A proc macro to insert appropriate flame::start_guard(_) calls (for use with
flame)
This proc macro requires Rust 1.30. Because flamer is a proc macro attribute, it uses APIs stabilized in Rust 1.30.
In your Cargo.toml add flame and flamer to your dependencies:
[dependencies]
flame = "0.2.2"
flamer = "0.5"Then in your crate root, add the following:
extern crate flame;
#[macro_use] extern crate flamer;
#[flame]
// The item to apply `flame` to goes here.Unfortunately, currently stable Rust doesn't allow custom attributes on modules.
To use #[flame] on modules you need a nightly Rust with
#![feature(proc_macro_hygiene)] in the crate root
(related issue):
#![feature(proc_macro_hygiene)]
extern crate flame;
#[macro_use] extern crate flamer;
#[flame]
mod flamed_module { .. }You may also opt for an optional dependency. In that case your Cargo.toml should have:
[dependencies]
flame = { version = "0.2.2", optional = true }
flamer = { version = "0.3", optional = true }
[features]
default = []
flame_it = ["flame", "flamer"]And your crate root should contain:
#[cfg(feature = "flame_it")]
extern crate flame;
#[cfg(feature = "flame_it")]
#[macro_use] extern crate flamer;
// as well as the following instead of `#[flame]`
#[cfg_attr(feature = "flame_it", flame)]
// The item to apply `flame` to goes here.For nightly module support, also add
#![cfg_attr(feature = "flame_it", feature(proc_macro_hygiene))] in the crate
root:
#![cfg_attr(feature = "flame_it", feature(proc_macro_hygiene))]
#[cfg(feature = "flame_it")]
extern crate flame;
#[cfg(feature = "flame_it")]
#[macro_use] extern crate flamer;
// as well as the following instead of `#[flame]`
#[cfg_attr(feature = "flame_it", flame)]
mod flamed_module { .. }You should then be able to annotate every item (alas, currently not the whole
crate; see the
custom inner attribute issue
for more details) with #[flame] annotations.
You can also use #[noflame] annotations to disable instrumentations for
subitems of #[flame]d items. Note that this only instruments the annotated
methods, it does not print out the results.
The flame annotation can also take an optional parameter specifying a string
to prefix to enclosed method names.
This is especially useful when annotating multiple methods with the same name,
but in different modules.
#[flame("prefix")]
fn method_name() {
//The corresponding block on the flamegraph will be named "prefix::method_name"
}use std::fs::File;
use flame as f;
use flamer::flame;
#[flame]
fn make_vec(size: usize) -> Vec<u32> {
// using the original lib is still possible
let mut res = f::span_of("vec init", || vec![0_u32; size]);
for x in 0..size {
res[x] = ((x + 10)/3) as u32;
}
let mut waste_time = 0;
for i in 0..size*10 {
waste_time += i
}
res
}
#[flame]
fn more_computing(i: usize) {
for x in 0..(i * 100) {
let mut v = make_vec(x);
let x = Vec::from(&v[..]);
for i in 0..v.len() {
let flip = (v.len() - 1) - i as usize;
v[i] = x[flip];
}
}
}
#[flame]
fn some_computation() {
for i in 0..15 {
more_computing(i);
}
}
#[flame]
fn main() {
some_computation();
// in order to create the flamegraph you must call one of the
// flame::dump_* functions.
f::dump_html(File::create("flamegraph.html").unwrap()).unwrap();
}
Refer to flame's documentation to see how output works.
License: Apache 2.0