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//! Callsites represent the source locations from which spans or events
//! originate.
use crate::stdlib::{
fmt,
hash::{Hash, Hasher},
sync::Mutex,
vec::Vec,
};
use crate::{
dispatcher::{self, Dispatch},
metadata::{LevelFilter, Metadata},
subscriber::Interest,
};
crate::lazy_static! {
static ref REGISTRY: Mutex<Registry> = Mutex::new(Registry {
callsites: Vec::new(),
dispatchers: Vec::new(),
});
}
struct Registry {
callsites: Vec<&'static dyn Callsite>,
dispatchers: Vec<dispatcher::Registrar>,
}
impl Registry {
fn rebuild_callsite_interest(&self, callsite: &'static dyn Callsite) {
let meta = callsite.metadata();
// Iterate over the subscribers in the registry, and — if they are
// active — register the callsite with them.
let mut interests = self
.dispatchers
.iter()
.filter_map(|registrar| registrar.try_register(meta));
// Use the first subscriber's `Interest` as the base value.
let interest = if let Some(interest) = interests.next() {
// Combine all remaining `Interest`s.
interests.fold(interest, Interest::and)
} else {
// If nobody was interested in this thing, just return `never`.
Interest::never()
};
callsite.set_interest(interest)
}
fn rebuild_interest(&mut self) {
let mut max_level = LevelFilter::OFF;
self.dispatchers.retain(|registrar| {
if let Some(dispatch) = registrar.upgrade() {
// If the subscriber did not provide a max level hint, assume
// that it may enable every level.
let level_hint = dispatch.max_level_hint().unwrap_or(LevelFilter::TRACE);
if level_hint > max_level {
max_level = level_hint;
}
true
} else {
false
}
});
self.callsites.iter().for_each(|&callsite| {
self.rebuild_callsite_interest(callsite);
});
LevelFilter::set_max(max_level);
}
}
/// Trait implemented by callsites.
///
/// These functions are only intended to be called by the callsite registry, which
/// correctly handles determining the common interest between all subscribers.
pub trait Callsite: Sync {
/// Sets the [`Interest`] for this callsite.
///
/// [`Interest`]: super::subscriber::Interest
fn set_interest(&self, interest: Interest);
/// Returns the [metadata] associated with the callsite.
///
/// [metadata]: super::metadata::Metadata
fn metadata(&self) -> &Metadata<'_>;
}
/// Uniquely identifies a [`Callsite`]
///
/// Two `Identifier`s are equal if they both refer to the same callsite.
///
/// [`Callsite`]: super::callsite::Callsite
#[derive(Clone)]
pub struct Identifier(
/// **Warning**: The fields on this type are currently `pub` because it must
/// be able to be constructed statically by macros. However, when `const
/// fn`s are available on stable Rust, this will no longer be necessary.
/// Thus, these fields are *not* considered stable public API, and they may
/// change warning. Do not rely on any fields on `Identifier`. When
/// constructing new `Identifier`s, use the `identify_callsite!` macro
/// instead.
#[doc(hidden)]
pub &'static dyn Callsite,
);
/// Clear and reregister interest on every [`Callsite`]
///
/// This function is intended for runtime reconfiguration of filters on traces
/// when the filter recalculation is much less frequent than trace events are.
/// The alternative is to have the [`Subscriber`] that supports runtime
/// reconfiguration of filters always return [`Interest::sometimes()`] so that
/// [`enabled`] is evaluated for every event.
///
/// This function will also re-compute the global maximum level as determined by
/// the [`max_level_hint`] method. If a [`Subscriber`]
/// implementation changes the value returned by its `max_level_hint`
/// implementation at runtime, then it **must** call this function after that
/// value changes, in order for the change to be reflected.
///
/// [`max_level_hint`]: super::subscriber::Subscriber::max_level_hint
/// [`Callsite`]: super::callsite::Callsite
/// [`enabled`]: super::subscriber::Subscriber#tymethod.enabled
/// [`Interest::sometimes()`]: super::subscriber::Interest::sometimes
/// [`Subscriber`]: super::subscriber::Subscriber
pub fn rebuild_interest_cache() {
let mut registry = REGISTRY.lock().unwrap();
registry.rebuild_interest();
}
/// Register a new `Callsite` with the global registry.
///
/// This should be called once per callsite after the callsite has been
/// constructed.
pub fn register(callsite: &'static dyn Callsite) {
let mut registry = REGISTRY.lock().unwrap();
registry.rebuild_callsite_interest(callsite);
registry.callsites.push(callsite);
}
pub(crate) fn register_dispatch(dispatch: &Dispatch) {
let mut registry = REGISTRY.lock().unwrap();
registry.dispatchers.push(dispatch.registrar());
registry.rebuild_interest();
}
// ===== impl Identifier =====
impl PartialEq for Identifier {
fn eq(&self, other: &Identifier) -> bool {
core::ptr::eq(
self.0 as *const _ as *const (),
other.0 as *const _ as *const (),
)
}
}
impl Eq for Identifier {}
impl fmt::Debug for Identifier {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "Identifier({:p})", self.0)
}
}
impl Hash for Identifier {
fn hash<H>(&self, state: &mut H)
where
H: Hasher,
{
(self.0 as *const dyn Callsite).hash(state)
}
}