rust-analyzer/crates/profile/src/hprof.rs
2021-10-03 23:53:30 +11:00

326 lines
9.1 KiB
Rust

//! Simple hierarchical profiler
use std::{
cell::RefCell,
collections::{BTreeMap, HashSet},
env, fmt,
io::{stderr, Write},
sync::{
atomic::{AtomicBool, Ordering},
RwLock,
},
time::{Duration, Instant},
};
use once_cell::sync::Lazy;
use crate::tree::{Idx, Tree};
/// Filtering syntax
/// env RA_PROFILE=* // dump everything
/// env RA_PROFILE=foo|bar|baz // enabled only selected entries
/// env RA_PROFILE=*@3>10 // dump everything, up to depth 3, if it takes more than 10 ms
pub fn init() {
countme::enable(env::var("RA_COUNT").is_ok());
let spec = env::var("RA_PROFILE").unwrap_or_default();
init_from(&spec);
}
pub fn init_from(spec: &str) {
let filter = if spec.is_empty() { Filter::disabled() } else { Filter::from_spec(spec) };
filter.install();
}
type Label = &'static str;
/// This function starts a profiling scope in the current execution stack with a given description.
/// It returns a `Profile` struct that measures elapsed time between this method invocation and `Profile` struct drop.
/// It supports nested profiling scopes in case when this function is invoked multiple times at the execution stack.
/// In this case the profiling information will be nested at the output.
/// Profiling information is being printed in the stderr.
///
/// # Example
/// ```
/// profile::init_from("profile1|profile2@2");
/// profiling_function1();
///
/// fn profiling_function1() {
/// let _p = profile::span("profile1");
/// profiling_function2();
/// }
///
/// fn profiling_function2() {
/// let _p = profile::span("profile2");
/// }
/// ```
/// This will print in the stderr the following:
/// ```text
/// 0ms - profile
/// 0ms - profile2
/// ```
#[inline]
pub fn span(label: Label) -> ProfileSpan {
debug_assert!(!label.is_empty());
let enabled = PROFILING_ENABLED.load(Ordering::Relaxed);
if enabled && with_profile_stack(|stack| stack.push(label)) {
ProfileSpan(Some(ProfilerImpl { label, detail: None }))
} else {
ProfileSpan(None)
}
}
#[inline]
pub fn heartbeat_span() -> HeartbeatSpan {
let enabled = PROFILING_ENABLED.load(Ordering::Relaxed);
HeartbeatSpan::new(enabled)
}
#[inline]
pub fn heartbeat() {
let enabled = PROFILING_ENABLED.load(Ordering::Relaxed);
if enabled {
with_profile_stack(|it| it.heartbeat(1));
}
}
pub struct ProfileSpan(Option<ProfilerImpl>);
struct ProfilerImpl {
label: Label,
detail: Option<String>,
}
impl ProfileSpan {
pub fn detail(mut self, detail: impl FnOnce() -> String) -> ProfileSpan {
if let Some(profiler) = &mut self.0 {
profiler.detail = Some(detail());
}
self
}
}
impl Drop for ProfilerImpl {
#[inline]
fn drop(&mut self) {
with_profile_stack(|it| it.pop(self.label, self.detail.take()));
}
}
pub struct HeartbeatSpan {
enabled: bool,
}
impl HeartbeatSpan {
#[inline]
pub fn new(enabled: bool) -> Self {
if enabled {
with_profile_stack(|it| it.heartbeats(true));
}
Self { enabled }
}
}
impl Drop for HeartbeatSpan {
fn drop(&mut self) {
if self.enabled {
with_profile_stack(|it| it.heartbeats(false));
}
}
}
static PROFILING_ENABLED: AtomicBool = AtomicBool::new(false);
static FILTER: Lazy<RwLock<Filter>> = Lazy::new(Default::default);
fn with_profile_stack<T>(f: impl FnOnce(&mut ProfileStack) -> T) -> T {
thread_local!(static STACK: RefCell<ProfileStack> = RefCell::new(ProfileStack::new()));
STACK.with(|it| f(&mut *it.borrow_mut()))
}
#[derive(Default, Clone, Debug)]
struct Filter {
depth: usize,
allowed: HashSet<String>,
longer_than: Duration,
heartbeat_longer_than: Duration,
version: usize,
}
impl Filter {
fn disabled() -> Filter {
Filter::default()
}
fn from_spec(mut spec: &str) -> Filter {
let longer_than = if let Some(idx) = spec.rfind('>') {
let longer_than = spec[idx + 1..].parse().expect("invalid profile longer_than");
spec = &spec[..idx];
Duration::from_millis(longer_than)
} else {
Duration::new(0, 0)
};
let heartbeat_longer_than = longer_than;
let depth = if let Some(idx) = spec.rfind('@') {
let depth: usize = spec[idx + 1..].parse().expect("invalid profile depth");
spec = &spec[..idx];
depth
} else {
999
};
let allowed =
if spec == "*" { HashSet::new() } else { spec.split('|').map(String::from).collect() };
Filter { depth, allowed, longer_than, heartbeat_longer_than, version: 0 }
}
fn install(mut self) {
PROFILING_ENABLED.store(self.depth > 0, Ordering::SeqCst);
let mut old = FILTER.write().unwrap();
self.version = old.version + 1;
*old = self;
}
}
struct ProfileStack {
frames: Vec<Frame>,
filter: Filter,
messages: Tree<Message>,
heartbeats: bool,
}
struct Frame {
t: Instant,
heartbeats: u32,
}
#[derive(Default)]
struct Message {
duration: Duration,
label: Label,
detail: Option<String>,
}
impl ProfileStack {
fn new() -> ProfileStack {
ProfileStack {
frames: Vec::new(),
messages: Tree::default(),
filter: Default::default(),
heartbeats: false,
}
}
fn push(&mut self, label: Label) -> bool {
if self.frames.is_empty() {
if let Ok(f) = FILTER.try_read() {
if f.version > self.filter.version {
self.filter = f.clone();
}
};
}
if self.frames.len() > self.filter.depth {
return false;
}
let allowed = &self.filter.allowed;
if self.frames.is_empty() && !allowed.is_empty() && !allowed.contains(label) {
return false;
}
self.frames.push(Frame { t: Instant::now(), heartbeats: 0 });
self.messages.start();
true
}
fn pop(&mut self, label: Label, detail: Option<String>) {
let frame = self.frames.pop().unwrap();
let duration = frame.t.elapsed();
if self.heartbeats {
self.heartbeat(frame.heartbeats);
let avg_span = duration / (frame.heartbeats + 1);
if avg_span > self.filter.heartbeat_longer_than {
eprintln!("Too few heartbeats {} ({}/{:?})?", label, frame.heartbeats, duration);
}
}
self.messages.finish(Message { duration, label, detail });
if self.frames.is_empty() {
let longer_than = self.filter.longer_than;
// Convert to millis for comparison to avoid problems with rounding
// (otherwise we could print `0ms` despite user's `>0` filter when
// `duration` is just a few nanos).
if duration.as_millis() > longer_than.as_millis() {
if let Some(root) = self.messages.root() {
print(&self.messages, root, 0, longer_than, &mut stderr().lock());
}
}
self.messages.clear();
}
}
fn heartbeats(&mut self, yes: bool) {
self.heartbeats = yes;
}
fn heartbeat(&mut self, n: u32) {
if let Some(frame) = self.frames.last_mut() {
frame.heartbeats += n;
}
}
}
fn print(
tree: &Tree<Message>,
curr: Idx<Message>,
level: u32,
longer_than: Duration,
out: &mut impl Write,
) {
let current_indent = " ".repeat(level as usize);
let detail = tree[curr].detail.as_ref().map(|it| format!(" @ {}", it)).unwrap_or_default();
writeln!(
out,
"{}{} - {}{}",
current_indent,
ms(tree[curr].duration),
tree[curr].label,
detail,
)
.expect("printing profiling info");
let mut accounted_for = Duration::default();
let mut short_children = BTreeMap::new(); // Use `BTreeMap` to get deterministic output.
for child in tree.children(curr) {
accounted_for += tree[child].duration;
if tree[child].duration.as_millis() > longer_than.as_millis() {
print(tree, child, level + 1, longer_than, out);
} else {
let (total_duration, cnt) =
short_children.entry(tree[child].label).or_insert((Duration::default(), 0));
*total_duration += tree[child].duration;
*cnt += 1;
}
}
for (child_msg, (duration, count)) in &short_children {
writeln!(out, " {}{} - {} ({} calls)", current_indent, ms(*duration), child_msg, count)
.expect("printing profiling info");
}
let unaccounted = tree[curr].duration - accounted_for;
if tree.children(curr).next().is_some() && unaccounted > longer_than {
writeln!(out, " {}{} - ???", current_indent, ms(unaccounted))
.expect("printing profiling info");
}
}
#[allow(non_camel_case_types)]
struct ms(Duration);
impl fmt::Display for ms {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self.0.as_millis() {
0 => f.write_str(" 0 "),
n => write!(f, "{:5}ms", n),
}
}
}