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denoland-deno/cli/tools/bench/mitata.rs

462 lines
12 KiB
Rust

// Copyright 2022 evanwashere
//
// Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
use crate::colors;
use std::str::FromStr;
fn avg_to_iter_per_s(time: f64) -> String {
let iter_per_s = 1e9 / time;
let (decimals, fractional) = into_decimal_and_fractional_parts(iter_per_s);
human_readable_decimal_with_fractional(decimals, fractional)
}
/// Return a tuple representing decimal part of provided float, as well as its
/// first fractional digit.
fn into_decimal_and_fractional_parts(num: f64) -> (i64, i64) {
let mut decimal_part = num.floor() as i64;
let fractional_part = {
let decs = ((num - num.floor()) * 10.0).round();
if decs == 10.0 {
decimal_part += 1;
0
} else {
decs as i64
}
};
(decimal_part, fractional_part)
}
fn human_readable_decimal_with_fractional(
decimal: i64,
fractional: i64,
) -> String {
// Sweet one-liner to separate integer by commas from:
// https://stackoverflow.com/a/67834588/21759102
let fmt_decimal = decimal
.to_string()
.as_bytes()
.rchunks(3)
.rev()
.map(std::str::from_utf8)
.collect::<Result<Vec<&str>, _>>()
.unwrap()
.join(",");
format!("{}.{}", fmt_decimal, fractional)
}
pub fn fmt_duration(time: f64) -> String {
// SAFETY: this is safe since its just reformatting numbers
unsafe {
if time < 1e0 {
return format!(
"{} ps",
f64::from_str(&format!("{:.2}", time * 1e3)).unwrap_unchecked()
);
}
if time < 1e3 {
return format!(
"{} ns",
f64::from_str(&format!("{:.2}", time)).unwrap_unchecked()
);
}
if time < 1e6 {
return format!(
"{} µs",
f64::from_str(&format!("{:.2}", time / 1e3)).unwrap_unchecked()
);
}
if time < 1e9 {
return format!(
"{} ms",
f64::from_str(&format!("{:.2}", time / 1e6)).unwrap_unchecked()
);
}
if time < 1e12 {
return format!(
"{} s",
f64::from_str(&format!("{:.2}", time / 1e9)).unwrap_unchecked()
);
}
if time < 36e11 {
return format!(
"{} m",
f64::from_str(&format!("{:.2}", time / 60e9)).unwrap_unchecked()
);
}
format!(
"{} h",
f64::from_str(&format!("{:.2}", time / 36e11)).unwrap_unchecked()
)
}
}
pub mod cpu {
#![allow(dead_code)]
pub fn name() -> String {
#[cfg(target_os = "linux")]
return linux();
#[cfg(target_os = "macos")]
return macos();
#[cfg(target_os = "windows")]
return windows();
#[allow(unreachable_code)]
{
"unknown".to_string()
}
}
pub fn macos() -> String {
let mut sysctl = std::process::Command::new("sysctl");
sysctl.arg("-n");
sysctl.arg("machdep.cpu.brand_string");
return std::str::from_utf8(
&sysctl
.output()
.map(|x| x.stdout)
.unwrap_or(Vec::from("unknown")),
)
.unwrap()
.trim()
.to_string();
}
pub fn windows() -> String {
let mut wmi = std::process::Command::new("wmic");
wmi.arg("cpu");
wmi.arg("get");
wmi.arg("name");
return match wmi.output() {
Err(_) => String::from("unknown"),
Ok(x) => {
let x = String::from_utf8_lossy(&x.stdout);
return x.lines().nth(1).unwrap_or("unknown").trim().to_string();
}
};
}
pub fn linux() -> String {
let info =
std::fs::read_to_string("/proc/cpuinfo").unwrap_or(String::new());
for line in info.lines() {
let mut iter = line.split(':');
let key = iter.next().unwrap_or("");
if key.contains("Hardware")
|| key.contains("Processor")
|| key.contains("chip type")
|| key.contains("model name")
|| key.starts_with("cpu type")
|| key.starts_with("cpu model")
{
return iter.next().unwrap_or("unknown").trim().to_string();
}
}
String::from("unknown")
}
}
pub mod reporter {
use super::*;
#[derive(Clone, PartialEq)]
pub struct Error {
pub message: String,
pub stack: Option<String>,
}
#[derive(Clone, PartialEq)]
pub struct BenchmarkStats {
pub avg: f64,
pub min: f64,
pub max: f64,
pub p75: f64,
pub p99: f64,
pub p995: f64,
}
#[derive(Clone, PartialEq)]
pub struct GroupBenchmark {
pub name: String,
pub group: String,
pub baseline: bool,
pub stats: BenchmarkStats,
}
#[derive(Clone, PartialEq)]
pub struct Options {
size: usize,
pub avg: bool,
pub colors: bool,
pub min_max: bool,
pub percentiles: bool,
}
impl Options {
pub fn new(names: &[&str]) -> Options {
Options {
avg: true,
colors: true,
min_max: true,
size: size(names),
percentiles: true,
}
}
}
pub fn size(names: &[&str]) -> usize {
let mut max = 9;
for name in names {
if max < name.len() {
max = name.len();
}
}
2 + max
}
pub fn br(options: &Options) -> String {
let mut s = String::new();
s.push_str(&"-".repeat(
options.size
+ 14 * options.avg as usize
+ 14 * options.avg as usize
+ 24 * options.min_max as usize,
));
if options.percentiles {
s.push(' ');
s.push_str(&"-".repeat(9 + 10 + 10));
}
s
}
pub fn benchmark_error(n: &str, e: &Error, options: &Options) -> String {
let size = options.size;
let mut s = String::new();
s.push_str(&format!("{:<size$}", n));
s.push_str(&format!(
"{}: {}",
&(if !options.colors {
"error".to_string()
} else {
colors::red("error").to_string()
}),
e.message
));
if let Some(ref stack) = e.stack {
s.push('\n');
match options.colors {
false => s.push_str(stack),
true => s.push_str(&colors::gray(stack).to_string()),
}
}
s
}
pub fn header(options: &Options) -> String {
let size = options.size;
let mut s = String::new();
s.push_str(&format!("{:<size$}", "benchmark"));
if options.avg {
s.push_str(&format!("{:>14}", "time (avg)"));
s.push_str(&format!("{:>14}", "iter/s"));
}
if options.min_max {
s.push_str(&format!("{:>24}", "(min … max)"));
}
if options.percentiles {
s.push_str(&format!(" {:>9} {:>9} {:>9}", "p75", "p99", "p995"));
}
s
}
pub fn benchmark(
name: &str,
stats: &BenchmarkStats,
options: &Options,
) -> String {
let size = options.size;
let mut s = String::new();
s.push_str(&format!("{:<size$}", name));
if !options.colors {
if options.avg {
s.push_str(&format!(
"{:>14}",
format!("{}/iter", fmt_duration(stats.avg))
));
s.push_str(&format!("{:>14}", avg_to_iter_per_s(stats.avg)));
}
if options.min_max {
s.push_str(&format!(
"{:>24}",
format!(
"({}{})",
fmt_duration(stats.min),
fmt_duration(stats.max)
)
));
}
if options.percentiles {
s.push_str(&format!(
" {:>9} {:>9} {:>9}",
fmt_duration(stats.p75),
fmt_duration(stats.p99),
fmt_duration(stats.p995)
));
}
} else {
if options.avg {
s.push_str(&format!(
"{:>30}",
format!("{}/iter", colors::yellow(fmt_duration(stats.avg)))
));
s.push_str(&format!("{:>14}", avg_to_iter_per_s(stats.avg)));
}
if options.min_max {
s.push_str(&format!(
"{:>50}",
format!(
"({}{})",
colors::cyan(fmt_duration(stats.min)),
colors::magenta(fmt_duration(stats.max))
)
));
}
if options.percentiles {
s.push_str(&format!(
" {:>22} {:>22} {:>22}",
colors::magenta(fmt_duration(stats.p75)),
colors::magenta(fmt_duration(stats.p99)),
colors::magenta(fmt_duration(stats.p995))
));
}
}
s
}
pub fn summary(benchmarks: &[GroupBenchmark], options: &Options) -> String {
let mut s = String::new();
let mut benchmarks = benchmarks.to_owned();
benchmarks.sort_by(|a, b| a.stats.avg.partial_cmp(&b.stats.avg).unwrap());
let baseline = benchmarks
.iter()
.find(|b| b.baseline)
.unwrap_or(&benchmarks[0]);
if !options.colors {
s.push_str(&format!("summary\n {}", baseline.name));
for b in benchmarks.iter().filter(|b| *b != baseline) {
let faster = b.stats.avg >= baseline.stats.avg;
let diff = f64::from_str(&format!(
"{:.2}",
1.0 / baseline.stats.avg * b.stats.avg
))
.unwrap();
let inv_diff = f64::from_str(&format!(
"{:.2}",
1.0 / b.stats.avg * baseline.stats.avg
))
.unwrap();
s.push_str(&format!(
"\n {}x times {} than {}",
if faster { diff } else { inv_diff },
if faster { "faster" } else { "slower" },
b.name
));
}
} else {
s.push_str(&format!(
"{}\n {}",
colors::bold("summary"),
colors::cyan_bold(&baseline.name)
));
for b in benchmarks.iter().filter(|b| *b != baseline) {
let faster = b.stats.avg >= baseline.stats.avg;
let diff = f64::from_str(&format!(
"{:.2}",
1.0 / baseline.stats.avg * b.stats.avg
))
.unwrap();
let inv_diff = f64::from_str(&format!(
"{:.2}",
1.0 / b.stats.avg * baseline.stats.avg
))
.unwrap();
s.push_str(&format!(
"\n {}x {} than {}",
if faster {
colors::green(diff.to_string()).to_string()
} else {
colors::red(inv_diff.to_string()).to_string()
},
if faster { "faster" } else { "slower" },
colors::cyan_bold(&b.name)
));
}
}
s
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_into_decimal_and_fractional_parts() {
assert_eq!(into_decimal_and_fractional_parts(10.0), (10, 0));
assert_eq!(into_decimal_and_fractional_parts(10.1), (10, 1));
assert_eq!(into_decimal_and_fractional_parts(10.2), (10, 2));
assert_eq!(into_decimal_and_fractional_parts(10.3), (10, 3));
assert_eq!(into_decimal_and_fractional_parts(10.4), (10, 4));
assert_eq!(into_decimal_and_fractional_parts(10.5), (10, 5));
assert_eq!(into_decimal_and_fractional_parts(10.6), (10, 6));
assert_eq!(into_decimal_and_fractional_parts(10.7), (10, 7));
assert_eq!(into_decimal_and_fractional_parts(10.8), (10, 8));
assert_eq!(into_decimal_and_fractional_parts(10.9), (10, 9));
assert_eq!(into_decimal_and_fractional_parts(10.99), (11, 0));
}
#[test]
fn test_avg_to_iter_per_s() {
assert_eq!(avg_to_iter_per_s(55.85), "17,905,103.0");
assert_eq!(avg_to_iter_per_s(64_870_000.0), "15.4");
assert_eq!(avg_to_iter_per_s(104_370_000.0), "9.6");
assert_eq!(avg_to_iter_per_s(6_400_000.0), "156.3");
assert_eq!(avg_to_iter_per_s(46_890_000.0), "21.3");
assert_eq!(avg_to_iter_per_s(100_000_000.0), "10.0");
assert_eq!(avg_to_iter_per_s(1_000_000_000.0), "1.0");
assert_eq!(avg_to_iter_per_s(5_920_000_000.0), "0.2");
}
}