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// Take a look at the license at the top of the repository in the LICENSE file.
//! # GTK 4 Macros
//!
//! The crate aims to provide useful macros to use with the GTK 4 Rust bindings.
mod attribute_parser;
#[cfg(feature = "blueprint")]
mod blueprint;
mod composite_template_derive;
mod template_callbacks_attribute;
mod util;
use proc_macro::TokenStream;
use proc_macro2::Span;
use syn::{parse_macro_input, DeriveInput, Error};
/// That macro includes and compiles blueprint file by path relative to project
/// rood
///
/// It expected to run inside composite_template_derive, not by users
#[cfg(feature = "blueprint")]
#[proc_macro]
#[doc(hidden)]
pub fn include_blueprint(input: TokenStream) -> TokenStream {
use quote::quote;
let tokens: Vec<_> = input.into_iter().collect();
if tokens.len() != 1 {
return Error::new(Span::call_site(), "File name not found")
.into_compile_error()
.into();
}
let root = std::env::var("CARGO_MANIFEST_DIR").unwrap_or_else(|_| ".".into());
let file_name = tokens[0].to_string();
let file_name = file_name.trim();
let file_name = &file_name[1..file_name.len() - 1];
let path = std::path::Path::new(&root).join(file_name);
if !path.exists() {
return Error::new(
Span::call_site(),
format!("{} not found", &path.to_string_lossy()),
)
.into_compile_error()
.into();
}
let path = path.to_string_lossy().to_string();
let template = match std::fs::read_to_string(&path) {
Ok(content) => blueprint::compile_blueprint(content.as_bytes()).unwrap(),
Err(err) => {
return Error::new(Span::call_site(), err)
.into_compile_error()
.into()
}
};
quote!({
// Compiler reruns macro if file changed
_ = include_str!(#path);
#template
})
.into()
}
/// Derive macro for using a composite template in a widget.
///
/// The `template` attribute specifies where the template should be loaded
/// from; it can be a `file`, a `resource`, or a `string`.
///
/// The `template_child` attribute is used to mark all internal widgets
/// we need to have programmatic access to. It can take two parameters:
/// - `id` which defaults to the item name if not defined
/// - `internal` whether the child should be accessible as an
/// “internal-child”, defaults to `false`
///
/// # Example
///
/// Specify that `MyWidget` is using a composite template and load the
/// template file the `composite_template.ui` file.
///
/// Then, in the [`ObjectSubclass`] implementation you will need to call
/// [`bind_template`] in the [`class_init`] function, and [`init_template`] in
/// [`instance_init`] function.
///
/// [`ObjectSubclass`]: ../glib/subclass/types/trait.ObjectSubclass.html
/// [`bind_template`]: ../gtk4/subclass/widget/trait.CompositeTemplate.html#tymethod.bind_template
/// [`class_init`]: ../glib/subclass/types/trait.ObjectSubclass.html#method.class_init
/// [`init_template`]: ../gtk4/subclass/prelude/trait.CompositeTemplateInitializingExt.html#tymethod.init_template
/// [`instance_init`]: ../glib/subclass/types/trait.ObjectSubclass.html#method.instance_init
///
/// ```no_run
/// # fn main() {}
/// use gtk::{glib, prelude::*, subclass::prelude::*};
///
/// mod imp {
/// use super::*;
///
/// #[derive(Debug, Default, gtk::CompositeTemplate)]
/// #[template(file = "test/template.ui")]
/// pub struct MyWidget {
/// #[template_child]
/// pub label: TemplateChild<gtk::Label>,
/// #[template_child(id = "my_button_id")]
/// pub button: TemplateChild<gtk::Button>,
/// }
///
/// #[glib::object_subclass]
/// impl ObjectSubclass for MyWidget {
/// const NAME: &'static str = "MyWidget";
/// type Type = super::MyWidget;
/// type ParentType = gtk::Box;
///
/// fn class_init(klass: &mut Self::Class) {
/// klass.bind_template();
/// }
///
/// fn instance_init(obj: &glib::subclass::InitializingObject<Self>) {
/// obj.init_template();
/// }
/// }
///
/// impl ObjectImpl for MyWidget {}
/// impl WidgetImpl for MyWidget {}
/// impl BoxImpl for MyWidget {}
/// }
///
/// glib::wrapper! {
/// pub struct MyWidget(ObjectSubclass<imp::MyWidget>) @extends gtk::Widget, gtk::Box;
/// }
///
/// impl MyWidget {
/// pub fn new() -> Self {
/// glib::Object::new()
/// }
/// }
/// ```
///
/// The [`CompositeTemplate`] macro can also be used with [Blueprint](https://jwestman.pages.gitlab.gnome.org/blueprint-compiler/)
/// if the feature `blueprint` is enabled.
/// you can use `string` or `file` relative to the project directory but not
/// `resource`
///
/// ```ignore
/// # fn main() {}
/// use gtk::{glib, prelude::*, subclass::prelude::*};
///
/// mod imp {
/// use super::*;
///
/// #[derive(Debug, Default, gtk::CompositeTemplate)]
/// #[template(string = "
/// template MyWidget : Widget {
/// Label label {
/// label: 'foobar';
/// }
///
/// Label my_label2 {
/// label: 'foobaz';
/// }
/// }
/// ")]
/// pub struct MyWidget {
/// #[template_child]
/// pub label: TemplateChild<gtk::Label>,
/// #[template_child(id = "my_label2")]
/// pub label2: gtk::TemplateChild<gtk::Label>,
/// }
///
/// #[glib::object_subclass]
/// impl ObjectSubclass for MyWidget {
/// const NAME: &'static str = "MyWidget";
/// type Type = super::MyWidget;
/// type ParentType = gtk::Widget;
/// fn class_init(klass: &mut Self::Class) {
/// klass.bind_template();
/// }
/// fn instance_init(obj: &glib::subclass::InitializingObject<Self>) {
/// obj.init_template();
/// }
/// }
///
/// impl ObjectImpl for MyWidget {
/// fn dispose(&self) {
/// while let Some(child) = self.obj().first_child() {
/// child.unparent();
/// }
/// }
/// }
/// impl WidgetImpl for MyWidget {}
/// }
///
/// glib::wrapper! {
/// pub struct MyWidget(ObjectSubclass<imp::MyWidget>) @extends gtk::Widget;
/// }
/// ```
#[proc_macro_derive(CompositeTemplate, attributes(template, template_child))]
pub fn composite_template_derive(input: TokenStream) -> TokenStream {
let input = parse_macro_input!(input as DeriveInput);
composite_template_derive::impl_composite_template(&input)
.unwrap_or_else(Error::into_compile_error)
.into()
}
/// Attribute macro for creating template callbacks from Rust methods.
///
/// Widgets with [`CompositeTemplate`] can then make use of these callbacks from
/// within their template XML definition. The attribute must be applied to an
/// `impl` statement of a struct. Functions marked as callbacks within the
/// `impl` will be stored in a static array. Then, in the [`ObjectSubclass`]
/// implementation you will need to call [`bind_template_callbacks`] and/or
/// [`bind_template_instance_callbacks`] in the [`class_init`] function.
///
/// Template callbacks can be specified on both a widget's public wrapper `impl`
/// or on its private subclass `impl`, or from external types. If callbacks are
/// specified on the public wrapper, then `bind_template_instance_callbacks`
/// must be called in `class_init`. If callbacks are specified on the private
/// subclass, then `bind_template_callbacks` must be called in `class_init`. To
/// use the callbacks from an external type, call [`T::bind_template_callbacks`]
/// in `class_init`, where `T` is the other type. See the example below for
/// usage of all three.
///
/// These callbacks can be bound using the `<signal>` or `<closure>` tags in the
/// template file. Note that the arguments and return type will only be checked
/// at run time when the method is invoked.
///
/// Template callbacks can optionally take `self` or `&self` as a first
/// parameter. In this case, the attribute `swapped="true"` will usually have to
/// be set on the `<signal>` or `<closure>` tag in order to invoke the function
/// correctly. Note that by-value `self` will only work with template callbacks
/// on the wrapper type.
///
/// Template callbacks that have no return value can also be `async`, in which
/// case the callback will be spawned as new future on the default main context
/// using [`glib::MainContext::spawn_local`]. Invoking the callback multiple
/// times will spawn an additional future each time it is invoked. This means
/// that multiple futures for an async callback can be active at any given time,
/// so care must be taken to avoid any kind of data races. Async callbacks may
/// prefer communicating back to the caller or widget over channels instead of
/// mutating internal widget state, or may want to make use of a locking flag to
/// ensure only one future can be active at once. Widgets may also want to show
/// a visual indicator such as a [`Spinner`] while the future is active to
/// communicate to the user that a background task is running.
///
/// The following options are supported on the attribute:
/// - `functions` makes all callbacks use the `function` attribute by default.
/// (see below)
///
/// The `template_callback` attribute is used to mark methods that will be
/// exposed to the template scope. It can take the following options:
/// - `name` renames the callback. Defaults to the function name if not defined.
/// - `function` ignores the first value when calling the callback and disallows
/// `self`. Useful
/// for callbacks called from `<closure>` tags.
/// - `function = false` reverts the effects of `functions` used on the `impl`,
/// so the callback
/// gets the first value and can take `self` again. Mainly useful for callbacks
/// that are invoked with `swapped="true"`.
///
/// The `rest` attribute can be placed on the last argument of a template
/// callback. This attribute must be used on an argument of type
/// <code>&\[[glib::Value]\]</code> and will pass in the remaining arguments.
/// The first and last values will be omitted from the slice if this callback is
/// a `function`.
///
/// Arguments and return types in template callbacks have some special
/// restrictions, similar to the restrictions on [`glib::closure`]. Each
/// argument's type must implement <code>[From]<Type> for
/// [glib::Value]</code>. The last argument can also be <code>&\[[glib::Value]\
/// ]</code> annotated with `#[rest]` as described above. The return type of
/// a callback, if present, must implement [`glib::FromValue`]. Type-checking of
/// inputs and outputs is done at run-time; if the argument types or return type
/// do not match the type of the signal or closure then the callback will panic.
/// To implement your own type checking or to use dynamic typing, an argument's
/// type can be left as a <code>&[glib::Value]</code>. This can also be used
/// if you need custom unboxing, such as if the target type does not implement
/// `FromValue`.
///
/// [`glib::closure`]: ../glib/macro.closure.html
/// [`glib::wrapper`]: ../glib/macro.wrapper.html
/// [`ObjectSubclass`]: ../glib/subclass/types/trait.ObjectSubclass.html
/// [`class_init`]: ../glib/subclass/types/trait.ObjectSubclass.html#method.class_init
/// [`bind_template_callbacks`]: ../gtk4/subclass/widget/trait.CompositeTemplateCallbacksClass.html#tymethod.bind_template_callbacks
/// [`bind_template_instance_callbacks`]: ../gtk4/subclass/widget/trait.CompositeTemplateInstanceCallbacksClass.html#tymethod.bind_template_instance_callbacks
/// [`T::bind_template_callbacks`]: ../gtk4/subclass/widget/trait.CompositeTemplateCallbacks.html#method.bind_template_callbacks
/// [`glib::FromValue`]: ../glib/value/trait.FromValue.html
/// [`glib::ToValue`]: ../glib/value/trait.ToValue.html
/// [glib::Value]: ../glib/value/struct.Value.html
/// [`glib::MainContext::spawn_local`]: ../glib/struct.MainContext.html#method.spawn_local
/// [`Spinner`]: ../gtk4/struct.Spinner.html
///
/// # Example
///
/// ```no_run
/// # fn main() {}
/// use gtk::{glib, prelude::*, subclass::prelude::*};
///
/// mod imp {
/// use super::*;
///
/// #[derive(Debug, Default, gtk::CompositeTemplate)]
/// #[template(file = "test/template_callbacks.ui")]
/// pub struct MyWidget {
/// #[template_child]
/// pub label: TemplateChild<gtk::Label>,
/// #[template_child(id = "my_button_id")]
/// pub button: TemplateChild<gtk::Button>,
/// }
///
/// #[glib::object_subclass]
/// impl ObjectSubclass for MyWidget {
/// const NAME: &'static str = "MyWidget";
/// type Type = super::MyWidget;
/// type ParentType = gtk::Box;
///
/// fn class_init(klass: &mut Self::Class) {
/// klass.bind_template();
/// // Bind the private callbacks
/// klass.bind_template_callbacks();
/// // Bind the public callbacks
/// klass.bind_template_instance_callbacks();
/// // Bind callbacks from another struct
/// super::Utility::bind_template_callbacks(klass);
/// }
///
/// fn instance_init(obj: &glib::subclass::InitializingObject<Self>) {
/// obj.init_template();
/// }
/// }
///
/// #[gtk::template_callbacks]
/// impl MyWidget {
/// #[template_callback]
/// fn button_clicked(&self, button: >k::Button) {
/// button.set_label("I was clicked!");
/// self.label.set_label("The button was clicked!");
/// }
/// #[template_callback(function, name = "strlen")]
/// fn string_length(s: &str) -> u64 {
/// s.len() as u64
/// }
/// }
///
/// impl ObjectImpl for MyWidget {}
/// impl WidgetImpl for MyWidget {}
/// impl BoxImpl for MyWidget {}
/// }
///
/// glib::wrapper! {
/// pub struct MyWidget(ObjectSubclass<imp::MyWidget>) @extends gtk::Widget, gtk::Box;
/// }
///
/// #[gtk::template_callbacks]
/// impl MyWidget {
/// pub fn new() -> Self {
/// glib::Object::new()
/// }
/// #[template_callback]
/// pub fn print_both_labels(&self) {
/// let imp = self.imp();
/// println!(
/// "{} {}",
/// imp.label.label(),
/// imp.button.label().unwrap().as_str()
/// );
/// }
/// }
///
/// pub struct Utility {}
///
/// #[gtk::template_callbacks(functions)]
/// impl Utility {
/// #[template_callback]
/// fn concat_strs(#[rest] values: &[glib::Value]) -> String {
/// let mut res = String::new();
/// for (index, value) in values.iter().enumerate() {
/// res.push_str(value.get::<&str>().unwrap_or_else(|e| {
/// panic!("Expected string value for argument {}: {}", index, e);
/// }));
/// }
/// res
/// }
/// #[template_callback(function = false)]
/// fn reset_label(label: >k::Label) {
/// label.set_label("");
/// }
/// }
/// ```
#[proc_macro_attribute]
pub fn template_callbacks(attr: TokenStream, item: TokenStream) -> TokenStream {
let args = parse_macro_input!(attr as template_callbacks_attribute::Args);
match syn::parse::<syn::ItemImpl>(item) {
Ok(input) => template_callbacks_attribute::impl_template_callbacks(input, args)
.unwrap_or_else(syn::Error::into_compile_error)
.into(),
Err(_) => Error::new(
Span::call_site(),
template_callbacks_attribute::WRONG_PLACE_MSG,
)
.into_compile_error()
.into(),
}
}
/// Attribute macro for declaring GTK tests.
///
/// Wraps the standard Rust [`test`] attribute with setup logic for GTK. All
/// tests that call into GTK must use this attribute. This attribute can also be
/// used on asynchronous functions; the asynchronous test will be run on the
/// main thread context.
///
/// # Technical Details
///
/// GTK is a single-threaded library, so Rust's normal multi-threaded test
/// behavior cannot be used. The `#[gtk::test]` attribute creates a main thread
/// for GTK and runs all tests on that thread. This has the side effect of
/// making all tests run serially, not in parallel.
///
/// [`test`]: <https://doc.rust-lang.org/std/prelude/v1/macro.test.html>
///
/// # Example
///
/// ```no_run
/// use gtk::prelude::*;
///
/// #[gtk::test]
/// fn test_button() {
/// let button = gtk::Button::new();
/// button.activate();
/// }
/// ```
#[proc_macro_attribute]
pub fn test(_attr: TokenStream, item: TokenStream) -> TokenStream {
use quote::quote;
match syn::parse::<syn::ItemFn>(item) {
Ok(mut input) => {
let crate_ident = util::crate_ident_new();
let block = &input.block;
let block = if input.sig.asyncness.is_some() {
quote! {
#crate_ident::glib::MainContext::default().block_on(async move {
#block
})
}
} else {
quote! { #block }
};
input.sig.asyncness.take();
let attrs = &input.attrs;
let vis = &input.vis;
let sig = &input.sig;
let test = quote! {
#(#attrs)*
#[::std::prelude::v1::test]
#vis #sig {
#crate_ident::test_synced(move || {
#block
})
}
};
test.into()
}
Err(_) => Error::new(
Span::call_site(),
"This macro should be used on a function definition",
)
.into_compile_error()
.into(),
}
}