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use super::retry_policy::BackoffSchedule;
use super::retry_result::RetryError;
use super::retry_result::RetryResult;
use std::future::Future;
use std::time::Duration;
use tokio::time::sleep;
pub async fn retry_async<F, T, E>(
retry_schedule: impl BackoffSchedule,
mut operation: impl FnMut() -> F,
) -> Result<T, RetryError<E>>
where
F: Future<Output = RetryResult<T, E>>,
E: std::fmt::Display,
{
let mut iterator = retry_schedule;
let mut current_try = 1;
let mut total_delay = Duration::default();
loop {
let result: RetryResult<T, E> = operation().await;
match result {
RetryResult::Success(value) => return Ok(value),
RetryResult::Retry(error) => {
if let Some(delay) = iterator.next() {
sleep(delay).await;
current_try += 1;
total_delay += delay;
} else {
return Err(RetryError {
error,
total_delay,
tries: current_try,
});
}
}
RetryResult::Fail(error) => {
return Err(RetryError {
error,
total_delay,
tries: current_try,
});
}
}
}
}
#[cfg(test)]
mod tests {
use super::super::retry_policy::RetryWithBackoff;
use super::retry_async;
use super::RetryError;
use super::RetryResult;
use snafu::Snafu;
use std::time::Duration;
use tokio::runtime::Runtime;
#[derive(Debug, PartialEq, Eq, Snafu)]
pub enum SnafuError {
#[snafu(display("Retryable error"))]
Retryable,
#[snafu(display("NonRetryable error"))]
Nonretryable,
}
#[test]
fn attempts_just_once() {
let runtime = Runtime::new().unwrap();
let retry_policy = RetryWithBackoff::default().max_tries(1);
let future = retry_async(retry_policy, || async {
let previous = 1;
match previous {
1 => RetryResult::Fail(SnafuError::Nonretryable),
2 => RetryResult::Success(previous),
_ => RetryResult::Retry(SnafuError::Retryable),
}
});
let res = runtime.block_on(future);
assert_eq!(
res,
Err(RetryError {
error: SnafuError::Nonretryable,
tries: 1,
total_delay: Duration::from_millis(0),
})
);
}
#[test]
fn attempts_until_max_retries_exceeded() {
let runtime = Runtime::new().unwrap();
let retry_policy = RetryWithBackoff::default().max_tries(3);
let future = retry_async(retry_policy, || async {
let previous = 3;
match previous {
1 => RetryResult::Fail(SnafuError::Nonretryable),
2 => RetryResult::Success(previous),
_ => RetryResult::Retry(SnafuError::Retryable),
}
});
let res = runtime.block_on(future);
assert_eq!(res.err().unwrap().tries, 4);
}
#[test]
fn attempts_until_success() {
let runtime = Runtime::new().unwrap();
let retry_policy = RetryWithBackoff::default().max_tries(3);
let mut counter = 0;
let future = retry_async(retry_policy, || {
let previous = counter;
counter += 1;
async move {
if previous < 3 {
RetryResult::Retry(SnafuError::Retryable)
} else {
RetryResult::Success(previous)
}
}
});
let res = runtime.block_on(future);
assert_eq!(res, Ok(3));
assert_eq!(counter, 4);
}
}