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slint/internal/core/item_tree.rs
Olivier Goffart af573e6401
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vtable: Don't automatically add extern C
2025-06-06 14:47:46 +02:00

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// Copyright © SixtyFPS GmbH <info@slint.dev>
// SPDX-License-Identifier: GPL-3.0-only OR LicenseRef-Slint-Royalty-free-2.0 OR LicenseRef-Slint-Software-3.0
// cSpell: ignore xffff
//! This module contains the ItemTree and code that helps navigating it
use crate::accessibility::{
AccessibilityAction, AccessibleStringProperty, SupportedAccessibilityAction,
};
use crate::items::{AccessibleRole, ItemRef, ItemVTable};
use crate::layout::{LayoutInfo, Orientation};
use crate::lengths::{ItemTransform, LogicalPoint, LogicalRect};
use crate::slice::Slice;
use crate::window::WindowAdapterRc;
use crate::SharedString;
use alloc::vec::Vec;
use core::ops::ControlFlow;
use core::pin::Pin;
use vtable::*;
#[repr(C)]
#[derive(Debug, Clone, Copy)]
/// A range of indices
pub struct IndexRange {
/// Start index
pub start: usize,
/// Index one past the last index
pub end: usize,
}
impl From<core::ops::Range<usize>> for IndexRange {
fn from(r: core::ops::Range<usize>) -> Self {
Self { start: r.start, end: r.end }
}
}
impl From<IndexRange> for core::ops::Range<usize> {
fn from(r: IndexRange) -> Self {
Self { start: r.start, end: r.end }
}
}
/// A ItemTree is representing an unit that is allocated together
#[cfg_attr(not(feature = "ffi"), i_slint_core_macros::remove_extern)]
#[vtable]
#[repr(C)]
pub struct ItemTreeVTable {
/// Visit the children of the item at index `index`.
/// Note that the root item is at index 0, so passing 0 would visit the item under root (the children of root).
/// If you want to visit the root item, you need to pass -1 as an index.
pub visit_children_item: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
index: isize,
order: TraversalOrder,
visitor: VRefMut<ItemVisitorVTable>,
) -> VisitChildrenResult,
/// Return a reference to an item using the given index
pub get_item_ref: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
index: u32,
) -> core::pin::Pin<VRef<ItemVTable>>,
/// Return the range of indices below the dynamic `ItemTreeNode` at `index`
pub get_subtree_range:
extern "C-unwind" fn(core::pin::Pin<VRef<ItemTreeVTable>>, index: u32) -> IndexRange,
/// Return the `ItemTreeRc` at `subindex` below the dynamic `ItemTreeNode` at `index`
pub get_subtree: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
index: u32,
subindex: usize,
result: &mut vtable::VWeak<ItemTreeVTable, Dyn>,
),
/// Return the item tree that is defined by this `ItemTree`.
/// The return value is an item weak because it can be null if there is no parent.
/// And the return value is passed by &mut because ItemWeak has a destructor
pub get_item_tree:
extern "C-unwind" fn(core::pin::Pin<VRef<ItemTreeVTable>>) -> Slice<ItemTreeNode>,
/// Return the node this ItemTree is a part of in the parent ItemTree.
///
/// The return value is an item weak because it can be null if there is no parent.
/// And the return value is passed by &mut because ItemWeak has a destructor
/// Note that the returned value will typically point to a repeater node, which is
/// strictly speaking not an Item at all!
pub parent_node:
extern "C-unwind" fn(core::pin::Pin<VRef<ItemTreeVTable>>, result: &mut ItemWeak),
/// This embeds this ItemTree into the item tree of another ItemTree
///
/// Returns `true` if this ItemTree was embedded into the `parent`
/// at `parent_item_tree_index`.
pub embed_component: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
parent: &VWeak<ItemTreeVTable>,
parent_item_tree_index: u32,
) -> bool,
/// Return the index of the current subtree or usize::MAX if this is not a subtree
pub subtree_index: extern "C-unwind" fn(core::pin::Pin<VRef<ItemTreeVTable>>) -> usize,
/// Returns the layout info for the root of the ItemTree
pub layout_info:
extern "C-unwind" fn(core::pin::Pin<VRef<ItemTreeVTable>>, Orientation) -> LayoutInfo,
/// Returns the item's geometry (relative to its parent item)
pub item_geometry:
extern "C-unwind" fn(core::pin::Pin<VRef<ItemTreeVTable>>, item_index: u32) -> LogicalRect,
/// Returns the accessible role for a given item
pub accessible_role: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
item_index: u32,
) -> AccessibleRole,
/// Returns the accessible property via the `result`. Returns true if such a property exists.
pub accessible_string_property: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
item_index: u32,
what: AccessibleStringProperty,
result: &mut SharedString,
) -> bool,
/// Executes an accessibility action.
pub accessibility_action: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
item_index: u32,
action: &AccessibilityAction,
),
/// Returns the supported accessibility actions.
pub supported_accessibility_actions: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
item_index: u32,
) -> SupportedAccessibilityAction,
/// Add the `ElementName::id` entries of the given item
pub item_element_infos: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
item_index: u32,
result: &mut SharedString,
) -> bool,
/// Returns a Window, creating a fresh one if `do_create` is true.
pub window_adapter: extern "C-unwind" fn(
core::pin::Pin<VRef<ItemTreeVTable>>,
do_create: bool,
result: &mut Option<WindowAdapterRc>,
),
/// in-place destructor (for VRc)
pub drop_in_place: unsafe extern "C-unwind" fn(VRefMut<ItemTreeVTable>) -> vtable::Layout,
/// dealloc function (for VRc)
pub dealloc: unsafe extern "C-unwind" fn(&ItemTreeVTable, ptr: *mut u8, layout: vtable::Layout),
}
#[cfg(test)]
pub(crate) use ItemTreeVTable_static;
/// Alias for `vtable::VRef<ItemTreeVTable>` which represent a pointer to a `dyn ItemTree` with
/// the associated vtable
pub type ItemTreeRef<'a> = vtable::VRef<'a, ItemTreeVTable>;
/// Type alias to the commonly used `Pin<VRef<ItemTreeVTable>>>`
pub type ItemTreeRefPin<'a> = core::pin::Pin<ItemTreeRef<'a>>;
/// Type alias to the commonly used VRc<ItemTreeVTable, Dyn>>
pub type ItemTreeRc = vtable::VRc<ItemTreeVTable, Dyn>;
/// Type alias to the commonly used VWeak<ItemTreeVTable, Dyn>>
pub type ItemTreeWeak = vtable::VWeak<ItemTreeVTable, Dyn>;
/// Call init() on the ItemVTable for each item of the ItemTree.
pub fn register_item_tree(item_tree_rc: &ItemTreeRc, window_adapter: Option<WindowAdapterRc>) {
let c = vtable::VRc::borrow_pin(item_tree_rc);
let item_tree = c.as_ref().get_item_tree();
item_tree.iter().enumerate().for_each(|(tree_index, node)| {
let tree_index = tree_index as u32;
if let ItemTreeNode::Item { .. } = &node {
let item = ItemRc::new(item_tree_rc.clone(), tree_index);
c.as_ref().get_item_ref(tree_index).as_ref().init(&item);
}
});
if let Some(adapter) = window_adapter.as_ref().and_then(|a| a.internal(crate::InternalToken)) {
adapter.register_item_tree();
}
}
/// Free the backend graphics resources allocated by the ItemTree's items.
pub fn unregister_item_tree<Base>(
base: core::pin::Pin<&Base>,
item_tree: ItemTreeRef,
item_array: &[vtable::VOffset<Base, ItemVTable, vtable::AllowPin>],
window_adapter: &WindowAdapterRc,
) {
window_adapter.renderer().free_graphics_resources(
item_tree,
&mut item_array.iter().map(|item| item.apply_pin(base)),
).expect("Fatal error encountered when freeing graphics resources while destroying Slint component");
if let Some(w) = window_adapter.internal(crate::InternalToken) {
w.unregister_item_tree(item_tree, &mut item_array.iter().map(|item| item.apply_pin(base)));
}
}
fn find_sibling_outside_repeater(
component: &ItemTreeRc,
comp_ref_pin: Pin<VRef<ItemTreeVTable>>,
index: u32,
sibling_step: &dyn Fn(&crate::item_tree::ItemTreeNodeArray, u32) -> Option<u32>,
subtree_child: &dyn Fn(usize, usize) -> usize,
) -> Option<ItemRc> {
assert_ne!(index, 0);
let item_tree = crate::item_tree::ItemTreeNodeArray::new(&comp_ref_pin);
let mut current_sibling = index;
loop {
current_sibling = sibling_step(&item_tree, current_sibling)?;
if let Some(node) = step_into_node(
component,
&comp_ref_pin,
current_sibling,
&item_tree,
subtree_child,
&core::convert::identity,
) {
return Some(node);
}
}
}
fn step_into_node(
component: &ItemTreeRc,
comp_ref_pin: &Pin<VRef<ItemTreeVTable>>,
node_index: u32,
item_tree: &crate::item_tree::ItemTreeNodeArray,
subtree_child: &dyn Fn(usize, usize) -> usize,
wrap_around: &dyn Fn(ItemRc) -> ItemRc,
) -> Option<ItemRc> {
match item_tree.get(node_index).expect("Invalid index passed to item tree") {
crate::item_tree::ItemTreeNode::Item { .. } => {
Some(ItemRc::new(component.clone(), node_index))
}
crate::item_tree::ItemTreeNode::DynamicTree { index, .. } => {
let range = comp_ref_pin.as_ref().get_subtree_range(*index);
let component_index = subtree_child(range.start, range.end);
let mut child_instance = Default::default();
comp_ref_pin.as_ref().get_subtree(*index, component_index, &mut child_instance);
child_instance
.upgrade()
.map(|child_instance| wrap_around(ItemRc::new(child_instance, 0)))
}
}
}
pub enum ParentItemTraversalMode {
FindAllParents,
StopAtPopups,
}
/// A ItemRc is holding a reference to a ItemTree containing the item, and the index of this item
#[repr(C)]
#[derive(Clone, Debug)]
pub struct ItemRc {
item_tree: vtable::VRc<ItemTreeVTable>,
index: u32,
}
impl ItemRc {
/// Create an ItemRc from a ItemTree and an index
pub fn new(item_tree: vtable::VRc<ItemTreeVTable>, index: u32) -> Self {
Self { item_tree, index }
}
pub fn is_root_item_of(&self, item_tree: &VRc<ItemTreeVTable>) -> bool {
self.index == 0 && VRc::ptr_eq(&self.item_tree, item_tree)
}
/// Return a `Pin<ItemRef<'a>>`
pub fn borrow<'a>(&'a self) -> Pin<ItemRef<'a>> {
#![allow(unsafe_code)]
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let result = comp_ref_pin.as_ref().get_item_ref(self.index);
// Safety: we can expand the lifetime of the ItemRef because we know it lives for at least the
// lifetime of the ItemTree, which is 'a. Pin::as_ref removes the lifetime, but we can just put it back.
unsafe { core::mem::transmute::<Pin<ItemRef<'_>>, Pin<ItemRef<'a>>>(result) }
}
/// Returns a `VRcMapped` of this item, to conveniently access specialized item API.
pub fn downcast<T: HasStaticVTable<ItemVTable>>(&self) -> Option<VRcMapped<ItemTreeVTable, T>> {
#![allow(unsafe_code)]
let item = self.borrow();
ItemRef::downcast_pin::<T>(item)?;
Some(vtable::VRc::map_dyn(self.item_tree.clone(), |comp_ref_pin| {
let result = comp_ref_pin.as_ref().get_item_ref(self.index);
// Safety: we can expand the lifetime of the ItemRef because we know it lives for at least the
// lifetime of the ItemTree, which is 'a. Pin::as_ref removes the lifetime, but we can just put it back.
let item =
unsafe { core::mem::transmute::<Pin<ItemRef<'_>>, Pin<ItemRef<'_>>>(result) };
ItemRef::downcast_pin::<T>(item).unwrap()
}))
}
pub fn downgrade(&self) -> ItemWeak {
ItemWeak { item_tree: VRc::downgrade(&self.item_tree), index: self.index }
}
/// Return the parent Item in the item tree.
///
/// If the item is a the root on its Window or PopupWindow, then the parent is None.
pub fn parent_item(&self, find_mode: ParentItemTraversalMode) -> Option<ItemRc> {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let item_tree = crate::item_tree::ItemTreeNodeArray::new(&comp_ref_pin);
if let Some(parent_index) = item_tree.parent(self.index) {
return Some(ItemRc::new(self.item_tree.clone(), parent_index));
}
let mut r = ItemWeak::default();
comp_ref_pin.as_ref().parent_node(&mut r);
let parent = r.upgrade()?;
let comp_ref_pin = vtable::VRc::borrow_pin(&parent.item_tree);
let item_tree_array = crate::item_tree::ItemTreeNodeArray::new(&comp_ref_pin);
if let Some(ItemTreeNode::DynamicTree { parent_index, .. }) =
item_tree_array.get(parent.index())
{
// parent_node returns the repeater node, go up one more level!
Some(ItemRc::new(parent.item_tree.clone(), *parent_index))
} else {
// the Item was most likely a PopupWindow and we don't want to return the item for the purpose of this call
// (eg, focus/geometry/...)
match find_mode {
ParentItemTraversalMode::FindAllParents => Some(parent),
ParentItemTraversalMode::StopAtPopups => None,
}
}
}
/// Returns true if this item is visible from the root of the item tree. Note that this will return
/// false for `Clip` elements with the `clip` property evaluating to true.
pub fn is_visible(&self) -> bool {
let (clip, geometry) = self.absolute_clip_rect_and_geometry();
let clip = clip.to_box2d();
let geometry = geometry.to_box2d();
!clip.is_empty()
&& clip.max.x >= geometry.min.x
&& clip.max.y >= geometry.min.y
&& clip.min.x <= geometry.max.x
&& clip.min.y <= geometry.max.y
}
/// Returns the clip rect that applies to this item (in window coordinates) as well as the
/// item's (unclipped) geometry (also in window coordinates).
fn absolute_clip_rect_and_geometry(&self) -> (LogicalRect, LogicalRect) {
let (mut clip, parent_geometry) =
self.parent_item(ParentItemTraversalMode::StopAtPopups).map_or_else(
|| {
(
LogicalRect::from_size((crate::Coord::MAX, crate::Coord::MAX).into()),
Default::default(),
)
},
|parent| parent.absolute_clip_rect_and_geometry(),
);
let geometry = self.geometry().translate(parent_geometry.origin.to_vector());
let item = self.borrow();
if item.as_ref().clips_children() {
clip = geometry.intersection(&clip).unwrap_or_default();
}
(clip, geometry)
}
pub fn is_accessible(&self) -> bool {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let item_tree = crate::item_tree::ItemTreeNodeArray::new(&comp_ref_pin);
if let Some(n) = &item_tree.get(self.index) {
match n {
ItemTreeNode::Item { is_accessible, .. } => *is_accessible,
ItemTreeNode::DynamicTree { .. } => false,
}
} else {
false
}
}
pub fn accessible_role(&self) -> crate::items::AccessibleRole {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
comp_ref_pin.as_ref().accessible_role(self.index)
}
pub fn accessible_string_property(
&self,
what: crate::accessibility::AccessibleStringProperty,
) -> Option<SharedString> {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let mut result = Default::default();
let ok = comp_ref_pin.as_ref().accessible_string_property(self.index, what, &mut result);
ok.then_some(result)
}
pub fn accessible_action(&self, action: &crate::accessibility::AccessibilityAction) {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
comp_ref_pin.as_ref().accessibility_action(self.index, action);
}
pub fn supported_accessibility_actions(&self) -> SupportedAccessibilityAction {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
comp_ref_pin.as_ref().supported_accessibility_actions(self.index)
}
pub fn element_count(&self) -> Option<usize> {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let mut result = SharedString::new();
comp_ref_pin
.as_ref()
.item_element_infos(self.index, &mut result)
.then(|| result.as_str().split("/").count())
}
pub fn element_type_names_and_ids(
&self,
element_index: usize,
) -> Option<Vec<(SharedString, SharedString)>> {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let mut result = SharedString::new();
comp_ref_pin.as_ref().item_element_infos(self.index, &mut result).then(|| {
result
.as_str()
.split("/")
.nth(element_index)
.unwrap()
.split(";")
.map(|encoded_elem_info| {
let mut decoder = encoded_elem_info.split(',');
let type_name = decoder.next().unwrap().into();
let id = decoder.next().map(Into::into).unwrap_or_default();
(type_name, id)
})
.collect()
})
}
pub fn geometry(&self) -> LogicalRect {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
comp_ref_pin.as_ref().item_geometry(self.index)
}
pub fn bounding_rect(
&self,
geometry: &LogicalRect,
window_adapter: &WindowAdapterRc,
) -> LogicalRect {
self.borrow().as_ref().bounding_rect(window_adapter, self, *geometry)
}
/// Returns an absolute position of `p` in the parent item coordinate system
/// (does not add this item's x and y)
pub fn map_to_window(&self, p: LogicalPoint) -> LogicalPoint {
let mut current = self.clone();
let mut result = p;
while let Some(parent) = current.parent_item(ParentItemTraversalMode::StopAtPopups) {
let geometry = parent.geometry();
result += geometry.origin.to_vector();
current = parent.clone();
}
result
}
/// Returns an absolute position of `p` in the `ItemTree`'s coordinate system
/// (does not add this item's x and y)
pub fn map_to_item_tree(
&self,
p: LogicalPoint,
item_tree: &vtable::VRc<ItemTreeVTable>,
) -> LogicalPoint {
let mut current = self.clone();
let mut result = p;
if current.is_root_item_of(item_tree) {
return result;
}
while let Some(parent) = current.parent_item(ParentItemTraversalMode::StopAtPopups) {
if parent.is_root_item_of(item_tree) {
break;
}
let geometry = parent.geometry();
result += geometry.origin.to_vector();
current = parent.clone();
}
result
}
/// Return the index of the item within the ItemTree
pub fn index(&self) -> u32 {
self.index
}
/// Returns a reference to the ItemTree holding this item
pub fn item_tree(&self) -> &vtable::VRc<ItemTreeVTable> {
&self.item_tree
}
fn find_child(
&self,
child_access: &dyn Fn(&crate::item_tree::ItemTreeNodeArray, u32) -> Option<u32>,
child_step: &dyn Fn(&crate::item_tree::ItemTreeNodeArray, u32) -> Option<u32>,
subtree_child: &dyn Fn(usize, usize) -> usize,
) -> Option<Self> {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let item_tree = crate::item_tree::ItemTreeNodeArray::new(&comp_ref_pin);
let mut current_child_index = child_access(&item_tree, self.index())?;
loop {
if let Some(item) = step_into_node(
self.item_tree(),
&comp_ref_pin,
current_child_index,
&item_tree,
subtree_child,
&core::convert::identity,
) {
return Some(item);
}
current_child_index = child_step(&item_tree, current_child_index)?;
}
}
/// The first child Item of this Item
pub fn first_child(&self) -> Option<Self> {
self.find_child(
&|item_tree, index| item_tree.first_child(index),
&|item_tree, index| item_tree.next_sibling(index),
&|start, _| start,
)
}
/// The last child Item of this Item
pub fn last_child(&self) -> Option<Self> {
self.find_child(
&|item_tree, index| item_tree.last_child(index),
&|item_tree, index| item_tree.previous_sibling(index),
&|_, end| end.wrapping_sub(1),
)
}
fn find_sibling(
&self,
sibling_step: &dyn Fn(&crate::item_tree::ItemTreeNodeArray, u32) -> Option<u32>,
subtree_step: &dyn Fn(usize) -> usize,
subtree_child: &dyn Fn(usize, usize) -> usize,
) -> Option<Self> {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
if self.index == 0 {
let mut parent_item = Default::default();
comp_ref_pin.as_ref().parent_node(&mut parent_item);
let current_component_subtree_index = comp_ref_pin.as_ref().subtree_index();
if let Some(parent_item) = parent_item.upgrade() {
let parent = parent_item.item_tree();
let parent_ref_pin = vtable::VRc::borrow_pin(parent);
let parent_item_index = parent_item.index();
let parent_item_tree = crate::item_tree::ItemTreeNodeArray::new(&parent_ref_pin);
let subtree_index = match parent_item_tree.get(parent_item_index)? {
crate::item_tree::ItemTreeNode::Item { .. } => {
// Popups can trigger this case!
return None;
}
crate::item_tree::ItemTreeNode::DynamicTree { index, .. } => *index,
};
let next_subtree_index = subtree_step(current_component_subtree_index);
// Get next subtree from repeater!
let mut next_subtree_instance = Default::default();
parent_ref_pin.as_ref().get_subtree(
subtree_index,
next_subtree_index,
&mut next_subtree_instance,
);
if let Some(next_subtree_instance) = next_subtree_instance.upgrade() {
return Some(ItemRc::new(next_subtree_instance, 0));
}
// We need to leave the repeater:
find_sibling_outside_repeater(
parent,
parent_ref_pin,
parent_item_index,
sibling_step,
subtree_child,
)
} else {
None // At root if the item tree
}
} else {
find_sibling_outside_repeater(
self.item_tree(),
comp_ref_pin,
self.index(),
sibling_step,
subtree_child,
)
}
}
/// The previous sibling of this Item
pub fn previous_sibling(&self) -> Option<Self> {
self.find_sibling(
&|item_tree, index| item_tree.previous_sibling(index),
&|index| index.wrapping_sub(1),
&|_, end| end.wrapping_sub(1),
)
}
/// The next sibling of this Item
pub fn next_sibling(&self) -> Option<Self> {
self.find_sibling(
&|item_tree, index| item_tree.next_sibling(index),
&|index| index.saturating_add(1),
&|start, _| start,
)
}
fn move_focus(
&self,
focus_step: &dyn Fn(&crate::item_tree::ItemTreeNodeArray, u32) -> Option<u32>,
subtree_step: &dyn Fn(ItemRc) -> Option<ItemRc>,
subtree_child: &dyn Fn(usize, usize) -> usize,
step_in: &dyn Fn(ItemRc) -> ItemRc,
step_out: &dyn Fn(&crate::item_tree::ItemTreeNodeArray, u32) -> Option<u32>,
) -> Self {
let mut component = self.item_tree().clone();
let mut comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let mut item_tree = crate::item_tree::ItemTreeNodeArray::new(&comp_ref_pin);
let mut to_focus = self.index();
'in_tree: loop {
if let Some(next) = focus_step(&item_tree, to_focus) {
if let Some(item) = step_into_node(
&component,
&comp_ref_pin,
next,
&item_tree,
subtree_child,
step_in,
) {
return item;
}
to_focus = next;
// Loop: We stepped into an empty repeater!
} else {
// Step out of this component:
let mut root = ItemRc::new(component, 0);
if let Some(item) = subtree_step(root.clone()) {
// Next component inside same repeater
return step_in(item);
}
// Step out of the repeater
let root_component = root.item_tree();
let root_comp_ref = vtable::VRc::borrow_pin(root_component);
let mut parent_node = Default::default();
root_comp_ref.as_ref().parent_node(&mut parent_node);
while let Some(parent) = parent_node.upgrade() {
// .. not at the root of the item tree:
component = parent.item_tree().clone();
comp_ref_pin = vtable::VRc::borrow_pin(&component);
item_tree = crate::item_tree::ItemTreeNodeArray::new(&comp_ref_pin);
let index = parent.index();
if !matches!(item_tree.get(index), Some(ItemTreeNode::DynamicTree { .. })) {
// That was not a repeater (eg, a popup window)
break;
}
if let Some(next) = step_out(&item_tree, index) {
if let Some(item) = step_into_node(
parent.item_tree(),
&comp_ref_pin,
next,
&item_tree,
subtree_child,
step_in,
) {
// Step into a dynamic node
return item;
} else {
// The dynamic node was empty, proceed in normal tree
to_focus = parent.index();
continue 'in_tree; // Find a node in the current (parent!) tree
}
}
root = ItemRc::new(component.clone(), 0);
if let Some(item) = subtree_step(root.clone()) {
return step_in(item);
}
// Go up one more level:
let root_component = root.item_tree();
let root_comp_ref = vtable::VRc::borrow_pin(root_component);
parent_node = Default::default();
root_comp_ref.as_ref().parent_node(&mut parent_node);
}
// Loop around after hitting the root node:
return step_in(root);
}
}
}
/// Move tab focus to the previous item:
pub fn previous_focus_item(&self) -> Self {
self.move_focus(
&|item_tree, index| {
crate::item_focus::default_previous_in_local_focus_chain(index, item_tree)
},
&|root| root.previous_sibling(),
&|_, end| end.wrapping_sub(1),
&|root| {
let mut current = root;
loop {
if let Some(next) = current.last_child() {
current = next;
} else {
return current;
}
}
},
&|item_tree, index| item_tree.parent(index),
)
}
/// Move tab focus to the next item:
pub fn next_focus_item(&self) -> Self {
self.move_focus(
&|item_tree, index| {
crate::item_focus::default_next_in_local_focus_chain(index, item_tree)
},
&|root| root.next_sibling(),
&|start, _| start,
&core::convert::identity,
&|item_tree, index| crate::item_focus::step_out_of_node(index, item_tree),
)
}
pub fn window_adapter(&self) -> Option<WindowAdapterRc> {
let comp_ref_pin = vtable::VRc::borrow_pin(&self.item_tree);
let mut result = None;
comp_ref_pin.as_ref().window_adapter(false, &mut result);
result
}
/// Visit the children of this element and call the visitor to each of them, until the visitor returns [`ControlFlow::Break`].
/// When the visitor breaks, the function returns the value. If it doesn't break, the function returns None.
fn visit_descendants_impl<R>(
&self,
visitor: &mut impl FnMut(&ItemRc) -> ControlFlow<R>,
) -> Option<R> {
let mut result = None;
let mut actual_visitor = |item_tree: &ItemTreeRc,
index: u32,
_item_pin: core::pin::Pin<ItemRef>|
-> VisitChildrenResult {
let item_rc = ItemRc::new(item_tree.clone(), index);
match visitor(&item_rc) {
ControlFlow::Continue(_) => {
if let Some(x) = item_rc.visit_descendants_impl(visitor) {
result = Some(x);
return VisitChildrenResult::abort(index, 0);
}
}
ControlFlow::Break(x) => {
result = Some(x);
return VisitChildrenResult::abort(index, 0);
}
}
VisitChildrenResult::CONTINUE
};
vtable::new_vref!(let mut actual_visitor : VRefMut<ItemVisitorVTable> for ItemVisitor = &mut actual_visitor);
VRc::borrow_pin(self.item_tree()).as_ref().visit_children_item(
self.index() as isize,
TraversalOrder::BackToFront,
actual_visitor,
);
result
}
/// Visit the children of this element and call the visitor to each of them, until the visitor returns [`ControlFlow::Break`].
/// When the visitor breaks, the function returns the value. If it doesn't break, the function returns None.
pub fn visit_descendants<R>(
&self,
mut visitor: impl FnMut(&ItemRc) -> ControlFlow<R>,
) -> Option<R> {
self.visit_descendants_impl(&mut visitor)
}
/// Returns the transform to apply to children to map them into the local coordinate space of this item.
/// Typically this is None, but rotation for example may return Some.
pub fn children_transform(&self) -> Option<ItemTransform> {
self.downcast::<crate::items::Rotate>().map(|rotate_item| {
let origin = euclid::Vector2D::<f32, crate::lengths::LogicalPx>::from_lengths(
rotate_item.as_pin_ref().rotation_origin_x().cast(),
rotate_item.as_pin_ref().rotation_origin_y().cast(),
);
ItemTransform::translation(-origin.x, -origin.y)
.cast()
.then_rotate(euclid::Angle {
radians: rotate_item.as_pin_ref().rotation_angle().to_radians(),
})
.then_translate(origin)
})
}
}
impl PartialEq for ItemRc {
fn eq(&self, other: &Self) -> bool {
VRc::ptr_eq(&self.item_tree, &other.item_tree) && self.index == other.index
}
}
impl Eq for ItemRc {}
/// A Weak reference to an item that can be constructed from an ItemRc.
#[derive(Clone, Default)]
#[repr(C)]
pub struct ItemWeak {
item_tree: crate::item_tree::ItemTreeWeak,
index: u32,
}
impl ItemWeak {
pub fn upgrade(&self) -> Option<ItemRc> {
self.item_tree.upgrade().map(|c| ItemRc::new(c, self.index))
}
}
impl PartialEq for ItemWeak {
fn eq(&self, other: &Self) -> bool {
VWeak::ptr_eq(&self.item_tree, &other.item_tree) && self.index == other.index
}
}
impl Eq for ItemWeak {}
#[repr(u8)]
#[derive(Debug, Copy, Clone, Eq, PartialEq)]
pub enum TraversalOrder {
BackToFront,
FrontToBack,
}
/// The return value of the ItemTree::visit_children_item function
///
/// Represents something like `enum { Continue, Aborted{aborted_at_item: isize} }`.
/// But this is just wrapping a int because it is easier to use ffi with isize than
/// complex enum.
///
/// -1 means the visitor will continue
/// otherwise this is the index of the item that aborted the visit.
#[repr(transparent)]
#[derive(Copy, Clone, Eq, PartialEq)]
pub struct VisitChildrenResult(u64);
impl VisitChildrenResult {
/// The result used for a visitor that want to continue the visit
pub const CONTINUE: Self = Self(u64::MAX);
/// Returns a result that means that the visitor must stop, and convey the item that caused the abort
pub fn abort(item_index: u32, index_within_repeater: usize) -> Self {
assert!(index_within_repeater < u32::MAX as usize);
Self(item_index as u64 | (index_within_repeater as u64) << 32)
}
/// True if the visitor wants to abort the visit
pub fn has_aborted(&self) -> bool {
self.0 != Self::CONTINUE.0
}
pub fn aborted_index(&self) -> Option<usize> {
if self.0 != Self::CONTINUE.0 {
Some((self.0 & 0xffff_ffff) as usize)
} else {
None
}
}
pub fn aborted_indexes(&self) -> Option<(usize, usize)> {
if self.0 != Self::CONTINUE.0 {
Some(((self.0 & 0xffff_ffff) as usize, (self.0 >> 32) as usize))
} else {
None
}
}
}
impl core::fmt::Debug for VisitChildrenResult {
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
if self.0 == Self::CONTINUE.0 {
write!(f, "CONTINUE")
} else {
write!(f, "({},{})", (self.0 & 0xffff_ffff) as usize, (self.0 >> 32) as usize)
}
}
}
/// The item tree is an array of ItemTreeNode representing a static tree of items
/// within a ItemTree.
#[repr(u8)]
#[derive(Debug)]
pub enum ItemTreeNode {
/// Static item
Item {
/// True when the item has accessibility properties attached
is_accessible: bool,
/// number of children
children_count: u32,
/// index of the first children within the item tree
children_index: u32,
/// The index of the parent item (not valid for the root)
parent_index: u32,
/// The index in the extra item_array
item_array_index: u32,
},
/// A placeholder for many instance of item in their own ItemTree which
/// are instantiated according to a model.
DynamicTree {
/// the index which is passed in the visit_dynamic callback.
index: u32,
/// The index of the parent item (not valid for the root)
parent_index: u32,
},
}
impl ItemTreeNode {
pub fn parent_index(&self) -> u32 {
match self {
ItemTreeNode::Item { parent_index, .. } => *parent_index,
ItemTreeNode::DynamicTree { parent_index, .. } => *parent_index,
}
}
}
/// The `ItemTreeNodeArray` provides tree walking code for the physical ItemTree stored in
/// a `ItemTree` without stitching any inter-ItemTree links together!
pub struct ItemTreeNodeArray<'a> {
node_array: &'a [ItemTreeNode],
}
impl<'a> ItemTreeNodeArray<'a> {
/// Create a new `ItemTree` from its raw data.
pub fn new(comp_ref_pin: &'a Pin<VRef<'a, ItemTreeVTable>>) -> Self {
Self { node_array: comp_ref_pin.as_ref().get_item_tree().as_slice() }
}
/// Get a ItemTreeNode
pub fn get(&self, index: u32) -> Option<&ItemTreeNode> {
self.node_array.get(index as usize)
}
/// Get the parent of a node, returns `None` if this is the root node of this item tree.
pub fn parent(&self, index: u32) -> Option<u32> {
let index = index as usize;
(index < self.node_array.len() && index != 0).then(|| self.node_array[index].parent_index())
}
/// Returns the next sibling or `None` if this is the last sibling.
pub fn next_sibling(&self, index: u32) -> Option<u32> {
if let Some(parent_index) = self.parent(index) {
match self.node_array[parent_index as usize] {
ItemTreeNode::Item { children_index, children_count, .. } => {
(index < (children_count + children_index - 1)).then_some(index + 1)
}
ItemTreeNode::DynamicTree { .. } => {
unreachable!("Parent in same item tree is a repeater.")
}
}
} else {
None // No parent, so we have no siblings either:-)
}
}
/// Returns the previous sibling or `None` if this is the first sibling.
pub fn previous_sibling(&self, index: u32) -> Option<u32> {
if let Some(parent_index) = self.parent(index) {
match self.node_array[parent_index as usize] {
ItemTreeNode::Item { children_index, .. } => {
(index > children_index).then_some(index - 1)
}
ItemTreeNode::DynamicTree { .. } => {
unreachable!("Parent in same item tree is a repeater.")
}
}
} else {
None // No parent, so we have no siblings either:-)
}
}
/// Returns the first child or `None` if this are no children or the `index`
/// points to a `DynamicTree`.
pub fn first_child(&self, index: u32) -> Option<u32> {
match self.node_array.get(index as usize)? {
ItemTreeNode::Item { children_index, children_count, .. } => {
(*children_count != 0).then_some(*children_index as _)
}
ItemTreeNode::DynamicTree { .. } => None,
}
}
/// Returns the last child or `None` if this are no children or the `index`
/// points to an `DynamicTree`.
pub fn last_child(&self, index: u32) -> Option<u32> {
match self.node_array.get(index as usize)? {
ItemTreeNode::Item { children_index, children_count, .. } => {
if *children_count != 0 {
Some(*children_index + *children_count - 1)
} else {
None
}
}
ItemTreeNode::DynamicTree { .. } => None,
}
}
/// Returns the number of nodes in the `ItemTreeNodeArray`
pub fn node_count(&self) -> usize {
self.node_array.len()
}
}
impl<'a> From<&'a [ItemTreeNode]> for ItemTreeNodeArray<'a> {
fn from(item_tree: &'a [ItemTreeNode]) -> Self {
Self { node_array: item_tree }
}
}
#[cfg_attr(not(feature = "ffi"), i_slint_core_macros::remove_extern)]
#[vtable]
#[repr(C)]
/// Object to be passed in visit_item_children method of the ItemTree.
pub struct ItemVisitorVTable {
/// Called for each child of the visited item
///
/// The `item_tree` parameter is the ItemTree in which the item live which might not be the same
/// as the parent's ItemTree.
/// `index` is to be used again in the visit_item_children function of the ItemTree (the one passed as parameter)
/// and `item` is a reference to the item itself
visit_item: extern "C-unwind" fn(
VRefMut<ItemVisitorVTable>,
item_tree: &VRc<ItemTreeVTable, vtable::Dyn>,
index: u32,
item: Pin<VRef<ItemVTable>>,
) -> VisitChildrenResult,
/// Destructor
drop: extern "C-unwind" fn(VRefMut<ItemVisitorVTable>),
}
/// Type alias to `vtable::VRefMut<ItemVisitorVTable>`
pub type ItemVisitorRefMut<'a> = vtable::VRefMut<'a, ItemVisitorVTable>;
impl<T: FnMut(&ItemTreeRc, u32, Pin<ItemRef>) -> VisitChildrenResult> ItemVisitor for T {
fn visit_item(
&mut self,
item_tree: &ItemTreeRc,
index: u32,
item: Pin<ItemRef>,
) -> VisitChildrenResult {
self(item_tree, index, item)
}
}
pub enum ItemVisitorResult<State> {
Continue(State),
Abort,
}
/// Visit each items recursively
///
/// The state parameter returned by the visitor is passed to each child.
///
/// Returns the index of the item that cancelled, or -1 if nobody cancelled
pub fn visit_items<State>(
item_tree: &ItemTreeRc,
order: TraversalOrder,
mut visitor: impl FnMut(&ItemTreeRc, Pin<ItemRef>, u32, &State) -> ItemVisitorResult<State>,
state: State,
) -> VisitChildrenResult {
visit_internal(item_tree, order, &mut visitor, -1, &state)
}
fn visit_internal<State>(
item_tree: &ItemTreeRc,
order: TraversalOrder,
visitor: &mut impl FnMut(&ItemTreeRc, Pin<ItemRef>, u32, &State) -> ItemVisitorResult<State>,
index: isize,
state: &State,
) -> VisitChildrenResult {
let mut actual_visitor =
|item_tree: &ItemTreeRc, index: u32, item: Pin<ItemRef>| -> VisitChildrenResult {
match visitor(item_tree, item, index, state) {
ItemVisitorResult::Continue(state) => {
visit_internal(item_tree, order, visitor, index as isize, &state)
}
ItemVisitorResult::Abort => VisitChildrenResult::abort(index, 0),
}
};
vtable::new_vref!(let mut actual_visitor : VRefMut<ItemVisitorVTable> for ItemVisitor = &mut actual_visitor);
VRc::borrow_pin(item_tree).as_ref().visit_children_item(index, order, actual_visitor)
}
/// Visit the children within an array of ItemTreeNode
///
/// The dynamic visitor is called for the dynamic nodes, its signature is
/// `fn(base: &Base, visitor: vtable::VRefMut<ItemVisitorVTable>, dyn_index: usize)`
///
/// FIXME: the design of this use lots of indirection and stack frame in recursive functions
/// Need to check if the compiler is able to optimize away some of it.
/// Possibly we should generate code that directly call the visitor instead
pub fn visit_item_tree<Base>(
base: Pin<&Base>,
item_tree: &ItemTreeRc,
item_tree_array: &[ItemTreeNode],
index: isize,
order: TraversalOrder,
mut visitor: vtable::VRefMut<ItemVisitorVTable>,
visit_dynamic: impl Fn(
Pin<&Base>,
TraversalOrder,
vtable::VRefMut<ItemVisitorVTable>,
u32,
) -> VisitChildrenResult,
) -> VisitChildrenResult {
let mut visit_at_index = |idx: u32| -> VisitChildrenResult {
match &item_tree_array[idx as usize] {
ItemTreeNode::Item { .. } => {
let item = crate::items::ItemRc::new(item_tree.clone(), idx);
visitor.visit_item(item_tree, idx, item.borrow())
}
ItemTreeNode::DynamicTree { index, .. } => {
if let Some(sub_idx) =
visit_dynamic(base, order, visitor.borrow_mut(), *index).aborted_index()
{
VisitChildrenResult::abort(idx, sub_idx)
} else {
VisitChildrenResult::CONTINUE
}
}
}
};
if index == -1 {
visit_at_index(0)
} else {
match &item_tree_array[index as usize] {
ItemTreeNode::Item { children_index, children_count, .. } => {
for c in 0..*children_count {
let idx = match order {
TraversalOrder::BackToFront => *children_index + c,
TraversalOrder::FrontToBack => *children_index + *children_count - c - 1,
};
let maybe_abort_index = visit_at_index(idx);
if maybe_abort_index.has_aborted() {
return maybe_abort_index;
}
}
}
ItemTreeNode::DynamicTree { .. } => panic!("should not be called with dynamic items"),
};
VisitChildrenResult::CONTINUE
}
}
#[cfg(feature = "ffi")]
pub(crate) mod ffi {
#![allow(unsafe_code)]
use super::*;
use core::ffi::c_void;
/// Call init() on the ItemVTable of each item in the item array.
#[unsafe(no_mangle)]
pub unsafe extern "C" fn slint_register_item_tree(
item_tree_rc: &ItemTreeRc,
window_handle: *const crate::window::ffi::WindowAdapterRcOpaque,
) {
let window_adapter = (window_handle as *const WindowAdapterRc).as_ref().cloned();
super::register_item_tree(item_tree_rc, window_adapter)
}
/// Free the backend graphics resources allocated in the item array.
#[unsafe(no_mangle)]
pub unsafe extern "C" fn slint_unregister_item_tree(
component: ItemTreeRefPin,
item_array: Slice<vtable::VOffset<u8, ItemVTable, vtable::AllowPin>>,
window_handle: *const crate::window::ffi::WindowAdapterRcOpaque,
) {
let window_adapter = &*(window_handle as *const WindowAdapterRc);
super::unregister_item_tree(
core::pin::Pin::new_unchecked(&*(component.as_ptr() as *const u8)),
core::pin::Pin::into_inner(component),
item_array.as_slice(),
window_adapter,
)
}
/// Expose `crate::item_tree::visit_item_tree` to C++
///
/// Safety: Assume a correct implementation of the item_tree array
#[unsafe(no_mangle)]
pub unsafe extern "C" fn slint_visit_item_tree(
item_tree: &ItemTreeRc,
item_tree_array: Slice<ItemTreeNode>,
index: isize,
order: TraversalOrder,
visitor: VRefMut<ItemVisitorVTable>,
visit_dynamic: extern "C-unwind" fn(
base: *const c_void,
order: TraversalOrder,
visitor: vtable::VRefMut<ItemVisitorVTable>,
dyn_index: u32,
) -> VisitChildrenResult,
) -> VisitChildrenResult {
crate::item_tree::visit_item_tree(
VRc::as_pin_ref(item_tree),
item_tree,
item_tree_array.as_slice(),
index,
order,
visitor,
|a, b, c, d| visit_dynamic(a.get_ref() as *const vtable::Dyn as *const c_void, b, c, d),
)
}
}
#[cfg(test)]
mod tests {
use super::*;
use std::vec;
struct TestItemTree {
parent_component: Option<ItemTreeRc>,
item_tree: Vec<ItemTreeNode>,
subtrees: std::cell::RefCell<Vec<Vec<vtable::VRc<ItemTreeVTable, TestItemTree>>>>,
subtree_index: usize,
}
impl ItemTree for TestItemTree {
fn visit_children_item(
self: core::pin::Pin<&Self>,
_1: isize,
_2: crate::item_tree::TraversalOrder,
_3: vtable::VRefMut<crate::item_tree::ItemVisitorVTable>,
) -> crate::item_tree::VisitChildrenResult {
unimplemented!("Not needed for this test")
}
fn get_item_ref(
self: core::pin::Pin<&Self>,
_1: u32,
) -> core::pin::Pin<vtable::VRef<'_, super::ItemVTable>> {
unimplemented!("Not needed for this test")
}
fn get_item_tree(self: core::pin::Pin<&Self>) -> Slice<'_, ItemTreeNode> {
Slice::from_slice(&self.get_ref().item_tree)
}
fn parent_node(self: core::pin::Pin<&Self>, result: &mut ItemWeak) {
if let Some(parent_item) = self.parent_component.clone() {
*result =
ItemRc::new(parent_item.clone(), self.item_tree[0].parent_index()).downgrade();
}
}
fn embed_component(
self: core::pin::Pin<&Self>,
_parent_component: &ItemTreeWeak,
_item_tree_index: u32,
) -> bool {
false
}
fn layout_info(self: core::pin::Pin<&Self>, _1: Orientation) -> LayoutInfo {
unimplemented!("Not needed for this test")
}
fn subtree_index(self: core::pin::Pin<&Self>) -> usize {
self.subtree_index
}
fn get_subtree_range(self: core::pin::Pin<&Self>, subtree_index: u32) -> IndexRange {
(0..self.subtrees.borrow()[subtree_index as usize].len()).into()
}
fn get_subtree(
self: core::pin::Pin<&Self>,
subtree_index: u32,
component_index: usize,
result: &mut ItemTreeWeak,
) {
if let Some(vrc) = self.subtrees.borrow()[subtree_index as usize].get(component_index) {
*result = vtable::VRc::downgrade(&vtable::VRc::into_dyn(vrc.clone()))
}
}
fn accessible_role(self: Pin<&Self>, _: u32) -> AccessibleRole {
unimplemented!("Not needed for this test")
}
fn accessible_string_property(
self: Pin<&Self>,
_: u32,
_: AccessibleStringProperty,
_: &mut SharedString,
) -> bool {
false
}
fn item_element_infos(self: Pin<&Self>, _: u32, _: &mut SharedString) -> bool {
false
}
fn window_adapter(
self: Pin<&Self>,
_do_create: bool,
_result: &mut Option<WindowAdapterRc>,
) {
unimplemented!("Not needed for this test")
}
fn item_geometry(self: Pin<&Self>, _: u32) -> LogicalRect {
unimplemented!("Not needed for this test")
}
fn accessibility_action(self: core::pin::Pin<&Self>, _: u32, _: &AccessibilityAction) {
unimplemented!("Not needed for this test")
}
fn supported_accessibility_actions(
self: core::pin::Pin<&Self>,
_: u32,
) -> SupportedAccessibilityAction {
unimplemented!("Not needed for this test")
}
}
crate::item_tree::ItemTreeVTable_static!(static TEST_COMPONENT_VT for TestItemTree);
fn create_one_node_component() -> VRc<ItemTreeVTable, vtable::Dyn> {
let component = VRc::new(TestItemTree {
parent_component: None,
item_tree: vec![ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 1,
parent_index: 0,
item_array_index: 0,
}],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: usize::MAX,
});
VRc::into_dyn(component)
}
#[test]
fn test_tree_traversal_one_node_structure() {
let component = create_one_node_component();
let item = ItemRc::new(component.clone(), 0);
assert!(item.first_child().is_none());
assert!(item.last_child().is_none());
assert!(item.previous_sibling().is_none());
assert!(item.next_sibling().is_none());
}
#[test]
fn test_tree_traversal_one_node_forward_focus() {
let component = create_one_node_component();
let item = ItemRc::new(component.clone(), 0);
// Wrap the focus around:
assert_eq!(item.next_focus_item(), item);
}
#[test]
fn test_tree_traversal_one_node_backward_focus() {
let component = create_one_node_component();
let item = ItemRc::new(component.clone(), 0);
// Wrap the focus around:
assert_eq!(item.previous_focus_item(), item);
}
fn create_children_nodes() -> VRc<ItemTreeVTable, vtable::Dyn> {
let component = VRc::new(TestItemTree {
parent_component: None,
item_tree: vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 3,
children_index: 1,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 1,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 2,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 3,
},
],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: usize::MAX,
});
VRc::into_dyn(component)
}
#[test]
fn test_tree_traversal_children_nodes_structure() {
let component = create_children_nodes();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
assert!(item.previous_sibling().is_none());
assert!(item.next_sibling().is_none());
let fc = item.first_child().unwrap();
assert_eq!(fc.index(), 1);
assert!(VRc::ptr_eq(fc.item_tree(), item.item_tree()));
let fcn = fc.next_sibling().unwrap();
assert_eq!(fcn.index(), 2);
let lc = item.last_child().unwrap();
assert_eq!(lc.index(), 3);
assert!(VRc::ptr_eq(lc.item_tree(), item.item_tree()));
let lcp = lc.previous_sibling().unwrap();
assert!(VRc::ptr_eq(lcp.item_tree(), item.item_tree()));
assert_eq!(lcp.index(), 2);
// Examine first child:
assert!(fc.first_child().is_none());
assert!(fc.last_child().is_none());
assert!(fc.previous_sibling().is_none());
assert_eq!(fc.parent_item(ParentItemTraversalMode::StopAtPopups).unwrap(), item);
// Examine item between first and last child:
assert_eq!(fcn, lcp);
assert_eq!(lcp.parent_item(ParentItemTraversalMode::StopAtPopups).unwrap(), item);
assert_eq!(fcn.previous_sibling().unwrap(), fc);
assert_eq!(fcn.next_sibling().unwrap(), lc);
// Examine last child:
assert!(lc.first_child().is_none());
assert!(lc.last_child().is_none());
assert!(lc.next_sibling().is_none());
assert_eq!(lc.parent_item(ParentItemTraversalMode::StopAtPopups).unwrap(), item);
}
#[test]
fn test_tree_traversal_children_nodes_forward_focus() {
let component = create_children_nodes();
let item = ItemRc::new(component.clone(), 0);
let fc = item.first_child().unwrap();
let fcn = fc.next_sibling().unwrap();
let lc = item.last_child().unwrap();
let mut cursor = item.clone();
cursor = cursor.next_focus_item();
assert_eq!(cursor, fc);
cursor = cursor.next_focus_item();
assert_eq!(cursor, fcn);
cursor = cursor.next_focus_item();
assert_eq!(cursor, lc);
cursor = cursor.next_focus_item();
assert_eq!(cursor, item);
}
#[test]
fn test_tree_traversal_children_nodes_backward_focus() {
let component = create_children_nodes();
let item = ItemRc::new(component.clone(), 0);
let fc = item.first_child().unwrap();
let fcn = fc.next_sibling().unwrap();
let lc = item.last_child().unwrap();
let mut cursor = item.clone();
cursor = cursor.previous_focus_item();
assert_eq!(cursor, lc);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, fcn);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, fc);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, item);
}
fn create_empty_subtree() -> VRc<ItemTreeVTable, vtable::Dyn> {
let component = vtable::VRc::new(TestItemTree {
parent_component: None,
item_tree: vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 1,
children_index: 1,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::DynamicTree { index: 0, parent_index: 0 },
],
subtrees: std::cell::RefCell::new(vec![vec![]]),
subtree_index: usize::MAX,
});
vtable::VRc::into_dyn(component)
}
#[test]
fn test_tree_traversal_empty_subtree_structure() {
let component = create_empty_subtree();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
assert!(item.previous_sibling().is_none());
assert!(item.next_sibling().is_none());
assert!(item.first_child().is_none());
assert!(item.last_child().is_none());
// Wrap the focus around:
assert!(item.previous_focus_item() == item);
assert!(item.next_focus_item() == item);
}
#[test]
fn test_tree_traversal_empty_subtree_forward_focus() {
let component = create_empty_subtree();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
assert!(item.next_focus_item() == item);
}
#[test]
fn test_tree_traversal_empty_subtree_backward_focus() {
let component = create_empty_subtree();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
assert!(item.previous_focus_item() == item);
}
fn create_item_subtree_item() -> VRc<ItemTreeVTable, vtable::Dyn> {
let component = VRc::new(TestItemTree {
parent_component: None,
item_tree: vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 3,
children_index: 1,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::DynamicTree { index: 0, parent_index: 0 },
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 0,
},
],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: usize::MAX,
});
component.as_pin_ref().subtrees.replace(vec![vec![VRc::new(TestItemTree {
parent_component: Some(VRc::into_dyn(component.clone())),
item_tree: vec![ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 1,
parent_index: 2,
item_array_index: 0,
}],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: 0,
})]]);
VRc::into_dyn(component)
}
#[test]
fn test_tree_traversal_item_subtree_item_structure() {
let component = create_item_subtree_item();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
assert!(item.previous_sibling().is_none());
assert!(item.next_sibling().is_none());
let fc = item.first_child().unwrap();
assert!(VRc::ptr_eq(fc.item_tree(), item.item_tree()));
assert_eq!(fc.index(), 1);
let lc = item.last_child().unwrap();
assert!(VRc::ptr_eq(lc.item_tree(), item.item_tree()));
assert_eq!(lc.index(), 3);
let fcn = fc.next_sibling().unwrap();
let lcp = lc.previous_sibling().unwrap();
assert_eq!(fcn, lcp);
assert!(!VRc::ptr_eq(fcn.item_tree(), item.item_tree()));
let last = fcn.next_sibling().unwrap();
assert_eq!(last, lc);
let first = lcp.previous_sibling().unwrap();
assert_eq!(first, fc);
}
#[test]
fn test_tree_traversal_item_subtree_item_forward_focus() {
let component = create_item_subtree_item();
let item = ItemRc::new(component.clone(), 0);
let fc = item.first_child().unwrap();
let lc = item.last_child().unwrap();
let fcn = fc.next_sibling().unwrap();
let mut cursor = item.clone();
cursor = cursor.next_focus_item();
assert_eq!(cursor, fc);
cursor = cursor.next_focus_item();
assert_eq!(cursor, fcn);
cursor = cursor.next_focus_item();
assert_eq!(cursor, lc);
cursor = cursor.next_focus_item();
assert_eq!(cursor, item);
}
#[test]
fn test_tree_traversal_item_subtree_item_backward_focus() {
let component = create_item_subtree_item();
let item = ItemRc::new(component.clone(), 0);
let fc = item.first_child().unwrap();
let lc = item.last_child().unwrap();
let fcn = fc.next_sibling().unwrap();
let mut cursor = item.clone();
cursor = cursor.previous_focus_item();
assert_eq!(cursor, lc);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, fcn);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, fc);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, item);
}
fn create_nested_subtrees() -> VRc<ItemTreeVTable, vtable::Dyn> {
let component = VRc::new(TestItemTree {
parent_component: None,
item_tree: vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 3,
children_index: 1,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::DynamicTree { index: 0, parent_index: 0 },
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 0,
},
],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: usize::MAX,
});
let sub_component1 = VRc::new(TestItemTree {
parent_component: Some(VRc::into_dyn(component.clone())),
item_tree: vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 1,
children_index: 1,
parent_index: 2,
item_array_index: 0,
},
ItemTreeNode::DynamicTree { index: 0, parent_index: 0 },
],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: usize::MAX,
});
let sub_component2 = VRc::new(TestItemTree {
parent_component: Some(VRc::into_dyn(sub_component1.clone())),
item_tree: vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 1,
children_index: 1,
parent_index: 1,
item_array_index: 0,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 2,
parent_index: 0,
item_array_index: 0,
},
],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: usize::MAX,
});
sub_component1.as_pin_ref().subtrees.replace(vec![vec![sub_component2]]);
component.as_pin_ref().subtrees.replace(vec![vec![sub_component1]]);
VRc::into_dyn(component)
}
#[test]
fn test_tree_traversal_nested_subtrees_structure() {
let component = create_nested_subtrees();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
assert!(item.previous_sibling().is_none());
assert!(item.next_sibling().is_none());
let fc = item.first_child().unwrap();
assert!(VRc::ptr_eq(fc.item_tree(), item.item_tree()));
assert_eq!(fc.index(), 1);
let lc = item.last_child().unwrap();
assert!(VRc::ptr_eq(lc.item_tree(), item.item_tree()));
assert_eq!(lc.index(), 3);
let fcn = fc.next_sibling().unwrap();
let lcp = lc.previous_sibling().unwrap();
assert_eq!(fcn, lcp);
assert!(!VRc::ptr_eq(fcn.item_tree(), item.item_tree()));
let last = fcn.next_sibling().unwrap();
assert_eq!(last, lc);
let first = lcp.previous_sibling().unwrap();
assert_eq!(first, fc);
// Nested component:
let nested_root = fcn.first_child().unwrap();
assert_eq!(nested_root, fcn.last_child().unwrap());
assert!(nested_root.next_sibling().is_none());
assert!(nested_root.previous_sibling().is_none());
assert!(!VRc::ptr_eq(nested_root.item_tree(), item.item_tree()));
assert!(!VRc::ptr_eq(nested_root.item_tree(), fcn.item_tree()));
let nested_child = nested_root.first_child().unwrap();
assert_eq!(nested_child, nested_root.last_child().unwrap());
assert!(VRc::ptr_eq(nested_root.item_tree(), nested_child.item_tree()));
}
#[test]
fn test_tree_traversal_nested_subtrees_forward_focus() {
let component = create_nested_subtrees();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
let fc = item.first_child().unwrap();
let fcn = fc.next_sibling().unwrap();
let lc = item.last_child().unwrap();
let nested_root = fcn.first_child().unwrap();
let nested_child = nested_root.first_child().unwrap();
// Focus traversal:
let mut cursor = item.clone();
cursor = cursor.next_focus_item();
assert_eq!(cursor, fc);
cursor = cursor.next_focus_item();
assert_eq!(cursor, fcn);
cursor = cursor.next_focus_item();
assert_eq!(cursor, nested_root);
cursor = cursor.next_focus_item();
assert_eq!(cursor, nested_child);
cursor = cursor.next_focus_item();
assert_eq!(cursor, lc);
cursor = cursor.next_focus_item();
assert_eq!(cursor, item);
}
#[test]
fn test_tree_traversal_nested_subtrees_backward_focus() {
let component = create_nested_subtrees();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
let fc = item.first_child().unwrap();
let fcn = fc.next_sibling().unwrap();
let lc = item.last_child().unwrap();
let nested_root = fcn.first_child().unwrap();
let nested_child = nested_root.first_child().unwrap();
// Focus traversal:
let mut cursor = item.clone();
cursor = cursor.previous_focus_item();
assert_eq!(cursor, lc);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, nested_child);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, nested_root);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, fcn);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, fc);
cursor = cursor.previous_focus_item();
assert_eq!(cursor, item);
}
fn create_subtrees_item() -> VRc<ItemTreeVTable, vtable::Dyn> {
let component = VRc::new(TestItemTree {
parent_component: None,
item_tree: vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 2,
children_index: 1,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::DynamicTree { index: 0, parent_index: 0 },
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 0,
},
],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: usize::MAX,
});
component.as_pin_ref().subtrees.replace(vec![vec![
VRc::new(TestItemTree {
parent_component: Some(VRc::into_dyn(component.clone())),
item_tree: vec![ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 1,
parent_index: 1,
item_array_index: 0,
}],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: 0,
}),
VRc::new(TestItemTree {
parent_component: Some(VRc::into_dyn(component.clone())),
item_tree: vec![ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 1,
parent_index: 1,
item_array_index: 0,
}],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: 1,
}),
VRc::new(TestItemTree {
parent_component: Some(VRc::into_dyn(component.clone())),
item_tree: vec![ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 1,
parent_index: 1,
item_array_index: 0,
}],
subtrees: std::cell::RefCell::new(vec![]),
subtree_index: 2,
}),
]]);
VRc::into_dyn(component)
}
#[test]
fn test_tree_traversal_subtrees_item_structure() {
let component = create_subtrees_item();
// Examine root node:
let item = ItemRc::new(component.clone(), 0);
assert!(item.previous_sibling().is_none());
assert!(item.next_sibling().is_none());
let sub1 = item.first_child().unwrap();
assert_eq!(sub1.index(), 0);
assert!(!VRc::ptr_eq(sub1.item_tree(), item.item_tree()));
// assert!(sub1.previous_sibling().is_none());
let sub2 = sub1.next_sibling().unwrap();
assert_eq!(sub2.index(), 0);
assert!(!VRc::ptr_eq(sub1.item_tree(), sub2.item_tree()));
assert!(!VRc::ptr_eq(item.item_tree(), sub2.item_tree()));
assert!(sub2.previous_sibling() == Some(sub1.clone()));
let sub3 = sub2.next_sibling().unwrap();
assert_eq!(sub3.index(), 0);
assert!(!VRc::ptr_eq(sub1.item_tree(), sub2.item_tree()));
assert!(!VRc::ptr_eq(sub2.item_tree(), sub3.item_tree()));
assert!(!VRc::ptr_eq(item.item_tree(), sub3.item_tree()));
assert_eq!(sub3.previous_sibling().unwrap(), sub2.clone());
}
#[test]
fn test_component_item_tree_root_only() {
let nodes = vec![ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 1,
parent_index: 0,
item_array_index: 0,
}];
let tree: ItemTreeNodeArray = (nodes.as_slice()).into();
assert_eq!(tree.first_child(0), None);
assert_eq!(tree.last_child(0), None);
assert_eq!(tree.previous_sibling(0), None);
assert_eq!(tree.next_sibling(0), None);
assert_eq!(tree.parent(0), None);
}
#[test]
fn test_component_item_tree_one_child() {
let nodes = vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 1,
children_index: 1,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 2,
parent_index: 0,
item_array_index: 0,
},
];
let tree: ItemTreeNodeArray = (nodes.as_slice()).into();
assert_eq!(tree.first_child(0), Some(1));
assert_eq!(tree.last_child(0), Some(1));
assert_eq!(tree.previous_sibling(0), None);
assert_eq!(tree.next_sibling(0), None);
assert_eq!(tree.parent(0), None);
assert_eq!(tree.previous_sibling(1), None);
assert_eq!(tree.next_sibling(1), None);
assert_eq!(tree.parent(1), Some(0));
}
#[test]
fn test_component_item_tree_tree_children() {
let nodes = vec![
ItemTreeNode::Item {
is_accessible: false,
children_count: 3,
children_index: 1,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 0,
},
ItemTreeNode::Item {
is_accessible: false,
children_count: 0,
children_index: 4,
parent_index: 0,
item_array_index: 0,
},
];
let tree: ItemTreeNodeArray = (nodes.as_slice()).into();
assert_eq!(tree.first_child(0), Some(1));
assert_eq!(tree.last_child(0), Some(3));
assert_eq!(tree.previous_sibling(0), None);
assert_eq!(tree.next_sibling(0), None);
assert_eq!(tree.parent(0), None);
assert_eq!(tree.previous_sibling(1), None);
assert_eq!(tree.next_sibling(1), Some(2));
assert_eq!(tree.parent(1), Some(0));
assert_eq!(tree.previous_sibling(2), Some(1));
assert_eq!(tree.next_sibling(2), Some(3));
assert_eq!(tree.parent(2), Some(0));
assert_eq!(tree.previous_sibling(3), Some(2));
assert_eq!(tree.next_sibling(3), None);
assert_eq!(tree.parent(3), Some(0));
}
}
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