Crates.io | defer-rs |
lib.rs | defer-rs |
version | 0.1.0 |
source | src |
created_at | 2024-04-04 08:38:28.273467 |
updated_at | 2024-04-04 08:38:28.273467 |
description | Deferred execution Rust utilities. |
homepage | https://github.com/AhmadAlHallak/defer-rs |
repository | https://github.com/AhmadAlHallak/defer-rs |
max_upload_size | |
id | 1196042 |
size | 41,721 |
Deferred execution Rust utilities.
This crate provides utility structs and macros for deferred execution of code in Rust. It allows you to specify actions that should be executed when a scope is exited, such as when a function ends or a block of code completes execution.
Defer Statements: The library introduces the concept of Defer
ed statements, providing similar functionality to those found in other programming languages. The Defer
struct allows you to register functions or closures to be executed when the active scope is exited.
DeferGroup: The DeferGroup
struct allows you to group multiple deferred actions together. When the DeferGroup
goes out of scope, all registered actions are executed in reverse order.
Macro Support: The defer!
and defer_scope!
macros simplify the process of creating deferred actions. They can be used to defer function calls, closures, or arbitrary code blocks.
To use the defer
library, add it as a dependency in your Cargo.toml
:
[dependencies]
defer-rs = "0.1"
defer!
MacroThe defer!
macro simplifies the creation of deferred actions. It supports both function calls and arbitrary code blocks.
Example:
use defer_rs::defer;
defer!({
println!("Deferred action using macro");
});
// ... other code ...
// The deferred action will be executed when it goes out of scope
defer_scope!
MacroThe defer_scope!
macro can be used in conjunction with the defer_scope_init!
macro to precisely manage the scope in which a collection of deferred statements will execute at the end of.
Example:
use defer_rs::{defer_scope, defer_scope_init};
use std::cell::Cell;
let val = Cell::new(0);
{
defer_scope_init!(); // Initiate scoped deferred collection
{
defer_scope!(val.set(1)); // Add to it in a nested scope
assert_eq!(val.get(), 0);
}
// `defer_scope!(val.set(1))` is still to run, even though the scope containing it has ended!
assert_eq!(val.get(), 0);
// ... other code ...
// The deferred collection will execute the contained closures when it goes out of scope on the following line
}
assert_eq!(val.get(), 1)
Defer
StructThe Defer
struct is used to create individual deferred actions. You can create a new deferred action by providing a closure or function that takes no arguments. When the Defer
instance goes out of scope, the provided closure or function will be executed.
Note: The defer!
macro is syntactic sugar for this struct.
Example:
use defer_rs::Defer;
let deferred_action = Defer::new(|| {
println!("Deferred action executed!");
});
// ... other code ...
// deferred_action will be executed when it goes out of scope
The DeferGroup
struct allows you to group multiple deferred actions together. Actions are executed in reverse order when the DeferGroup
goes out of scope.
Note: The defer_scope!
and defer_scope_init!
macros are syntactic sugar for this struct and it's ::add()
method.
Example:
use defer_rs::DeferGroup;
let mut defer_group = DeferGroup::new();
defer_group.add(Box::new(|| {
println!("First deferred action");
}));
defer_group.push(Box::new(|| {
println!("Second deferred action");
}));
// ... other code ...
// Both deferred actions will be executed in reverse order
Prefixing the statement(s) in a 'defer!' or 'defer_scope!' macro with the move
keyword will capture the closure’s environment by value.
Note: This is the same as adding move
to the closure passed to Defer::new()
or DeferGroup::add()
.
Example:
use defer_rs::{defer_scope, defer_scope_init};
let val = "Variable that must be passed by value!";
defer_scope_init!(); // Initiate scoped deferred collection
{
defer_scope!(move {
println!("`val` is captured by value!");
println!("{}", val);
});
}
It's sometimes desireable to have the arguments passed to a deferred function call be evaluated at time of deferment, rather than the deferred time of execution (similar to how the defer
keyword works in Go
and other programming languages), this behavior is mimicked when the 'defer!' (or 'defer_scope!') macro is used on a solitary function call.
Note: This behavior can be disbled by simply postfixing the function call passed to the macro by a ;
.
Example:
use defer_rs::{defer_scope, defer_scope_init};
use std::cell::{Cell, RefCell};
use std::io::Write;
fn add_to_buffer(to_add: String, buff: &RefCell<Vec<u8>>) {
writeln!(buff.borrow_mut(), "{to_add}");
}
let buff = RefCell::new(Vec::new());
let buff2 = RefCell::new(Vec::new());
let val = Cell::new(0);
defer_scope_init!();
defer_scope ! {
let res = b"x is: 3\n";
assert_eq!(*buff.borrow(), res.to_vec());
let res = b"x is: 0\n";
assert_eq!(*buff2.borrow(), res.to_vec());
};
// This will evaluate the arguments passed to the invoked at function at call time (deferred-to time / later), `val.get()` results in `3`
defer_scope!(
add_to_buffer(
format!("x is: {}", val.get()),
&buff
); // Notice the `;` at the end of the function call, disables the immediate evaluation of passed arguments.
);
// This will evaluate the arguments passed to the invoked function at time of macro invocation (now), `val.get()` results in `0`
defer_scope!(
add_to_buffer(
format!("x is: {}", val.get()),
&buff2
) // No `;`. Arguments are immediately evaluated!
);
val.set(3);
use defer_rs::{defer, defer_scope, defer_scope_init};
use std::cell::Cell;
fn print(to_print: String) {
println!("{to_print}");
}
fn main() {
let x = Cell::new(0);
defer_scope_init!();
{
// The macro deferrs execution of the code passed to it to the end of the scope of the nearest `DeferGroup` (or `defer_scope_init!` invocation) going up
defer_scope!({
println!("This will be printed 13th/last");
});
defer_scope!(
println!("This will be printed 12th");
);
{
let x = Cell::new(1);
// Define a new DeferGroup
defer_scope_init!();
// This will evaluate the arguments passed to the invoked at function at time of macro invocation (now), results in `0`
// Using `defer!` here instead of `defer_scope!` will result in identical behavior!
defer_scope!(print(format!("This will be printed 1st, x is: {}", x.get())));
x.set(3);
}
// `defer!` will delay the execution of code passed to it until the end of it's containg scope!
defer! { move
println!("This will be printed 3rd");
println!("This will be printed 4th");
};
defer_scope! {
println!("This will be printed 11th");
};
defer! { move
println!("This will be printed 2nd");
};
}
println!("This will be printed 5th");
// This will evaluate the arguments passed to the invoked at function at time of macro invocation (now), `x.get()` results in `0`
defer_scope!(print(format!("This will be printed 10th, x is: {}", x.get())));
// This will evaluate the arguments passed to the invoked at function at call time (deferred-to time, later), `x.get()` results in `3`
defer!({ print(format!("This will be printed 8th, x is: {}", x.get())) });
x.set(3);
defer_scope! {
println!("This will be printed 9th");
};
println!("This will be printed 6th");
defer! {
println!("This will be printed 7th");
};
}
This will result in the following lines being printed to stdout
:
This will be printed 1st, x is: 1
This will be printed 2nd
This will be printed 3rd
This will be printed 4th
This will be printed 5th
This will be printed 6th
This will be printed 7th
This will be printed 8th, x is: 3
This will be printed 9th
This will be printed 10th, x is: 0
This will be printed 11th
This will be printed 12th
This will be printed 13th/last