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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
use dom::bindings::codegen::Bindings::NodeBinding::NodeMethods;
use dom::bindings::codegen::Bindings::NodeListBinding;
use dom::bindings::codegen::Bindings::NodeListBinding::NodeListMethods;
use dom::bindings::reflector::{Reflector, reflect_dom_object};
use dom::bindings::root::{Dom, DomRoot, MutNullableDom, RootedReference};
use dom::node::{ChildrenMutation, Node};
use dom::window::Window;
use dom_struct::dom_struct;
use std::cell::Cell;
#[derive(JSTraceable, MallocSizeOf)]
#[must_root]
pub enum NodeListType {
Simple(Vec<Dom<Node>>),
Children(ChildrenList),
}
// https://dom.spec.whatwg.org/#interface-nodelist
#[dom_struct]
pub struct NodeList {
reflector_: Reflector,
list_type: NodeListType,
}
impl NodeList {
#[allow(unrooted_must_root)]
pub fn new_inherited(list_type: NodeListType) -> NodeList {
NodeList {
reflector_: Reflector::new(),
list_type: list_type,
}
}
#[allow(unrooted_must_root)]
pub fn new(window: &Window, list_type: NodeListType) -> DomRoot<NodeList> {
reflect_dom_object(Box::new(NodeList::new_inherited(list_type)),
window,
NodeListBinding::Wrap)
}
pub fn new_simple_list<T>(window: &Window, iter: T) -> DomRoot<NodeList>
where T: Iterator<Item=DomRoot<Node>> {
NodeList::new(window, NodeListType::Simple(iter.map(|r| Dom::from_ref(&*r)).collect()))
}
pub fn new_simple_list_slice(window: &Window, slice: &[&Node]) -> DomRoot<NodeList> {
NodeList::new(window, NodeListType::Simple(slice.iter().map(|r| Dom::from_ref(*r)).collect()))
}
pub fn new_child_list(window: &Window, node: &Node) -> DomRoot<NodeList> {
NodeList::new(window, NodeListType::Children(ChildrenList::new(node)))
}
pub fn empty(window: &Window) -> DomRoot<NodeList> {
NodeList::new(window, NodeListType::Simple(vec![]))
}
}
impl NodeListMethods for NodeList {
// https://dom.spec.whatwg.org/#dom-nodelist-length
fn Length(&self) -> u32 {
match self.list_type {
NodeListType::Simple(ref elems) => elems.len() as u32,
NodeListType::Children(ref list) => list.len(),
}
}
// https://dom.spec.whatwg.org/#dom-nodelist-item
fn Item(&self, index: u32) -> Option<DomRoot<Node>> {
match self.list_type {
NodeListType::Simple(ref elems) => {
elems.get(index as usize).map(|node| DomRoot::from_ref(&**node))
},
NodeListType::Children(ref list) => list.item(index),
}
}
// https://dom.spec.whatwg.org/#dom-nodelist-item
fn IndexedGetter(&self, index: u32) -> Option<DomRoot<Node>> {
self.Item(index)
}
}
impl NodeList {
pub fn as_children_list(&self) -> &ChildrenList {
if let NodeListType::Children(ref list) = self.list_type {
list
} else {
panic!("called as_children_list() on a simple node list")
}
}
pub fn as_simple_list(&self) -> &Vec<Dom<Node>> {
if let NodeListType::Simple(ref list) = self.list_type {
list
} else {
panic!("called as_simple_list() on a children node list")
}
}
pub fn iter<'a>(&'a self) -> impl Iterator<Item=DomRoot<Node>> + 'a {
let len = self.Length();
(0..len).flat_map(move |i| self.Item(i))
}
}
#[derive(JSTraceable, MallocSizeOf)]
#[must_root]
pub struct ChildrenList {
node: Dom<Node>,
#[ignore_malloc_size_of = "Defined in rust-mozjs"]
last_visited: MutNullableDom<Node>,
last_index: Cell<u32>,
}
impl ChildrenList {
pub fn new(node: &Node) -> ChildrenList {
let last_visited = node.GetFirstChild();
ChildrenList {
node: Dom::from_ref(node),
last_visited: MutNullableDom::new(last_visited.r()),
last_index: Cell::new(0u32),
}
}
pub fn len(&self) -> u32 {
self.node.children_count()
}
pub fn item(&self, index: u32) -> Option<DomRoot<Node>> {
// This always start traversing the children from the closest element
// among parent's first and last children and the last visited one.
let len = self.len() as u32;
if index >= len {
return None;
}
if index == 0u32 {
// Item is first child if any, not worth updating last visited.
return self.node.GetFirstChild();
}
let last_index = self.last_index.get();
if index == last_index {
// Item is last visited child, no need to update last visited.
return Some(self.last_visited.get().unwrap());
}
let last_visited = if index - 1u32 == last_index {
// Item is last visited's next sibling.
self.last_visited.get().unwrap().GetNextSibling().unwrap()
} else if last_index > 0 && index == last_index - 1u32 {
// Item is last visited's previous sibling.
self.last_visited.get().unwrap().GetPreviousSibling().unwrap()
} else if index > last_index {
if index == len - 1u32 {
// Item is parent's last child, not worth updating last visited.
return Some(self.node.GetLastChild().unwrap());
}
if index <= last_index + (len - last_index) / 2u32 {
// Item is closer to the last visited child and follows it.
self.last_visited.get().unwrap()
.inclusively_following_siblings()
.nth((index - last_index) as usize).unwrap()
} else {
// Item is closer to parent's last child and obviously
// precedes it.
self.node.GetLastChild().unwrap()
.inclusively_preceding_siblings()
.nth((len - index - 1u32) as usize).unwrap()
}
} else if index >= last_index / 2u32 {
// Item is closer to the last visited child and precedes it.
self.last_visited.get().unwrap()
.inclusively_preceding_siblings()
.nth((last_index - index) as usize).unwrap()
} else {
// Item is closer to parent's first child and obviously follows it.
debug_assert!(index < last_index / 2u32);
self.node.GetFirstChild().unwrap()
.inclusively_following_siblings()
.nth(index as usize)
.unwrap()
};
self.last_visited.set(Some(&last_visited));
self.last_index.set(index);
Some(last_visited)
}
pub fn children_changed(&self, mutation: &ChildrenMutation) {
fn prepend(list: &ChildrenList, added: &[&Node], next: &Node) {
let len = added.len() as u32;
if len == 0u32 {
return;
}
let index = list.last_index.get();
if index < len {
list.last_visited.set(Some(added[index as usize]));
} else if index / 2u32 >= len {
// If last index is twice as large as the number of added nodes,
// updating only it means that less nodes will be traversed if
// caller is traversing the node list linearly.
list.last_index.set(len + index);
} else {
// If last index is not twice as large but still larger,
// it's better to update it to the number of added nodes.
list.last_visited.set(Some(next));
list.last_index.set(len);
}
}
fn replace(list: &ChildrenList,
prev: Option<&Node>,
removed: &Node,
added: &[&Node],
next: Option<&Node>) {
let index = list.last_index.get();
if removed == &*list.last_visited.get().unwrap() {
let visited = match (prev, added, next) {
(None, _, None) => {
// Such cases where parent had only one child should
// have been changed into ChildrenMutation::ReplaceAll
// by ChildrenMutation::replace().
unreachable!()
},
(_, added, _) if !added.is_empty() => added[0],
(_, _, Some(next)) => next,
(Some(prev), _, None) => {
list.last_index.set(index - 1u32);
prev
},
};
list.last_visited.set(Some(visited));
} else if added.len() != 1 {
// The replaced child isn't the last visited one, and there are
// 0 or more than 1 nodes to replace it. Special care must be
// given to update the state of that ChildrenList.
match (prev, next) {
(Some(_), None) => {},
(None, Some(next)) => {
list.last_index.set(index - 1);
prepend(list, added, next);
},
(Some(_), Some(_)) => {
list.reset();
},
(None, None) => unreachable!(),
}
}
}
match *mutation {
ChildrenMutation::Append { .. } => {},
ChildrenMutation::Insert { .. } => {
self.reset();
},
ChildrenMutation::Prepend { added, next } => {
prepend(self, added, next);
},
ChildrenMutation::Replace { prev, removed, added, next } => {
replace(self, prev, removed, added, next);
},
ChildrenMutation::ReplaceAll { added, .. } => {
let len = added.len();
let index = self.last_index.get();
if len == 0 {
self.last_visited.set(None);
self.last_index.set(0u32);
} else if index < len as u32 {
self.last_visited.set(Some(added[index as usize]));
} else {
// Setting last visited to parent's last child serves no purpose,
// so the middle is arbitrarily chosen here in case the caller
// wants random access.
let middle = len / 2;
self.last_visited.set(Some(added[middle]));
self.last_index.set(middle as u32);
}
},
ChildrenMutation::ChangeText => {},
}
}
fn reset(&self) {
self.last_visited.set(self.node.GetFirstChild().r());
self.last_index.set(0u32);
}
}
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