//! Defines various views to use when creating the layout. //! //! Views are the main building blocks of your UI. //! //! A view can delegate part or all of its responsabilities to child views, //! forming a view tree. The root of this tree is a `StackView` handled //! directly by the `Cursive` element. //! //! # Layout //! //! The layout phase is when the size and location of each view is computed. //! //! Each view is given an area of the screen by the `View::layout()` method. //! With this, the view is free to plan its content, including calling //! `View::layout()` on its own children. //! //! In order to determine how much space should be given each child, parents //! can use `View::get_min_size()` on them. //! //! //! ### Contracts //! //! When building new Views, you should respect these contracts: //! //! * By default, `View::layout()` should be called before any call to //! `View::draw()` with the same available size. The only exceptions is //! when both following conditions are met: //! * The available size has not changed since the last call to //! `View::layout()` //! * `View::needs_relayout()` returns `false` //! //! In this case, it is safe to omit the call to `View::layout()`. //! //! * The value returned by `get_min_size` should be an actually viable size, //! no matter what the request is. This means calling `View::layout()` with //! a size returned by `get_min_size` is **never** an error. #[macro_use] mod view_wrapper; // Essentials components mod position; mod view_path; // Helper bases mod scroll; // Views mod box_view; mod button; mod checkbox; mod dialog; mod edit_view; mod full_view; mod id_view; mod key_event_view; mod linear_layout; mod list_view; mod menubar; mod menu_popup; mod panel; mod progress_bar; mod shadow_view; mod select_view; mod sized_view; mod stack_view; mod text_view; mod tracked_view; use std::any::Any; use XY; use direction::Direction; use event::{Event, EventResult}; use vec::Vec2; use Printer; pub use self::position::{Offset, Position}; pub use self::scroll::ScrollBase; pub use self::id_view::{IdView, Identifiable}; pub use self::box_view::BoxView; pub use self::button::Button; pub use self::checkbox::Checkbox; pub use self::dialog::Dialog; pub use self::edit_view::EditView; pub use self::full_view::FullView; pub use self::key_event_view::KeyEventView; pub use self::linear_layout::LinearLayout; pub use self::list_view::ListView; pub use self::menubar::Menubar; pub use self::menu_popup::MenuPopup; pub use self::view_path::ViewPath; pub use self::panel::Panel; pub use self::progress_bar::ProgressBar; pub use self::select_view::SelectView; pub use self::shadow_view::ShadowView; pub use self::sized_view::SizedView; pub use self::stack_view::StackView; pub use self::text_view::TextView; pub use self::tracked_view::TrackedView; pub use self::view_wrapper::ViewWrapper; /// Main trait defining a view behaviour. pub trait View { /// Called when a key was pressed. Default implementation just ignores it. fn on_event(&mut self, Event) -> EventResult { EventResult::Ignored } /// Returns the minimum size the view requires with the given restrictions. /// /// If the view is flexible (it has multiple size options), it can try /// to return one that fits the given `constraint`. /// It's also fine to ignore it and return a fixed value. fn get_min_size(&mut self, constraint: Vec2) -> Vec2 { let _ = constraint; Vec2::new(1, 1) } /// Returns `true` if the view content changed since last layout phase. /// /// This is mostly an optimisation for views where the layout phase is /// expensive. /// /// * Views can ignore it and always return true (default implementation). /// They will always be assumed to have changed. /// * View Groups can ignore it and always re-layout their children. /// * If they call `get_min_size` or `layout` with stable parameters, /// the children may cache the result themselves and speed up the /// process anyway. fn needs_relayout(&self) -> bool { true } /// Called once the size for this view has been decided, /// /// View groups should propagate the information to their children. fn layout(&mut self, Vec2) {} /// Draws the view with the given printer (includes bounds) and focus. fn draw(&self, printer: &Printer); /// Finds the view pointed to by the given path. /// /// Returns None if the path doesn't lead to a view. fn find(&mut self, &Selector) -> Option<&mut Any> { None } /// This view is offered focus. Will it take it? /// /// `source` indicates where the focus comes from. /// When the source is unclear, `Front` is usually used. fn take_focus(&mut self, source: Direction) -> bool { let _ = source; false } } /// Cache around a one-dimensional layout result. /// /// This is not a View, but something to help you if you create your own Views. #[derive(PartialEq, Debug, Clone, Copy)] pub struct SizeCache { /// Cached value pub value: usize, /// `true` if the last size was constrained. /// /// If unconstrained, any request larger than this value /// would return the same size. pub constrained: bool, } impl SizeCache { /// Creates a new sized cache pub fn new(value: usize, constrained: bool) -> Self { SizeCache { value: value, constrained: constrained, } } /// Returns `true` if `self` is still valid for the given `request`. pub fn accept(self, request: usize) -> bool { if request < self.value { false } else if request == self.value { true } else { !self.constrained } } /// Creates a new bi-dimensional cache. /// /// * `size` must fit inside `req`. /// * for each dimension, `constrained = (size == req)` fn build(size: Vec2, req: Vec2) -> XY { XY::new(SizeCache::new(size.x, size.x >= req.x), SizeCache::new(size.y, size.y >= req.y)) } } /// Selects a single view (if any) in the tree. pub enum Selector<'a> { /// Selects a view from its ID. Id(&'a str), /// Selects a view from its path. Path(&'a ViewPath), }