = nil
	l.len--
	return e
	}

	// move moves e to next to at and returns e.
	func (l List[T]) move(e, at Element[T]) *Element[T] {
	if e == at {
	return e
	}
	e.prev.next = e.next
	e.next.prev = e.prev

	e.prev = at
	e.next = at.next
	e.prev.next = e
	e.next.prev = e

	return e
	}

	// Remove removes e from l if e is an element of list l.
	// It returns the element value e.Value.
	// The element must not be nil.
	func (l List[T]) Remove(e Element[T]) T {
	if e.list == l {
	// if e.list == l, l must have been initialized when e was inserted
	// in l or l == nil (e is a zero Element) and l.remove will crash
	l.remove(e)
	}
	return e.Value
	}

	// PushFront inserts a new element e with value v at the front of list l and returns e.
	func (l List[T]) PushFront(v T) Element[T] {
	l.lazyInit()
	return l.insertValue(v, &l.root)
	}

	// PushBack inserts a new element e with value v at the back of list l and returns e.
	func (l List[T]) PushBack(v T) Element[T] {
	l.lazyInit()
	return l.insertValue(v, l.root.prev)
	}

	// InsertBefore inserts a new element e with value v immediately before mark and returns e.
	// If mark is not an element of l, the list is not modified.
	// The mark must not be nil.
	func (l List[T]) InsertBefore(v T, mark Element[T]) *Element[T] {
	if mark.list != l {
	return nil
	}
	// see comment in List.Remove about initialization of l
	return l.insertValue(v, mark.prev)
	}

	// InsertAfter inserts a new element e with value v immediately after mark and returns e.
	// If mark is not an element of l, the list is not modified.
	// The mark must not be nil.
	func (l List[T]) InsertAfter(v T, mark Element[T]) *Element[T] {
	if mark.list != l {
	return nil
	}
	// see comment in List.Remove about initialization of l
	return l.insertValue(v, mark)
	}

	// MoveToFront moves element e to the front of list l.
	// If e is not an element of l, the list is not modified.
	// The element must not be nil.
	func (l List[T]) MoveToFront(e Element[T]) {
	if e.list != l \|\| l.root.next == e {
	return
	}
	// see comment in List.Remove about initialization of l
	l.move(e, &l.root)
	}

	// MoveToBack moves element e to the back of list l.
	// If e is not an element of l, the list is not modified.
	// The element must not be nil.
	func (l List[T]) MoveToBack(e Element[T]) {
	if e.list != l \|\| l.root.prev == e {
	return
	}
	// see comment in List.Remove about initialization of l
	l.move(e, l.root.prev)
	}

	// MoveBefore moves element e to its new position before mark.
	// If e or mark is not an element of l, or e == mark, the list is not modified.
	// The element and mark must not be nil.
	func (l List[T]) MoveBefore(e, mark Element[T]) {
	if e.list != l \|\| e == mark \|\| mark.list != l {
	return
	}
	l.move(e, mark.prev)
	}

	// MoveAfter moves element e to its new position after mark.
	// If e or mark is not an element of l, or e == mark, the list is not modified.
	// The element and mark must not be nil.
	func (l List[T]) MoveAfter(e, mark Element[T]) {
	if e.list != l \|\| e == mark \|\| mark.list != l {
	return
	}
	l.move(e, mark)
	}

	// PushBackList inserts a copy of an other list at the back of list l.
	// The lists l and other may be the same. They must not be nil.
	func (l List[T]) PushBackList(other List[T]) {
	l.lazyInit()
	for i, e := other.Len(), other.Front(); i > 0; i, e = i-1, e.Next() {
	l.insertValue(e.Value, l.root.prev)
	}
	}

	// PushFrontList inserts a copy of an other list at the front of list l.
	// The lists l and other may be the same. They must not be nil.
	func (l List[T]) PushFrontList(other List[T]) {
	l.lazyInit()
	for i, e := other.Len(), other.Back(); i > 0; i, e = i-1, e.Prev() {
	l.insertValue(e.Value, &l.root)
	}
	}

	// Transform runs a transform function on a list returning a new list.
	func Transform[TElem1, TElem2 any](lst List[TElem1], f func(TElem1) TElem2) List[TElem2] {
	ret := New[TElem2]()
	for p := lst.Front(); p != nil; p = p.Next() {
	ret.PushBack(f(p.Value))
	}
	return ret
	}

	func CheckListLen[T any](l *List[T], len int) bool {
	if n := l.Len(); n != len {
	panic(fmt.Sprintf("l.Len() = %d, want %d", n, len))
	return false
	}
	return true
	}

	func CheckListPointers[T any](l List[T], es []Element[T]) {
	root := &l.root

	if !CheckListLen(l, len(es)) {
	return
	}

	// zero length lists must be the zero value or properly initialized (sentinel circle)
	if len(es) == 0 {
	if l.root.next != nil && l.root.next != root \|\| l.root.prev != nil && l.root.prev != root {
	panic(fmt.Sprintf("l.root.next = %p, l.root.prev = %p; both should both be nil or %p", l.root.next, l.root.prev, root))
	}
	return
	}
	// len(es) > 0

	// check internal and external prev/next connections
	for i, e := range es {
	prev := root
	Prev := (*Element[T])(nil)
	if i > 0 {
	prev = es[i-1]
	Prev = prev
	}
	if p := e.prev; p != prev {
	panic(fmt.Sprintf("elt[%d](%p).prev = %p, want %p", i, e, p, prev))
	}
	if p := e.Prev(); p != Prev {
	panic(fmt.Sprintf("elt[%d](%p).Prev() = %p, want %p", i, e, p, Prev))
	}

	next := root
	Next := (*Element[T])(nil)
	if i < len(es)-1 {
	next = es[i+1]
	Next = next
	}
	if n := e.next; n != next {
	panic(fmt.Sprintf("elt[%d](%p).next = %p, want %p", i, e, n, next))
	}
	if n := e.Next(); n != Next {
	panic(fmt.Sprintf("elt[%d](%p).Next() = %p, want %p", i, e, n, Next))
	}
	}
	}