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// taken from https://github.com/hyperium/http/blob/master/src/extensions.rs.
use crate::sync::{RwLockReadGuard, RwLockWriteGuard};
use std::{
any::{Any, TypeId},
collections::HashMap,
fmt,
hash::{BuildHasherDefault, Hasher},
};
#[allow(warnings)]
type AnyMap = HashMap<TypeId, Box<dyn Any + Send + Sync>, BuildHasherDefault<IdHasher>>;
/// With TypeIds as keys, there's no need to hash them. They are already hashes
/// themselves, coming from the compiler. The IdHasher holds the u64 of
/// the TypeId, and then returns it, instead of doing any bit fiddling.
#[derive(Default, Debug)]
struct IdHasher(u64);
impl Hasher for IdHasher {
fn write(&mut self, _: &[u8]) {
unreachable!("TypeId calls write_u64");
}
#[inline]
fn write_u64(&mut self, id: u64) {
self.0 = id;
}
#[inline]
fn finish(&self) -> u64 {
self.0
}
}
/// An immutable, read-only reference to a Span's extensions.
#[derive(Debug)]
pub struct Extensions<'a> {
inner: RwLockReadGuard<'a, ExtensionsInner>,
}
impl<'a> Extensions<'a> {
#[cfg(feature = "registry")]
pub(crate) fn new(inner: RwLockReadGuard<'a, ExtensionsInner>) -> Self {
Self { inner }
}
/// Immutably borrows a type previously inserted into this `Extensions`.
pub fn get<T: 'static>(&self) -> Option<&T> {
self.inner.get::<T>()
}
}
/// An mutable reference to a Span's extensions.
#[derive(Debug)]
pub struct ExtensionsMut<'a> {
inner: RwLockWriteGuard<'a, ExtensionsInner>,
}
impl<'a> ExtensionsMut<'a> {
#[cfg(feature = "registry")]
pub(crate) fn new(inner: RwLockWriteGuard<'a, ExtensionsInner>) -> Self {
Self { inner }
}
/// Insert a type into this `Extensions`.
///
/// Note that extensions are _not_
/// `Layer`-specific—they are _span_-specific. This means that
/// other layers can access and mutate extensions that
/// a different Layer recorded. For example, an application might
/// have a layer that records execution timings, alongside a layer
/// that reports spans and events to a distributed
/// tracing system that requires timestamps for spans.
/// Ideally, if one layer records a timestamp _x_, the other layer
/// should be able to reuse timestamp _x_.
///
/// Therefore, extensions should generally be newtypes, rather than common
/// types like [`String`](https://doc.rust-lang.org/std/string/struct.String.html), to avoid accidental
/// cross-`Layer` clobbering.
///
/// ## Panics
///
/// If `T` is already present in `Extensions`, then this method will panic.
pub fn insert<T: Send + Sync + 'static>(&mut self, val: T) {
assert!(self.replace(val).is_none())
}
/// Replaces an existing `T` into this extensions.
///
/// If `T` is not present, `Option::None` will be returned.
pub fn replace<T: Send + Sync + 'static>(&mut self, val: T) -> Option<T> {
self.inner.insert(val)
}
/// Get a mutable reference to a type previously inserted on this `ExtensionsMut`.
pub fn get_mut<T: 'static>(&mut self) -> Option<&mut T> {
self.inner.get_mut::<T>()
}
/// Remove a type from this `Extensions`.
///
/// If a extension of this type existed, it will be returned.
pub fn remove<T: Send + Sync + 'static>(&mut self) -> Option<T> {
self.inner.remove::<T>()
}
}
/// A type map of span extensions.
///
/// [ExtensionsInner] is used by `SpanData` to store and
/// span-specific data. A given `Layer` can read and write
/// data that it is interested in recording and emitting.
#[derive(Default)]
pub(crate) struct ExtensionsInner {
map: AnyMap,
}
impl ExtensionsInner {
/// Create an empty `Extensions`.
#[inline]
#[cfg(any(test, feature = "registry"))]
pub(crate) fn new() -> ExtensionsInner {
ExtensionsInner {
map: AnyMap::default(),
}
}
/// Insert a type into this `Extensions`.
///
/// If a extension of this type already existed, it will
/// be returned.
pub(crate) fn insert<T: Send + Sync + 'static>(&mut self, val: T) -> Option<T> {
self.map
.insert(TypeId::of::<T>(), Box::new(val))
.and_then(|boxed| {
#[allow(warnings)]
{
(boxed as Box<Any + 'static>)
.downcast()
.ok()
.map(|boxed| *boxed)
}
})
}
/// Get a reference to a type previously inserted on this `Extensions`.
pub(crate) fn get<T: 'static>(&self) -> Option<&T> {
self.map
.get(&TypeId::of::<T>())
.and_then(|boxed| (&**boxed as &(dyn Any + 'static)).downcast_ref())
}
/// Get a mutable reference to a type previously inserted on this `Extensions`.
pub(crate) fn get_mut<T: 'static>(&mut self) -> Option<&mut T> {
self.map
.get_mut(&TypeId::of::<T>())
.and_then(|boxed| (&mut **boxed as &mut (dyn Any + 'static)).downcast_mut())
}
/// Remove a type from this `Extensions`.
///
/// If a extension of this type existed, it will be returned.
pub(crate) fn remove<T: Send + Sync + 'static>(&mut self) -> Option<T> {
self.map.remove(&TypeId::of::<T>()).and_then(|boxed| {
#[allow(warnings)]
{
(boxed as Box<Any + 'static>)
.downcast()
.ok()
.map(|boxed| *boxed)
}
})
}
/// Clear the `ExtensionsInner` in-place, dropping any elements in the map but
/// retaining allocated capacity.
///
/// This permits the hash map allocation to be pooled by the registry so
/// that future spans will not need to allocate new hashmaps.
#[cfg(any(test, feature = "registry"))]
pub(crate) fn clear(&mut self) {
self.map.clear();
}
}
impl fmt::Debug for ExtensionsInner {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_struct("Extensions")
.field("len", &self.map.len())
.field("capacity", &self.map.capacity())
.finish()
}
}
#[cfg(test)]
mod tests {
use super::*;
#[derive(Debug, PartialEq)]
struct MyType(i32);
#[test]
fn test_extensions() {
let mut extensions = ExtensionsInner::new();
extensions.insert(5i32);
extensions.insert(MyType(10));
assert_eq!(extensions.get(), Some(&5i32));
assert_eq!(extensions.get_mut(), Some(&mut 5i32));
assert_eq!(extensions.remove::<i32>(), Some(5i32));
assert!(extensions.get::<i32>().is_none());
assert_eq!(extensions.get::<bool>(), None);
assert_eq!(extensions.get(), Some(&MyType(10)));
}
#[test]
fn clear_retains_capacity() {
let mut extensions = ExtensionsInner::new();
extensions.insert(5i32);
extensions.insert(MyType(10));
extensions.insert(true);
assert_eq!(extensions.map.len(), 3);
let prev_capacity = extensions.map.capacity();
extensions.clear();
assert_eq!(
extensions.map.len(),
0,
"after clear(), extensions map should have length 0"
);
assert_eq!(
extensions.map.capacity(),
prev_capacity,
"after clear(), extensions map should retain prior capacity"
);
}
#[test]
fn clear_drops_elements() {
use std::sync::Arc;
struct DropMePlease(Arc<()>);
struct DropMeTooPlease(Arc<()>);
let mut extensions = ExtensionsInner::new();
let val1 = DropMePlease(Arc::new(()));
let val2 = DropMeTooPlease(Arc::new(()));
let val1_dropped = Arc::downgrade(&val1.0);
let val2_dropped = Arc::downgrade(&val2.0);
extensions.insert(val1);
extensions.insert(val2);
assert!(val1_dropped.upgrade().is_some());
assert!(val2_dropped.upgrade().is_some());
extensions.clear();
assert!(
val1_dropped.upgrade().is_none(),
"after clear(), val1 should be dropped"
);
assert!(
val2_dropped.upgrade().is_none(),
"after clear(), val2 should be dropped"
);
}
}