/*
* Copyright (c) 2020, the SerenityOS developers.
* Copyright (c) 2022, Luke Wilde <lukew@serenityos.org>
* Copyright (c) 2022-2023, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <LibWeb/Bindings/Intrinsics.h>
#include <LibWeb/DOM/Comment.h>
#include <LibWeb/DOM/Document.h>
#include <LibWeb/DOM/DocumentFragment.h>
#include <LibWeb/DOM/DocumentType.h>
#include <LibWeb/DOM/ElementFactory.h>
#include <LibWeb/DOM/Node.h>
#include <LibWeb/DOM/ProcessingInstruction.h>
#include <LibWeb/DOM/Range.h>
#include <LibWeb/DOM/Text.h>
#include <LibWeb/DOMParsing/InnerHTML.h>
#include <LibWeb/Geometry/DOMRect.h>
#include <LibWeb/HTML/HTMLHtmlElement.h>
#include <LibWeb/HTML/Window.h>
#include <LibWeb/Layout/Viewport.h>
#include <LibWeb/Namespace.h>
namespace Web::DOM {
HashTable<Range*>& Range::live_ranges()
{
static HashTable<Range*> ranges;
return ranges;
}
WebIDL::ExceptionOr<JS::NonnullGCPtr<Range>> Range::create(HTML::Window& window)
{
return Range::create(window.associated_document());
}
WebIDL::ExceptionOr<JS::NonnullGCPtr<Range>> Range::create(Document& document)
{
auto& realm = document.realm();
return MUST_OR_THROW_OOM(realm.heap().allocate<Range>(realm, document));
}
WebIDL::ExceptionOr<JS::NonnullGCPtr<Range>> Range::create(Node& start_container, u32 start_offset, Node& end_container, u32 end_offset)
{
auto& realm = start_container.realm();
return MUST_OR_THROW_OOM(realm.heap().allocate<Range>(realm, start_container, start_offset, end_container, end_offset));
}
WebIDL::ExceptionOr<JS::NonnullGCPtr<Range>> Range::construct_impl(JS::Realm& realm)
{
auto& window = verify_cast<HTML::Window>(realm.global_object());
return Range::create(window);
}
Range::Range(Document& document)
: Range(document, 0, document, 0)
{
}
Range::Range(Node& start_container, u32 start_offset, Node& end_container, u32 end_offset)
: AbstractRange(start_container, start_offset, end_container, end_offset)
{
live_ranges().set(this);
}
Range::~Range()
{
live_ranges().remove(this);
}
JS::ThrowCompletionOr<void> Range::initialize(JS::Realm& realm)
{
MUST_OR_THROW_OOM(Base::initialize(realm));
set_prototype(&Bindings::ensure_web_prototype<Bindings::RangePrototype>(realm, "Range"));
return {};
}
void Range::visit_edges(Cell::Visitor& visitor)
{
Base::visit_edges(visitor);
visitor.visit(m_associated_selection);
}
void Range::set_associated_selection(Badge<Selection::Selection>, JS::GCPtr<Selection::Selection> selection)
{
m_associated_selection = selection;
update_associated_selection();
}
void Range::update_associated_selection()
{
if (!m_associated_selection)
return;
if (auto* layout_root = m_associated_selection->document()->layout_node()) {
layout_root->recompute_selection_states();
layout_root->set_needs_display();
}
}
// https://dom.spec.whatwg.org/#concept-range-root
Node& Range::root()
{
// The root of a live range is the root of its start node.
return m_start_container->root();
}
Node const& Range::root() const
{
return m_start_container->root();
}
// https://dom.spec.whatwg.org/#concept-range-bp-position
RelativeBoundaryPointPosition position_of_boundary_point_relative_to_other_boundary_point(Node const& node_a, u32 offset_a, Node const& node_b, u32 offset_b)
{
// 1. Assert: nodeA and nodeB have the same root.
VERIFY(&node_a.root() == &node_b.root());
// 2. If nodeA is nodeB, then return equal if offsetA is offsetB, before if offsetA is less than offsetB, and after if offsetA is greater than offsetB.
if (&node_a == &node_b) {
if (offset_a == offset_b)
return RelativeBoundaryPointPosition::Equal;
if (offset_a < offset_b)
return RelativeBoundaryPointPosition::Before;
return RelativeBoundaryPointPosition::After;
}
// 3. If nodeA is following nodeB, then if the position of (nodeB, offsetB) relative to (nodeA, offsetA) is before, return after, and if it is after, return before.
if (node_a.is_following(node_b)) {
auto relative_position = position_of_boundary_point_relative_to_other_boundary_point(node_b, offset_b, node_a, offset_a);
if (relative_position == RelativeBoundaryPointPosition::Before)
return RelativeBoundaryPointPosition::After;
if (relative_position == RelativeBoundaryPointPosition::After)
return RelativeBoundaryPointPosition::Before;
}
// 4. If nodeA is an ancestor of nodeB:
if (node_a.is_ancestor_of(node_b)) {
// 1. Let child be nodeB.
JS::NonnullGCPtr<Node const> child = node_b;
// 2. While child is not a child of nodeA, set child to its parent.
while (!node_a.is_parent_of(child)) {
auto* parent = child->parent();
VERIFY(parent);
child = *parent;
}
// 3. If child’s index is less than offsetA, then return after.
if (child->index() < offset_a)
return RelativeBoundaryPointPosition::After;
}
// 5. Return before.
return RelativeBoundaryPointPosition::Before;
}
WebIDL::ExceptionOr<void> Range::set_start_or_end(Node& node, u32 offset, StartOrEnd start_or_end)
{
// To set the start or end of a range to a boundary point (node, offset), run these steps:
// 1. If node is a doctype, then throw an "InvalidNodeTypeError" DOMException.
if (is<DocumentType>(node))
return WebIDL::InvalidNodeTypeError::create(realm(), "Node cannot be a DocumentType.");
// 2. If offset is greater than node’s length, then throw an "IndexSizeError" DOMException.
if (offset > node.length())
return WebIDL::IndexSizeError::create(realm(), DeprecatedString::formatted("Node does not contain a child at offset {}", offset));
// 3. Let bp be the boundary point (node, offset).
if (start_or_end == StartOrEnd::Start) {
// -> If these steps were invoked as "set the start"
// 1. If range’s root is not equal to node’s root, or if bp is after the range’s end, set range’s end to bp.
if (&root() != &node.root() || position_of_boundary_point_relative_to_other_boundary_point(node, offset, m_end_container, m_end_offset) == RelativeBoundaryPointPosition::After) {
m_end_container = node;
m_end_offset = offset;
}
// 2. Set range’s start to bp.
m_start_container = node;
m_start_offset = offset;
} else {
// -> If these steps were invoked as "set the end"
VERIFY(start_or_end == StartOrEnd::End);
// 1. If range’s root is not equal to node’s root, or if bp is before the range’s start, set range’s start to bp.
if (&root() != &node.root() || position_of_boundary_point_relative_to_other_boundary_point(node, offset, m_start_container, m_start_offset) == RelativeBoundaryPointPosition::Before) {
m_start_container = node;
m_start_offset = offset;
}
// 2. Set range’s end to bp.
m_end_container = node;
m_end_offset = offset;
}
update_associated_selection();
return {};
}
// https://dom.spec.whatwg.org/#concept-range-bp-set
WebIDL::ExceptionOr<void> Range::set_start(Node& node, u32 offset)
{
// The setStart(node, offset) method steps are to set the start of this to boundary point (node, offset).
return set_start_or_end(node, offset, StartOrEnd::Start);
}
WebIDL::ExceptionOr<void> Range::set_end(Node& node, u32 offset)
{
// The setEnd(node, offset) method steps are to set the end of this to boundary point (node, offset).
return set_start_or_end(node, offset, StartOrEnd::End);
}
// https://dom.spec.whatwg.org/#dom-range-setstartbefore
WebIDL::ExceptionOr<void> Range::set_start_before(Node& node)
{
// 1. Let parent be node’s parent.
auto* parent = node.parent();
// 2. If parent is null, then throw an "InvalidNodeTypeError" DOMException.
if (!parent)
return WebIDL::InvalidNodeTypeError::create(realm(), "Given node has no parent.");
// 3. Set the start of this to boundary point (parent, node’s index).
return set_start_or_end(*parent, node.index(), StartOrEnd::Start);
}
// https://dom.spec.whatwg.org/#dom-range-setstartafter
WebIDL::ExceptionOr<void> Range::set_start_after(Node& node)
{
// 1. Let parent be node’s parent.
auto* parent = node.parent();
// 2. If parent is null, then throw an "InvalidNodeTypeError" DOMException.
if (!parent)
return WebIDL::InvalidNodeTypeError::create(realm(), "Given node has no parent.");
// 3. Set the start of this to boundary point (parent, node’s index plus 1).
return set_start_or_end(*parent, node.index() + 1, StartOrEnd::Start);
}
// https://dom.spec.whatwg.org/#dom-range-setendbefore
WebIDL::ExceptionOr<void> Range::set_end_before(Node& node)
{
// 1. Let parent be node’s parent.
auto* parent = node.parent();
// 2. If parent is null, then throw an "InvalidNodeTypeError" DOMException.
if (!parent)
return WebIDL::InvalidNodeTypeError::create(realm(), "Given node has no parent.");
// 3. Set the end of this to boundary point (parent, node’s index).
return set_start_or_end(*parent, node.index(), StartOrEnd::End);
}
// https://dom.spec.whatwg.org/#dom-range-setendafter
WebIDL::ExceptionOr<void> Range::set_end_after(Node& node)
{
// 1. Let parent be node’s parent.
auto* parent = node.parent();
// 2. If parent is null, then throw an "InvalidNodeTypeError" DOMException.
if (!parent)
return WebIDL::InvalidNodeTypeError::create(realm(), "Given node has no parent.");
// 3. Set the end of this to boundary point (parent, node’s index plus 1).
return set_start_or_end(*parent, node.index() + 1, StartOrEnd::End);
}
// https://dom.spec.whatwg.org/#dom-range-compareboundarypoints
WebIDL::ExceptionOr<i16> Range::compare_boundary_points(u16 how, Range const& source_range) const
{
// 1. If how is not one of
// - START_TO_START,
// - START_TO_END,
// - END_TO_END, and
// - END_TO_START,
// then throw a "NotSupportedError" DOMException.
if (how != HowToCompareBoundaryPoints::START_TO_START && how != HowToCompareBoundaryPoints::START_TO_END && how != HowToCompareBoundaryPoints::END_TO_END && how != HowToCompareBoundaryPoints::END_TO_START)
return WebIDL::NotSupportedError::create(realm(), DeprecatedString::formatted("Expected 'how' to be one of START_TO_START (0), START_TO_END (1), END_TO_END (2) or END_TO_START (3), got {}", how));
// 2. If this’s root is not the same as sourceRange’s root, then throw a "WrongDocumentError" DOMException.
if (&root() != &source_range.root())
return WebIDL::WrongDocumentError::create(realm(), "This range is not in the same tree as the source range.");
JS::GCPtr<Node> this_point_node;
u32 this_point_offset = 0;
JS::GCPtr<Node> other_point_node;
u32 other_point_offset = 0;
// 3. If how is:
switch (how) {
case HowToCompareBoundaryPoints::START_TO_START:
// -> START_TO_START:
// Let this point be this’s start. Let other point be sourceRange’s start.
this_point_node = m_start_container;
this_point_offset = m_start_offset;
other_point_node = source_range.m_start_container;
other_point_offset = source_range.m_start_offset;
break;
case HowToCompareBoundaryPoints::START_TO_END:
// -> START_TO_END:
// Let this point be this’s end. Let other point be sourceRange’s start.
this_point_node = m_end_container;
this_point_offset = m_end_offset;
other_point_node = source_range.m_start_container;
other_point_offset = source_range.m_start_offset;
break;
case HowToCompareBoundaryPoints::END_TO_END:
// -> END_TO_END:
// Let this point be this’s end. Let other point be sourceRange’s end.
this_point_node = m_end_container;
this_point_offset = m_end_offset;
other_point_node = source_range.m_end_container;
other_point_offset = source_range.m_end_offset;
break;
case HowToCompareBoundaryPoints::END_TO_START:
// -> END_TO_START:
// Let this point be this’s start. Let other point be sourceRange’s end.
this_point_node = m_start_container;
this_point_offset = m_start_offset;
other_point_node = source_range.m_end_container;
other_point_offset = source_range.m_end_offset;
break;
default:
VERIFY_NOT_REACHED();
}
VERIFY(this_point_node);
VERIFY(other_point_node);
// 4. If the position of this point relative to other point is
auto relative_position = position_of_boundary_point_relative_to_other_boundary_point(*this_point_node, this_point_offset, *other_point_node, other_point_offset);
switch (relative_position) {
case RelativeBoundaryPointPosition::Before:
// -> before
// Return −1.
return -1;
case RelativeBoundaryPointPosition::Equal:
// -> equal
// Return 0.
return 0;
case RelativeBoundaryPointPosition::After:
// -> after
// Return 1.
return 1;
default:
VERIFY_NOT_REACHED();
}
}
// https://dom.spec.whatwg.org/#concept-range-select
WebIDL::ExceptionOr<void> Range::select(Node& node)
{
// 1. Let parent be node’s parent.
auto* parent = node.parent();
// 2. If parent is null, then throw an "InvalidNodeTypeError" DOMException.
if (!parent)
return WebIDL::InvalidNodeTypeError::create(realm(), "Given node has no parent.");
// 3. Let index be node’s index.
auto index = node.index();
// 4. Set range’s start to boundary point (parent, index).
m_start_container = *parent;
m_start_offset = index;
// 5. Set range’s end to boundary point (parent, index plus 1).
m_end_container = *parent;
m_end_offset = index + 1;
update_associated_selection();
return {};
}
// https://dom.spec.whatwg.org/#dom-range-selectnode
WebIDL::ExceptionOr<void> Range::select_node(Node& node)
{
// The selectNode(node) method steps are to select node within this.
return select(node);
}
// https://dom.spec.whatwg.org/#dom-range-collapse
void Range::collapse(bool to_start)
{
// The collapse(toStart) method steps are to, if toStart is true, set end to start; otherwise set start to end.
if (to_start) {
m_end_container = m_start_container;
m_end_offset = m_start_offset;
} else {
m_start_container = m_end_container;
m_start_offset = m_end_offset;
}
update_associated_selection();
}
// https://dom.spec.whatwg.org/#dom-range-selectnodecontents
WebIDL::ExceptionOr<void> Range::select_node_contents(Node& node)
{
// 1. If node is a doctype, throw an "InvalidNodeTypeError" DOMException.
if (is<DocumentType>(node))
return WebIDL::InvalidNodeTypeError::create(realm(), "Node cannot be a DocumentType.");
// 2. Let length be the length of node.
auto length = node.length();
// 3. Set start to the boundary point (node, 0).
m_start_container = node;
m_start_offset = 0;
// 4. Set end to the boundary point (node, length).
m_end_container = node;
m_end_offset = length;
update_associated_selection();
return {};
}
JS::NonnullGCPtr<Range> Range::clone_range() const
{
return heap().allocate<Range>(shape().realm(), const_cast<Node&>(*m_start_container), m_start_offset, const_cast<Node&>(*m_end_container), m_end_offset).release_allocated_value_but_fixme_should_propagate_errors();
}
JS::NonnullGCPtr<Range> Range::inverted() const
{
return heap().allocate<Range>(shape().realm(), const_cast<Node&>(*m_end_container), m_end_offset, const_cast<Node&>(*m_start_container), m_start_offset).release_allocated_value_but_fixme_should_propagate_errors();
}
JS::NonnullGCPtr<Range> Range::normalized() const
{
if (m_start_container.ptr() == m_end_container.ptr()) {
if (m_start_offset <= m_end_offset)
return clone_range();
return inverted();
}
if (m_start_container->is_before(m_end_container))
return clone_range();
return inverted();
}
// https://dom.spec.whatwg.org/#dom-range-commonancestorcontainer
JS::NonnullGCPtr<Node> Range::common_ancestor_container() const
{
// 1. Let container be start node.
auto container = m_start_container;
// 2. While container is not an inclusive ancestor of end node, let container be container’s parent.
while (!container->is_inclusive_ancestor_of(m_end_container)) {
VERIFY(container->parent());
container = *container->parent();
}
// 3. Return container.
return container;
}
// https://dom.spec.whatwg.org/#dom-range-intersectsnode
bool Range::intersects_node(Node const& node) const
{
// 1. If node’s root is different from this’s root, return false.
if (&node.root() != &root())
return false;
// 2. Let parent be node’s parent.
auto* parent = node.parent();
// 3. If parent is null, return true.
if (!parent)
return true;
// 4. Let offset be node’s index.
auto offset = node.index();
// 5. If (parent, offset) is before end and (parent, offset plus 1) is after start, return true
auto relative_position_to_end = position_of_boundary_point_relative_to_other_boundary_point(*parent, offset, m_end_container, m_end_offset);
auto relative_position_to_start = position_of_boundary_point_relative_to_other_boundary_point(*parent, offset + 1, m_start_container, m_start_offset);
if (relative_position_to_end == RelativeBoundaryPointPosition::Before && relative_position_to_start == RelativeBoundaryPointPosition::After)
return true;
// 6. Return false.
return false;
}
// https://dom.spec.whatwg.org/#dom-range-ispointinrange
WebIDL::ExceptionOr<bool> Range::is_point_in_range(Node const& node, u32 offset) const
{
// 1. If node’s root is different from this’s root, return false.
if (&node.root() != &root())
return false;
// 2. If node is a doctype, then throw an "InvalidNodeTypeError" DOMException.
if (is<DocumentType>(node))
return WebIDL::InvalidNodeTypeError::create(realm(), "Node cannot be a DocumentType.");
// 3. If offset is greater than node’s length, then throw an "IndexSizeError" DOMException.
if (offset > node.length())
return WebIDL::IndexSizeError::create(realm(), DeprecatedString::formatted("Node does not contain a child at offset {}", offset));
// 4. If (node, offset) is before start or after end, return false.
auto relative_position_to_start = position_of_boundary_point_relative_to_other_boundary_point(node, offset, m_start_container, m_start_offset);
auto relative_position_to_end = position_of_boundary_point_relative_to_other_boundary_point(node, offset, m_end_container, m_end_offset);
if (relative_position_to_start == RelativeBoundaryPointPosition::Before || relative_position_to_end == RelativeBoundaryPointPosition::After)
return false;
// 5. Return true.
return true;
}
// https://dom.spec.whatwg.org/#dom-range-comparepoint
WebIDL::ExceptionOr<i16> Range::compare_point(Node const& node, u32 offset) const
{
// 1. If node’s root is different from this’s root, then throw a "WrongDocumentError" DOMException.
if (&node.root() != &root())
return WebIDL::WrongDocumentError::create(realm(), "Given node is not in the same document as the range.");
// 2. If node is a doctype, then throw an "InvalidNodeTypeError" DOMException.
if (is<DocumentType>(node))
return WebIDL::InvalidNodeTypeError::create(realm(), "Node cannot be a DocumentType.");
// 3. If offset is greater than node’s length, then throw an "IndexSizeError" DOMException.
if (offset > node.length())
return WebIDL::IndexSizeError::create(realm(), DeprecatedString::formatted("Node does not contain a child at offset {}", offset));
// 4. If (node, offset) is before start, return −1.
auto relative_position_to_start = position_of_boundary_point_relative_to_other_boundary_point(node, offset, m_start_container, m_start_offset);
if (relative_position_to_start == RelativeBoundaryPointPosition::Before)
return -1;
// 5. If (node, offset) is after end, return 1.
auto relative_position_to_end = position_of_boundary_point_relative_to_other_boundary_point(node, offset, m_end_container, m_end_offset);
if (relative_position_to_end == RelativeBoundaryPointPosition::After)
return 1;
// 6. Return 0.
return 0;
}
// https://dom.spec.whatwg.org/#dom-range-stringifier
DeprecatedString Range::to_deprecated_string() const
{
// 1. Let s be the empty string.
StringBuilder builder;
// 2. If this’s start node is this’s end node and it is a Text node,
// then return the substring of that Text node’s data beginning at this’s start offset and ending at this’s end offset.
if (start_container() == end_container() && is<Text>(*start_container()))
return static_cast<Text const&>(*start_container()).data().substring(start_offset(), end_offset() - start_offset());
// 3. If this’s start node is a Text node, then append the substring of that node’s data from this’s start offset until the end to s.
if (is<Text>(*start_container()))
builder.append(static_cast<Text const&>(*start_container()).data().substring_view(start_offset()));
// 4. Append the concatenation of the data of all Text nodes that are contained in this, in tree order, to s.
for (Node const* node = start_container(); node != end_container()->next_sibling(); node = node->next_in_pre_order()) {
if (is<Text>(*node) && contains_node(*node))
builder.append(static_cast<Text const&>(*node).data());
}
// 5. If this’s end node is a Text node, then append the substring of that node’s data from its start until this’s end offset to s.
if (is<Text>(*end_container()))
builder.append(static_cast<Text const&>(*end_container()).data().substring_view(0, end_offset()));
// 6. Return s.
return builder.to_deprecated_string();
}
// https://dom.spec.whatwg.org/#dom-range-extractcontents
WebIDL::ExceptionOr<JS::NonnullGCPtr<DocumentFragment>> Range::extract_contents()
{
return extract();
}
// https://dom.spec.whatwg.org/#concept-range-extract
WebIDL::ExceptionOr<JS::NonnullGCPtr<DocumentFragment>> Range::extract()
{
// 1. Let fragment be a new DocumentFragment node whose node document is range’s start node’s node document.
auto fragment = MUST_OR_THROW_OOM(heap().allocate<DOM::DocumentFragment>(realm(), const_cast<Document&>(start_container()->document())));
// 2. If range is collapsed, then return fragment.
if (collapsed())
return fragment;
// 3. Let original start node, original start offset, original end node, and original end offset
// be range’s start node, start offset, end node, and end offset, respectively.
JS::NonnullGCPtr<Node> original_start_node = m_start_container;
auto original_start_offset = m_start_offset;
JS::NonnullGCPtr<Node> original_end_node = m_end_container;
auto original_end_offset = m_end_offset;
// 4. If original start node is original end node and it is a CharacterData node, then:
if (original_start_node.ptr() == original_end_node.ptr() && is<CharacterData>(*original_start_node)) {
// 1. Let clone be a clone of original start node.
auto clone = original_start_node->clone_node();
// 2. Set the data of clone to the result of substringing data with node original start node,
// offset original start offset, and count original end offset minus original start offset.
auto result = TRY(static_cast<CharacterData const&>(*original_start_node).substring_data(original_start_offset, original_end_offset - original_start_offset));
verify_cast<CharacterData>(*clone).set_data(move(result));
// 3. Append clone to fragment.
TRY(fragment->append_child(clone));
// 4. Replace data with node original start node, offset original start offset, count original end offset minus original start offset, and data the empty string.
TRY(static_cast<CharacterData&>(*original_start_node).replace_data(original_start_offset, original_end_offset - original_start_offset, ""));
// 5. Return fragment.
return fragment;
}
// 5. Let common ancestor be original start node.
JS::NonnullGCPtr<Node> common_ancestor = original_start_node;
// 6. While common ancestor is not an inclusive ancestor of original end node, set common ancestor to its own parent.
while (!common_ancestor->is_inclusive_ancestor_of(original_end_node))
common_ancestor = *common_ancestor->parent_node();
// 7. Let first partially contained child be null.
JS::GCPtr<Node> first_partially_contained_child;
// 8. If original start node is not an inclusive ancestor of original end node,
// set first partially contained child to the first child of common ancestor that is partially contained in range.
if (!original_start_node->is_inclusive_ancestor_of(original_end_node)) {
for (auto* child = common_ancestor->first_child(); child; child = child->next_sibling()) {
if (partially_contains_node(*child)) {
first_partially_contained_child = child;
break;
}
}
}
// 9. Let last partially contained child be null.
JS::GCPtr<Node> last_partially_contained_child;
// 10. If original end node is not an inclusive ancestor of original start node,
// set last partially contained child to the last child of common ancestor that is partially contained in range.
if (!original_end_node->is_inclusive_ancestor_of(original_start_node)) {
for (auto* child = common_ancestor->last_child(); child; child = child->previous_sibling()) {
if (partially_contains_node(*child)) {
last_partially_contained_child = child;
break;
}
}
}
// 11. Let contained children be a list of all children of common ancestor that are contained in range, in tree order.
Vector<JS::NonnullGCPtr<Node>> contained_children;
for (Node* node = common_ancestor->first_child(); node; node = node->next_sibling()) {
if (contains_node(*node))
contained_children.append(*node);
}
// 12. If any member of contained children is a doctype, then throw a "HierarchyRequestError" DOMException.
for (auto const& child : contained_children) {
if (is<DocumentType>(*child))
return WebIDL::HierarchyRequestError::create(realm(), "Contained child is a DocumentType");
}
JS::GCPtr<Node> new_node;
size_t new_offset = 0;
// 13. If original start node is an inclusive ancestor of original end node, set new node to original start node and new offset to original start offset.
if (original_start_node->is_inclusive_ancestor_of(original_end_node)) {
new_node = original_start_node;
new_offset = original_start_offset;
}
// 14. Otherwise:
else {
// 1. Let reference node equal original start node.
JS::GCPtr<Node> reference_node = original_start_node;
// 2. While reference node’s parent is not null and is not an inclusive ancestor of original end node, set reference node to its parent.
while (reference_node->parent_node() && !reference_node->parent_node()->is_inclusive_ancestor_of(original_end_node))
reference_node = reference_node->parent_node();
// 3. Set new node to the parent of reference node, and new offset to one plus reference node’s index.
new_node = reference_node->parent_node();
new_offset = 1 + reference_node->index();
}
// 15. If first partially contained child is a CharacterData node, then:
if (first_partially_contained_child && is<CharacterData>(*first_partially_contained_child)) {
// 1. Let clone be a clone of original start node.
auto clone = original_start_node->clone_node();
// 2. Set the data of clone to the result of substringing data with node original start node, offset original start offset,
// and count original start node’s length minus original start offset.
auto result = TRY(static_cast<CharacterData const&>(*original_start_node).substring_data(original_start_offset, original_start_node->length() - original_start_offset));
verify_cast<CharacterData>(*clone).set_data(move(result));
// 3. Append clone to fragment.
TRY(fragment->append_child(clone));
// 4. Replace data with node original start node, offset original start offset, count original start node’s length minus original start offset, and data the empty string.
TRY(static_cast<CharacterData&>(*original_start_node).replace_data(original_start_offset, original_start_node->length() - original_start_offset, ""));
}
// 16. Otherwise, if first partially contained child is not null:
else if (first_partially_contained_child) {
// 1. Let clone be a clone of first partially contained child.
auto clone = first_partially_contained_child->clone_node();
// 2. Append clone to fragment.
TRY(fragment->append_child(clone));
// 3. Let subrange be a new live range whose start is (original start node, original start offset) and whose end is (first partially contained child, first partially contained child’s length).
auto subrange = TRY(Range::create(original_start_node, original_start_offset, *first_partially_contained_child, first_partially_contained_child->length()));
// 4. Let subfragment be the result of extracting subrange.
auto subfragment = TRY(subrange->extract());
// 5. Append subfragment to clone.
TRY(clone->append_child(subfragment));
}
// 17. For each contained child in contained children, append contained child to fragment.
for (auto& contained_child : contained_children) {
TRY(fragment->append_child(contained_child));
}
// 18. If last partially contained child is a CharacterData node, then:
if (last_partially_contained_child && is<CharacterData>(*last_partially_contained_child)) {
// 1. Let clone be a clone of original end node.
auto clone = original_end_node->clone_node();
// 2. Set the data of clone to the result of substringing data with node original end node, offset 0, and count original end offset.
auto result = TRY(static_cast<CharacterData const&>(*original_end_node).substring_data(0, original_end_offset));
verify_cast<CharacterData>(*clone).set_data(move(result));
// 3. Append clone to fragment.
TRY(fragment->append_child(clone));
// 4. Replace data with node original end node, offset 0, count original end offset, and data the empty string.
TRY(verify_cast<CharacterData>(*original_end_node).replace_data(0, original_end_offset, ""));
}
// 19. Otherwise, if last partially contained child is not null:
else if (last_partially_contained_child) {
// 1. Let clone be a clone of last partially contained child.
auto clone = last_partially_contained_child->clone_node();
// 2. Append clone to fragment.
TRY(fragment->append_child(clone));
// 3. Let subrange be a new live range whose start is (last partially contained child, 0) and whose end is (original end node, original end offset).
auto subrange = TRY(Range::create(*last_partially_contained_child, 0, original_end_node, original_end_offset));
// 4. Let subfragment be the result of extracting subrange.
auto subfragment = TRY(subrange->extract());
// 5. Append subfragment to clone.
TRY(clone->append_child(subfragment));
}
// 20. Set range’s start and end to (new node, new offset).
TRY(set_start(*new_node, new_offset));
TRY(set_end(*new_node, new_offset));
// 21. Return fragment.
return fragment;
}
// https://dom.spec.whatwg.org/#contained
bool Range::contains_node(Node const& node) const
{
// A node node is contained in a live range range if node’s root is range’s root,
if (&node.root() != &root())
return false;
// and (node, 0) is after range’s start,
if (position_of_boundary_point_relative_to_other_boundary_point(node, 0, m_start_container, m_start_offset) != RelativeBoundaryPointPosition::After)
return false;
// and (node, node’s length) is before range’s end.
if (position_of_boundary_point_relative_to_other_boundary_point(node, node.length(), m_end_container, m_end_offset) != RelativeBoundaryPointPosition::Before)
return false;
return true;
}
// https://dom.spec.whatwg.org/#partially-contained
bool Range::partially_contains_node(Node const& node) const
{
// A node is partially contained in a live range if it’s an inclusive ancestor of the live range’s start node but not its end node, or vice versa.
if (node.is_inclusive_ancestor_of(m_start_container) && &node != m_end_container.ptr())
return true;
if (node.is_inclusive_ancestor_of(m_end_container) && &node != m_start_container.ptr())
return true;
return false;
}
// https://dom.spec.whatwg.org/#dom-range-insertnode
WebIDL::ExceptionOr<void> Range::insert_node(JS::NonnullGCPtr<Node> node)
{
return insert(node);
}
// https://dom.spec.whatwg.org/#concept-range-insert
WebIDL::ExceptionOr<void> Range::insert(JS::NonnullGCPtr<Node> node)
{
// 1. If range’s start node is a ProcessingInstruction or Comment node, is a Text node whose parent is null, or is node, then throw a "HierarchyRequestError" DOMException.
if ((is<ProcessingInstruction>(*m_start_container) || is<Comment>(*m_start_container))
|| (is<Text>(*m_start_container) && !m_start_container->parent_node())
|| m_start_container.ptr() == node.ptr()) {
return WebIDL::HierarchyRequestError::create(realm(), "Range has inappropriate start node for insertion");
}
// 2. Let referenceNode be null.
JS::GCPtr<Node> reference_node;
// 3. If range’s start node is a Text node, set referenceNode to that Text node.
if (is<Text>(*m_start_container)) {
reference_node = m_start_container;
}
// 4. Otherwise, set referenceNode to the child of start node whose index is start offset, and null if there is no such child.
else {
reference_node = m_start_container->child_at_index(m_start_offset);
}
// 5. Let parent be range’s start node if referenceNode is null, and referenceNode’s parent otherwise.
JS::GCPtr<Node> parent;
if (!reference_node)
parent = m_start_container;
else
parent = reference_node->parent();
// 6. Ensure pre-insertion validity of node into parent before referenceNode.
TRY(parent->ensure_pre_insertion_validity(node, reference_node));
// 7. If range’s start node is a Text node, set referenceNode to the result of splitting it with offset range’s start offset.
if (is<Text>(*m_start_container))
reference_node = TRY(static_cast<Text&>(*m_start_container).split_text(m_start_offset));
// 8. If node is referenceNode, set referenceNode to its next sibling.
if (node == reference_node)
reference_node = reference_node->next_sibling();
// 9. If node’s parent is non-null, then remove node.
if (node->parent())
node->remove();
// 10. Let newOffset be parent’s length if referenceNode is null, and referenceNode’s index otherwise.
size_t new_offset = 0;
if (!reference_node)
new_offset = parent->length();
else
new_offset = reference_node->index();
// 11. Increase newOffset by node’s length if node is a DocumentFragment node, and one otherwise.
if (is<DocumentFragment>(*node))
new_offset += node->length();
else
new_offset += 1;
// 12. Pre-insert node into parent before referenceNode.
(void)TRY(parent->pre_insert(node, reference_node));
// 13. If range is collapsed, then set range’s end to (parent, newOffset).
if (collapsed())
TRY(set_end(*parent, new_offset));
return {};
}
// https://dom.spec.whatwg.org/#dom-range-surroundcontents
WebIDL::ExceptionOr<void> Range::surround_contents(JS::NonnullGCPtr<Node> new_parent)
{
// 1. If a non-Text node is partially contained in this, then throw an "InvalidStateError" DOMException.
Node* start_non_text_node = start_container();
if (is<Text>(*start_non_text_node))
start_non_text_node = start_non_text_node->parent_node();
Node* end_non_text_node = end_container();
if (is<Text>(*end_non_text_node))
end_non_text_node = end_non_text_node->parent_node();
if (start_non_text_node != end_non_text_node)
return WebIDL::InvalidStateError::create(realm(), "Non-Text node is partially contained in range.");
// 2. If newParent is a Document, DocumentType, or DocumentFragment node, then throw an "InvalidNodeTypeError" DOMException.
if (is<Document>(*new_parent) || is<DocumentType>(*new_parent) || is<DocumentFragment>(*new_parent))
return WebIDL::InvalidNodeTypeError::create(realm(), "Invalid parent node type");
// 3. Let fragment be the result of extracting this.
auto fragment = TRY(extract());
// 4. If newParent has children, then replace all with null within newParent.
if (new_parent->has_children())
new_parent->replace_all(nullptr);
// 5. Insert newParent into this.
TRY(insert(new_parent));
// 6. Append fragment to newParent.
(void)TRY(new_parent->append_child(fragment));
// 7. Select newParent within this.
return select(*new_parent);
}
// https://dom.spec.whatwg.org/#dom-range-clonecontents
WebIDL::ExceptionOr<JS::NonnullGCPtr<DocumentFragment>> Range::clone_contents()
{
return clone_the_contents();
}
// https://dom.spec.whatwg.org/#concept-range-clone
WebIDL::ExceptionOr<JS::NonnullGCPtr<DocumentFragment>> Range::clone_the_contents()
{
// 1. Let fragment be a new DocumentFragment node whose node document is range’s start node’s node document.
auto fragment = MUST_OR_THROW_OOM(heap().allocate<DOM::DocumentFragment>(realm(), const_cast<Document&>(start_container()->document())));
// 2. If range is collapsed, then return fragment.
if (collapsed())
return fragment;
// 3. Let original start node, original start offset, original end node, and original end offset
// be range’s start node, start offset, end node, and end offset, respectively.
JS::NonnullGCPtr<Node> original_start_node = m_start_container;
auto original_start_offset = m_start_offset;
JS::NonnullGCPtr<Node> original_end_node = m_end_container;
auto original_end_offset = m_end_offset;
// 4. If original start node is original end node and it is a CharacterData node, then:
if (original_start_node.ptr() == original_end_node.ptr() && is<CharacterData>(*original_start_node)) {
// 1. Let clone be a clone of original start node.
auto clone = original_start_node->clone_node();
// 2. Set the data of clone to the result of substringing data with node original start node,
// offset original start offset, and count original end offset minus original start offset.
auto result = TRY(static_cast<CharacterData const&>(*original_start_node).substring_data(original_start_offset, original_end_offset - original_start_offset));
verify_cast<CharacterData>(*clone).set_data(move(result));
// 3. Append clone to fragment.
TRY(fragment->append_child(clone));
// 4. Return fragment.
return fragment;
}
// 5. Let common ancestor be original start node.
JS::NonnullGCPtr<Node> common_ancestor = original_start_node;
// 6. While common ancestor is not an inclusive ancestor of original end node, set common ancestor to its own parent.
while (!common_ancestor->is_inclusive_ancestor_of(original_end_node))
common_ancestor = *common_ancestor->parent_node();
// 7. Let first partially contained child be null.
JS::GCPtr<Node> first_partially_contained_child;
// 8. If original start node is not an inclusive ancestor of original end node,
// set first partially contained child to the first child of common ancestor that is partially contained in range.
if (!original_start_node->is_inclusive_ancestor_of(original_end_node)) {
for (auto* child = common_ancestor->first_child(); child; child = child->next_sibling()) {
if (partially_contains_node(*child)) {
first_partially_contained_child = child;
break;
}
}
}
// 9. Let last partially contained child be null.
JS::GCPtr<Node> last_partially_contained_child;
// 10. If original end node is not an inclusive ancestor of original start node,
// set last partially contained child to the last child of common ancestor that is partially contained in range.
if (!original_end_node->is_inclusive_ancestor_of(original_start_node)) {
for (auto* child = common_ancestor->last_child(); child; child = child->previous_sibling()) {
if (partially_contains_node(*child)) {
last_partially_contained_child = child;
break;
}
}
}
// 11. Let contained children be a list of all children of common ancestor that are contained in range, in tree order.
Vector<JS::NonnullGCPtr<Node>> contained_children;
for (Node* node = common_ancestor->first_child(); node; node = node->next_sibling()) {
if (contains_node(*node))
contained_children.append(*node);
}
// 12. If any member of contained children is a doctype, then throw a "HierarchyRequestError" DOMException.
for (auto const& child : contained_children) {
if (is<DocumentType>(*child))
return WebIDL::HierarchyRequestError::create(realm(), "Contained child is a DocumentType");
}
// 13. If first partially contained child is a CharacterData node, then:
if (first_partially_contained_child && is<CharacterData>(*first_partially_contained_child)) {
// 1. Let clone be a clone of original start node.
auto clone = original_start_node->clone_node();
// 2. Set the data of clone to the result of substringing data with node original start node, offset original start offset,
// and count original start node’s length minus original start offset.
auto result = TRY(static_cast<CharacterData const&>(*original_start_node).substring_data(original_start_offset, original_start_node->length() - original_start_offset));
verify_cast<CharacterData>(*clone).set_data(move(result));
// 3. Append clone to fragment.
TRY(fragment->append_child(clone));
}
// 14. Otherwise, if first partially contained child is not null:
else if (first_partially_contained_child) {
// 1. Let clone be a clone of first partially contained child.
auto clone = first_partially_contained_child->clone_node();
// 2. Append clone to fragment.
TRY(fragment->append_child(clone));
// 3. Let subrange be a new live range whose start is (original start node, original start offset) and whose end is (first partially contained child, first partially contained child’s length).
auto subrange = TRY(Range::create(original_start_node, original_start_offset, *first_partially_contained_child, first_partially_contained_child->length()));
// 4. Let subfragment be the result of cloning the contents of subrange.
auto subfragment = TRY(subrange->clone_the_contents());
// 5. Append subfragment to clone.
TRY(clone->append_child(subfragment));
}
// 15. For each contained child in contained children.
for (auto& contained_child : contained_children) {
// 1. Let clone be a clone of contained child with the clone children flag set.
auto clone = contained_child->clone_node(nullptr, true);
// 2. Append clone to fragment.
TRY(fragment->append_child(move(clone)));
}
// 16. If last partially contained child is a CharacterData node, then:
if (last_partially_contained_child && is<CharacterData>(*last_partially_contained_child)) {
// 1. Let clone be a clone of original end node.
auto clone = original_end_node->clone_node();
// 2. Set the data of clone to the result of substringing data with node original end node, offset 0, and count original end offset.
auto result = TRY(static_cast<CharacterData const&>(*original_end_node).substring_data(0, original_end_offset));
verify_cast<CharacterData>(*clone).set_data(move(result));
// 3. Append clone to fragment.
TRY(fragment->append_child(clone));
}
// 17. Otherwise, if last partially contained child is not null:
else if (last_partially_contained_child) {
// 1. Let clone be a clone of last partially contained child.
auto clone = last_partially_contained_child->clone_node();
// 2. Append clone to fragment.
TRY(fragment->append_child(clone));
// 3. Let subrange be a new live range whose start is (last partially contained child, 0) and whose end is (original end node, original end offset).
auto subrange = TRY(Range::create(*last_partially_contained_child, 0, original_end_node, original_end_offset));
// 4. Let subfragment be the result of cloning the contents of subrange.
auto subfragment = TRY(subrange->clone_the_contents());
// 5. Append subfragment to clone.
TRY(clone->append_child(subfragment));
}
// 18. Return fragment.
return fragment;
}
// https://dom.spec.whatwg.org/#dom-range-deletecontents
WebIDL::ExceptionOr<void> Range::delete_contents()
{
// 1. If this is collapsed, then return.
if (collapsed())
return {};
// 2. Let original start node, original start offset, original end node, and original end offset be this’s start node, start offset, end node, and end offset, respectively.
JS::NonnullGCPtr<Node> original_start_node = m_start_container;
auto original_start_offset = m_start_offset;
JS::NonnullGCPtr<Node> original_end_node = m_end_container;
auto original_end_offset = m_end_offset;
// 3. If original start node is original end node and it is a CharacterData node, then replace data with node original start node, offset original start offset,
// count original end offset minus original start offset, and data the empty string, and then return.
if (original_start_node.ptr() == original_end_node.ptr() && is<CharacterData>(*original_start_node)) {
TRY(static_cast<CharacterData&>(*original_start_node).replace_data(original_start_offset, original_end_offset - original_start_offset, ""));
return {};
}
// 4. Let nodes to remove be a list of all the nodes that are contained in this, in tree order, omitting any node whose parent is also contained in this.
JS::MarkedVector<Node*> nodes_to_remove(heap());
for (Node const* node = start_container(); node != end_container()->next_in_pre_order(); node = node->next_in_pre_order()) {
if (contains_node(*node) && (!node->parent_node() || !contains_node(*node->parent_node())))
nodes_to_remove.append(const_cast<Node*>(node));
}
JS::GCPtr<Node> new_node;
size_t new_offset = 0;
// 5. If original start node is an inclusive ancestor of original end node, set new node to original start node and new offset to original start offset.
if (original_start_node->is_inclusive_ancestor_of(original_end_node)) {
new_node = original_start_node;
new_offset = original_start_offset;
}
// 6. Otherwise
else {
// 1. Let reference node equal original start node.
auto reference_node = original_start_node;
// 2. While reference node’s parent is not null and is not an inclusive ancestor of original end node, set reference node to its parent.
while (reference_node->parent_node() && !reference_node->parent_node()->is_inclusive_ancestor_of(original_end_node))
reference_node = *reference_node->parent_node();
// 3. Set new node to the parent of reference node, and new offset to one plus the index of reference node.
new_node = reference_node->parent_node();
new_offset = 1 + reference_node->index();
}
// 7. If original start node is a CharacterData node, then replace data with node original start node, offset original start offset, count original start node’s length minus original start offset, data the empty string.
if (is<CharacterData>(*original_start_node))
TRY(static_cast<CharacterData&>(*original_start_node).replace_data(original_start_offset, original_start_node->length() - original_start_offset, ""));
// 8. For each node in nodes to remove, in tree order, remove node.
for (auto& node : nodes_to_remove)
node->remove();
// 9. If original end node is a CharacterData node, then replace data with node original end node, offset 0, count original end offset and data the empty string.
if (is<CharacterData>(*original_end_node))
TRY(static_cast<CharacterData&>(*original_end_node).replace_data(0, original_end_offset, ""));
// 10. Set start and end to (new node, new offset).
TRY(set_start(*new_node, new_offset));
TRY(set_end(*new_node, new_offset));
return {};
}
// https://w3c.github.io/csswg-drafts/cssom-view/#dom-range-getboundingclientrect
JS::NonnullGCPtr<Geometry::DOMRect> Range::get_bounding_client_rect() const
{
dbgln("(STUBBED) Range::get_bounding_client_rect()");
return Geometry::DOMRect::construct_impl(realm(), 0, 0, 0, 0).release_value_but_fixme_should_propagate_errors();
}
// https://w3c.github.io/DOM-Parsing/#dom-range-createcontextualfragment
WebIDL::ExceptionOr<JS::NonnullGCPtr<DocumentFragment>> Range::create_contextual_fragment(DeprecatedString const& fragment)
{
// 1. Let node be the context object's start node.
JS::NonnullGCPtr<Node> node = *start_container();
// Let element be as follows, depending on node's interface:
JS::GCPtr<Element> element;
switch (static_cast<NodeType>(node->node_type())) {
case NodeType::DOCUMENT_NODE:
case NodeType::DOCUMENT_FRAGMENT_NODE:
element = nullptr;
break;
case NodeType::ELEMENT_NODE:
element = static_cast<DOM::Element&>(*node);
break;
case NodeType::TEXT_NODE:
case NodeType::COMMENT_NODE:
element = node->parent_element();
break;
case NodeType::DOCUMENT_TYPE_NODE:
case NodeType::PROCESSING_INSTRUCTION_NODE:
// [DOM4] prevents this case.
VERIFY_NOT_REACHED();
default:
VERIFY_NOT_REACHED();
}
// 2. If either element is null or the following are all true:
// - element's node document is an HTML document,
// - element's local name is "html", and
// - element's namespace is the HTML namespace;
if (!element || is<HTML::HTMLHtmlElement>(*element)) {
// let element be a new Element with
// - "body" as its local name,
// - The HTML namespace as its namespace, and
// - The context object's node document as its node document.
element = TRY(DOM::create_element(node->document(), "body"sv, Namespace::HTML));
}
// 3. Let fragment node be the result of invoking the fragment parsing algorithm with fragment as markup, and element as the context element.
auto fragment_node = TRY(DOMParsing::parse_fragment(fragment, *element));
// 4. Unmark all scripts in fragment node as "already started" and as "parser-inserted".
fragment_node->for_each_in_subtree_of_type<HTML::HTMLScriptElement>([&](HTML::HTMLScriptElement& script_element) {
script_element.unmark_as_already_started({});
script_element.unmark_as_parser_inserted({});
return IterationDecision::Continue;
});
// 5. Return the value of fragment node.
return fragment_node;
}
}