# # # Nim's Runtime Library # (c) Copyright 2012 Andreas Rumpf # # See the file "copying.txt", included in this # distribution, for details about the copyright. # ## Implementation of: ## * `singly linked lists <#SinglyLinkedList>`_ ## * `doubly linked lists <#DoublyLinkedList>`_ ## * `singly linked rings <#SinglyLinkedRing>`_ (circular lists) ## * `doubly linked rings <#DoublyLinkedRing>`_ (circular lists) ## ## ## Basic Usage ## =========== ## ## Because it makes no sense to do otherwise, the `next` and `prev` pointers ## are not hidden from you and can be manipulated directly for efficiency. ## ## Lists ## ----- ## ## .. code-block:: ## import lists ## ## var ## l = initDoublyLinkedList[int]() ## a = newDoublyLinkedNode[int](3) ## b = newDoublyLinkedNode[int](7) ## c = newDoublyLinkedNode[int](9) ## ## l.append(a) ## l.append(b) ## l.prepend(c) ## ## assert a.next == b ## assert a.prev == c ## assert c.next == a ## assert c.next.next == b ## assert c.prev == nil ## assert b.next == nil ## ## ## Rings ## ----- ## ## .. code-block:: ## import lists ## ## var ## l = initSinglyLinkedRing[int]() ## a = newSinglyLinkedNode[int](3) ## b = newSinglyLinkedNode[int](7) ## c = newSinglyLinkedNode[int](9) ## ## l.append(a) ## l.append(b) ## l.prepend(c) ## ## assert c.next == a ## assert a.next == b ## assert c.next.next == b ## assert b.next == c ## assert c.next.next.next == c ## ## See also ## ======== ## ## * `deques module <#deques.html>`_ for double-ended queues ## * `sharedlist module <#sharedlist.html>`_ for shared singly-linked lists when not defined(nimhygiene): {.pragma: dirty.} type DoublyLinkedNodeObj*[T] = object ## A node a doubly linked list consists of. ## ## It consists of a `value` field, and pointers to `next` and `prev`. next*, prev*: ref DoublyLinkedNodeObj[T] value*: T DoublyLinkedNode*[T] = ref DoublyLinkedNodeObj[T] SinglyLinkedNodeObj*[T] = object ## A node a singly linked list consists of. ## ## It consists of a `value` field, and a pointer to `next`. next*: ref SinglyLinkedNodeObj[T] value*: T SinglyLinkedNode*[T] = ref SinglyLinkedNodeObj[T] SinglyLinkedList*[T] = object ## A singly linked list. ## ## Use `initSinglyLinkedList proc <#initSinglyLinkedList>`_ to create ## a new empty list. head*, tail*: SinglyLinkedNode[T] DoublyLinkedList*[T] = object ## A doubly linked list. ## ## Use `initDoublyLinkedList proc <#initDoublyLinkedList>`_ to create ## a new empty list. head*, tail*: DoublyLinkedNode[T] SinglyLinkedRing*[T] = object ## A singly linked ring. ## ## Use `initSinglyLinkedRing proc <#initSinglyLinkedRing>`_ to create ## a new empty ring. head*, tail*: SinglyLinkedNode[T] DoublyLinkedRing*[T] = object ## A doubly linked ring. ## ## Use `initDoublyLinkedRing proc <#initDoublyLinkedRing>`_ to create ## a new empty ring. head*: DoublyLinkedNode[T] SomeLinkedList*[T] = SinglyLinkedList[T] | DoublyLinkedList[T] SomeLinkedRing*[T] = SinglyLinkedRing[T] | DoublyLinkedRing[T] SomeLinkedCollection*[T] = SomeLinkedList[T] | SomeLinkedRing[T] SomeLinkedNode*[T] = SinglyLinkedNode[T] | DoublyLinkedNode[T] proc initSinglyLinkedList*[T](): SinglyLinkedList[T] = ## Creates a new singly linked list that is empty. runnableExamples: var a = initSinglyLinkedList[int]() discard proc initDoublyLinkedList*[T](): DoublyLinkedList[T] = ## Creates a new doubly linked list that is empty. runnableExamples: var a = initDoublyLinkedList[int]() discard proc initSinglyLinkedRing*[T](): SinglyLinkedRing[T] = ## Creates a new singly linked ring that is empty. runnableExamples: var a = initSinglyLinkedRing[int]() discard proc initDoublyLinkedRing*[T](): DoublyLinkedRing[T] = ## Creates a new doubly linked ring that is empty. runnableExamples: var a = initDoublyLinkedRing[int]() discard proc newDoublyLinkedNode*[T](value: T): DoublyLinkedNode[T] = ## Creates a new doubly linked node with the given `value`. runnableExamples: var n = newDoublyLinkedNode[int](5) assert n.value == 5 new(result) result.value = value proc newSinglyLinkedNode*[T](value: T): SinglyLinkedNode[T] = ## Creates a new singly linked node with the given `value`. runnableExamples: var n = newSinglyLinkedNode[int](5) assert n.value == 5 new(result) result.value = value template itemsListImpl() {.dirty.} = var it = L.head while it != nil: yield it.value it = it.next template itemsRingImpl() {.dirty.} = var it = L.head if it != nil: while true: yield it.value it = it.next if it == L.head: break iterator items*[T](L: SomeLinkedList[T]): T = ## Yields every value of `L`. ## ## See also: ## * `mitems iterator <#mitems.i,SomeLinkedList[T]>`_ ## * `nodes iterator <#nodes.i,SomeLinkedList[T]>`_ ## ## **Examples:** ## ## .. code-block:: ## var a = initSinglyLinkedList[int]() ## for i in 1 .. 3: ## a.append(10*i) ## ## for x in a: # the same as: for x in items(a): ## echo x ## ## # 10 ## # 20 ## # 30 itemsListImpl() iterator items*[T](L: SomeLinkedRing[T]): T = ## Yields every value of `L`. ## ## See also: ## * `mitems iterator <#mitems.i,SomeLinkedRing[T]>`_ ## * `nodes iterator <#nodes.i,SomeLinkedRing[T]>`_ ## ## **Examples:** ## ## .. code-block:: ## var a = initSinglyLinkedRing[int]() ## for i in 1 .. 3: ## a.append(10*i) ## ## for x in a: # the same as: for x in items(a): ## echo x ## ## # 10 ## # 20 ## # 30 itemsRingImpl() iterator mitems*[T](L: var SomeLinkedList[T]): var T = ## Yields every value of `L` so that you can modify it. ## ## See also: ## * `items iterator <#items.i,SomeLinkedList[T]>`_ ## * `nodes iterator <#nodes.i,SomeLinkedList[T]>`_ runnableExamples: var a = initSinglyLinkedList[int]() for i in 1 .. 5: a.append(10*i) assert $a == "[10, 20, 30, 40, 50]" for x in mitems(a): x = 5*x - 1 assert $a == "[49, 99, 149, 199, 249]" itemsListImpl() iterator mitems*[T](L: var SomeLinkedRing[T]): var T = ## Yields every value of `L` so that you can modify it. ## ## See also: ## * `items iterator <#items.i,SomeLinkedRing[T]>`_ ## * `nodes iterator <#nodes.i,SomeLinkedRing[T]>`_ runnableExamples: var a = initSinglyLinkedRing[int]() for i in 1 .. 5: a.append(10*i) assert $a == "[10, 20, 30, 40, 50]" for x in mitems(a): x = 5*x - 1 assert $a == "[49, 99, 149, 199, 249]" itemsRingImpl() iterator nodes*[T](L: SomeLinkedList[T]): SomeLinkedNode[T] = ## Iterates over every node of `x`. Removing the current node from the ## list during traversal is supported. ## ## See also: ## * `items iterator <#items.i,SomeLinkedList[T]>`_ ## * `mitems iterator <#mitems.i,SomeLinkedList[T]>`_ runnableExamples: var a = initDoublyLinkedList[int]() for i in 1 .. 5: a.append(10*i) assert $a == "[10, 20, 30, 40, 50]" for x in nodes(a): if x.value == 30: a.remove(x) else: x.value = 5*x.value - 1 assert $a == "[49, 99, 199, 249]" var it = L.head while it != nil: var nxt = it.next yield it it = nxt iterator nodes*[T](L: SomeLinkedRing[T]): SomeLinkedNode[T] = ## Iterates over every node of `x`. Removing the current node from the ## list during traversal is supported. ## ## See also: ## * `items iterator <#items.i,SomeLinkedRing[T]>`_ ## * `mitems iterator <#mitems.i,SomeLinkedRing[T]>`_ runnableExamples: var a = initDoublyLinkedRing[int]() for i in 1 .. 5: a.append(10*i) assert $a == "[10, 20, 30, 40, 50]" for x in nodes(a): if x.value == 30: a.remove(x) else: x.value = 5*x.value - 1 assert $a == "[49, 99, 199, 249]" var it = L.head if it != nil: while true: var nxt = it.next yield it it = nxt if it == L.head: break proc `$`*[T](L: SomeLinkedCollection[T]): string = ## Turns a list into its string representation for logging and printing. result = "[" for x in nodes(L): if result.len > 1: result.add(", ") result.addQuoted(x.value) result.add("]") proc find*[T](L: SomeLinkedCollection[T], value: T): SomeLinkedNode[T] = ## Searches in the list for a value. Returns `nil` if the value does not ## exist. ## ## See also: ## * `contains proc <#contains,SomeLinkedCollection[T],T>`_ runnableExamples: var a = initSinglyLinkedList[int]() a.append(9) a.append(8) assert a.find(9).value == 9 assert a.find(1) == nil for x in nodes(L): if x.value == value: return x proc contains*[T](L: SomeLinkedCollection[T], value: T): bool {.inline.} = ## Searches in the list for a value. Returns `false` if the value does not ## exist, `true` otherwise. ## ## See also: ## * `find proc <#find,SomeLinkedCollection[T],T>`_ runnableExamples: var a = initSinglyLinkedList[int]() a.append(9) a.append(8) assert a.contains(9) assert 8 in a assert(not a.contains(1)) assert 2 notin a result = find(L, value) != nil proc append*[T](L: var SinglyLinkedList[T], n: SinglyLinkedNode[T]) {.inline.} = ## Appends (adds to the end) a node `n` to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,SinglyLinkedList[T],T>`_ for appending a value ## * `prepend proc <#prepend,SinglyLinkedList[T],SinglyLinkedNode[T]>`_ ## for prepending a node ## * `prepend proc <#prepend,SinglyLinkedList[T],T>`_ for prepending a value runnableExamples: var a = initSinglyLinkedList[int]() n = newSinglyLinkedNode[int](9) a.append(n) assert a.contains(9) n.next = nil if L.tail != nil: assert(L.tail.next == nil) L.tail.next = n L.tail = n if L.head == nil: L.head = n proc append*[T](L: var SinglyLinkedList[T], value: T) {.inline.} = ## Appends (adds to the end) a value to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,SinglyLinkedList[T],T>`_ for appending a value ## * `prepend proc <#prepend,SinglyLinkedList[T],SinglyLinkedNode[T]>`_ ## for prepending a node ## * `prepend proc <#prepend,SinglyLinkedList[T],T>`_ for prepending a value runnableExamples: var a = initSinglyLinkedList[int]() a.append(9) a.append(8) assert a.contains(9) append(L, newSinglyLinkedNode(value)) proc prepend*[T](L: var SinglyLinkedList[T], n: SinglyLinkedNode[T]) {.inline.} = ## Prepends (adds to the beginning) a node to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,SinglyLinkedList[T],SinglyLinkedNode[T]>`_ ## for appending a node ## * `append proc <#append,SinglyLinkedList[T],T>`_ for appending a value ## * `prepend proc <#prepend,SinglyLinkedList[T],T>`_ for prepending a value runnableExamples: var a = initSinglyLinkedList[int]() n = newSinglyLinkedNode[int](9) a.prepend(n) assert a.contains(9) n.next = L.head L.head = n if L.tail == nil: L.tail = n proc prepend*[T](L: var SinglyLinkedList[T], value: T) {.inline.} = ## Prepends (adds to the beginning) a node to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,SinglyLinkedList[T],SinglyLinkedNode[T]>`_ ## for appending a node ## * `append proc <#append,SinglyLinkedList[T],T>`_ for appending a value ## * `prepend proc <#prepend,SinglyLinkedList[T],SinglyLinkedNode[T]>`_ ## for prepending a node runnableExamples: var a = initSinglyLinkedList[int]() a.prepend(9) a.prepend(8) assert a.contains(9) prepend(L, newSinglyLinkedNode(value)) proc append*[T](L: var DoublyLinkedList[T], n: DoublyLinkedNode[T]) = ## Appends (adds to the end) a node `n` to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,DoublyLinkedList[T],T>`_ for appending a value ## * `prepend proc <#prepend,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for prepending a node ## * `prepend proc <#prepend,DoublyLinkedList[T],T>`_ for prepending a value ## * `remove proc <#remove,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for removing a node runnableExamples: var a = initDoublyLinkedList[int]() n = newDoublyLinkedNode[int](9) a.append(n) assert a.contains(9) n.next = nil n.prev = L.tail if L.tail != nil: assert(L.tail.next == nil) L.tail.next = n L.tail = n if L.head == nil: L.head = n proc append*[T](L: var DoublyLinkedList[T], value: T) = ## Appends (adds to the end) a value to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for appending a node ## * `prepend proc <#prepend,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for prepending a node ## * `prepend proc <#prepend,DoublyLinkedList[T],T>`_ for prepending a value ## * `remove proc <#remove,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for removing a node runnableExamples: var a = initDoublyLinkedList[int]() a.append(9) a.append(8) assert a.contains(9) append(L, newDoublyLinkedNode(value)) proc prepend*[T](L: var DoublyLinkedList[T], n: DoublyLinkedNode[T]) = ## Prepends (adds to the beginning) a node `n` to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for appending a node ## * `append proc <#append,DoublyLinkedList[T],T>`_ for appending a value ## * `prepend proc <#prepend,DoublyLinkedList[T],T>`_ for prepending a value ## * `remove proc <#remove,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for removing a node runnableExamples: var a = initDoublyLinkedList[int]() n = newDoublyLinkedNode[int](9) a.prepend(n) assert a.contains(9) n.prev = nil n.next = L.head if L.head != nil: assert(L.head.prev == nil) L.head.prev = n L.head = n if L.tail == nil: L.tail = n proc prepend*[T](L: var DoublyLinkedList[T], value: T) = ## Prepends (adds to the beginning) a value to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for appending a node ## * `append proc <#append,DoublyLinkedList[T],T>`_ for appending a value ## * `prepend proc <#prepend,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for prepending a node ## * `remove proc <#remove,DoublyLinkedList[T],DoublyLinkedNode[T]>`_ ## for removing a node runnableExamples: var a = initDoublyLinkedList[int]() a.prepend(9) a.prepend(8) assert a.contains(9) prepend(L, newDoublyLinkedNode(value)) proc remove*[T](L: var DoublyLinkedList[T], n: DoublyLinkedNode[T]) = ## Removes a node `n` from `L`. Efficiency: O(1). runnableExamples: var a = initDoublyLinkedList[int]() n = newDoublyLinkedNode[int](5) a.append(n) assert 5 in a a.remove(n) assert 5 notin a if n == L.tail: L.tail = n.prev if n == L.head: L.head = n.next if n.next != nil: n.next.prev = n.prev if n.prev != nil: n.prev.next = n.next proc append*[T](L: var SinglyLinkedRing[T], n: SinglyLinkedNode[T]) = ## Appends (adds to the end) a node `n` to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,SinglyLinkedRing[T],T>`_ for appending a value ## * `prepend proc <#prepend,SinglyLinkedRing[T],SinglyLinkedNode[T]>`_ ## for prepending a node ## * `prepend proc <#prepend,SinglyLinkedRing[T],T>`_ for prepending a value runnableExamples: var a = initSinglyLinkedRing[int]() n = newSinglyLinkedNode[int](9) a.append(n) assert a.contains(9) if L.head != nil: n.next = L.head assert(L.tail != nil) L.tail.next = n L.tail = n else: n.next = n L.head = n L.tail = n proc append*[T](L: var SinglyLinkedRing[T], value: T) = ## Appends (adds to the end) a value to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,SinglyLinkedRing[T],SinglyLinkedNode[T]>`_ ## for appending a node ## * `prepend proc <#prepend,SinglyLinkedRing[T],SinglyLinkedNode[T]>`_ ## for prepending a node ## * `prepend proc <#prepend,SinglyLinkedRing[T],T>`_ for prepending a value runnableExamples: var a = initSinglyLinkedRing[int]() a.append(9) a.append(8) assert a.contains(9) append(L, newSinglyLinkedNode(value)) proc prepend*[T](L: var SinglyLinkedRing[T], n: SinglyLinkedNode[T]) = ## Prepends (adds to the beginning) a node `n` to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,SinglyLinkedRing[T],SinglyLinkedNode[T]>`_ ## for appending a node ## * `append proc <#append,SinglyLinkedRing[T],T>`_ for appending a value ## * `prepend proc <#prepend,SinglyLinkedRing[T],T>`_ for prepending a value runnableExamples: var a = initSinglyLinkedRing[int]() n = newSinglyLinkedNode[int](9) a.prepend(n) assert a.contains(9) if L.head != nil: n.next = L.head assert(L.tail != nil) L.tail.next = n else: n.next = n L.tail = n L.head = n proc prepend*[T](L: var SinglyLinkedRing[T], value: T) = ## Prepends (adds to the beginning) a value to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,SinglyLinkedRing[T],SinglyLinkedNode[T]>`_ ## for appending a node ## * `append proc <#append,SinglyLinkedRing[T],T>`_ for appending a value ## * `prepend proc <#prepend,SinglyLinkedRing[T],SinglyLinkedNode[T]>`_ ## for prepending a node runnableExamples: var a = initSinglyLinkedRing[int]() a.prepend(9) a.prepend(8) assert a.contains(9) prepend(L, newSinglyLinkedNode(value)) proc append*[T](L: var DoublyLinkedRing[T], n: DoublyLinkedNode[T]) = ## Appends (adds to the end) a node `n` to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,DoublyLinkedRing[T],T>`_ for appending a value ## * `prepend proc <#prepend,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for prepending a node ## * `prepend proc <#prepend,DoublyLinkedRing[T],T>`_ for prepending a value ## * `remove proc <#remove,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for removing a node runnableExamples: var a = initDoublyLinkedRing[int]() n = newDoublyLinkedNode[int](9) a.append(n) assert a.contains(9) if L.head != nil: n.next = L.head n.prev = L.head.prev L.head.prev.next = n L.head.prev = n else: n.prev = n n.next = n L.head = n proc append*[T](L: var DoublyLinkedRing[T], value: T) = ## Appends (adds to the end) a value to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for appending a node ## * `prepend proc <#prepend,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for prepending a node ## * `prepend proc <#prepend,DoublyLinkedRing[T],T>`_ for prepending a value ## * `remove proc <#remove,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for removing a node runnableExamples: var a = initDoublyLinkedRing[int]() a.append(9) a.append(8) assert a.contains(9) append(L, newDoublyLinkedNode(value)) proc prepend*[T](L: var DoublyLinkedRing[T], n: DoublyLinkedNode[T]) = ## Prepends (adds to the beginning) a node `n` to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for appending a node ## * `append proc <#append,DoublyLinkedRing[T],T>`_ for appending a value ## * `prepend proc <#prepend,DoublyLinkedRing[T],T>`_ for prepending a value ## * `remove proc <#remove,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for removing a node runnableExamples: var a = initDoublyLinkedRing[int]() n = newDoublyLinkedNode[int](9) a.prepend(n) assert a.contains(9) if L.head != nil: n.next = L.head n.prev = L.head.prev L.head.prev.next = n L.head.prev = n else: n.prev = n n.next = n L.head = n proc prepend*[T](L: var DoublyLinkedRing[T], value: T) = ## Prepends (adds to the beginning) a value to `L`. Efficiency: O(1). ## ## See also: ## * `append proc <#append,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for appending a node ## * `append proc <#append,DoublyLinkedRing[T],T>`_ for appending a value ## * `prepend proc <#prepend,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for prepending a node ## * `remove proc <#remove,DoublyLinkedRing[T],DoublyLinkedNode[T]>`_ ## for removing a node runnableExamples: var a = initDoublyLinkedRing[int]() a.prepend(9) a.prepend(8) assert a.contains(9) prepend(L, newDoublyLinkedNode(value)) proc remove*[T](L: var DoublyLinkedRing[T], n: DoublyLinkedNode[T]) = ## Removes `n` from `L`. Efficiency: O(1). runnableExamples: var a = initDoublyLinkedRing[int]() n = newDoublyLinkedNode[int](5) a.append(n) assert 5 in a a.remove(n) assert 5 notin a n.next.prev = n.prev n.prev.next = n.next if n == L.head: var p = L.head.prev if p == L.head: # only one element left: L.head = nil else: L.head = L.head.prev