zig/std/linked_list.zig

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const std = @import("index.zig");
const debug = std.debug;
const assert = debug.assert;
const mem = std.mem;
const Allocator = mem.Allocator;
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/// Generic doubly linked list.
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pub fn LinkedList(comptime T: type) type {
return struct {
const Self = @This();
/// Node inside the linked list wrapping the actual data.
pub const Node = struct {
prev: ?*Node,
next: ?*Node,
data: T,
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pub fn init(data: T) Node {
return Node{
.prev = null,
.next = null,
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.data = data,
};
}
};
first: ?*Node,
last: ?*Node,
len: usize,
/// Initialize a linked list.
///
/// Returns:
/// An empty linked list.
pub fn init() Self {
return Self{
.first = null,
.last = null,
.len = 0,
};
}
/// Insert a new node after an existing one.
///
/// Arguments:
/// node: Pointer to a node in the list.
/// new_node: Pointer to the new node to insert.
pub fn insertAfter(list: *Self, node: *Node, new_node: *Node) void {
new_node.prev = node;
if (node.next) |next_node| {
// Intermediate node.
new_node.next = next_node;
next_node.prev = new_node;
} else {
// Last element of the list.
new_node.next = null;
list.last = new_node;
}
node.next = new_node;
list.len += 1;
}
/// Insert a new node before an existing one.
///
/// Arguments:
/// node: Pointer to a node in the list.
/// new_node: Pointer to the new node to insert.
pub fn insertBefore(list: *Self, node: *Node, new_node: *Node) void {
new_node.next = node;
if (node.prev) |prev_node| {
// Intermediate node.
new_node.prev = prev_node;
prev_node.next = new_node;
} else {
// First element of the list.
new_node.prev = null;
list.first = new_node;
}
node.prev = new_node;
list.len += 1;
}
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/// Concatenate list2 onto the end of list1, removing all entries from the former.
///
/// Arguments:
/// list1: the list to concatenate onto
/// list2: the list to be concatenated
pub fn concatByMoving(list1: *Self, list2: *Self) void {
const l2_first = list2.first orelse return;
if (list1.last) |l1_last| {
l1_last.next = list2.first;
l2_first.prev = list1.last;
list1.len += list2.len;
} else {
// list1 was empty
list1.first = list2.first;
list1.len = list2.len;
}
list1.last = list2.last;
list2.first = null;
list2.last = null;
list2.len = 0;
}
/// Insert a new node at the end of the list.
///
/// Arguments:
/// new_node: Pointer to the new node to insert.
pub fn append(list: *Self, new_node: *Node) void {
if (list.last) |last| {
// Insert after last.
list.insertAfter(last, new_node);
} else {
// Empty list.
list.prepend(new_node);
}
}
/// Insert a new node at the beginning of the list.
///
/// Arguments:
/// new_node: Pointer to the new node to insert.
pub fn prepend(list: *Self, new_node: *Node) void {
if (list.first) |first| {
// Insert before first.
list.insertBefore(first, new_node);
} else {
// Empty list.
list.first = new_node;
list.last = new_node;
new_node.prev = null;
new_node.next = null;
list.len = 1;
}
}
/// Remove a node from the list.
///
/// Arguments:
/// node: Pointer to the node to be removed.
pub fn remove(list: *Self, node: *Node) void {
if (node.prev) |prev_node| {
// Intermediate node.
prev_node.next = node.next;
} else {
// First element of the list.
list.first = node.next;
}
if (node.next) |next_node| {
// Intermediate node.
next_node.prev = node.prev;
} else {
// Last element of the list.
list.last = node.prev;
}
list.len -= 1;
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assert(list.len == 0 or (list.first != null and list.last != null));
}
/// Remove and return the last node in the list.
///
/// Returns:
/// A pointer to the last node in the list.
pub fn pop(list: *Self) ?*Node {
const last = list.last orelse return null;
list.remove(last);
return last;
}
/// Remove and return the first node in the list.
///
/// Returns:
/// A pointer to the first node in the list.
pub fn popFirst(list: *Self) ?*Node {
const first = list.first orelse return null;
list.remove(first);
return first;
}
/// Allocate a new node.
///
/// Arguments:
/// allocator: Dynamic memory allocator.
///
/// Returns:
/// A pointer to the new node.
pub fn allocateNode(list: *Self, allocator: *Allocator) !*Node {
return allocator.create(Node(undefined));
}
/// Deallocate a node.
///
/// Arguments:
/// node: Pointer to the node to deallocate.
/// allocator: Dynamic memory allocator.
pub fn destroyNode(list: *Self, node: *Node, allocator: *Allocator) void {
allocator.destroy(node);
}
/// Allocate and initialize a node and its data.
///
/// Arguments:
/// data: The data to put inside the node.
/// allocator: Dynamic memory allocator.
///
/// Returns:
/// A pointer to the new node.
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pub fn createNode(list: *Self, data: T, allocator: *Allocator) !*Node {
var node = try list.allocateNode(allocator);
node.* = Node.init(data);
return node;
}
};
}
test "basic linked list test" {
const allocator = debug.global_allocator;
var list = LinkedList(u32).init();
var one = try list.createNode(1, allocator);
var two = try list.createNode(2, allocator);
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var three = try list.createNode(3, allocator);
var four = try list.createNode(4, allocator);
var five = try list.createNode(5, allocator);
defer {
list.destroyNode(one, allocator);
list.destroyNode(two, allocator);
list.destroyNode(three, allocator);
list.destroyNode(four, allocator);
list.destroyNode(five, allocator);
}
list.append(two); // {2}
list.append(five); // {2, 5}
list.prepend(one); // {1, 2, 5}
list.insertBefore(five, four); // {1, 2, 4, 5}
list.insertAfter(two, three); // {1, 2, 3, 4, 5}
// Traverse forwards.
{
var it = list.first;
var index: u32 = 1;
while (it) |node| : (it = node.next) {
assert(node.data == index);
index += 1;
}
}
// Traverse backwards.
{
var it = list.last;
var index: u32 = 1;
while (it) |node| : (it = node.prev) {
assert(node.data == (6 - index));
index += 1;
}
}
var first = list.popFirst(); // {2, 3, 4, 5}
var last = list.pop(); // {2, 3, 4}
list.remove(three); // {2, 4}
assert(list.first.?.data == 2);
assert(list.last.?.data == 4);
assert(list.len == 2);
}
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test "linked list concatenation" {
const allocator = debug.global_allocator;
var list1 = LinkedList(u32).init();
var list2 = LinkedList(u32).init();
var one = try list1.createNode(1, allocator);
defer list1.destroyNode(one, allocator);
var two = try list1.createNode(2, allocator);
defer list1.destroyNode(two, allocator);
var three = try list1.createNode(3, allocator);
defer list1.destroyNode(three, allocator);
var four = try list1.createNode(4, allocator);
defer list1.destroyNode(four, allocator);
var five = try list1.createNode(5, allocator);
defer list1.destroyNode(five, allocator);
list1.append(one);
list1.append(two);
list2.append(three);
list2.append(four);
list2.append(five);
list1.concatByMoving(&list2);
assert(list1.last == five);
assert(list1.len == 5);
assert(list2.first == null);
assert(list2.last == null);
assert(list2.len == 0);
// Traverse forwards.
{
var it = list1.first;
var index: u32 = 1;
while (it) |node| : (it = node.next) {
assert(node.data == index);
index += 1;
}
}
// Traverse backwards.
{
var it = list1.last;
var index: u32 = 1;
while (it) |node| : (it = node.prev) {
assert(node.data == (6 - index));
index += 1;
}
}
// Swap them back, this verifies that concating to an empty list works.
list2.concatByMoving(&list1);
// Traverse forwards.
{
var it = list2.first;
var index: u32 = 1;
while (it) |node| : (it = node.next) {
assert(node.data == index);
index += 1;
}
}
// Traverse backwards.
{
var it = list2.last;
var index: u32 = 1;
while (it) |node| : (it = node.prev) {
assert(node.data == (6 - index));
index += 1;
}
}
}