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servo/components/script/dom/node.rs
Simon Wülker b100a98e1d
Fully support <input type=color> (#36992) 
This change adds a shadow-tree widget for `<input type=color>` elements.
It also involves some changes to the way layout interacts with the DOM,
because currently all `input` and `textarea` elements are rendered as
plain text and their descendants are ignored. This obviously doesn't
work for `<input type={color, date, range, etc}>`.


![image](https://github.com/user-attachments/assets/4f16c3b0-1f79-4095-b19d-1153f5853dd5)

<details><summary>HTML used for the screenshot above</summary>

```html
<input type=color>
```

</details>



Testing: I doubt that this affects WPT tests, because the appearance and
behaviour of the widget is almost entirely unspecified.

---------

Signed-off-by: Simon Wülker <simon.wuelker@arcor.de>
2025-05-15 17:30:38 +00:00

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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 https://mozilla.org/MPL/2.0/. */
//! The core DOM types. Defines the basic DOM hierarchy as well as all the HTML elements.
use std::borrow::Cow;
use std::cell::{Cell, LazyCell, UnsafeCell};
use std::default::Default;
use std::f64::consts::PI;
use std::ops::Range;
use std::slice::from_ref;
use std::sync::Arc as StdArc;
use std::{cmp, fmt, iter};
use app_units::Au;
use base::id::{BrowsingContextId, PipelineId};
use bitflags::bitflags;
use devtools_traits::NodeInfo;
use dom_struct::dom_struct;
use embedder_traits::UntrustedNodeAddress;
use euclid::default::{Rect, Size2D, Vector2D};
use html5ever::serialize::HtmlSerializer;
use html5ever::{Namespace, Prefix, QualName, ns, serialize as html_serialize};
use js::jsapi::JSObject;
use js::rust::HandleObject;
use libc::{self, c_void, uintptr_t};
use malloc_size_of::{MallocSizeOf, MallocSizeOfOps};
use pixels::{Image, ImageMetadata};
use script_bindings::codegen::InheritTypes::DocumentFragmentTypeId;
use script_layout_interface::{
GenericLayoutData, HTMLCanvasData, HTMLMediaData, LayoutElementType, LayoutNodeType, QueryMsg,
SVGSVGData, StyleData, TrustedNodeAddress,
};
use script_traits::DocumentActivity;
use selectors::matching::{
MatchingContext, MatchingForInvalidation, MatchingMode, NeedsSelectorFlags,
matches_selector_list,
};
use selectors::parser::SelectorList;
use servo_arc::Arc;
use servo_config::pref;
use servo_url::ServoUrl;
use smallvec::SmallVec;
use style::context::QuirksMode;
use style::dom::OpaqueNode;
use style::properties::ComputedValues;
use style::selector_parser::{SelectorImpl, SelectorParser};
use style::stylesheets::{Stylesheet, UrlExtraData};
use uuid::Uuid;
use xml5ever::serialize as xml_serialize;
use crate::conversions::Convert;
use crate::document_loader::DocumentLoader;
use crate::dom::attr::Attr;
use crate::dom::bindings::cell::{DomRefCell, Ref, RefMut};
use crate::dom::bindings::codegen::Bindings::AttrBinding::AttrMethods;
use crate::dom::bindings::codegen::Bindings::CSSStyleDeclarationBinding::CSSStyleDeclarationMethods;
use crate::dom::bindings::codegen::Bindings::CharacterDataBinding::CharacterDataMethods;
use crate::dom::bindings::codegen::Bindings::DocumentBinding::DocumentMethods;
use crate::dom::bindings::codegen::Bindings::ElementBinding::ElementMethods;
use crate::dom::bindings::codegen::Bindings::HTMLCollectionBinding::HTMLCollectionMethods;
use crate::dom::bindings::codegen::Bindings::NodeBinding::{
GetRootNodeOptions, NodeConstants, NodeMethods,
};
use crate::dom::bindings::codegen::Bindings::NodeListBinding::NodeListMethods;
use crate::dom::bindings::codegen::Bindings::ProcessingInstructionBinding::ProcessingInstructionMethods;
use crate::dom::bindings::codegen::Bindings::ShadowRootBinding::ShadowRoot_Binding::ShadowRootMethods;
use crate::dom::bindings::codegen::Bindings::ShadowRootBinding::{
ShadowRootMode, SlotAssignmentMode,
};
use crate::dom::bindings::codegen::Bindings::WindowBinding::WindowMethods;
use crate::dom::bindings::codegen::UnionTypes::NodeOrString;
use crate::dom::bindings::conversions::{self, DerivedFrom};
use crate::dom::bindings::error::{Error, ErrorResult, Fallible};
use crate::dom::bindings::inheritance::{
Castable, CharacterDataTypeId, ElementTypeId, EventTargetTypeId, HTMLElementTypeId, NodeTypeId,
SVGElementTypeId, SVGGraphicsElementTypeId, TextTypeId,
};
use crate::dom::bindings::refcounted::Trusted;
use crate::dom::bindings::reflector::{DomObject, DomObjectWrap, reflect_dom_object_with_proto};
use crate::dom::bindings::root::{Dom, DomRoot, DomSlice, LayoutDom, MutNullableDom, ToLayout};
use crate::dom::bindings::str::{DOMString, USVString};
use crate::dom::bindings::xmlname::namespace_from_domstring;
use crate::dom::characterdata::{CharacterData, LayoutCharacterDataHelpers};
use crate::dom::cssstylesheet::CSSStyleSheet;
use crate::dom::customelementregistry::{CallbackReaction, try_upgrade_element};
use crate::dom::document::{Document, DocumentSource, HasBrowsingContext, IsHTMLDocument};
use crate::dom::documentfragment::DocumentFragment;
use crate::dom::documenttype::DocumentType;
use crate::dom::element::{CustomElementCreationMode, Element, ElementCreator, SelectorWrapper};
use crate::dom::event::{Event, EventBubbles, EventCancelable};
use crate::dom::eventtarget::EventTarget;
use crate::dom::globalscope::GlobalScope;
use crate::dom::htmlbodyelement::HTMLBodyElement;
use crate::dom::htmlcanvaselement::{HTMLCanvasElement, LayoutHTMLCanvasElementHelpers};
use crate::dom::htmlcollection::HTMLCollection;
use crate::dom::htmlelement::HTMLElement;
use crate::dom::htmliframeelement::{HTMLIFrameElement, HTMLIFrameElementLayoutMethods};
use crate::dom::htmlimageelement::{HTMLImageElement, LayoutHTMLImageElementHelpers};
use crate::dom::htmlinputelement::{HTMLInputElement, InputType, LayoutHTMLInputElementHelpers};
use crate::dom::htmllinkelement::HTMLLinkElement;
use crate::dom::htmlslotelement::{HTMLSlotElement, Slottable};
use crate::dom::htmlstyleelement::HTMLStyleElement;
use crate::dom::htmltextareaelement::{HTMLTextAreaElement, LayoutHTMLTextAreaElementHelpers};
use crate::dom::htmlvideoelement::{HTMLVideoElement, LayoutHTMLVideoElementHelpers};
use crate::dom::mutationobserver::{Mutation, MutationObserver, RegisteredObserver};
use crate::dom::nodelist::NodeList;
use crate::dom::pointerevent::{PointerEvent, PointerId};
use crate::dom::processinginstruction::ProcessingInstruction;
use crate::dom::range::WeakRangeVec;
use crate::dom::raredata::NodeRareData;
use crate::dom::servoparser::{ServoParser, serialize_html_fragment};
use crate::dom::shadowroot::{IsUserAgentWidget, LayoutShadowRootHelpers, ShadowRoot};
use crate::dom::stylesheetlist::StyleSheetListOwner;
use crate::dom::svgsvgelement::{LayoutSVGSVGElementHelpers, SVGSVGElement};
use crate::dom::text::Text;
use crate::dom::virtualmethods::{VirtualMethods, vtable_for};
use crate::dom::window::Window;
use crate::script_runtime::CanGc;
use crate::script_thread::ScriptThread;
//
// The basic Node structure
//
/// An HTML node.
#[dom_struct]
pub struct Node {
/// The JavaScript reflector for this node.
eventtarget: EventTarget,
/// The parent of this node.
parent_node: MutNullableDom<Node>,
/// The first child of this node.
first_child: MutNullableDom<Node>,
/// The last child of this node.
last_child: MutNullableDom<Node>,
/// The next sibling of this node.
next_sibling: MutNullableDom<Node>,
/// The previous sibling of this node.
prev_sibling: MutNullableDom<Node>,
/// The document that this node belongs to.
owner_doc: MutNullableDom<Document>,
/// Rare node data.
rare_data: DomRefCell<Option<Box<NodeRareData>>>,
/// The live count of children of this node.
children_count: Cell<u32>,
/// A bitfield of flags for node items.
flags: Cell<NodeFlags>,
/// The maximum version of any inclusive descendant of this node.
inclusive_descendants_version: Cell<u64>,
/// Style data for this node. This is accessed and mutated by style
/// passes and is used to lay out this node and populate layout data.
#[no_trace]
style_data: DomRefCell<Option<Box<StyleData>>>,
/// Layout data for this node. This is populated during layout and can
/// be used for incremental relayout and script queries.
#[no_trace]
layout_data: DomRefCell<Option<Box<GenericLayoutData>>>,
}
impl fmt::Debug for Node {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
if matches!(self.type_id(), NodeTypeId::Element(_)) {
let el = self.downcast::<Element>().unwrap();
el.fmt(f)
} else {
write!(f, "[Node({:?})]", self.type_id())
}
}
}
/// Flags for node items
#[derive(Clone, Copy, JSTraceable, MallocSizeOf)]
pub(crate) struct NodeFlags(u16);
bitflags! {
impl NodeFlags: u16 {
/// Specifies whether this node is in a document.
///
/// <https://dom.spec.whatwg.org/#in-a-document-tree>
const IS_IN_A_DOCUMENT_TREE = 1 << 0;
/// Specifies whether this node needs style recalc on next reflow.
const HAS_DIRTY_DESCENDANTS = 1 << 1;
/// Specifies whether or not there is an authentic click in progress on
/// this element.
const CLICK_IN_PROGRESS = 1 << 2;
/// Specifies whether this node is focusable and whether it is supposed
/// to be reachable with using sequential focus navigation."]
const SEQUENTIALLY_FOCUSABLE = 1 << 3;
// There are two free bits here.
/// Specifies whether the parser has set an associated form owner for
/// this element. Only applicable for form-associatable elements.
const PARSER_ASSOCIATED_FORM_OWNER = 1 << 6;
/// Whether this element has a snapshot stored due to a style or
/// attribute change.
///
/// See the `style::restyle_hints` module.
const HAS_SNAPSHOT = 1 << 7;
/// Whether this element has already handled the stored snapshot.
const HANDLED_SNAPSHOT = 1 << 8;
/// Whether this node participates in a shadow tree.
const IS_IN_SHADOW_TREE = 1 << 9;
/// Specifies whether this node's shadow-including root is a document.
///
/// <https://dom.spec.whatwg.org/#connected>
const IS_CONNECTED = 1 << 10;
/// Whether this node has a weird parser insertion mode. i.e whether setting innerHTML
/// needs extra work or not
const HAS_WEIRD_PARSER_INSERTION_MODE = 1 << 11;
}
}
/// suppress observers flag
/// <https://dom.spec.whatwg.org/#concept-node-insert>
/// <https://dom.spec.whatwg.org/#concept-node-remove>
#[derive(Clone, Copy, MallocSizeOf)]
enum SuppressObserver {
Suppressed,
Unsuppressed,
}
impl Node {
/// Adds a new child to the end of this node's list of children.
///
/// Fails unless `new_child` is disconnected from the tree.
fn add_child(&self, new_child: &Node, before: Option<&Node>, can_gc: CanGc) {
assert!(new_child.parent_node.get().is_none());
assert!(new_child.prev_sibling.get().is_none());
assert!(new_child.next_sibling.get().is_none());
match before {
Some(before) => {
assert!(before.parent_node.get().as_deref() == Some(self));
let prev_sibling = before.GetPreviousSibling();
match prev_sibling {
None => {
assert!(self.first_child.get().as_deref() == Some(before));
self.first_child.set(Some(new_child));
},
Some(ref prev_sibling) => {
prev_sibling.next_sibling.set(Some(new_child));
new_child.prev_sibling.set(Some(prev_sibling));
},
}
before.prev_sibling.set(Some(new_child));
new_child.next_sibling.set(Some(before));
},
None => {
let last_child = self.GetLastChild();
match last_child {
None => self.first_child.set(Some(new_child)),
Some(ref last_child) => {
assert!(last_child.next_sibling.get().is_none());
last_child.next_sibling.set(Some(new_child));
new_child.prev_sibling.set(Some(last_child));
},
}
self.last_child.set(Some(new_child));
},
}
new_child.parent_node.set(Some(self));
self.children_count.set(self.children_count.get() + 1);
let parent_is_in_a_document_tree = self.is_in_a_document_tree();
let parent_in_shadow_tree = self.is_in_a_shadow_tree();
let parent_is_connected = self.is_connected();
for node in new_child.traverse_preorder(ShadowIncluding::No) {
if parent_in_shadow_tree {
if let Some(shadow_root) = self.containing_shadow_root() {
node.set_containing_shadow_root(Some(&*shadow_root));
}
debug_assert!(node.containing_shadow_root().is_some());
}
node.set_flag(
NodeFlags::IS_IN_A_DOCUMENT_TREE,
parent_is_in_a_document_tree,
);
node.set_flag(NodeFlags::IS_IN_SHADOW_TREE, parent_in_shadow_tree);
node.set_flag(NodeFlags::IS_CONNECTED, parent_is_connected);
// Out-of-document elements never have the descendants flag set.
debug_assert!(!node.get_flag(NodeFlags::HAS_DIRTY_DESCENDANTS));
vtable_for(&node).bind_to_tree(
&BindContext {
tree_connected: parent_is_connected,
tree_is_in_a_document_tree: parent_is_in_a_document_tree,
tree_is_in_a_shadow_tree: parent_in_shadow_tree,
},
can_gc,
);
}
}
/// Implements the "unsafely set HTML" algorithm as specified in:
/// <https://html.spec.whatwg.org/multipage/#concept-unsafely-set-html>
pub fn unsafely_set_html(
target: &Node,
context_element: &Element,
html: DOMString,
can_gc: CanGc,
) {
// Step 1. Let newChildren be the result of the HTML fragment parsing algorithm.
let new_children = ServoParser::parse_html_fragment(context_element, html, true, can_gc);
// Step 2. Let fragment be a new DocumentFragment whose node document is contextElement's node document.
let context_document = context_element.owner_document();
let fragment = DocumentFragment::new(&context_document, can_gc);
// Step 3. For each node in newChildren, append node to fragment.
for child in new_children {
fragment
.upcast::<Node>()
.AppendChild(&child, can_gc)
.unwrap();
}
// Step 4. Replace all with fragment within target.
Node::replace_all(Some(fragment.upcast()), target, can_gc);
}
pub(crate) fn clean_up_style_and_layout_data(&self) {
self.owner_doc().cancel_animations_for_node(self);
self.style_data.borrow_mut().take();
self.layout_data.borrow_mut().take();
}
/// Clean up flags and runs steps 11-14 of remove a node.
/// <https://dom.spec.whatwg.org/#concept-node-remove>
pub(crate) fn complete_remove_subtree(root: &Node, context: &UnbindContext, can_gc: CanGc) {
// Flags that reset when a node is disconnected
const RESET_FLAGS: NodeFlags = NodeFlags::IS_IN_A_DOCUMENT_TREE
.union(NodeFlags::IS_CONNECTED)
.union(NodeFlags::HAS_DIRTY_DESCENDANTS)
.union(NodeFlags::HAS_SNAPSHOT)
.union(NodeFlags::HANDLED_SNAPSHOT);
for node in root.traverse_preorder(ShadowIncluding::No) {
node.set_flag(RESET_FLAGS | NodeFlags::IS_IN_SHADOW_TREE, false);
// If the element has a shadow root attached to it then we traverse that as well,
// but without touching the IS_IN_SHADOW_TREE flags of the children
if let Some(shadow_root) = node.downcast::<Element>().and_then(Element::shadow_root) {
for node in shadow_root
.upcast::<Node>()
.traverse_preorder(ShadowIncluding::Yes)
{
node.set_flag(RESET_FLAGS, false);
}
}
}
// Step 12.
let is_parent_connected = context.parent.is_connected();
for node in root.traverse_preorder(ShadowIncluding::Yes) {
node.clean_up_style_and_layout_data();
// Step 11 & 14.1. Run the removing steps.
// This needs to be in its own loop, because unbind_from_tree may
// rely on the state of IS_IN_DOC of the context node's descendants,
// e.g. when removing a <form>.
vtable_for(&node).unbind_from_tree(context, can_gc);
// Step 12 & 14.2. Enqueue disconnected custom element reactions.
if is_parent_connected {
if let Some(element) = node.as_custom_element() {
ScriptThread::enqueue_callback_reaction(
&element,
CallbackReaction::Disconnected,
None,
);
}
}
}
}
/// Removes the given child from this node's list of children.
///
/// Fails unless `child` is a child of this node.
fn remove_child(&self, child: &Node, cached_index: Option<u32>, can_gc: CanGc) {
assert!(child.parent_node.get().as_deref() == Some(self));
self.note_dirty_descendants();
let prev_sibling = child.GetPreviousSibling();
match prev_sibling {
None => {
self.first_child.set(child.next_sibling.get().as_deref());
},
Some(ref prev_sibling) => {
prev_sibling
.next_sibling
.set(child.next_sibling.get().as_deref());
},
}
let next_sibling = child.GetNextSibling();
match next_sibling {
None => {
self.last_child.set(child.prev_sibling.get().as_deref());
},
Some(ref next_sibling) => {
next_sibling
.prev_sibling
.set(child.prev_sibling.get().as_deref());
},
}
let context = UnbindContext::new(
self,
prev_sibling.as_deref(),
next_sibling.as_deref(),
cached_index,
);
child.prev_sibling.set(None);
child.next_sibling.set(None);
child.parent_node.set(None);
self.children_count.set(self.children_count.get() - 1);
Self::complete_remove_subtree(child, &context, can_gc);
}
pub(crate) fn to_untrusted_node_address(&self) -> UntrustedNodeAddress {
UntrustedNodeAddress(self.reflector().get_jsobject().get() as *const c_void)
}
pub(crate) fn to_opaque(&self) -> OpaqueNode {
OpaqueNode(self.reflector().get_jsobject().get() as usize)
}
pub(crate) fn as_custom_element(&self) -> Option<DomRoot<Element>> {
self.downcast::<Element>().and_then(|element| {
if element.is_custom() {
assert!(element.get_custom_element_definition().is_some());
Some(DomRoot::from_ref(element))
} else {
None
}
})
}
/// <https://html.spec.whatwg.org/multipage/#fire-a-synthetic-pointer-event>
pub(crate) fn fire_synthetic_pointer_event_not_trusted(&self, name: DOMString, can_gc: CanGc) {
// Spec says the choice of which global to create the pointer event
// on is not well-defined,
// and refers to heycam/webidl#135
let window = self.owner_window();
// <https://w3c.github.io/pointerevents/#the-click-auxclick-and-contextmenu-events>
let pointer_event = PointerEvent::new(
&window, // ambiguous in spec
name,
EventBubbles::Bubbles, // Step 3: bubbles
EventCancelable::Cancelable, // Step 3: cancelable
Some(&window), // Step 7: view
0, // detail uninitialized
0, // coordinates uninitialized
0, // coordinates uninitialized
0, // coordinates uninitialized
0, // coordinates uninitialized
false, // ctrl_key
false, // alt_key
false, // shift_key
false, // meta_key
0, // button, left mouse button
0, // buttons
None, // related_target
None, // point_in_target
PointerId::NonPointerDevice as i32, // pointer_id
1, // width
1, // height
0.5, // pressure
0.0, // tangential_pressure
0, // tilt_x
0, // tilt_y
0, // twist
PI / 2.0, // altitude_angle
0.0, // azimuth_angle
DOMString::from(""), // pointer_type
false, // is_primary
vec![], // coalesced_events
vec![], // predicted_events
can_gc,
);
// Step 4. Set event's composed flag.
pointer_event.upcast::<Event>().set_composed(true);
// Step 5. If the not trusted flag is set, initialize event's isTrusted attribute to false.
pointer_event.upcast::<Event>().set_trusted(false);
// Step 6,8. TODO keyboard modifiers
pointer_event
.upcast::<Event>()
.dispatch(self.upcast::<EventTarget>(), false, can_gc);
}
pub(crate) fn parent_directionality(&self) -> String {
let mut current = self.GetParentNode();
loop {
match current {
Some(node) => {
if let Some(directionality) = node
.downcast::<HTMLElement>()
.and_then(|html_element| html_element.directionality())
{
return directionality;
} else {
current = node.GetParentNode();
}
},
None => return "ltr".to_owned(),
}
}
}
}
pub(crate) struct QuerySelectorIterator {
selectors: SelectorList<SelectorImpl>,
iterator: TreeIterator,
}
impl QuerySelectorIterator {
fn new(iter: TreeIterator, selectors: SelectorList<SelectorImpl>) -> QuerySelectorIterator {
QuerySelectorIterator {
selectors,
iterator: iter,
}
}
}
impl Iterator for QuerySelectorIterator {
type Item = DomRoot<Node>;
fn next(&mut self) -> Option<DomRoot<Node>> {
let selectors = &self.selectors;
self.iterator
.by_ref()
.filter_map(|node| {
// TODO(cgaebel): Is it worth it to build a bloom filter here
// (instead of passing `None`)? Probably.
let mut nth_index_cache = Default::default();
let mut ctx = MatchingContext::new(
MatchingMode::Normal,
None,
&mut nth_index_cache,
node.owner_doc().quirks_mode(),
NeedsSelectorFlags::No,
MatchingForInvalidation::No,
);
if let Some(element) = DomRoot::downcast(node) {
if matches_selector_list(
selectors,
&SelectorWrapper::Borrowed(&element),
&mut ctx,
) {
return Some(DomRoot::upcast(element));
}
}
None
})
.next()
}
}
impl Node {
fn rare_data(&self) -> Ref<Option<Box<NodeRareData>>> {
self.rare_data.borrow()
}
fn ensure_rare_data(&self) -> RefMut<Box<NodeRareData>> {
let mut rare_data = self.rare_data.borrow_mut();
if rare_data.is_none() {
*rare_data = Some(Default::default());
}
RefMut::map(rare_data, |rare_data| rare_data.as_mut().unwrap())
}
/// Returns true if this node is before `other` in the same connected DOM
/// tree.
pub(crate) fn is_before(&self, other: &Node) -> bool {
let cmp = other.CompareDocumentPosition(self);
if cmp & NodeConstants::DOCUMENT_POSITION_DISCONNECTED != 0 {
return false;
}
cmp & NodeConstants::DOCUMENT_POSITION_PRECEDING != 0
}
/// Return all registered mutation observers for this node. Lazily initialize the
/// raredata if it does not exist.
pub(crate) fn registered_mutation_observers_mut(&self) -> RefMut<Vec<RegisteredObserver>> {
RefMut::map(self.ensure_rare_data(), |rare_data| {
&mut rare_data.mutation_observers
})
}
pub(crate) fn registered_mutation_observers(&self) -> Option<Ref<Vec<RegisteredObserver>>> {
let rare_data: Ref<_> = self.rare_data.borrow();
if rare_data.is_none() {
return None;
}
Some(Ref::map(rare_data, |rare_data| {
&rare_data.as_ref().unwrap().mutation_observers
}))
}
/// Add a new mutation observer for a given node.
pub(crate) fn add_mutation_observer(&self, observer: RegisteredObserver) {
self.ensure_rare_data().mutation_observers.push(observer);
}
/// Removes the mutation observer for a given node.
pub(crate) fn remove_mutation_observer(&self, observer: &MutationObserver) {
self.ensure_rare_data()
.mutation_observers
.retain(|reg_obs| &*reg_obs.observer != observer)
}
/// Dumps the subtree rooted at this node, for debugging.
pub(crate) fn dump(&self) {
self.dump_indent(0);
}
/// Dumps the node tree, for debugging, with indentation.
pub(crate) fn dump_indent(&self, indent: u32) {
let mut s = String::new();
for _ in 0..indent {
s.push_str(" ");
}
s.push_str(&self.debug_str());
debug!("{:?}", s);
// FIXME: this should have a pure version?
for kid in self.children() {
kid.dump_indent(indent + 1)
}
}
/// Returns a string that describes this node.
pub(crate) fn debug_str(&self) -> String {
format!("{:?}", self.type_id())
}
/// <https://dom.spec.whatwg.org/#in-a-document-tree>
pub(crate) fn is_in_a_document_tree(&self) -> bool {
self.flags.get().contains(NodeFlags::IS_IN_A_DOCUMENT_TREE)
}
/// Return true iff node's root is a shadow-root.
pub(crate) fn is_in_a_shadow_tree(&self) -> bool {
self.flags.get().contains(NodeFlags::IS_IN_SHADOW_TREE)
}
pub(crate) fn has_weird_parser_insertion_mode(&self) -> bool {
self.flags
.get()
.contains(NodeFlags::HAS_WEIRD_PARSER_INSERTION_MODE)
}
pub(crate) fn set_weird_parser_insertion_mode(&self) {
self.set_flag(NodeFlags::HAS_WEIRD_PARSER_INSERTION_MODE, true)
}
/// <https://dom.spec.whatwg.org/#connected>
pub(crate) fn is_connected(&self) -> bool {
self.flags.get().contains(NodeFlags::IS_CONNECTED)
}
/// Returns the type ID of this node.
pub(crate) fn type_id(&self) -> NodeTypeId {
match *self.eventtarget.type_id() {
EventTargetTypeId::Node(type_id) => type_id,
_ => unreachable!(),
}
}
/// <https://dom.spec.whatwg.org/#concept-node-length>
pub(crate) fn len(&self) -> u32 {
match self.type_id() {
NodeTypeId::DocumentType => 0,
NodeTypeId::CharacterData(_) => self.downcast::<CharacterData>().unwrap().Length(),
_ => self.children_count(),
}
}
pub(crate) fn is_empty(&self) -> bool {
// A node is considered empty if its length is 0.
self.len() == 0
}
/// <https://dom.spec.whatwg.org/#concept-tree-index>
pub(crate) fn index(&self) -> u32 {
self.preceding_siblings().count() as u32
}
/// Returns true if this node has a parent.
pub(crate) fn has_parent(&self) -> bool {
self.parent_node.get().is_some()
}
pub(crate) fn children_count(&self) -> u32 {
self.children_count.get()
}
pub(crate) fn ranges(&self) -> RefMut<WeakRangeVec> {
RefMut::map(self.ensure_rare_data(), |rare_data| &mut rare_data.ranges)
}
pub(crate) fn ranges_is_empty(&self) -> bool {
match self.rare_data().as_ref() {
Some(data) => data.ranges.is_empty(),
None => false,
}
}
#[inline]
pub(crate) fn is_doctype(&self) -> bool {
self.type_id() == NodeTypeId::DocumentType
}
pub(crate) fn get_flag(&self, flag: NodeFlags) -> bool {
self.flags.get().contains(flag)
}
pub(crate) fn set_flag(&self, flag: NodeFlags, value: bool) {
let mut flags = self.flags.get();
if value {
flags.insert(flag);
} else {
flags.remove(flag);
}
self.flags.set(flags);
}
// FIXME(emilio): This and the function below should move to Element.
pub(crate) fn note_dirty_descendants(&self) {
self.owner_doc().note_node_with_dirty_descendants(self);
}
pub(crate) fn has_dirty_descendants(&self) -> bool {
self.get_flag(NodeFlags::HAS_DIRTY_DESCENDANTS)
}
pub(crate) fn rev_version(&self) {
// The new version counter is 1 plus the max of the node's current version counter,
// its descendants version, and the document's version. Normally, this will just be
// the document's version, but we do have to deal with the case where the node has moved
// document, so may have a higher version count than its owning document.
let doc: DomRoot<Node> = DomRoot::upcast(self.owner_doc());
let version = cmp::max(
self.inclusive_descendants_version(),
doc.inclusive_descendants_version(),
) + 1;
for ancestor in self.inclusive_ancestors(ShadowIncluding::No) {
ancestor.inclusive_descendants_version.set(version);
}
doc.inclusive_descendants_version.set(version);
}
pub(crate) fn dirty(&self, damage: NodeDamage) {
self.rev_version();
if !self.is_connected() {
return;
}
match self.type_id() {
NodeTypeId::CharacterData(CharacterDataTypeId::Text(TextTypeId::Text)) => {
self.parent_node.get().unwrap().dirty(damage)
},
NodeTypeId::Element(_) => self.downcast::<Element>().unwrap().restyle(damage),
NodeTypeId::DocumentFragment(DocumentFragmentTypeId::ShadowRoot) => self
.downcast::<ShadowRoot>()
.unwrap()
.Host()
.upcast::<Element>()
.restyle(damage),
_ => {},
};
}
/// The maximum version number of this node's descendants, including itself
pub(crate) fn inclusive_descendants_version(&self) -> u64 {
self.inclusive_descendants_version.get()
}
/// Iterates over this node and all its descendants, in preorder.
pub(crate) fn traverse_preorder(&self, shadow_including: ShadowIncluding) -> TreeIterator {
TreeIterator::new(self, shadow_including)
}
pub(crate) fn inclusively_following_siblings(
&self,
) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: Some(DomRoot::from_ref(self)),
next_node: |n| n.GetNextSibling(),
}
}
pub(crate) fn inclusively_preceding_siblings(
&self,
) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: Some(DomRoot::from_ref(self)),
next_node: |n| n.GetPreviousSibling(),
}
}
pub(crate) fn common_ancestor(
&self,
other: &Node,
shadow_including: ShadowIncluding,
) -> Option<DomRoot<Node>> {
self.inclusive_ancestors(shadow_including).find(|ancestor| {
other
.inclusive_ancestors(shadow_including)
.any(|node| node == *ancestor)
})
}
pub(crate) fn common_ancestor_in_flat_tree(&self, other: &Node) -> Option<DomRoot<Node>> {
self.inclusive_ancestors_in_flat_tree().find(|ancestor| {
other
.inclusive_ancestors_in_flat_tree()
.any(|node| node == *ancestor)
})
}
pub(crate) fn is_inclusive_ancestor_of(&self, parent: &Node) -> bool {
self == parent || self.is_ancestor_of(parent)
}
pub(crate) fn is_ancestor_of(&self, parent: &Node) -> bool {
parent.ancestors().any(|ancestor| &*ancestor == self)
}
pub(crate) fn is_shadow_including_inclusive_ancestor_of(&self, node: &Node) -> bool {
node.inclusive_ancestors(ShadowIncluding::Yes)
.any(|ancestor| &*ancestor == self)
}
pub(crate) fn following_siblings(&self) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: self.GetNextSibling(),
next_node: |n| n.GetNextSibling(),
}
}
pub(crate) fn preceding_siblings(&self) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: self.GetPreviousSibling(),
next_node: |n| n.GetPreviousSibling(),
}
}
pub(crate) fn following_nodes(&self, root: &Node) -> FollowingNodeIterator {
FollowingNodeIterator {
current: Some(DomRoot::from_ref(self)),
root: DomRoot::from_ref(root),
}
}
pub(crate) fn preceding_nodes(&self, root: &Node) -> PrecedingNodeIterator {
PrecedingNodeIterator {
current: Some(DomRoot::from_ref(self)),
root: DomRoot::from_ref(root),
}
}
pub(crate) fn descending_last_children(&self) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: self.GetLastChild(),
next_node: |n| n.GetLastChild(),
}
}
pub(crate) fn is_parent_of(&self, child: &Node) -> bool {
child
.parent_node
.get()
.is_some_and(|parent| &*parent == self)
}
pub(crate) fn to_trusted_node_address(&self) -> TrustedNodeAddress {
TrustedNodeAddress(self as *const Node as *const libc::c_void)
}
/// Returns the rendered bounding content box if the element is rendered,
/// and none otherwise.
pub(crate) fn bounding_content_box(&self, can_gc: CanGc) -> Option<Rect<Au>> {
self.owner_window().content_box_query(self, can_gc)
}
pub(crate) fn bounding_content_box_or_zero(&self, can_gc: CanGc) -> Rect<Au> {
self.bounding_content_box(can_gc).unwrap_or_else(Rect::zero)
}
pub(crate) fn bounding_content_box_no_reflow(&self) -> Option<Rect<Au>> {
self.owner_window().content_box_query_unchecked(self)
}
pub(crate) fn content_boxes(&self, can_gc: CanGc) -> Vec<Rect<Au>> {
self.owner_window().content_boxes_query(self, can_gc)
}
pub(crate) fn client_rect(&self, can_gc: CanGc) -> Rect<i32> {
self.owner_window().client_rect_query(self, can_gc)
}
/// <https://drafts.csswg.org/cssom-view/#dom-element-scrollwidth>
/// <https://drafts.csswg.org/cssom-view/#dom-element-scrollheight>
pub(crate) fn scroll_area(&self, can_gc: CanGc) -> Rect<i32> {
// "1. Let document be the elements node document.""
let document = self.owner_doc();
// "2. If document is not the active document, return zero and terminate these steps.""
if !document.is_active() {
return Rect::zero();
}
// "3. Let viewport width/height be the width of the viewport excluding the width/height of the
// scroll bar, if any, or zero if there is no viewport."
let window = document.window();
let viewport = Size2D::new(window.InnerWidth(), window.InnerHeight());
let in_quirks_mode = document.quirks_mode() == QuirksMode::Quirks;
let is_root = self.downcast::<Element>().is_some_and(|e| e.is_root());
let is_body_element = self
.downcast::<HTMLBodyElement>()
.is_some_and(|e| e.is_the_html_body_element());
// "4. If the element is the root element and document is not in quirks mode
// return max(viewport scrolling area width/height, viewport width/height)."
// "5. If the element is the body element, document is in quirks mode and the
// element is not potentially scrollable, return max(viewport scrolling area
// width, viewport width)."
if (is_root && !in_quirks_mode) || (is_body_element && in_quirks_mode) {
let viewport_scrolling_area = window.scrolling_area_query(None, can_gc);
return Rect::new(
viewport_scrolling_area.origin,
viewport_scrolling_area.size.max(viewport),
);
}
// "6. If the element does not have any associated box return zero and terminate
// these steps."
// "7. Return the width of the elements scrolling area."
window.scrolling_area_query(Some(self), can_gc)
}
pub(crate) fn scroll_offset(&self) -> Vector2D<f32> {
let document = self.owner_doc();
let window = document.window();
window.scroll_offset_query(self).to_untyped()
}
/// <https://dom.spec.whatwg.org/#dom-childnode-before>
pub(crate) fn before(&self, nodes: Vec<NodeOrString>, can_gc: CanGc) -> ErrorResult {
// Step 1.
let parent = &self.parent_node;
// Step 2.
let parent = match parent.get() {
None => return Ok(()),
Some(parent) => parent,
};
// Step 3.
let viable_previous_sibling = first_node_not_in(self.preceding_siblings(), &nodes);
// Step 4.
let node = self
.owner_doc()
.node_from_nodes_and_strings(nodes, can_gc)?;
// Step 5.
let viable_previous_sibling = match viable_previous_sibling {
Some(ref viable_previous_sibling) => viable_previous_sibling.next_sibling.get(),
None => parent.first_child.get(),
};
// Step 6.
Node::pre_insert(&node, &parent, viable_previous_sibling.as_deref(), can_gc)?;
Ok(())
}
/// <https://dom.spec.whatwg.org/#dom-childnode-after>
pub(crate) fn after(&self, nodes: Vec<NodeOrString>, can_gc: CanGc) -> ErrorResult {
// Step 1.
let parent = &self.parent_node;
// Step 2.
let parent = match parent.get() {
None => return Ok(()),
Some(parent) => parent,
};
// Step 3.
let viable_next_sibling = first_node_not_in(self.following_siblings(), &nodes);
// Step 4.
let node = self
.owner_doc()
.node_from_nodes_and_strings(nodes, can_gc)?;
// Step 5.
Node::pre_insert(&node, &parent, viable_next_sibling.as_deref(), can_gc)?;
Ok(())
}
/// <https://dom.spec.whatwg.org/#dom-childnode-replacewith>
pub(crate) fn replace_with(&self, nodes: Vec<NodeOrString>, can_gc: CanGc) -> ErrorResult {
// Step 1. Let parent be thiss parent.
let Some(parent) = self.GetParentNode() else {
// Step 2. If parent is null, then return.
return Ok(());
};
// Step 3. Let viableNextSibling be thiss first following sibling not in nodes; otherwise null.
let viable_next_sibling = first_node_not_in(self.following_siblings(), &nodes);
// Step 4. Let node be the result of converting nodes into a node, given nodes and thiss node document.
let node = self
.owner_doc()
.node_from_nodes_and_strings(nodes, can_gc)?;
if self.parent_node == Some(&*parent) {
// Step 5. If thiss parent is parent, replace this with node within parent.
parent.ReplaceChild(&node, self, can_gc)?;
} else {
// Step 6. Otherwise, pre-insert node into parent before viableNextSibling.
Node::pre_insert(&node, &parent, viable_next_sibling.as_deref(), can_gc)?;
}
Ok(())
}
/// <https://dom.spec.whatwg.org/#dom-parentnode-prepend>
pub(crate) fn prepend(&self, nodes: Vec<NodeOrString>, can_gc: CanGc) -> ErrorResult {
// Step 1.
let doc = self.owner_doc();
let node = doc.node_from_nodes_and_strings(nodes, can_gc)?;
// Step 2.
let first_child = self.first_child.get();
Node::pre_insert(&node, self, first_child.as_deref(), can_gc).map(|_| ())
}
/// <https://dom.spec.whatwg.org/#dom-parentnode-append>
pub(crate) fn append(&self, nodes: Vec<NodeOrString>, can_gc: CanGc) -> ErrorResult {
// Step 1.
let doc = self.owner_doc();
let node = doc.node_from_nodes_and_strings(nodes, can_gc)?;
// Step 2.
self.AppendChild(&node, can_gc).map(|_| ())
}
/// <https://dom.spec.whatwg.org/#dom-parentnode-replacechildren>
pub(crate) fn replace_children(&self, nodes: Vec<NodeOrString>, can_gc: CanGc) -> ErrorResult {
// Step 1.
let doc = self.owner_doc();
let node = doc.node_from_nodes_and_strings(nodes, can_gc)?;
// Step 2.
Node::ensure_pre_insertion_validity(&node, self, None)?;
// Step 3.
Node::replace_all(Some(&node), self, can_gc);
Ok(())
}
/// <https://dom.spec.whatwg.org/#dom-parentnode-queryselector>
pub(crate) fn query_selector(
&self,
selectors: DOMString,
) -> Fallible<Option<DomRoot<Element>>> {
// Step 1.
let doc = self.owner_doc();
match SelectorParser::parse_author_origin_no_namespace(
&selectors,
&UrlExtraData(doc.url().get_arc()),
) {
// Step 2.
Err(_) => Err(Error::Syntax),
// Step 3.
Ok(selectors) => {
let mut nth_index_cache = Default::default();
let mut ctx = MatchingContext::new(
MatchingMode::Normal,
None,
&mut nth_index_cache,
doc.quirks_mode(),
NeedsSelectorFlags::No,
MatchingForInvalidation::No,
);
let mut descendants = self.traverse_preorder(ShadowIncluding::No);
// Skip the root of the tree.
assert!(&*descendants.next().unwrap() == self);
Ok(descendants.filter_map(DomRoot::downcast).find(|element| {
matches_selector_list(&selectors, &SelectorWrapper::Borrowed(element), &mut ctx)
}))
},
}
}
/// <https://dom.spec.whatwg.org/#scope-match-a-selectors-string>
/// Get an iterator over all nodes which match a set of selectors
/// Be careful not to do anything which may manipulate the DOM tree
/// whilst iterating, otherwise the iterator may be invalidated.
pub(crate) fn query_selector_iter(
&self,
selectors: DOMString,
) -> Fallible<QuerySelectorIterator> {
// Step 1.
let url = self.owner_doc().url();
match SelectorParser::parse_author_origin_no_namespace(
&selectors,
&UrlExtraData(url.get_arc()),
) {
// Step 2.
Err(_) => Err(Error::Syntax),
// Step 3.
Ok(selectors) => {
let mut descendants = self.traverse_preorder(ShadowIncluding::No);
// Skip the root of the tree.
assert!(&*descendants.next().unwrap() == self);
Ok(QuerySelectorIterator::new(descendants, selectors))
},
}
}
/// <https://dom.spec.whatwg.org/#dom-parentnode-queryselectorall>
#[allow(unsafe_code)]
pub(crate) fn query_selector_all(&self, selectors: DOMString) -> Fallible<DomRoot<NodeList>> {
let window = self.owner_window();
let iter = self.query_selector_iter(selectors)?;
Ok(NodeList::new_simple_list(&window, iter, CanGc::note()))
}
pub(crate) fn ancestors(&self) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: self.GetParentNode(),
next_node: |n| n.GetParentNode(),
}
}
/// <https://dom.spec.whatwg.org/#concept-shadow-including-inclusive-ancestor>
pub(crate) fn inclusive_ancestors(
&self,
shadow_including: ShadowIncluding,
) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: Some(DomRoot::from_ref(self)),
next_node: move |n| {
if shadow_including == ShadowIncluding::Yes {
if let Some(shadow_root) = n.downcast::<ShadowRoot>() {
return Some(DomRoot::from_ref(shadow_root.Host().upcast::<Node>()));
}
}
n.GetParentNode()
},
}
}
pub(crate) fn owner_doc(&self) -> DomRoot<Document> {
self.owner_doc.get().unwrap()
}
pub(crate) fn set_owner_doc(&self, document: &Document) {
self.owner_doc.set(Some(document));
}
pub(crate) fn containing_shadow_root(&self) -> Option<DomRoot<ShadowRoot>> {
self.rare_data()
.as_ref()?
.containing_shadow_root
.as_ref()
.map(|sr| DomRoot::from_ref(&**sr))
}
pub(crate) fn set_containing_shadow_root(&self, shadow_root: Option<&ShadowRoot>) {
self.ensure_rare_data().containing_shadow_root = shadow_root.map(Dom::from_ref);
}
pub(crate) fn is_in_html_doc(&self) -> bool {
self.owner_doc().is_html_document()
}
pub(crate) fn is_connected_with_browsing_context(&self) -> bool {
self.is_connected() && self.owner_doc().browsing_context().is_some()
}
pub(crate) fn children(&self) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: self.GetFirstChild(),
next_node: |n| n.GetNextSibling(),
}
}
pub(crate) fn rev_children(&self) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: self.GetLastChild(),
next_node: |n| n.GetPreviousSibling(),
}
}
pub(crate) fn child_elements(&self) -> impl Iterator<Item = DomRoot<Element>> + use<> {
self.children()
.filter_map(DomRoot::downcast as fn(_) -> _)
.peekable()
}
pub(crate) fn remove_self(&self, can_gc: CanGc) {
if let Some(ref parent) = self.GetParentNode() {
Node::remove(self, parent, SuppressObserver::Unsuppressed, can_gc);
}
}
pub(crate) fn unique_id(&self) -> String {
let mut rare_data = self.ensure_rare_data();
if rare_data.unique_id.is_none() {
let id = UniqueId::new();
ScriptThread::save_node_id(id.borrow().simple().to_string());
rare_data.unique_id = Some(id);
}
rare_data
.unique_id
.as_ref()
.unwrap()
.borrow()
.simple()
.to_string()
}
pub(crate) fn summarize(&self, can_gc: CanGc) -> NodeInfo {
let USVString(base_uri) = self.BaseURI();
let node_type = self.NodeType();
let maybe_shadow_root = self.downcast::<ShadowRoot>();
let shadow_root_mode = maybe_shadow_root
.map(ShadowRoot::Mode)
.map(ShadowRootMode::convert);
let host = maybe_shadow_root
.map(ShadowRoot::Host)
.map(|host| host.upcast::<Node>().unique_id());
let is_shadow_host = self.downcast::<Element>().is_some_and(|potential_host| {
let Some(root) = potential_host.shadow_root() else {
return false;
};
!root.is_user_agent_widget() || pref!(inspector_show_servo_internal_shadow_roots)
});
let num_children = if is_shadow_host {
// Shadow roots count as children
self.ChildNodes(can_gc).Length() as usize + 1
} else {
self.ChildNodes(can_gc).Length() as usize
};
let window = self.owner_window();
let display = self
.downcast::<Element>()
.map(|elem| window.GetComputedStyle(elem, None))
.map(|style| style.Display().into());
NodeInfo {
unique_id: self.unique_id(),
host,
base_uri,
parent: self
.GetParentNode()
.map_or("".to_owned(), |node| node.unique_id()),
node_type,
is_top_level_document: node_type == NodeConstants::DOCUMENT_NODE,
node_name: String::from(self.NodeName()),
node_value: self.GetNodeValue().map(|v| v.into()),
num_children,
attrs: self.downcast().map(Element::summarize).unwrap_or(vec![]),
is_shadow_host,
shadow_root_mode,
display,
doctype_name: self
.downcast::<DocumentType>()
.map(DocumentType::name)
.cloned()
.map(String::from),
doctype_public_identifier: self
.downcast::<DocumentType>()
.map(DocumentType::public_id)
.cloned()
.map(String::from),
doctype_system_identifier: self
.downcast::<DocumentType>()
.map(DocumentType::system_id)
.cloned()
.map(String::from),
}
}
/// Used by `HTMLTableSectionElement::InsertRow` and `HTMLTableRowElement::InsertCell`
pub(crate) fn insert_cell_or_row<F, G, I>(
&self,
index: i32,
get_items: F,
new_child: G,
can_gc: CanGc,
) -> Fallible<DomRoot<HTMLElement>>
where
F: Fn() -> DomRoot<HTMLCollection>,
G: Fn() -> DomRoot<I>,
I: DerivedFrom<Node> + DerivedFrom<HTMLElement> + DomObject,
{
if index < -1 {
return Err(Error::IndexSize);
}
let tr = new_child();
{
let tr_node = tr.upcast::<Node>();
if index == -1 {
self.InsertBefore(tr_node, None, can_gc)?;
} else {
let items = get_items();
let node = match items
.elements_iter()
.map(DomRoot::upcast::<Node>)
.map(Some)
.chain(iter::once(None))
.nth(index as usize)
{
None => return Err(Error::IndexSize),
Some(node) => node,
};
self.InsertBefore(tr_node, node.as_deref(), can_gc)?;
}
}
Ok(DomRoot::upcast::<HTMLElement>(tr))
}
/// Used by `HTMLTableSectionElement::DeleteRow` and `HTMLTableRowElement::DeleteCell`
pub(crate) fn delete_cell_or_row<F, G>(
&self,
index: i32,
get_items: F,
is_delete_type: G,
can_gc: CanGc,
) -> ErrorResult
where
F: Fn() -> DomRoot<HTMLCollection>,
G: Fn(&Element) -> bool,
{
let element = match index {
index if index < -1 => return Err(Error::IndexSize),
-1 => {
let last_child = self.upcast::<Node>().GetLastChild();
match last_child.and_then(|node| {
node.inclusively_preceding_siblings()
.filter_map(DomRoot::downcast::<Element>)
.find(|elem| is_delete_type(elem))
}) {
Some(element) => element,
None => return Ok(()),
}
},
index => match get_items().Item(index as u32) {
Some(element) => element,
None => return Err(Error::IndexSize),
},
};
element.upcast::<Node>().remove_self(can_gc);
Ok(())
}
pub(crate) fn get_stylesheet(&self) -> Option<Arc<Stylesheet>> {
if let Some(node) = self.downcast::<HTMLStyleElement>() {
node.get_stylesheet()
} else if let Some(node) = self.downcast::<HTMLLinkElement>() {
node.get_stylesheet()
} else {
None
}
}
pub(crate) fn get_cssom_stylesheet(&self) -> Option<DomRoot<CSSStyleSheet>> {
if let Some(node) = self.downcast::<HTMLStyleElement>() {
node.get_cssom_stylesheet()
} else if let Some(node) = self.downcast::<HTMLLinkElement>() {
node.get_cssom_stylesheet(CanGc::note())
} else {
None
}
}
pub(crate) fn is_styled(&self) -> bool {
self.style_data.borrow().is_some()
}
pub(crate) fn is_display_none(&self) -> bool {
self.style_data.borrow().as_ref().is_none_or(|data| {
data.element_data
.borrow()
.styles
.primary()
.get_box()
.display
.is_none()
})
}
pub(crate) fn style(&self, can_gc: CanGc) -> Option<Arc<ComputedValues>> {
if !self
.owner_window()
.layout_reflow(QueryMsg::StyleQuery, can_gc)
{
return None;
}
self.style_data
.borrow()
.as_ref()
.map(|data| data.element_data.borrow().styles.primary().clone())
}
/// <https://dom.spec.whatwg.org/#assign-slotables-for-a-tree>
pub(crate) fn assign_slottables_for_a_tree(&self) {
// NOTE: This method traverses all descendants of the node and is potentially very
// expensive. If the node is not a shadow root then assigning slottables to it won't
// have any effect, so we take a fast path out.
let Some(shadow_root) = self.downcast::<ShadowRoot>() else {
return;
};
if !shadow_root.has_slot_descendants() {
return;
}
// > To assign slottables for a tree, given a node root, run assign slottables for each slot
// > slot in roots inclusive descendants, in tree order.
for node in self.traverse_preorder(ShadowIncluding::No) {
if let Some(slot) = node.downcast::<HTMLSlotElement>() {
slot.assign_slottables();
}
}
}
pub(crate) fn assigned_slot(&self) -> Option<DomRoot<HTMLSlotElement>> {
let assigned_slot = self
.rare_data
.borrow()
.as_ref()?
.slottable_data
.assigned_slot
.as_ref()?
.as_rooted();
Some(assigned_slot)
}
pub(crate) fn set_assigned_slot(&self, assigned_slot: Option<&HTMLSlotElement>) {
self.ensure_rare_data().slottable_data.assigned_slot = assigned_slot.map(Dom::from_ref);
}
pub(crate) fn manual_slot_assignment(&self) -> Option<DomRoot<HTMLSlotElement>> {
let manually_assigned_slot = self
.rare_data
.borrow()
.as_ref()?
.slottable_data
.manual_slot_assignment
.as_ref()?
.as_rooted();
Some(manually_assigned_slot)
}
pub(crate) fn set_manual_slot_assignment(
&self,
manually_assigned_slot: Option<&HTMLSlotElement>,
) {
self.ensure_rare_data()
.slottable_data
.manual_slot_assignment = manually_assigned_slot.map(Dom::from_ref);
}
/// Gets the parent of this node from the perspective of layout and style.
///
/// The returned node is the node's assigned slot, if any, or the
/// shadow host if it's a shadow root. Otherwise, it is the node's
/// parent.
pub(crate) fn parent_in_flat_tree(&self) -> Option<DomRoot<Node>> {
if let Some(assigned_slot) = self.assigned_slot() {
return Some(DomRoot::upcast(assigned_slot));
}
let parent_or_none = self.GetParentNode();
if let Some(parent) = parent_or_none.as_deref() {
if let Some(shadow_root) = parent.downcast::<ShadowRoot>() {
return Some(DomRoot::from_ref(shadow_root.Host().upcast::<Node>()));
}
}
parent_or_none
}
pub(crate) fn inclusive_ancestors_in_flat_tree(
&self,
) -> impl Iterator<Item = DomRoot<Node>> + use<> {
SimpleNodeIterator {
current: Some(DomRoot::from_ref(self)),
next_node: move |n| n.parent_in_flat_tree(),
}
}
}
/// Iterate through `nodes` until we find a `Node` that is not in `not_in`
fn first_node_not_in<I>(mut nodes: I, not_in: &[NodeOrString]) -> Option<DomRoot<Node>>
where
I: Iterator<Item = DomRoot<Node>>,
{
nodes.find(|node| {
not_in.iter().all(|n| match *n {
NodeOrString::Node(ref n) => n != node,
_ => true,
})
})
}
/// If the given untrusted node address represents a valid DOM node in the given runtime,
/// returns it.
#[allow(unsafe_code)]
pub(crate) unsafe fn from_untrusted_node_address(candidate: UntrustedNodeAddress) -> DomRoot<Node> {
DomRoot::from_ref(Node::from_untrusted_node_address(candidate))
}
#[allow(unsafe_code)]
pub(crate) trait LayoutNodeHelpers<'dom> {
fn type_id_for_layout(self) -> NodeTypeId;
fn composed_parent_node_ref(self) -> Option<LayoutDom<'dom, Node>>;
fn first_child_ref(self) -> Option<LayoutDom<'dom, Node>>;
fn last_child_ref(self) -> Option<LayoutDom<'dom, Node>>;
fn prev_sibling_ref(self) -> Option<LayoutDom<'dom, Node>>;
fn next_sibling_ref(self) -> Option<LayoutDom<'dom, Node>>;
fn owner_doc_for_layout(self) -> LayoutDom<'dom, Document>;
fn containing_shadow_root_for_layout(self) -> Option<LayoutDom<'dom, ShadowRoot>>;
fn assigned_slot_for_layout(self) -> Option<LayoutDom<'dom, HTMLSlotElement>>;
fn is_element_for_layout(&self) -> bool;
unsafe fn get_flag(self, flag: NodeFlags) -> bool;
unsafe fn set_flag(self, flag: NodeFlags, value: bool);
fn style_data(self) -> Option<&'dom StyleData>;
fn layout_data(self) -> Option<&'dom GenericLayoutData>;
/// Initialize the style data of this node.
///
/// # Safety
///
/// This method is unsafe because it modifies the given node during
/// layout. Callers should ensure that no other layout thread is
/// attempting to read or modify the opaque layout data of this node.
unsafe fn initialize_style_data(self);
/// Initialize the opaque layout data of this node.
///
/// # Safety
///
/// This method is unsafe because it modifies the given node during
/// layout. Callers should ensure that no other layout thread is
/// attempting to read or modify the opaque layout data of this node.
unsafe fn initialize_layout_data(self, data: Box<GenericLayoutData>);
/// Clear the style and opaque layout data of this node.
///
/// # Safety
///
/// This method is unsafe because it modifies the given node during
/// layout. Callers should ensure that no other layout thread is
/// attempting to read or modify the opaque layout data of this node.
unsafe fn clear_style_and_layout_data(self);
/// Whether this element is a `<input>` rendered as text or a `<textarea>`.
fn is_text_input(&self) -> bool;
fn text_content(self) -> Cow<'dom, str>;
fn selection(self) -> Option<Range<usize>>;
fn image_url(self) -> Option<ServoUrl>;
fn image_density(self) -> Option<f64>;
fn image_data(self) -> Option<(Option<StdArc<Image>>, Option<ImageMetadata>)>;
fn canvas_data(self) -> Option<HTMLCanvasData>;
fn media_data(self) -> Option<HTMLMediaData>;
fn svg_data(self) -> Option<SVGSVGData>;
fn iframe_browsing_context_id(self) -> Option<BrowsingContextId>;
fn iframe_pipeline_id(self) -> Option<PipelineId>;
fn opaque(self) -> OpaqueNode;
}
impl<'dom> LayoutDom<'dom, Node> {
#[inline]
#[allow(unsafe_code)]
fn parent_node_ref(self) -> Option<LayoutDom<'dom, Node>> {
unsafe { self.unsafe_get().parent_node.get_inner_as_layout() }
}
}
impl<'dom> LayoutNodeHelpers<'dom> for LayoutDom<'dom, Node> {
#[inline]
fn type_id_for_layout(self) -> NodeTypeId {
self.unsafe_get().type_id()
}
#[inline]
fn is_element_for_layout(&self) -> bool {
(*self).is::<Element>()
}
#[inline]
fn composed_parent_node_ref(self) -> Option<LayoutDom<'dom, Node>> {
let parent = self.parent_node_ref();
if let Some(parent) = parent {
if let Some(shadow_root) = parent.downcast::<ShadowRoot>() {
return Some(shadow_root.get_host_for_layout().upcast());
}
}
parent
}
#[inline]
#[allow(unsafe_code)]
fn first_child_ref(self) -> Option<LayoutDom<'dom, Node>> {
unsafe { self.unsafe_get().first_child.get_inner_as_layout() }
}
#[inline]
#[allow(unsafe_code)]
fn last_child_ref(self) -> Option<LayoutDom<'dom, Node>> {
unsafe { self.unsafe_get().last_child.get_inner_as_layout() }
}
#[inline]
#[allow(unsafe_code)]
fn prev_sibling_ref(self) -> Option<LayoutDom<'dom, Node>> {
unsafe { self.unsafe_get().prev_sibling.get_inner_as_layout() }
}
#[inline]
#[allow(unsafe_code)]
fn next_sibling_ref(self) -> Option<LayoutDom<'dom, Node>> {
unsafe { self.unsafe_get().next_sibling.get_inner_as_layout() }
}
#[inline]
#[allow(unsafe_code)]
fn owner_doc_for_layout(self) -> LayoutDom<'dom, Document> {
unsafe { self.unsafe_get().owner_doc.get_inner_as_layout().unwrap() }
}
#[inline]
#[allow(unsafe_code)]
fn containing_shadow_root_for_layout(self) -> Option<LayoutDom<'dom, ShadowRoot>> {
unsafe {
self.unsafe_get()
.rare_data
.borrow_for_layout()
.as_ref()?
.containing_shadow_root
.as_ref()
.map(|sr| sr.to_layout())
}
}
#[inline]
#[allow(unsafe_code)]
fn assigned_slot_for_layout(self) -> Option<LayoutDom<'dom, HTMLSlotElement>> {
unsafe {
self.unsafe_get()
.rare_data
.borrow_for_layout()
.as_ref()?
.slottable_data
.assigned_slot
.as_ref()
.map(|assigned_slot| assigned_slot.to_layout())
}
}
// FIXME(nox): get_flag/set_flag (especially the latter) are not safe because
// they mutate stuff while values of this type can be used from multiple
// threads at once, this should be revisited.
#[inline]
#[allow(unsafe_code)]
unsafe fn get_flag(self, flag: NodeFlags) -> bool {
(self.unsafe_get()).flags.get().contains(flag)
}
#[inline]
#[allow(unsafe_code)]
unsafe fn set_flag(self, flag: NodeFlags, value: bool) {
let this = self.unsafe_get();
let mut flags = (this).flags.get();
if value {
flags.insert(flag);
} else {
flags.remove(flag);
}
(this).flags.set(flags);
}
// FIXME(nox): How we handle style and layout data needs to be completely
// revisited so we can do that more cleanly and safely in layout 2020.
#[inline]
#[allow(unsafe_code)]
fn style_data(self) -> Option<&'dom StyleData> {
unsafe { self.unsafe_get().style_data.borrow_for_layout().as_deref() }
}
#[inline]
#[allow(unsafe_code)]
fn layout_data(self) -> Option<&'dom GenericLayoutData> {
unsafe { self.unsafe_get().layout_data.borrow_for_layout().as_deref() }
}
#[inline]
#[allow(unsafe_code)]
unsafe fn initialize_style_data(self) {
let data = self.unsafe_get().style_data.borrow_mut_for_layout();
debug_assert!(data.is_none());
*data = Some(Box::default());
}
#[inline]
#[allow(unsafe_code)]
unsafe fn initialize_layout_data(self, new_data: Box<GenericLayoutData>) {
let data = self.unsafe_get().layout_data.borrow_mut_for_layout();
debug_assert!(data.is_none());
*data = Some(new_data);
}
#[inline]
#[allow(unsafe_code)]
unsafe fn clear_style_and_layout_data(self) {
self.unsafe_get().style_data.borrow_mut_for_layout().take();
self.unsafe_get().layout_data.borrow_mut_for_layout().take();
}
fn is_text_input(&self) -> bool {
let type_id = self.type_id_for_layout();
if type_id ==
NodeTypeId::Element(ElementTypeId::HTMLElement(
HTMLElementTypeId::HTMLInputElement,
))
{
let input = self.unsafe_get().downcast::<HTMLInputElement>().unwrap();
// FIXME: All the non-color input types currently render as text
input.input_type() != InputType::Color
} else {
type_id ==
NodeTypeId::Element(ElementTypeId::HTMLElement(
HTMLElementTypeId::HTMLTextAreaElement,
))
}
}
fn text_content(self) -> Cow<'dom, str> {
if let Some(text) = self.downcast::<Text>() {
return text.upcast().data_for_layout().into();
}
if let Some(input) = self.downcast::<HTMLInputElement>() {
return input.value_for_layout();
}
if let Some(area) = self.downcast::<HTMLTextAreaElement>() {
return area.value_for_layout().into();
}
panic!("not text!")
}
fn selection(self) -> Option<Range<usize>> {
if let Some(area) = self.downcast::<HTMLTextAreaElement>() {
return area.selection_for_layout();
}
if let Some(input) = self.downcast::<HTMLInputElement>() {
return input.selection_for_layout();
}
None
}
fn image_url(self) -> Option<ServoUrl> {
self.downcast::<HTMLImageElement>()
.expect("not an image!")
.image_url()
}
fn image_data(self) -> Option<(Option<StdArc<Image>>, Option<ImageMetadata>)> {
self.downcast::<HTMLImageElement>().map(|e| e.image_data())
}
fn image_density(self) -> Option<f64> {
self.downcast::<HTMLImageElement>()
.expect("not an image!")
.image_density()
}
fn canvas_data(self) -> Option<HTMLCanvasData> {
self.downcast::<HTMLCanvasElement>()
.map(|canvas| canvas.data())
}
fn media_data(self) -> Option<HTMLMediaData> {
self.downcast::<HTMLVideoElement>()
.map(|media| media.data())
}
fn svg_data(self) -> Option<SVGSVGData> {
self.downcast::<SVGSVGElement>().map(|svg| svg.data())
}
fn iframe_browsing_context_id(self) -> Option<BrowsingContextId> {
self.downcast::<HTMLIFrameElement>()
.and_then(|iframe_element| iframe_element.browsing_context_id())
}
fn iframe_pipeline_id(self) -> Option<PipelineId> {
self.downcast::<HTMLIFrameElement>()
.and_then(|iframe_element| iframe_element.pipeline_id())
}
#[allow(unsafe_code)]
fn opaque(self) -> OpaqueNode {
unsafe { OpaqueNode(self.get_jsobject() as usize) }
}
}
//
// Iteration and traversal
//
pub(crate) struct FollowingNodeIterator {
current: Option<DomRoot<Node>>,
root: DomRoot<Node>,
}
impl FollowingNodeIterator {
/// Skips iterating the children of the current node
pub(crate) fn next_skipping_children(&mut self) -> Option<DomRoot<Node>> {
let current = self.current.take()?;
self.next_skipping_children_impl(current)
}
fn next_skipping_children_impl(&mut self, current: DomRoot<Node>) -> Option<DomRoot<Node>> {
if self.root == current {
self.current = None;
return None;
}
if let Some(next_sibling) = current.GetNextSibling() {
self.current = Some(next_sibling);
return current.GetNextSibling();
}
for ancestor in current.inclusive_ancestors(ShadowIncluding::No) {
if self.root == ancestor {
break;
}
if let Some(next_sibling) = ancestor.GetNextSibling() {
self.current = Some(next_sibling);
return ancestor.GetNextSibling();
}
}
self.current = None;
None
}
}
impl Iterator for FollowingNodeIterator {
type Item = DomRoot<Node>;
/// <https://dom.spec.whatwg.org/#concept-tree-following>
fn next(&mut self) -> Option<DomRoot<Node>> {
let current = self.current.take()?;
if let Some(first_child) = current.GetFirstChild() {
self.current = Some(first_child);
return current.GetFirstChild();
}
self.next_skipping_children_impl(current)
}
}
pub(crate) struct PrecedingNodeIterator {
current: Option<DomRoot<Node>>,
root: DomRoot<Node>,
}
impl Iterator for PrecedingNodeIterator {
type Item = DomRoot<Node>;
/// <https://dom.spec.whatwg.org/#concept-tree-preceding>
fn next(&mut self) -> Option<DomRoot<Node>> {
let current = self.current.take()?;
self.current = if self.root == current {
None
} else if let Some(previous_sibling) = current.GetPreviousSibling() {
if self.root == previous_sibling {
None
} else if let Some(last_child) = previous_sibling.descending_last_children().last() {
Some(last_child)
} else {
Some(previous_sibling)
}
} else {
current.GetParentNode()
};
self.current.clone()
}
}
struct SimpleNodeIterator<I>
where
I: Fn(&Node) -> Option<DomRoot<Node>>,
{
current: Option<DomRoot<Node>>,
next_node: I,
}
impl<I> Iterator for SimpleNodeIterator<I>
where
I: Fn(&Node) -> Option<DomRoot<Node>>,
{
type Item = DomRoot<Node>;
fn next(&mut self) -> Option<Self::Item> {
let current = self.current.take();
self.current = current.as_ref().and_then(|c| (self.next_node)(c));
current
}
}
/// Whether a tree traversal should pass shadow tree boundaries.
#[derive(Clone, Copy, PartialEq)]
pub(crate) enum ShadowIncluding {
No,
Yes,
}
pub(crate) struct TreeIterator {
current: Option<DomRoot<Node>>,
depth: usize,
shadow_including: bool,
}
impl TreeIterator {
fn new(root: &Node, shadow_including: ShadowIncluding) -> TreeIterator {
TreeIterator {
current: Some(DomRoot::from_ref(root)),
depth: 0,
shadow_including: shadow_including == ShadowIncluding::Yes,
}
}
pub(crate) fn next_skipping_children(&mut self) -> Option<DomRoot<Node>> {
let current = self.current.take()?;
self.next_skipping_children_impl(current)
}
fn next_skipping_children_impl(&mut self, current: DomRoot<Node>) -> Option<DomRoot<Node>> {
let iter = current.inclusive_ancestors(if self.shadow_including {
ShadowIncluding::Yes
} else {
ShadowIncluding::No
});
for ancestor in iter {
if self.depth == 0 {
break;
}
if let Some(next_sibling) = ancestor.GetNextSibling() {
self.current = Some(next_sibling);
return Some(current);
}
if let Some(shadow_root) = ancestor.downcast::<ShadowRoot>() {
// Shadow roots don't have sibling, so after we're done traversing
// one we jump to the first child of the host
if let Some(child) = shadow_root.Host().upcast::<Node>().GetFirstChild() {
self.current = Some(child);
return Some(current);
}
}
self.depth -= 1;
}
debug_assert_eq!(self.depth, 0);
self.current = None;
Some(current)
}
}
impl Iterator for TreeIterator {
type Item = DomRoot<Node>;
/// <https://dom.spec.whatwg.org/#concept-tree-order>
/// <https://dom.spec.whatwg.org/#concept-shadow-including-tree-order>
fn next(&mut self) -> Option<DomRoot<Node>> {
let current = self.current.take()?;
// Handle a potential shadow root on the element
if let Some(element) = current.downcast::<Element>() {
if let Some(shadow_root) = element.shadow_root() {
if self.shadow_including {
self.current = Some(DomRoot::from_ref(shadow_root.upcast::<Node>()));
self.depth += 1;
return Some(current);
}
}
}
if let Some(first_child) = current.GetFirstChild() {
self.current = Some(first_child);
self.depth += 1;
return Some(current);
};
self.next_skipping_children_impl(current)
}
}
/// Specifies whether children must be recursively cloned or not.
#[derive(Clone, Copy, MallocSizeOf, PartialEq)]
pub(crate) enum CloneChildrenFlag {
CloneChildren,
DoNotCloneChildren,
}
fn as_uintptr<T>(t: &T) -> uintptr_t {
t as *const T as uintptr_t
}
impl Node {
pub(crate) fn reflect_node<N>(node: Box<N>, document: &Document, can_gc: CanGc) -> DomRoot<N>
where
N: DerivedFrom<Node> + DomObject + DomObjectWrap<crate::DomTypeHolder>,
{
Self::reflect_node_with_proto(node, document, None, can_gc)
}
pub(crate) fn reflect_node_with_proto<N>(
node: Box<N>,
document: &Document,
proto: Option<HandleObject>,
can_gc: CanGc,
) -> DomRoot<N>
where
N: DerivedFrom<Node> + DomObject + DomObjectWrap<crate::DomTypeHolder>,
{
let window = document.window();
reflect_dom_object_with_proto(node, window, proto, can_gc)
}
pub(crate) fn new_inherited(doc: &Document) -> Node {
Node::new_(NodeFlags::empty(), Some(doc))
}
#[cfg_attr(crown, allow(crown::unrooted_must_root))]
pub(crate) fn new_document_node() -> Node {
Node::new_(
NodeFlags::IS_IN_A_DOCUMENT_TREE | NodeFlags::IS_CONNECTED,
None,
)
}
#[cfg_attr(crown, allow(crown::unrooted_must_root))]
fn new_(flags: NodeFlags, doc: Option<&Document>) -> Node {
Node {
eventtarget: EventTarget::new_inherited(),
parent_node: Default::default(),
first_child: Default::default(),
last_child: Default::default(),
next_sibling: Default::default(),
prev_sibling: Default::default(),
owner_doc: MutNullableDom::new(doc),
rare_data: Default::default(),
children_count: Cell::new(0u32),
flags: Cell::new(flags),
inclusive_descendants_version: Cell::new(0),
style_data: Default::default(),
layout_data: Default::default(),
}
}
/// <https://dom.spec.whatwg.org/#concept-node-adopt>
pub(crate) fn adopt(node: &Node, document: &Document, can_gc: CanGc) {
document.add_script_and_layout_blocker();
// Step 1. Let oldDocument be nodes node document.
let old_doc = node.owner_doc();
old_doc.add_script_and_layout_blocker();
// Step 2. If nodes parent is non-null, then remove node.
node.remove_self(can_gc);
// Step 3. If document is not oldDocument:
if &*old_doc != document {
// Step 3.1. For each inclusiveDescendant in nodes shadow-including inclusive descendants:
for descendant in node.traverse_preorder(ShadowIncluding::Yes) {
// Step 3.1.1 Set inclusiveDescendants node document to document.
descendant.set_owner_doc(document);
// Step 3.1.2 If inclusiveDescendant is an element, then set the node document of each
// attribute in inclusiveDescendants attribute list to document.
if let Some(element) = descendant.downcast::<Element>() {
for attribute in element.attrs().iter() {
attribute.upcast::<Node>().set_owner_doc(document);
}
}
}
// Step 3.2 For each inclusiveDescendant in nodes shadow-including inclusive descendants
// that is custom, enqueue a custom element callback reaction with inclusiveDescendant,
// callback name "adoptedCallback", and « oldDocument, document ».
for descendant in node
.traverse_preorder(ShadowIncluding::Yes)
.filter_map(|d| d.as_custom_element())
{
ScriptThread::enqueue_callback_reaction(
&descendant,
CallbackReaction::Adopted(old_doc.clone(), DomRoot::from_ref(document)),
None,
);
}
// Step 3.3 For each inclusiveDescendant in nodes shadow-including inclusive descendants,
// in shadow-including tree order, run the adopting steps with inclusiveDescendant and oldDocument.
for descendant in node.traverse_preorder(ShadowIncluding::Yes) {
vtable_for(&descendant).adopting_steps(&old_doc, can_gc);
}
}
old_doc.remove_script_and_layout_blocker();
document.remove_script_and_layout_blocker();
}
/// <https://dom.spec.whatwg.org/#concept-node-ensure-pre-insertion-validity>
pub(crate) fn ensure_pre_insertion_validity(
node: &Node,
parent: &Node,
child: Option<&Node>,
) -> ErrorResult {
// Step 1.
match parent.type_id() {
NodeTypeId::Document(_) | NodeTypeId::DocumentFragment(_) | NodeTypeId::Element(..) => {
},
_ => return Err(Error::HierarchyRequest),
}
// Step 2.
if node.is_inclusive_ancestor_of(parent) {
return Err(Error::HierarchyRequest);
}
// Step 3.
if let Some(child) = child {
if !parent.is_parent_of(child) {
return Err(Error::NotFound);
}
}
// Step 4-5.
match node.type_id() {
NodeTypeId::CharacterData(CharacterDataTypeId::Text(_)) => {
if parent.is::<Document>() {
return Err(Error::HierarchyRequest);
}
},
NodeTypeId::DocumentType => {
if !parent.is::<Document>() {
return Err(Error::HierarchyRequest);
}
},
NodeTypeId::DocumentFragment(_) |
NodeTypeId::Element(_) |
NodeTypeId::CharacterData(CharacterDataTypeId::ProcessingInstruction) |
NodeTypeId::CharacterData(CharacterDataTypeId::Comment) => (),
NodeTypeId::Document(_) | NodeTypeId::Attr => return Err(Error::HierarchyRequest),
}
// Step 6.
if parent.is::<Document>() {
match node.type_id() {
// Step 6.1
NodeTypeId::DocumentFragment(_) => {
// Step 6.1.1(b)
if node.children().any(|c| c.is::<Text>()) {
return Err(Error::HierarchyRequest);
}
match node.child_elements().count() {
0 => (),
// Step 6.1.2
1 => {
if parent.child_elements().next().is_some() {
return Err(Error::HierarchyRequest);
}
if let Some(child) = child {
if child
.inclusively_following_siblings()
.any(|child| child.is_doctype())
{
return Err(Error::HierarchyRequest);
}
}
},
// Step 6.1.1(a)
_ => return Err(Error::HierarchyRequest),
}
},
// Step 6.2
NodeTypeId::Element(_) => {
if parent.child_elements().next().is_some() {
return Err(Error::HierarchyRequest);
}
if let Some(child) = child {
if child
.inclusively_following_siblings()
.any(|child| child.is_doctype())
{
return Err(Error::HierarchyRequest);
}
}
},
// Step 6.3
NodeTypeId::DocumentType => {
if parent.children().any(|c| c.is_doctype()) {
return Err(Error::HierarchyRequest);
}
match child {
Some(child) => {
if parent
.children()
.take_while(|c| &**c != child)
.any(|c| c.is::<Element>())
{
return Err(Error::HierarchyRequest);
}
},
None => {
if parent.child_elements().next().is_some() {
return Err(Error::HierarchyRequest);
}
},
}
},
NodeTypeId::CharacterData(_) => (),
// Because Document and Attr should already throw `HierarchyRequest`
// error, both of them are unreachable here.
NodeTypeId::Document(_) | NodeTypeId::Attr => unreachable!(),
}
}
Ok(())
}
/// <https://dom.spec.whatwg.org/#concept-node-pre-insert>
pub(crate) fn pre_insert(
node: &Node,
parent: &Node,
child: Option<&Node>,
can_gc: CanGc,
) -> Fallible<DomRoot<Node>> {
// Step 1.
Node::ensure_pre_insertion_validity(node, parent, child)?;
// Steps 2-3.
let reference_child_root;
let reference_child = match child {
Some(child) if child == node => {
reference_child_root = node.GetNextSibling();
reference_child_root.as_deref()
},
_ => child,
};
// Step 4.
Node::insert(
node,
parent,
reference_child,
SuppressObserver::Unsuppressed,
can_gc,
);
// Step 5.
Ok(DomRoot::from_ref(node))
}
/// <https://dom.spec.whatwg.org/#concept-node-insert>
fn insert(
node: &Node,
parent: &Node,
child: Option<&Node>,
suppress_observers: SuppressObserver,
can_gc: CanGc,
) {
debug_assert!(child.is_none_or(|child| Some(parent) == child.GetParentNode().as_deref()));
// Step 1. Let nodes be nodes children, if node is a DocumentFragment node; otherwise « node ».
rooted_vec!(let mut new_nodes);
let new_nodes = if let NodeTypeId::DocumentFragment(_) = node.type_id() {
new_nodes.extend(node.children().map(|node| Dom::from_ref(&*node)));
new_nodes.r()
} else {
from_ref(&node)
};
// Step 2. Let count be nodess size.
let count = new_nodes.len();
// Step 3. If count is 0, then return.
if count == 0 {
return;
}
// Script and layout blockers must be added after any early return.
// `node.owner_doc()` may change during the algorithm.
let parent_document = parent.owner_doc();
let from_document = node.owner_doc();
from_document.add_script_and_layout_blocker();
parent_document.add_script_and_layout_blocker();
// Step 4. If node is a DocumentFragment node:
if let NodeTypeId::DocumentFragment(_) = node.type_id() {
// Step 4.1. Remove its children with the suppress observers flag set.
for kid in new_nodes {
Node::remove(kid, node, SuppressObserver::Suppressed, can_gc);
}
vtable_for(node).children_changed(&ChildrenMutation::replace_all(new_nodes, &[]));
// Step 4.2. Queue a tree mutation record for node with « », nodes, null, and null.
let mutation = LazyCell::new(|| Mutation::ChildList {
added: None,
removed: Some(new_nodes),
prev: None,
next: None,
});
MutationObserver::queue_a_mutation_record(node, mutation);
}
// Step 5. If child is non-null:
// 1. For each live range whose start node is parent and start offset is
// greater than childs index, increase its start offset by count.
// 2. For each live range whose end node is parent and end offset is
// greater than childs index, increase its end offset by count.
if let Some(child) = child {
if !parent.ranges_is_empty() {
parent
.ranges()
.increase_above(parent, child.index(), count.try_into().unwrap());
}
}
// Step 6. Let previousSibling be childs previous sibling or parents last child if child is null.
let previous_sibling = match suppress_observers {
SuppressObserver::Unsuppressed => match child {
Some(child) => child.GetPreviousSibling(),
None => parent.GetLastChild(),
},
SuppressObserver::Suppressed => None,
};
// Step 7. For each node in nodes, in tree order:
for kid in new_nodes {
// Step 7.1. Adopt node into parents node document.
Node::adopt(kid, &parent.owner_document(), can_gc);
// Step 7.2. If child is null, then append node to parents children.
// Step 7.3. Otherwise, insert node into parents children before childs index.
parent.add_child(kid, child, can_gc);
// Step 7.4 If parent is a shadow host whose shadow roots slot assignment is "named"
// and node is a slottable, then assign a slot for node.
if let Some(shadow_root) = parent.downcast::<Element>().and_then(Element::shadow_root) {
if shadow_root.SlotAssignment() == SlotAssignmentMode::Named {
let cx = GlobalScope::get_cx();
if node.is::<Element>() || node.is::<Text>() {
rooted!(in(*cx) let slottable = Slottable(Dom::from_ref(node)));
slottable.assign_a_slot();
}
}
}
// Step 7.5 If parents root is a shadow root, and parent is a slot whose assigned nodes
// is the empty list, then run signal a slot change for parent.
if parent.is_in_a_shadow_tree() {
if let Some(slot_element) = parent.downcast::<HTMLSlotElement>() {
if !slot_element.has_assigned_nodes() {
slot_element.signal_a_slot_change();
}
}
}
// Step 7.6 Run assign slottables for a tree with nodes root.
kid.GetRootNode(&GetRootNodeOptions::empty())
.assign_slottables_for_a_tree();
// Step 7.7. For each shadow-including inclusive descendant inclusiveDescendant of node,
// in shadow-including tree order:
for descendant in kid
.traverse_preorder(ShadowIncluding::Yes)
.filter_map(DomRoot::downcast::<Element>)
{
// Step 7.7.1. Run the insertion steps with inclusiveDescendant.
// This is done in `parent.add_child()`.
// Step 7.7.2, whatwg/dom#833
// Enqueue connected reactions for custom elements or try upgrade.
if descendant.is_custom() {
if descendant.is_connected() {
ScriptThread::enqueue_callback_reaction(
&descendant,
CallbackReaction::Connected,
None,
);
}
} else {
try_upgrade_element(&descendant);
}
}
}
if let SuppressObserver::Unsuppressed = suppress_observers {
// Step 9. Run the children changed steps for parent.
// TODO(xiaochengh): If we follow the spec and move it out of the if block, some WPT fail. Investigate.
vtable_for(parent).children_changed(&ChildrenMutation::insert(
previous_sibling.as_deref(),
new_nodes,
child,
));
// Step 8. If suppress observers flag is unset, then queue a tree mutation record for parent
// with nodes, « », previousSibling, and child.
let mutation = LazyCell::new(|| Mutation::ChildList {
added: Some(new_nodes),
removed: None,
prev: previous_sibling.as_deref(),
next: child,
});
MutationObserver::queue_a_mutation_record(parent, mutation);
}
// Step 10. Let staticNodeList be a list of nodes, initially « ».
let mut static_node_list = vec![];
// Step 11. For each node of nodes, in tree order:
for node in new_nodes {
// Step 11.1 For each shadow-including inclusive descendant inclusiveDescendant of node,
// in shadow-including tree order, append inclusiveDescendant to staticNodeList.
static_node_list.extend(
node.traverse_preorder(ShadowIncluding::Yes)
.map(|n| Trusted::new(&*n)),
);
}
// We use a delayed task for this step to work around an awkward interaction between
// script/layout blockers, Node::replace_all, and the children_changed vtable method.
// Any node with a post connection step that triggers layout (such as iframes) needs
// to be marked as dirty before doing so. This is handled by Node's children_changed
// callback, but when Node::insert is called as part of Node::replace_all then the
// callback is suppressed until we return to Node::replace_all. To ensure the sequence:
// 1) children_changed in Node::replace_all,
// 2) post_connection_steps from Node::insert,
// we use a delayed task that will run as soon as Node::insert removes its
// script/layout blocker.
parent_document.add_delayed_task(task!(PostConnectionSteps: move || {
// Step 12. For each node of staticNodeList, if node is connected, then run the
// post-connection steps with node.
for node in static_node_list.iter().map(Trusted::root).filter(|n| n.is_connected()) {
vtable_for(&node).post_connection_steps();
}
}));
parent_document.remove_script_and_layout_blocker();
from_document.remove_script_and_layout_blocker();
}
/// <https://dom.spec.whatwg.org/#concept-node-replace-all>
pub(crate) fn replace_all(node: Option<&Node>, parent: &Node, can_gc: CanGc) {
parent.owner_doc().add_script_and_layout_blocker();
// Step 1.
if let Some(node) = node {
Node::adopt(node, &parent.owner_doc(), can_gc);
}
// Step 2.
rooted_vec!(let removed_nodes <- parent.children().map(|c| DomRoot::as_traced(&c)));
// Step 3.
rooted_vec!(let mut added_nodes);
let added_nodes = if let Some(node) = node.as_ref() {
if let NodeTypeId::DocumentFragment(_) = node.type_id() {
added_nodes.extend(node.children().map(|child| Dom::from_ref(&*child)));
added_nodes.r()
} else {
from_ref(node)
}
} else {
&[] as &[&Node]
};
// Step 4.
for child in &*removed_nodes {
Node::remove(child, parent, SuppressObserver::Suppressed, can_gc);
}
// Step 5.
if let Some(node) = node {
Node::insert(node, parent, None, SuppressObserver::Suppressed, can_gc);
}
// Step 6.
vtable_for(parent).children_changed(&ChildrenMutation::replace_all(
removed_nodes.r(),
added_nodes,
));
if !removed_nodes.is_empty() || !added_nodes.is_empty() {
let mutation = LazyCell::new(|| Mutation::ChildList {
added: Some(added_nodes),
removed: Some(removed_nodes.r()),
prev: None,
next: None,
});
MutationObserver::queue_a_mutation_record(parent, mutation);
}
parent.owner_doc().remove_script_and_layout_blocker();
}
/// <https://dom.spec.whatwg.org/multipage/#string-replace-all>
pub(crate) fn string_replace_all(string: DOMString, parent: &Node, can_gc: CanGc) {
if string.len() == 0 {
Node::replace_all(None, parent, can_gc);
} else {
let text = Text::new(string, &parent.owner_document(), can_gc);
Node::replace_all(Some(text.upcast::<Node>()), parent, can_gc);
};
}
/// <https://dom.spec.whatwg.org/#concept-node-pre-remove>
fn pre_remove(child: &Node, parent: &Node, can_gc: CanGc) -> Fallible<DomRoot<Node>> {
// Step 1.
match child.GetParentNode() {
Some(ref node) if &**node != parent => return Err(Error::NotFound),
None => return Err(Error::NotFound),
_ => (),
}
// Step 2.
Node::remove(child, parent, SuppressObserver::Unsuppressed, can_gc);
// Step 3.
Ok(DomRoot::from_ref(child))
}
/// <https://dom.spec.whatwg.org/#concept-node-remove>
fn remove(node: &Node, parent: &Node, suppress_observers: SuppressObserver, can_gc: CanGc) {
parent.owner_doc().add_script_and_layout_blocker();
// Step 2.
assert!(
node.GetParentNode()
.is_some_and(|node_parent| &*node_parent == parent)
);
// Step 3. Run the live range pre-remove steps.
// https://dom.spec.whatwg.org/#live-range-pre-remove-steps
let cached_index = {
if parent.ranges_is_empty() {
None
} else {
// Step 1.
let index = node.index();
// Steps 2-3 are handled in Node::unbind_from_tree.
// Steps 4-5.
parent.ranges().decrease_above(parent, index, 1);
// Parent had ranges, we needed the index, let's keep track of
// it to avoid computing it for other ranges when calling
// unbind_from_tree recursively.
Some(index)
}
};
// TODO: Step 4. Pre-removing steps for node iterators
// Step 5.
let old_previous_sibling = node.GetPreviousSibling();
// Step 6.
let old_next_sibling = node.GetNextSibling();
// Step 7. Remove node from its parent's children.
// Step 11-14. Run removing steps and enqueue disconnected custom element reactions for the subtree.
parent.remove_child(node, cached_index, can_gc);
// Step 8. If node is assigned, then run assign slottables for nodes assigned slot.
if let Some(slot) = node.assigned_slot() {
slot.assign_slottables();
}
// Step 9. If parents root is a shadow root, and parent is a slot whose assigned nodes is the empty list,
// then run signal a slot change for parent.
if parent.is_in_a_shadow_tree() {
if let Some(slot_element) = parent.downcast::<HTMLSlotElement>() {
if !slot_element.has_assigned_nodes() {
slot_element.signal_a_slot_change();
}
}
}
// Step 10. If node has an inclusive descendant that is a slot:
let has_slot_descendant = node
.traverse_preorder(ShadowIncluding::No)
.any(|elem| elem.is::<HTMLSlotElement>());
if has_slot_descendant {
// Step 10.1 Run assign slottables for a tree with parents root.
parent
.GetRootNode(&GetRootNodeOptions::empty())
.assign_slottables_for_a_tree();
// Step 10.2 Run assign slottables for a tree with node.
node.assign_slottables_for_a_tree();
}
// TODO: Step 15. transient registered observers
// Step 16.
if let SuppressObserver::Unsuppressed = suppress_observers {
vtable_for(parent).children_changed(&ChildrenMutation::replace(
old_previous_sibling.as_deref(),
&Some(node),
&[],
old_next_sibling.as_deref(),
));
let removed = [node];
let mutation = LazyCell::new(|| Mutation::ChildList {
added: None,
removed: Some(&removed),
prev: old_previous_sibling.as_deref(),
next: old_next_sibling.as_deref(),
});
MutationObserver::queue_a_mutation_record(parent, mutation);
}
parent.owner_doc().remove_script_and_layout_blocker();
}
/// <https://dom.spec.whatwg.org/#concept-node-clone>
pub(crate) fn clone(
node: &Node,
maybe_doc: Option<&Document>,
clone_children: CloneChildrenFlag,
can_gc: CanGc,
) -> DomRoot<Node> {
// Step 1. If document is not given, let document be nodes node document.
let document = match maybe_doc {
Some(doc) => DomRoot::from_ref(doc),
None => node.owner_doc(),
};
// Step 2. / Step 3.
// XXXabinader: clone() for each node as trait?
let copy: DomRoot<Node> = match node.type_id() {
NodeTypeId::DocumentType => {
let doctype = node.downcast::<DocumentType>().unwrap();
let doctype = DocumentType::new(
doctype.name().clone(),
Some(doctype.public_id().clone()),
Some(doctype.system_id().clone()),
&document,
can_gc,
);
DomRoot::upcast::<Node>(doctype)
},
NodeTypeId::Attr => {
let attr = node.downcast::<Attr>().unwrap();
let attr = Attr::new(
&document,
attr.local_name().clone(),
attr.value().clone(),
attr.name().clone(),
attr.namespace().clone(),
attr.prefix().cloned(),
None,
can_gc,
);
DomRoot::upcast::<Node>(attr)
},
NodeTypeId::DocumentFragment(_) => {
let doc_fragment = DocumentFragment::new(&document, can_gc);
DomRoot::upcast::<Node>(doc_fragment)
},
NodeTypeId::CharacterData(_) => {
let cdata = node.downcast::<CharacterData>().unwrap();
cdata.clone_with_data(cdata.Data(), &document, can_gc)
},
NodeTypeId::Document(_) => {
let document = node.downcast::<Document>().unwrap();
let is_html_doc = if document.is_html_document() {
IsHTMLDocument::HTMLDocument
} else {
IsHTMLDocument::NonHTMLDocument
};
let window = document.window();
let loader = DocumentLoader::new(&document.loader());
let document = Document::new(
window,
HasBrowsingContext::No,
Some(document.url()),
// https://github.com/whatwg/dom/issues/378
document.origin().clone(),
is_html_doc,
None,
None,
DocumentActivity::Inactive,
DocumentSource::NotFromParser,
loader,
None,
document.status_code(),
Default::default(),
false,
document.allow_declarative_shadow_roots(),
Some(document.insecure_requests_policy()),
document.has_trustworthy_ancestor_or_current_origin(),
can_gc,
);
DomRoot::upcast::<Node>(document)
},
NodeTypeId::Element(..) => {
let element = node.downcast::<Element>().unwrap();
let name = QualName {
prefix: element.prefix().as_ref().map(|p| Prefix::from(&**p)),
ns: element.namespace().clone(),
local: element.local_name().clone(),
};
let element = Element::create(
name,
element.get_is(),
&document,
ElementCreator::ScriptCreated,
CustomElementCreationMode::Asynchronous,
None,
can_gc,
);
DomRoot::upcast::<Node>(element)
},
};
// Step 4. Set copys node document and document to copy, if copy is a document,
// and set copys node document to document otherwise.
let document = match copy.downcast::<Document>() {
Some(doc) => DomRoot::from_ref(doc),
None => DomRoot::from_ref(&*document),
};
assert!(copy.owner_doc() == document);
// TODO: The spec tells us to do this in step 3.
match node.type_id() {
NodeTypeId::Document(_) => {
let node_doc = node.downcast::<Document>().unwrap();
let copy_doc = copy.downcast::<Document>().unwrap();
copy_doc.set_encoding(node_doc.encoding());
copy_doc.set_quirks_mode(node_doc.quirks_mode());
},
NodeTypeId::Element(..) => {
let node_elem = node.downcast::<Element>().unwrap();
let copy_elem = copy.downcast::<Element>().unwrap();
for attr in node_elem.attrs().iter() {
copy_elem.push_new_attribute(
attr.local_name().clone(),
attr.value().clone(),
attr.name().clone(),
attr.namespace().clone(),
attr.prefix().cloned(),
can_gc,
);
}
},
_ => (),
}
// Step 5: Run any cloning steps defined for node in other applicable specifications and pass copy,
// node, document, and the clone children flag if set, as parameters.
vtable_for(node).cloning_steps(&copy, maybe_doc, clone_children, can_gc);
// Step 6. If the clone children flag is set, then for each child child of node, in tree order: append the
// result of cloning child with document and the clone children flag set, to copy.
if clone_children == CloneChildrenFlag::CloneChildren {
for child in node.children() {
let child_copy = Node::clone(&child, Some(&document), clone_children, can_gc);
let _inserted_node = Node::pre_insert(&child_copy, &copy, None, can_gc);
}
}
// Step 7. If node is a shadow host whose shadow roots clonable is true:
// NOTE: Only elements can be shadow hosts
if matches!(node.type_id(), NodeTypeId::Element(_)) {
let node_elem = node.downcast::<Element>().unwrap();
let copy_elem = copy.downcast::<Element>().unwrap();
if let Some(shadow_root) = node_elem.shadow_root().filter(|r| r.Clonable()) {
// Step 7.1 Assert: copy is not a shadow host.
assert!(!copy_elem.is_shadow_host());
// Step 7.2 Run attach a shadow root with copy, nodes shadow roots mode, true,
// nodes shadow roots serializable, nodes shadow roots delegates focus,
// and nodes shadow roots slot assignment.
let copy_shadow_root =
copy_elem.attach_shadow(
IsUserAgentWidget::No,
shadow_root.Mode(),
shadow_root.Clonable(),
shadow_root.Serializable(),
shadow_root.DelegatesFocus(),
shadow_root.SlotAssignment(),
can_gc
)
.expect("placement of attached shadow root must be valid, as this is a copy of an existing one");
// Step 7.3 Set copys shadow roots declarative to nodes shadow roots declarative.
copy_shadow_root.set_declarative(shadow_root.is_declarative());
// Step 7.4 For each child child of nodes shadow root, in tree order: append the result of
// cloning child with document and the clone children flag set, to copys shadow root.
for child in shadow_root.upcast::<Node>().children() {
let child_copy = Node::clone(
&child,
Some(&document),
CloneChildrenFlag::CloneChildren,
can_gc,
);
// TODO: Should we handle the error case here and in step 6?
let _inserted_node = Node::pre_insert(
&child_copy,
copy_shadow_root.upcast::<Node>(),
None,
can_gc,
);
}
}
}
// Step 8. Return copy.
copy
}
/// <https://html.spec.whatwg.org/multipage/#child-text-content>
pub(crate) fn child_text_content(&self) -> DOMString {
Node::collect_text_contents(self.children())
}
/// <https://html.spec.whatwg.org/multipage/#descendant-text-content>
pub(crate) fn descendant_text_content(&self) -> DOMString {
Node::collect_text_contents(self.traverse_preorder(ShadowIncluding::No))
}
pub(crate) fn collect_text_contents<T: Iterator<Item = DomRoot<Node>>>(
iterator: T,
) -> DOMString {
let mut content = String::new();
for node in iterator {
if let Some(text) = node.downcast::<Text>() {
content.push_str(&text.upcast::<CharacterData>().data());
}
}
DOMString::from(content)
}
pub(crate) fn namespace_to_string(namespace: Namespace) -> Option<DOMString> {
match namespace {
ns!() => None,
// FIXME(ajeffrey): convert directly from Namespace to DOMString
_ => Some(DOMString::from(&*namespace)),
}
}
/// <https://dom.spec.whatwg.org/#locate-a-namespace>
pub(crate) fn locate_namespace(node: &Node, prefix: Option<DOMString>) -> Namespace {
match node.type_id() {
NodeTypeId::Element(_) => node.downcast::<Element>().unwrap().locate_namespace(prefix),
NodeTypeId::Attr => node
.downcast::<Attr>()
.unwrap()
.GetOwnerElement()
.as_ref()
.map_or(ns!(), |elem| elem.locate_namespace(prefix)),
NodeTypeId::Document(_) => node
.downcast::<Document>()
.unwrap()
.GetDocumentElement()
.as_ref()
.map_or(ns!(), |elem| elem.locate_namespace(prefix)),
NodeTypeId::DocumentType | NodeTypeId::DocumentFragment(_) => ns!(),
_ => node
.GetParentElement()
.as_ref()
.map_or(ns!(), |elem| elem.locate_namespace(prefix)),
}
}
/// If the given untrusted node address represents a valid DOM node in the given runtime,
/// returns it.
///
/// # Safety
///
/// Callers should ensure they pass an UntrustedNodeAddress that points to a valid [`JSObject`]
/// in memory that represents a [`Node`].
#[allow(unsafe_code)]
pub(crate) unsafe fn from_untrusted_node_address(
candidate: UntrustedNodeAddress,
) -> &'static Self {
// https://github.com/servo/servo/issues/6383
let candidate = candidate.0 as usize;
let object = candidate as *mut JSObject;
if object.is_null() {
panic!("Attempted to create a `Node` from an invalid pointer!")
}
&*(conversions::private_from_object(object) as *const Self)
}
pub(crate) fn html_serialize(
&self,
traversal_scope: html_serialize::TraversalScope,
serialize_shadow_roots: bool,
shadow_roots: Vec<DomRoot<ShadowRoot>>,
can_gc: CanGc,
) -> DOMString {
let mut writer = vec![];
let mut serializer = HtmlSerializer::new(
&mut writer,
html_serialize::SerializeOpts {
traversal_scope: traversal_scope.clone(),
..Default::default()
},
);
serialize_html_fragment(
self,
&mut serializer,
traversal_scope,
serialize_shadow_roots,
shadow_roots,
can_gc,
)
.expect("Serializing node failed");
// FIXME(ajeffrey): Directly convert UTF8 to DOMString
DOMString::from(String::from_utf8(writer).unwrap())
}
/// <https://w3c.github.io/DOM-Parsing/#dfn-xml-serialization>
pub(crate) fn xml_serialize(
&self,
traversal_scope: xml_serialize::TraversalScope,
) -> DOMString {
let mut writer = vec![];
xml_serialize::serialize(
&mut writer,
&self,
xml_serialize::SerializeOpts { traversal_scope },
)
.expect("Cannot serialize node");
// FIXME(ajeffrey): Directly convert UTF8 to DOMString
DOMString::from(String::from_utf8(writer).unwrap())
}
/// <https://html.spec.whatwg.org/multipage/#fragment-serializing-algorithm-steps>
pub(crate) fn fragment_serialization_algorithm(
&self,
require_well_formed: bool,
can_gc: CanGc,
) -> DOMString {
// Step 1. Let context document be node's node document.
let context_document = self.owner_document();
// Step 2. If context document is an HTML document, return the result of HTML fragment serialization algorithm
// with node, false, and « ».
if context_document.is_html_document() {
return self.html_serialize(
html_serialize::TraversalScope::ChildrenOnly(None),
false,
vec![],
can_gc,
);
}
// Step 3. Return the XML serialization of node given require well-formed.
// TODO: xml5ever doesn't seem to want require_well_formed
let _ = require_well_formed;
self.xml_serialize(xml_serialize::TraversalScope::ChildrenOnly(None))
}
}
impl NodeMethods<crate::DomTypeHolder> for Node {
/// <https://dom.spec.whatwg.org/#dom-node-nodetype>
fn NodeType(&self) -> u16 {
match self.type_id() {
NodeTypeId::Attr => NodeConstants::ATTRIBUTE_NODE,
NodeTypeId::CharacterData(CharacterDataTypeId::Text(TextTypeId::Text)) => {
NodeConstants::TEXT_NODE
},
NodeTypeId::CharacterData(CharacterDataTypeId::Text(TextTypeId::CDATASection)) => {
NodeConstants::CDATA_SECTION_NODE
},
NodeTypeId::CharacterData(CharacterDataTypeId::ProcessingInstruction) => {
NodeConstants::PROCESSING_INSTRUCTION_NODE
},
NodeTypeId::CharacterData(CharacterDataTypeId::Comment) => NodeConstants::COMMENT_NODE,
NodeTypeId::Document(_) => NodeConstants::DOCUMENT_NODE,
NodeTypeId::DocumentType => NodeConstants::DOCUMENT_TYPE_NODE,
NodeTypeId::DocumentFragment(_) => NodeConstants::DOCUMENT_FRAGMENT_NODE,
NodeTypeId::Element(_) => NodeConstants::ELEMENT_NODE,
}
}
/// <https://dom.spec.whatwg.org/#dom-node-nodename>
fn NodeName(&self) -> DOMString {
match self.type_id() {
NodeTypeId::Attr => self.downcast::<Attr>().unwrap().qualified_name(),
NodeTypeId::Element(..) => self.downcast::<Element>().unwrap().TagName(),
NodeTypeId::CharacterData(CharacterDataTypeId::Text(TextTypeId::Text)) => {
DOMString::from("#text")
},
NodeTypeId::CharacterData(CharacterDataTypeId::Text(TextTypeId::CDATASection)) => {
DOMString::from("#cdata-section")
},
NodeTypeId::CharacterData(CharacterDataTypeId::ProcessingInstruction) => {
self.downcast::<ProcessingInstruction>().unwrap().Target()
},
NodeTypeId::CharacterData(CharacterDataTypeId::Comment) => DOMString::from("#comment"),
NodeTypeId::DocumentType => self.downcast::<DocumentType>().unwrap().name().clone(),
NodeTypeId::DocumentFragment(_) => DOMString::from("#document-fragment"),
NodeTypeId::Document(_) => DOMString::from("#document"),
}
}
/// <https://dom.spec.whatwg.org/#dom-node-baseuri>
fn BaseURI(&self) -> USVString {
USVString(String::from(self.owner_doc().base_url().as_str()))
}
/// <https://dom.spec.whatwg.org/#dom-node-isconnected>
fn IsConnected(&self) -> bool {
self.is_connected()
}
/// <https://dom.spec.whatwg.org/#dom-node-ownerdocument>
fn GetOwnerDocument(&self) -> Option<DomRoot<Document>> {
match self.type_id() {
NodeTypeId::Document(_) => None,
_ => Some(self.owner_doc()),
}
}
/// <https://dom.spec.whatwg.org/#dom-node-getrootnode>
fn GetRootNode(&self, options: &GetRootNodeOptions) -> DomRoot<Node> {
if !options.composed {
if let Some(shadow_root) = self.containing_shadow_root() {
return DomRoot::upcast(shadow_root);
}
}
if self.is_connected() {
DomRoot::from_ref(self.owner_doc().upcast::<Node>())
} else {
self.inclusive_ancestors(ShadowIncluding::Yes)
.last()
.unwrap()
}
}
/// <https://dom.spec.whatwg.org/#dom-node-parentnode>
fn GetParentNode(&self) -> Option<DomRoot<Node>> {
self.parent_node.get()
}
/// <https://dom.spec.whatwg.org/#dom-node-parentelement>
fn GetParentElement(&self) -> Option<DomRoot<Element>> {
self.GetParentNode().and_then(DomRoot::downcast)
}
/// <https://dom.spec.whatwg.org/#dom-node-haschildnodes>
fn HasChildNodes(&self) -> bool {
self.first_child.get().is_some()
}
/// <https://dom.spec.whatwg.org/#dom-node-childnodes>
fn ChildNodes(&self, can_gc: CanGc) -> DomRoot<NodeList> {
if let Some(list) = self.ensure_rare_data().child_list.get() {
return list;
}
let doc = self.owner_doc();
let window = doc.window();
let list = NodeList::new_child_list(window, self, can_gc);
self.ensure_rare_data().child_list.set(Some(&list));
list
}
/// <https://dom.spec.whatwg.org/#dom-node-firstchild>
fn GetFirstChild(&self) -> Option<DomRoot<Node>> {
self.first_child.get()
}
/// <https://dom.spec.whatwg.org/#dom-node-lastchild>
fn GetLastChild(&self) -> Option<DomRoot<Node>> {
self.last_child.get()
}
/// <https://dom.spec.whatwg.org/#dom-node-previoussibling>
fn GetPreviousSibling(&self) -> Option<DomRoot<Node>> {
self.prev_sibling.get()
}
/// <https://dom.spec.whatwg.org/#dom-node-nextsibling>
fn GetNextSibling(&self) -> Option<DomRoot<Node>> {
self.next_sibling.get()
}
/// <https://dom.spec.whatwg.org/#dom-node-nodevalue>
fn GetNodeValue(&self) -> Option<DOMString> {
match self.type_id() {
NodeTypeId::Attr => Some(self.downcast::<Attr>().unwrap().Value()),
NodeTypeId::CharacterData(_) => {
self.downcast::<CharacterData>().map(CharacterData::Data)
},
_ => None,
}
}
/// <https://dom.spec.whatwg.org/#dom-node-nodevalue>
fn SetNodeValue(&self, val: Option<DOMString>, can_gc: CanGc) {
match self.type_id() {
NodeTypeId::Attr => {
let attr = self.downcast::<Attr>().unwrap();
attr.SetValue(val.unwrap_or_default(), can_gc);
},
NodeTypeId::CharacterData(_) => {
let character_data = self.downcast::<CharacterData>().unwrap();
character_data.SetData(val.unwrap_or_default());
},
_ => {},
}
}
/// <https://dom.spec.whatwg.org/#dom-node-textcontent>
fn GetTextContent(&self) -> Option<DOMString> {
match self.type_id() {
NodeTypeId::DocumentFragment(_) | NodeTypeId::Element(..) => {
let content =
Node::collect_text_contents(self.traverse_preorder(ShadowIncluding::No));
Some(content)
},
NodeTypeId::Attr => Some(self.downcast::<Attr>().unwrap().Value()),
NodeTypeId::CharacterData(..) => {
let characterdata = self.downcast::<CharacterData>().unwrap();
Some(characterdata.Data())
},
NodeTypeId::DocumentType | NodeTypeId::Document(_) => None,
}
}
/// <https://dom.spec.whatwg.org/#dom-node-textcontent>
fn SetTextContent(&self, value: Option<DOMString>, can_gc: CanGc) {
let value = value.unwrap_or_default();
match self.type_id() {
NodeTypeId::DocumentFragment(_) | NodeTypeId::Element(..) => {
// Step 1-2.
let node = if value.is_empty() {
None
} else {
Some(DomRoot::upcast(
self.owner_doc().CreateTextNode(value, can_gc),
))
};
// Step 3.
Node::replace_all(node.as_deref(), self, can_gc);
},
NodeTypeId::Attr => {
let attr = self.downcast::<Attr>().unwrap();
attr.SetValue(value, can_gc);
},
NodeTypeId::CharacterData(..) => {
let characterdata = self.downcast::<CharacterData>().unwrap();
characterdata.SetData(value);
},
NodeTypeId::DocumentType | NodeTypeId::Document(_) => {},
}
}
/// <https://dom.spec.whatwg.org/#dom-node-insertbefore>
fn InsertBefore(
&self,
node: &Node,
child: Option<&Node>,
can_gc: CanGc,
) -> Fallible<DomRoot<Node>> {
Node::pre_insert(node, self, child, can_gc)
}
/// <https://dom.spec.whatwg.org/#dom-node-appendchild>
fn AppendChild(&self, node: &Node, can_gc: CanGc) -> Fallible<DomRoot<Node>> {
Node::pre_insert(node, self, None, can_gc)
}
/// <https://dom.spec.whatwg.org/#concept-node-replace>
fn ReplaceChild(&self, node: &Node, child: &Node, can_gc: CanGc) -> Fallible<DomRoot<Node>> {
// Step 1. If parent is not a Document, DocumentFragment, or Element node,
// then throw a "HierarchyRequestError" DOMException.
match self.type_id() {
NodeTypeId::Document(_) | NodeTypeId::DocumentFragment(_) | NodeTypeId::Element(..) => {
},
_ => return Err(Error::HierarchyRequest),
}
// Step 2. If node is a host-including inclusive ancestor of parent,
// then throw a "HierarchyRequestError" DOMException.
if node.is_inclusive_ancestor_of(self) {
return Err(Error::HierarchyRequest);
}
// Step 3. If childs parent is not parent, then throw a "NotFoundError" DOMException.
if !self.is_parent_of(child) {
return Err(Error::NotFound);
}
// Step 4. If node is not a DocumentFragment, DocumentType, Element, or CharacterData node,
// then throw a "HierarchyRequestError" DOMException.
// Step 5. If either node is a Text node and parent is a document,
// or node is a doctype and parent is not a document, then throw a "HierarchyRequestError" DOMException.
match node.type_id() {
NodeTypeId::CharacterData(CharacterDataTypeId::Text(_)) if self.is::<Document>() => {
return Err(Error::HierarchyRequest);
},
NodeTypeId::DocumentType if !self.is::<Document>() => {
return Err(Error::HierarchyRequest);
},
NodeTypeId::Document(_) | NodeTypeId::Attr => return Err(Error::HierarchyRequest),
_ => (),
}
// Step 6. If parent is a document, and any of the statements below, switched on the interface node implements,
// are true, then throw a "HierarchyRequestError" DOMException.
if self.is::<Document>() {
match node.type_id() {
// Step 6.1
NodeTypeId::DocumentFragment(_) => {
// Step 6.1.1(b)
if node.children().any(|c| c.is::<Text>()) {
return Err(Error::HierarchyRequest);
}
match node.child_elements().count() {
0 => (),
// Step 6.1.2
1 => {
if self.child_elements().any(|c| c.upcast::<Node>() != child) {
return Err(Error::HierarchyRequest);
}
if child.following_siblings().any(|child| child.is_doctype()) {
return Err(Error::HierarchyRequest);
}
},
// Step 6.1.1(a)
_ => return Err(Error::HierarchyRequest),
}
},
// Step 6.2
NodeTypeId::Element(..) => {
if self.child_elements().any(|c| c.upcast::<Node>() != child) {
return Err(Error::HierarchyRequest);
}
if child.following_siblings().any(|child| child.is_doctype()) {
return Err(Error::HierarchyRequest);
}
},
// Step 6.3
NodeTypeId::DocumentType => {
if self.children().any(|c| c.is_doctype() && &*c != child) {
return Err(Error::HierarchyRequest);
}
if self
.children()
.take_while(|c| &**c != child)
.any(|c| c.is::<Element>())
{
return Err(Error::HierarchyRequest);
}
},
NodeTypeId::CharacterData(..) => (),
// Because Document and Attr should already throw `HierarchyRequest`
// error, both of them are unreachable here.
NodeTypeId::Document(_) => unreachable!(),
NodeTypeId::Attr => unreachable!(),
}
}
// Step 7. Let referenceChild be childs next sibling.
// Step 8. If referenceChild is node, then set referenceChild to nodes next sibling.
let child_next_sibling = child.GetNextSibling();
let node_next_sibling = node.GetNextSibling();
let reference_child = if child_next_sibling.as_deref() == Some(node) {
node_next_sibling.as_deref()
} else {
child_next_sibling.as_deref()
};
// Step 9. Let previousSibling be childs previous sibling.
let previous_sibling = child.GetPreviousSibling();
// NOTE: All existing browsers assume that adoption is performed here, which does not follow the DOM spec.
// However, if we follow the spec and delay adoption to inside `Node::insert()`, then the mutation records will
// be different, and we will fail WPT dom/nodes/MutationObserver-childList.html.
let document = self.owner_document();
Node::adopt(node, &document, can_gc);
// Step 10. Let removedNodes be the empty set.
// Step 11. If childs parent is non-null:
// 1. Set removedNodes to « child ».
// 2. Remove child with the suppress observers flag set.
let removed_child = if node != child {
// Step 11.
Node::remove(child, self, SuppressObserver::Suppressed, can_gc);
Some(child)
} else {
None
};
// Step 12. Let nodes be nodes children if node is a DocumentFragment node; otherwise « node ».
rooted_vec!(let mut nodes);
let nodes = if node.type_id() ==
NodeTypeId::DocumentFragment(DocumentFragmentTypeId::DocumentFragment) ||
node.type_id() == NodeTypeId::DocumentFragment(DocumentFragmentTypeId::ShadowRoot)
{
nodes.extend(node.children().map(|node| Dom::from_ref(&*node)));
nodes.r()
} else {
from_ref(&node)
};
// Step 13. Insert node into parent before referenceChild with the suppress observers flag set.
Node::insert(
node,
self,
reference_child,
SuppressObserver::Suppressed,
can_gc,
);
vtable_for(self).children_changed(&ChildrenMutation::replace(
previous_sibling.as_deref(),
&removed_child,
nodes,
reference_child,
));
// Step 14. Queue a tree mutation record for parent with nodes, removedNodes,
// previousSibling, and referenceChild.
let removed = removed_child.map(|r| [r]);
let mutation = LazyCell::new(|| Mutation::ChildList {
added: Some(nodes),
removed: removed.as_ref().map(|r| &r[..]),
prev: previous_sibling.as_deref(),
next: reference_child,
});
MutationObserver::queue_a_mutation_record(self, mutation);
// Step 15. Return child.
Ok(DomRoot::from_ref(child))
}
/// <https://dom.spec.whatwg.org/#dom-node-removechild>
fn RemoveChild(&self, node: &Node, can_gc: CanGc) -> Fallible<DomRoot<Node>> {
Node::pre_remove(node, self, can_gc)
}
/// <https://dom.spec.whatwg.org/#dom-node-normalize>
fn Normalize(&self, can_gc: CanGc) {
let mut children = self.children().enumerate().peekable();
while let Some((_, node)) = children.next() {
if let Some(text) = node.downcast::<Text>() {
let cdata = text.upcast::<CharacterData>();
let mut length = cdata.Length();
if length == 0 {
Node::remove(&node, self, SuppressObserver::Unsuppressed, can_gc);
continue;
}
while children
.peek()
.is_some_and(|(_, sibling)| sibling.is::<Text>())
{
let (index, sibling) = children.next().unwrap();
sibling
.ranges()
.drain_to_preceding_text_sibling(&sibling, &node, length);
self.ranges()
.move_to_text_child_at(self, index as u32, &node, length);
let sibling_cdata = sibling.downcast::<CharacterData>().unwrap();
length += sibling_cdata.Length();
cdata.append_data(&sibling_cdata.data());
Node::remove(&sibling, self, SuppressObserver::Unsuppressed, can_gc);
}
} else {
node.Normalize(can_gc);
}
}
}
/// <https://dom.spec.whatwg.org/#dom-node-clonenode>
fn CloneNode(&self, subtree: bool, can_gc: CanGc) -> Fallible<DomRoot<Node>> {
// Step 1. If this is a shadow root, then throw a "NotSupportedError" DOMException.
if self.is::<ShadowRoot>() {
return Err(Error::NotSupported);
}
// Step 2. Return the result of cloning a node given this with subtree set to subtree.
let result = Node::clone(
self,
None,
if subtree {
CloneChildrenFlag::CloneChildren
} else {
CloneChildrenFlag::DoNotCloneChildren
},
can_gc,
);
Ok(result)
}
/// <https://dom.spec.whatwg.org/#dom-node-isequalnode>
fn IsEqualNode(&self, maybe_node: Option<&Node>) -> bool {
fn is_equal_doctype(node: &Node, other: &Node) -> bool {
let doctype = node.downcast::<DocumentType>().unwrap();
let other_doctype = other.downcast::<DocumentType>().unwrap();
(*doctype.name() == *other_doctype.name()) &&
(*doctype.public_id() == *other_doctype.public_id()) &&
(*doctype.system_id() == *other_doctype.system_id())
}
fn is_equal_element(node: &Node, other: &Node) -> bool {
let element = node.downcast::<Element>().unwrap();
let other_element = other.downcast::<Element>().unwrap();
(*element.namespace() == *other_element.namespace()) &&
(*element.prefix() == *other_element.prefix()) &&
(*element.local_name() == *other_element.local_name()) &&
(element.attrs().len() == other_element.attrs().len())
}
fn is_equal_processinginstruction(node: &Node, other: &Node) -> bool {
let pi = node.downcast::<ProcessingInstruction>().unwrap();
let other_pi = other.downcast::<ProcessingInstruction>().unwrap();
(*pi.target() == *other_pi.target()) &&
(*pi.upcast::<CharacterData>().data() ==
*other_pi.upcast::<CharacterData>().data())
}
fn is_equal_characterdata(node: &Node, other: &Node) -> bool {
let characterdata = node.downcast::<CharacterData>().unwrap();
let other_characterdata = other.downcast::<CharacterData>().unwrap();
*characterdata.data() == *other_characterdata.data()
}
fn is_equal_attr(node: &Node, other: &Node) -> bool {
let attr = node.downcast::<Attr>().unwrap();
let other_attr = other.downcast::<Attr>().unwrap();
(*attr.namespace() == *other_attr.namespace()) &&
(attr.local_name() == other_attr.local_name()) &&
(**attr.value() == **other_attr.value())
}
fn is_equal_element_attrs(node: &Node, other: &Node) -> bool {
let element = node.downcast::<Element>().unwrap();
let other_element = other.downcast::<Element>().unwrap();
assert!(element.attrs().len() == other_element.attrs().len());
element.attrs().iter().all(|attr| {
other_element.attrs().iter().any(|other_attr| {
(*attr.namespace() == *other_attr.namespace()) &&
(attr.local_name() == other_attr.local_name()) &&
(**attr.value() == **other_attr.value())
})
})
}
fn is_equal_node(this: &Node, node: &Node) -> bool {
// Step 2.
if this.NodeType() != node.NodeType() {
return false;
}
match node.type_id() {
// Step 3.
NodeTypeId::DocumentType if !is_equal_doctype(this, node) => return false,
NodeTypeId::Element(..) if !is_equal_element(this, node) => return false,
NodeTypeId::CharacterData(CharacterDataTypeId::ProcessingInstruction)
if !is_equal_processinginstruction(this, node) =>
{
return false;
},
NodeTypeId::CharacterData(CharacterDataTypeId::Text(_)) |
NodeTypeId::CharacterData(CharacterDataTypeId::Comment)
if !is_equal_characterdata(this, node) =>
{
return false;
},
// Step 4.
NodeTypeId::Element(..) if !is_equal_element_attrs(this, node) => return false,
NodeTypeId::Attr if !is_equal_attr(this, node) => return false,
_ => (),
}
// Step 5.
if this.children_count() != node.children_count() {
return false;
}
// Step 6.
this.children()
.zip(node.children())
.all(|(child, other_child)| is_equal_node(&child, &other_child))
}
match maybe_node {
// Step 1.
None => false,
// Step 2-6.
Some(node) => is_equal_node(self, node),
}
}
/// <https://dom.spec.whatwg.org/#dom-node-issamenode>
fn IsSameNode(&self, other_node: Option<&Node>) -> bool {
match other_node {
Some(node) => self == node,
None => false,
}
}
/// <https://dom.spec.whatwg.org/#dom-node-comparedocumentposition>
fn CompareDocumentPosition(&self, other: &Node) -> u16 {
// step 1.
if self == other {
return 0;
}
// step 2
let mut node1 = Some(other);
let mut node2 = Some(self);
// step 3
let mut attr1: Option<&Attr> = None;
let mut attr2: Option<&Attr> = None;
// step 4: spec says to operate on node1 here,
// node1 is definitely Some(other) going into this step
// The compiler doesn't know the lifetime of attr1.GetOwnerElement
// is guaranteed by the lifetime of attr1, so we hold it explicitly
let attr1owner;
if let Some(a) = other.downcast::<Attr>() {
attr1 = Some(a);
attr1owner = a.GetOwnerElement();
node1 = match attr1owner {
Some(ref e) => Some(e.upcast()),
None => None,
}
}
// step 5.1: spec says to operate on node2 here,
// node2 is definitely just Some(self) going into this step
let attr2owner;
if let Some(a) = self.downcast::<Attr>() {
attr2 = Some(a);
attr2owner = a.GetOwnerElement();
node2 = match attr2owner {
Some(ref e) => Some(e.upcast()),
None => None,
}
}
// Step 5.2
// This substep seems lacking in test coverage.
// We hit this when comparing two attributes that have the
// same owner element.
if let Some(node2) = node2 {
if Some(node2) == node1 {
if let (Some(a1), Some(a2)) = (attr1, attr2) {
let attrs = node2.downcast::<Element>().unwrap().attrs();
// go through the attrs in order to see if self
// or other is first; spec is clear that we
// want value-equality, not reference-equality
for attr in attrs.iter() {
if (*attr.namespace() == *a1.namespace()) &&
(attr.local_name() == a1.local_name()) &&
(**attr.value() == **a1.value())
{
return NodeConstants::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC +
NodeConstants::DOCUMENT_POSITION_PRECEDING;
}
if (*attr.namespace() == *a2.namespace()) &&
(attr.local_name() == a2.local_name()) &&
(**attr.value() == **a2.value())
{
return NodeConstants::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC +
NodeConstants::DOCUMENT_POSITION_FOLLOWING;
}
}
// both attrs have node2 as their owner element, so
// we can't have left the loop without seeing them
unreachable!();
}
}
}
// Step 6
match (node1, node2) {
(None, _) => {
// node1 is null
NodeConstants::DOCUMENT_POSITION_FOLLOWING +
NodeConstants::DOCUMENT_POSITION_DISCONNECTED +
NodeConstants::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC
},
(_, None) => {
// node2 is null
NodeConstants::DOCUMENT_POSITION_PRECEDING +
NodeConstants::DOCUMENT_POSITION_DISCONNECTED +
NodeConstants::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC
},
(Some(node1), Some(node2)) => {
// still step 6, testing if node1 and 2 share a root
let mut self_and_ancestors = node2
.inclusive_ancestors(ShadowIncluding::No)
.collect::<SmallVec<[_; 20]>>();
let mut other_and_ancestors = node1
.inclusive_ancestors(ShadowIncluding::No)
.collect::<SmallVec<[_; 20]>>();
if self_and_ancestors.last() != other_and_ancestors.last() {
let random = as_uintptr(self_and_ancestors.last().unwrap()) <
as_uintptr(other_and_ancestors.last().unwrap());
let random = if random {
NodeConstants::DOCUMENT_POSITION_FOLLOWING
} else {
NodeConstants::DOCUMENT_POSITION_PRECEDING
};
// Disconnected.
return random +
NodeConstants::DOCUMENT_POSITION_DISCONNECTED +
NodeConstants::DOCUMENT_POSITION_IMPLEMENTATION_SPECIFIC;
}
// steps 7-10
let mut parent = self_and_ancestors.pop().unwrap();
other_and_ancestors.pop().unwrap();
let mut current_position =
cmp::min(self_and_ancestors.len(), other_and_ancestors.len());
while current_position > 0 {
current_position -= 1;
let child_1 = self_and_ancestors.pop().unwrap();
let child_2 = other_and_ancestors.pop().unwrap();
if child_1 != child_2 {
let is_before = parent.children().position(|c| c == child_1).unwrap() <
parent.children().position(|c| c == child_2).unwrap();
// If I am before, `other` is following, and the other way
// around.
return if is_before {
NodeConstants::DOCUMENT_POSITION_FOLLOWING
} else {
NodeConstants::DOCUMENT_POSITION_PRECEDING
};
}
parent = child_1;
}
// We hit the end of one of the parent chains, so one node needs to be
// contained in the other.
//
// If we're the container, return that `other` is contained by us.
if self_and_ancestors.len() < other_and_ancestors.len() {
NodeConstants::DOCUMENT_POSITION_FOLLOWING +
NodeConstants::DOCUMENT_POSITION_CONTAINED_BY
} else {
NodeConstants::DOCUMENT_POSITION_PRECEDING +
NodeConstants::DOCUMENT_POSITION_CONTAINS
}
},
}
}
/// <https://dom.spec.whatwg.org/#dom-node-contains>
fn Contains(&self, maybe_other: Option<&Node>) -> bool {
match maybe_other {
None => false,
Some(other) => self.is_inclusive_ancestor_of(other),
}
}
/// <https://dom.spec.whatwg.org/#dom-node-lookupprefix>
fn LookupPrefix(&self, namespace: Option<DOMString>) -> Option<DOMString> {
let namespace = namespace_from_domstring(namespace);
// Step 1.
if namespace == ns!() {
return None;
}
// Step 2.
match self.type_id() {
NodeTypeId::Element(..) => self.downcast::<Element>().unwrap().lookup_prefix(namespace),
NodeTypeId::Document(_) => self
.downcast::<Document>()
.unwrap()
.GetDocumentElement()
.and_then(|element| element.lookup_prefix(namespace)),
NodeTypeId::DocumentType | NodeTypeId::DocumentFragment(_) => None,
NodeTypeId::Attr => self
.downcast::<Attr>()
.unwrap()
.GetOwnerElement()
.and_then(|element| element.lookup_prefix(namespace)),
_ => self
.GetParentElement()
.and_then(|element| element.lookup_prefix(namespace)),
}
}
/// <https://dom.spec.whatwg.org/#dom-node-lookupnamespaceuri>
fn LookupNamespaceURI(&self, prefix: Option<DOMString>) -> Option<DOMString> {
// Step 1.
let prefix = match prefix {
Some(ref p) if p.is_empty() => None,
pre => pre,
};
// Step 2.
Node::namespace_to_string(Node::locate_namespace(self, prefix))
}
/// <https://dom.spec.whatwg.org/#dom-node-isdefaultnamespace>
fn IsDefaultNamespace(&self, namespace: Option<DOMString>) -> bool {
// Step 1.
let namespace = namespace_from_domstring(namespace);
// Steps 2 and 3.
Node::locate_namespace(self, None) == namespace
}
}
pub(crate) trait NodeTraits {
/// Get the [`Document`] that owns this node. Note that this may differ from the
/// [`Document`] that the node was created in if it was adopted by a different
/// [`Document`] (the owner).
fn owner_document(&self) -> DomRoot<Document>;
/// Get the [`Window`] of the [`Document`] that owns this node. Note that this may
/// differ from the [`Document`] that the node was created in if it was adopted by a
/// different [`Document`] (the owner).
fn owner_window(&self) -> DomRoot<Window>;
/// Get the [`GlobalScope`] of the [`Document`] that owns this node. Note that this may
/// differ from the [`GlobalScope`] that the node was created in if it was adopted by a
/// different [`Document`] (the owner).
fn owner_global(&self) -> DomRoot<GlobalScope>;
/// If this [`Node`] is contained in a [`ShadowRoot`] return it, otherwise `None`.
fn containing_shadow_root(&self) -> Option<DomRoot<ShadowRoot>>;
/// Get the stylesheet owner for this node: either the [`Document`] or the [`ShadowRoot`]
/// of the node.
#[cfg_attr(crown, allow(crown::unrooted_must_root))]
fn stylesheet_list_owner(&self) -> StyleSheetListOwner;
}
impl<T: DerivedFrom<Node> + DomObject> NodeTraits for T {
fn owner_document(&self) -> DomRoot<Document> {
self.upcast().owner_doc()
}
fn owner_window(&self) -> DomRoot<Window> {
DomRoot::from_ref(self.owner_document().window())
}
fn owner_global(&self) -> DomRoot<GlobalScope> {
DomRoot::from_ref(self.owner_window().upcast())
}
fn containing_shadow_root(&self) -> Option<DomRoot<ShadowRoot>> {
Node::containing_shadow_root(self.upcast())
}
#[cfg_attr(crown, allow(crown::unrooted_must_root))]
fn stylesheet_list_owner(&self) -> StyleSheetListOwner {
self.containing_shadow_root()
.map(|shadow_root| StyleSheetListOwner::ShadowRoot(Dom::from_ref(&*shadow_root)))
.unwrap_or_else(|| {
StyleSheetListOwner::Document(Dom::from_ref(&*self.owner_document()))
})
}
}
impl VirtualMethods for Node {
fn super_type(&self) -> Option<&dyn VirtualMethods> {
Some(self.upcast::<EventTarget>() as &dyn VirtualMethods)
}
fn children_changed(&self, mutation: &ChildrenMutation) {
if let Some(s) = self.super_type() {
s.children_changed(mutation);
}
if let Some(data) = self.rare_data().as_ref() {
if let Some(list) = data.child_list.get() {
list.as_children_list().children_changed(mutation);
}
}
self.owner_doc().content_and_heritage_changed(self);
}
// This handles the ranges mentioned in steps 2-3 when removing a node.
/// <https://dom.spec.whatwg.org/#concept-node-remove>
fn unbind_from_tree(&self, context: &UnbindContext, can_gc: CanGc) {
self.super_type().unwrap().unbind_from_tree(context, can_gc);
if !self.ranges_is_empty() {
self.ranges().drain_to_parent(context, self);
}
}
}
/// A summary of the changes that happened to a node.
#[derive(Clone, Copy, MallocSizeOf, PartialEq)]
pub(crate) enum NodeDamage {
/// The node's `style` attribute changed.
NodeStyleDamaged,
/// Other parts of a node changed; attributes, text content, etc.
OtherNodeDamage,
}
pub(crate) enum ChildrenMutation<'a> {
Append {
prev: &'a Node,
added: &'a [&'a Node],
},
Insert {
prev: &'a Node,
added: &'a [&'a Node],
next: &'a Node,
},
Prepend {
added: &'a [&'a Node],
next: &'a Node,
},
Replace {
prev: Option<&'a Node>,
removed: &'a Node,
added: &'a [&'a Node],
next: Option<&'a Node>,
},
ReplaceAll {
removed: &'a [&'a Node],
added: &'a [&'a Node],
},
/// Mutation for when a Text node's data is modified.
/// This doesn't change the structure of the list, which is what the other
/// variants' fields are stored for at the moment, so this can just have no
/// fields.
ChangeText,
}
impl<'a> ChildrenMutation<'a> {
fn insert(
prev: Option<&'a Node>,
added: &'a [&'a Node],
next: Option<&'a Node>,
) -> ChildrenMutation<'a> {
match (prev, next) {
(None, None) => ChildrenMutation::ReplaceAll {
removed: &[],
added,
},
(Some(prev), None) => ChildrenMutation::Append { prev, added },
(None, Some(next)) => ChildrenMutation::Prepend { added, next },
(Some(prev), Some(next)) => ChildrenMutation::Insert { prev, added, next },
}
}
fn replace(
prev: Option<&'a Node>,
removed: &'a Option<&'a Node>,
added: &'a [&'a Node],
next: Option<&'a Node>,
) -> ChildrenMutation<'a> {
if let Some(ref removed) = *removed {
if let (None, None) = (prev, next) {
ChildrenMutation::ReplaceAll {
removed: from_ref(removed),
added,
}
} else {
ChildrenMutation::Replace {
prev,
removed,
added,
next,
}
}
} else {
ChildrenMutation::insert(prev, added, next)
}
}
fn replace_all(removed: &'a [&'a Node], added: &'a [&'a Node]) -> ChildrenMutation<'a> {
ChildrenMutation::ReplaceAll { removed, added }
}
/// Get the child that follows the added or removed children.
/// Currently only used when this mutation might force us to
/// restyle later children (see HAS_SLOW_SELECTOR_LATER_SIBLINGS and
/// Element's implementation of VirtualMethods::children_changed).
pub(crate) fn next_child(&self) -> Option<&Node> {
match *self {
ChildrenMutation::Append { .. } => None,
ChildrenMutation::Insert { next, .. } => Some(next),
ChildrenMutation::Prepend { next, .. } => Some(next),
ChildrenMutation::Replace { next, .. } => next,
ChildrenMutation::ReplaceAll { .. } => None,
ChildrenMutation::ChangeText => None,
}
}
/// If nodes were added or removed at the start or end of a container, return any
/// previously-existing child whose ":first-child" or ":last-child" status *may* have changed.
///
/// NOTE: This does not check whether the inserted/removed nodes were elements, so in some
/// cases it will return a false positive. This doesn't matter for correctness, because at
/// worst the returned element will be restyled unnecessarily.
pub(crate) fn modified_edge_element(&self) -> Option<DomRoot<Node>> {
match *self {
// Add/remove at start of container: Return the first following element.
ChildrenMutation::Prepend { next, .. } |
ChildrenMutation::Replace {
prev: None,
next: Some(next),
..
} => next
.inclusively_following_siblings()
.find(|node| node.is::<Element>()),
// Add/remove at end of container: Return the last preceding element.
ChildrenMutation::Append { prev, .. } |
ChildrenMutation::Replace {
prev: Some(prev),
next: None,
..
} => prev
.inclusively_preceding_siblings()
.find(|node| node.is::<Element>()),
// Insert or replace in the middle:
ChildrenMutation::Insert { prev, next, .. } |
ChildrenMutation::Replace {
prev: Some(prev),
next: Some(next),
..
} => {
if prev
.inclusively_preceding_siblings()
.all(|node| !node.is::<Element>())
{
// Before the first element: Return the first following element.
next.inclusively_following_siblings()
.find(|node| node.is::<Element>())
} else if next
.inclusively_following_siblings()
.all(|node| !node.is::<Element>())
{
// After the last element: Return the last preceding element.
prev.inclusively_preceding_siblings()
.find(|node| node.is::<Element>())
} else {
None
}
},
ChildrenMutation::Replace {
prev: None,
next: None,
..
} => unreachable!(),
ChildrenMutation::ReplaceAll { .. } => None,
ChildrenMutation::ChangeText => None,
}
}
}
/// The context of the binding to tree of a node.
pub(crate) struct BindContext {
/// Whether the tree is connected.
///
/// <https://dom.spec.whatwg.org/#connected>
pub(crate) tree_connected: bool,
/// Whether the tree's root is a document.
///
/// <https://dom.spec.whatwg.org/#in-a-document-tree>
pub(crate) tree_is_in_a_document_tree: bool,
/// Whether the tree's root is a shadow root
pub(crate) tree_is_in_a_shadow_tree: bool,
}
impl BindContext {
/// Return true iff the tree is inside either a document- or a shadow tree.
pub(crate) fn is_in_tree(&self) -> bool {
self.tree_is_in_a_document_tree || self.tree_is_in_a_shadow_tree
}
}
/// The context of the unbinding from a tree of a node when one of its
/// inclusive ancestors is removed.
pub(crate) struct UnbindContext<'a> {
/// The index of the inclusive ancestor that was removed.
index: Cell<Option<u32>>,
/// The parent of the inclusive ancestor that was removed.
pub(crate) parent: &'a Node,
/// The previous sibling of the inclusive ancestor that was removed.
prev_sibling: Option<&'a Node>,
/// The next sibling of the inclusive ancestor that was removed.
pub(crate) next_sibling: Option<&'a Node>,
/// Whether the tree is connected.
///
/// <https://dom.spec.whatwg.org/#connected>
pub(crate) tree_connected: bool,
/// Whether the tree's root is a document.
///
/// <https://dom.spec.whatwg.org/#in-a-document-tree>
pub(crate) tree_is_in_a_document_tree: bool,
/// Whether the tree's root is a shadow root
pub(crate) tree_is_in_a_shadow_tree: bool,
}
impl<'a> UnbindContext<'a> {
/// Create a new `UnbindContext` value.
pub(crate) fn new(
parent: &'a Node,
prev_sibling: Option<&'a Node>,
next_sibling: Option<&'a Node>,
cached_index: Option<u32>,
) -> Self {
UnbindContext {
index: Cell::new(cached_index),
parent,
prev_sibling,
next_sibling,
tree_connected: parent.is_connected(),
tree_is_in_a_document_tree: parent.is_in_a_document_tree(),
tree_is_in_a_shadow_tree: parent.is_in_a_shadow_tree(),
}
}
/// The index of the inclusive ancestor that was removed from the tree.
#[allow(unsafe_code)]
pub(crate) fn index(&self) -> u32 {
if let Some(index) = self.index.get() {
return index;
}
let index = self.prev_sibling.map_or(0, |sibling| sibling.index() + 1);
self.index.set(Some(index));
index
}
}
/// A node's unique ID, for devtools.
pub(crate) struct UniqueId {
cell: UnsafeCell<Option<Box<Uuid>>>,
}
unsafe_no_jsmanaged_fields!(UniqueId);
impl MallocSizeOf for UniqueId {
#[allow(unsafe_code)]
fn size_of(&self, ops: &mut MallocSizeOfOps) -> usize {
if let Some(uuid) = unsafe { &*self.cell.get() } {
unsafe { ops.malloc_size_of(&**uuid) }
} else {
0
}
}
}
impl UniqueId {
/// Create a new `UniqueId` value. The underlying `Uuid` is lazily created.
fn new() -> UniqueId {
UniqueId {
cell: UnsafeCell::new(None),
}
}
/// The Uuid of that unique ID.
#[allow(unsafe_code)]
fn borrow(&self) -> &Uuid {
unsafe {
let ptr = self.cell.get();
if (*ptr).is_none() {
*ptr = Some(Box::new(Uuid::new_v4()));
}
(*ptr).as_ref().unwrap()
}
}
}
pub(crate) struct NodeTypeIdWrapper(pub(crate) NodeTypeId);
impl From<NodeTypeIdWrapper> for LayoutNodeType {
#[inline(always)]
fn from(node_type: NodeTypeIdWrapper) -> LayoutNodeType {
match node_type.0 {
NodeTypeId::Element(e) => LayoutNodeType::Element(ElementTypeIdWrapper(e).into()),
NodeTypeId::CharacterData(CharacterDataTypeId::Text(_)) => LayoutNodeType::Text,
x => unreachable!("Layout should not traverse nodes of type {:?}", x),
}
}
}
struct ElementTypeIdWrapper(ElementTypeId);
impl From<ElementTypeIdWrapper> for LayoutElementType {
#[inline(always)]
fn from(element_type: ElementTypeIdWrapper) -> LayoutElementType {
match element_type.0 {
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLBodyElement) => {
LayoutElementType::HTMLBodyElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLBRElement) => {
LayoutElementType::HTMLBRElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLCanvasElement) => {
LayoutElementType::HTMLCanvasElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLHtmlElement) => {
LayoutElementType::HTMLHtmlElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLIFrameElement) => {
LayoutElementType::HTMLIFrameElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLImageElement) => {
LayoutElementType::HTMLImageElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLMediaElement(_)) => {
LayoutElementType::HTMLMediaElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLInputElement) => {
LayoutElementType::HTMLInputElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLOptGroupElement) => {
LayoutElementType::HTMLOptGroupElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLOptionElement) => {
LayoutElementType::HTMLOptionElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLObjectElement) => {
LayoutElementType::HTMLObjectElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLParagraphElement) => {
LayoutElementType::HTMLParagraphElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLPreElement) => {
LayoutElementType::HTMLPreElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLSelectElement) => {
LayoutElementType::HTMLSelectElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLTableCellElement) => {
LayoutElementType::HTMLTableCellElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLTableColElement) => {
LayoutElementType::HTMLTableColElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLTableElement) => {
LayoutElementType::HTMLTableElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLTableRowElement) => {
LayoutElementType::HTMLTableRowElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLTableSectionElement) => {
LayoutElementType::HTMLTableSectionElement
},
ElementTypeId::HTMLElement(HTMLElementTypeId::HTMLTextAreaElement) => {
LayoutElementType::HTMLTextAreaElement
},
ElementTypeId::SVGElement(SVGElementTypeId::SVGGraphicsElement(
SVGGraphicsElementTypeId::SVGImageElement,
)) => LayoutElementType::SVGImageElement,
ElementTypeId::SVGElement(SVGElementTypeId::SVGGraphicsElement(
SVGGraphicsElementTypeId::SVGSVGElement,
)) => LayoutElementType::SVGSVGElement,
_ => LayoutElementType::Element,
}
}
}
/// Helper trait to insert an element into vector whose elements
/// are maintained in tree order
pub(crate) trait VecPreOrderInsertionHelper<T> {
fn insert_pre_order(&mut self, elem: &T, tree_root: &Node);
}
impl<T> VecPreOrderInsertionHelper<T> for Vec<Dom<T>>
where
T: DerivedFrom<Node> + DomObject,
{
/// This algorithm relies on the following assumptions:
/// * any elements inserted in this vector share the same tree root
/// * any time an element is removed from the tree root, it is also removed from this array
/// * any time an element is moved within the tree, it is removed from this array and re-inserted
///
/// Under these assumptions, an element's tree-order position in this array can be determined by
/// performing a [preorder traversal](https://dom.spec.whatwg.org/#concept-tree-order) of the tree root's children,
/// and increasing the destination index in the array every time a node in the array is encountered during
/// the traversal.
fn insert_pre_order(&mut self, elem: &T, tree_root: &Node) {
if self.is_empty() {
self.push(Dom::from_ref(elem));
return;
}
let elem_node = elem.upcast::<Node>();
let mut head: usize = 0;
for node in tree_root.traverse_preorder(ShadowIncluding::No) {
let head_node = DomRoot::upcast::<Node>(DomRoot::from_ref(&*self[head]));
if head_node == node {
head += 1;
}
if elem_node == &*node || head == self.len() {
break;
}
}
self.insert(head, Dom::from_ref(elem));
}
}
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