Lib.rs

Algorithms
#state-machine #recovery #persistence #step #abilities #programs #debugging

step-machine

Run your CLI program as state machines with persistence and recovery abilities

by Imbolc

3 unstable releases

0.2.0 Aug 26, 2021
0.1.1 Aug 21, 2021
0.1.0 Aug 21, 2021

#2021 in Algorithms

MIT/Apache

12KB
147 lines

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step-machine

Run your CLI programs as state machines with persistence and recovery abilities. When such a program breaks you'll have opportunity to change the external world (create a missing folder, change a file permissions or something) and continue the program from the step it was interrupted on.

Usage

Let's toss two coins and make sure they both landed on the same side. We express the behaviour as two states of our machine. Step logic is implemented in State::next() methods which return the next state or None for the last step (the full code is in examples/coin.rs).

#[derive(Debug, Serialize, Deserialize, From)]
enum Machine {
    FirstToss(FirstToss),
    SecondToss(SecondToss),
}

#[derive(Debug, Serialize, Deserialize)]
struct FirstToss;
impl FirstToss {
    fn next(self) -> StepResult {
        let first_coin = Coin::toss();
        println!("First coin: {:?}", first_coin);
        Ok(Some(SecondToss { first_coin }.into()))
    }
}

#[derive(Debug, Serialize, Deserialize)]
struct SecondToss {
    first_coin: Coin,
}
impl SecondToss {
    fn next(self) -> StepResult {
        let second_coin = Coin::toss();
        println!("Second coin: {:?}", second_coin);
        ensure!(second_coin == self.first_coin, "Coins landed differently");
        println!("Coins match");
        Ok(None)
    }
}

Then we start our machine like this:

let init_state = FirstToss.into();
let mut engine = Engine::<Machine>::new(init_state)?.restore()?;
engine.drop_error()?;
engine.run()?;

We initialize the Engine with the first step. Then we restore the previous state if the process was interrupted (e.g. by an error). Then we drop a possible error and run all the steps to completion.

Let's run it now:

$ cargo run --example coin
First coin: Heads
Second coin: Tails
Error: Coins landed differently

We weren't lucky this time and the program resulted in an error. Let's run it again:

$ cargo run --example coin
Second coin: Heads
Coins match

Notice that, thanks to the restore(), our machine run from the step it was interrupted, knowing about the first coin landed on heads.

Dependencies

~0.8–1.7MB
~37K SLoC