veilid/veilid-core/src/xx/tools.rs

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use crate::xx::*;
use alloc::string::ToString;
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#[macro_export]
macro_rules! assert_err {
($ex:expr) => {
if let Ok(v) = $ex {
panic!("assertion failed, expected Err(..), got {:?}", v);
}
};
}
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pub fn split_port(name: &str) -> Result<(String, Option<u16>), String> {
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if let Some(split) = name.rfind(':') {
let hoststr = &name[0..split];
let portstr = &name[split + 1..];
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let port: u16 = portstr
.parse::<u16>()
.map_err(|e| format!("Invalid port: {}", e))?;
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Ok((hoststr.to_string(), Some(port)))
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} else {
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Ok((name.to_string(), None))
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}
}
pub fn prepend_slash(s: String) -> String {
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if s.starts_with('/') {
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return s;
}
let mut out = "/".to_owned();
out.push_str(s.as_str());
out
}
pub fn timestamp_to_secs(ts: u64) -> f64 {
ts as f64 / 1000000.0f64
}
pub fn secs_to_timestamp(secs: f64) -> u64 {
(secs * 1000000.0f64) as u64
}
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pub fn ms_to_us(ms: u32) -> u64 {
(ms as u64) * 1000u64
}
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// Calculate retry attempt with logarhythmic falloff
pub fn retry_falloff_log(
last_us: u64,
cur_us: u64,
interval_start_us: u64,
interval_max_us: u64,
interval_multiplier_us: f64,
) -> bool {
//
if cur_us < interval_start_us {
// Don't require a retry within the first 'interval_start_us' microseconds of the reliable time period
false
} else if cur_us >= last_us + interval_max_us {
// Retry at least every 'interval_max_us' microseconds
true
} else {
// Exponential falloff between 'interval_start_us' and 'interval_max_us' microseconds
// Optimal equation here is: y = Sum[Power[b,x],{n,0,x}] --> y = (x+1)b^x
// but we're just gonna simplify this to a log curve for speed
let last_secs = timestamp_to_secs(last_us);
let nth = (last_secs / timestamp_to_secs(interval_start_us))
.log(interval_multiplier_us)
.floor() as i32;
let next_secs = timestamp_to_secs(interval_start_us) * interval_multiplier_us.powi(nth + 1);
let next_us = secs_to_timestamp(next_secs);
cur_us >= next_us
}
}
pub fn try_at_most_n_things<T, I, C, R>(max: usize, things: I, closure: C) -> Option<R>
where
I: IntoIterator<Item = T>,
C: Fn(T) -> Option<R>,
{
let mut fails = 0usize;
for thing in things.into_iter() {
if let Some(r) = closure(thing) {
return Some(r);
}
fails += 1;
if fails >= max {
break;
}
}
None
}
pub async fn async_try_at_most_n_things<T, I, C, R, F>(
max: usize,
things: I,
closure: C,
) -> Option<R>
where
I: IntoIterator<Item = T>,
C: Fn(T) -> F,
F: Future<Output = Option<R>>,
{
let mut fails = 0usize;
for thing in things.into_iter() {
if let Some(r) = closure(thing).await {
return Some(r);
}
fails += 1;
if fails >= max {
break;
}
}
None
}
pub trait CmpAssign {
fn min_assign(&mut self, other: Self);
fn max_assign(&mut self, other: Self);
}
impl<T> CmpAssign for T
where
T: core::cmp::Ord,
{
fn min_assign(&mut self, other: Self) {
if &other < self {
*self = other;
}
}
fn max_assign(&mut self, other: Self) {
if &other > self {
*self = other;
}
}
}