Macro glib_macros::clone
source · [−]clone!() { /* proc-macro */ }
Expand description
Macro for passing variables as strong or weak references into a closure.
This macro can be useful in combination with closures, e.g. signal handlers, to reduce the boilerplate required for passing strong or weak references into the closure. It will automatically create the new reference and pass it with the same name into the closure.
If upgrading the weak reference to a strong reference inside the closure is failing, the
closure is immediately returning an optional default return value. If none is provided, ()
is
returned.
⚠️ IMPORTANT ⚠️
glib
needs to be in scope, so unless it’s one of the direct crate dependencies, you need to
import it because clone!
is using it. For example:
use gtk::glib;
Debugging
In case something goes wrong inside the clone!
macro, we use the g_debug
macro. Meaning
that if you want to see these debug messages, you’ll have to set the G_MESSAGES_DEBUG
environment variable when running your code (either in the code directly or when running the
binary) to either “all” or CLONE_MACRO_LOG_DOMAIN
:
use glib::CLONE_MACRO_LOG_DOMAIN;
std::env::set_var("G_MESSAGES_DEBUG", CLONE_MACRO_LOG_DOMAIN);
std::env::set_var("G_MESSAGES_DEBUG", "all");
Or:
$ G_MESSAGES_DEBUG=all ./binary
Passing a strong reference
use glib;
use glib_macros::clone;
use std::rc::Rc;
let v = Rc::new(1);
let closure = clone!(@strong v => move |x| {
println!("v: {}, x: {}", v, x);
});
closure(2);
Passing a weak reference
use glib;
use glib_macros::clone;
use std::rc::Rc;
let u = Rc::new(2);
let closure = clone!(@weak u => move |x| {
println!("u: {}, x: {}", u, x);
});
closure(3);
Allowing a nullable weak reference
In some cases, even if the weak references can’t be retrieved, you might want to still have
your closure called. In this case, you need to use @weak-allow-none
:
use glib;
use glib_macros::clone;
use std::rc::Rc;
let closure = {
// This `Rc` won't be available in the closure because it's dropped at the end of the
// current block
let u = Rc::new(2);
clone!(@weak-allow-none u => @default-return false, move |x| {
// We need to use a Debug print for `u` because it'll be an `Option`.
println!("u: {:?}, x: {}", u, x);
true
})
};
assert_eq!(closure(3), true);
Renaming variables
use glib;
use glib_macros::clone;
use std::rc::Rc;
let v = Rc::new(1);
let u = Rc::new(2);
let closure = clone!(@strong v as y, @weak u => move |x| {
println!("v as y: {}, u: {}, x: {}", y, u, x);
});
closure(3);
Providing a default return value if upgrading a weak reference fails
You can do it in two different ways:
Either by providing the value yourself using @default-return
:
use glib;
use glib_macros::clone;
use std::rc::Rc;
let v = Rc::new(1);
let closure = clone!(@weak v => @default-return false, move |x| {
println!("v: {}, x: {}", v, x);
true
});
// Drop value so that the weak reference can't be upgraded.
drop(v);
assert_eq!(closure(2), false);
Or by using @default-panic
(if the value fails to get upgraded, it’ll panic):
let closure = clone!(@weak v => @default-panic, move |x| {
println!("v: {}, x: {}", v, x);
true
});
Errors
Here is a list of errors you might encounter:
Missing @weak
or @strong
:
let v = Rc::new(1);
let closure = clone!(v => move |x| println!("v: {}, x: {}", v, x));
Passing self
as an argument:
#[derive(Debug)]
struct Foo;
impl Foo {
fn foo(&self) {
let closure = clone!(@strong self => move |x| {
println!("self: {:?}", self);
});
}
}
If you want to use self
directly, you’ll need to rename it:
#[derive(Debug)]
struct Foo;
impl Foo {
fn foo(&self) {
let closure = clone!(@strong self as this => move |x| {
println!("self: {:?}", this);
});
}
}
Passing fields directly
#[derive(Debug)]
struct Foo {
v: Rc<usize>,
}
impl Foo {
fn foo(&self) {
let closure = clone!(@strong self.v => move |x| {
println!("self.v: {:?}", v);
});
}
}
You can do it by renaming it:
impl Foo {
fn foo(&self) {
let closure = clone!(@strong self.v as v => move |x| {
println!("self.v: {}", v);
});
}
}