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//! Collectors collect and record trace data.
use crate::{span, Dispatch, Event, LevelFilter, Metadata};
use core::any::{Any, TypeId};
use core::ptr::NonNull;
/// Trait representing the functions required to collect trace data.
///
/// Crates that provide implementations of methods for collecting or recording
/// trace data should implement the `Collect` interface. This trait is
/// intended to represent fundamental primitives for collecting trace events and
/// spans — other libraries may offer utility functions and types to make
/// collector implementations more modular or improve the ergonomics of writing
/// collectors.
///
/// A collector is responsible for the following:
/// - Registering new spans as they are created, and providing them with span
/// IDs. Implicitly, this means the collector may determine the strategy for
/// determining span equality.
/// - Recording the attachment of field values and follows-from annotations to
/// spans.
/// - Filtering spans and events, and determining when those filters must be
/// invalidated.
/// - Observing spans as they are entered, exited, and closed, and events as
/// they occur.
///
/// When a span is entered or exited, the collector is provided only with the
/// [ID] with which it tagged that span when it was created. This means
/// that it is up to the collector to determine whether and how span _data_ —
/// the fields and metadata describing the span — should be stored. The
/// [`new_span`] function is called when a new span is created, and at that
/// point, the collector _may_ choose to store the associated data if it will
/// be referenced again. However, if the data has already been recorded and will
/// not be needed by the implementations of `enter` and `exit`, the collector
/// may freely discard that data without allocating space to store it.
///
/// ## Overriding default impls
///
/// Some trait methods on `Collect` have default implementations, either in
/// order to reduce the surface area of implementing `Collect`, or for
/// backward-compatibility reasons. However, many collectors will likely want
/// to override these default implementations.
///
/// The following methods are likely of interest:
///
/// - [`register_callsite`] is called once for each callsite from which a span
/// event may originate, and returns an [`Interest`] value describing whether or
/// not the collector wishes to see events or spans from that callsite. By
/// default, it calls [`enabled`], and returns `Interest::always()` if
/// `enabled` returns true, or `Interest::never()` if enabled returns false.
/// However, if the collector's interest can change dynamically at runtime,
/// it may want to override this function to return `Interest::sometimes()`.
/// Additionally, collectors which wish to perform a behaviour once for each
/// callsite, such as allocating storage for data related to that callsite,
/// can perform it in `register_callsite`.
///
/// See also the [documentation on the callsite registry][cs-reg] for details
/// on [`register_callsite`].
///
/// - [`event_enabled`] is called once before every call to the [`event`]
/// method. This can be used to implement filtering on events once their field
/// values are known, but before any processing is done in the `event` method.
/// - [`clone_span`] is called every time a span ID is cloned, and [`try_close`]
/// is called when a span ID is dropped. By default, these functions do
/// nothing. However, they can be used to implement reference counting for
/// spans, allowing collectors to free storage for span data and to determine
/// when a span has _closed_ permanently (rather than being exited).
/// Collectors which store per-span data or which need to track span closures
/// should override these functions together.
///
/// [ID]: super::span::Id
/// [`new_span`]: Collect::new_span
/// [`register_callsite`]: Collect::register_callsite
/// [`enabled`]: Collect::enabled
/// [`clone_span`]: Collect::clone_span
/// [`try_close`]: Collect::try_close
/// [cs-reg]: crate::callsite#registering-callsites
/// [`event`]: Collect::event
/// [`event_enabled`]: Collect::event_enabled
pub trait Collect: 'static {
/// Invoked when this collector becomes a [`Dispatch`].
///
/// ## Avoiding Memory Leaks
///
/// Collectors should not store their own [`Dispatch`]. Because the
/// `Dispatch` owns the collector, storing the `Dispatch` within the
/// collector will create a reference count cycle, preventing the `Dispatch`
/// from ever being dropped.
///
/// Instead, when it is necessary to store a cyclical reference to the
/// `Dispatch` within a collector, use [`Dispatch::downgrade`] to convert a
/// `Dispatch` into a [`WeakDispatch`]. This type is analogous to
/// [`std::sync::Weak`], and does not create a reference count cycle. A
/// [`WeakDispatch`] can be stored within a collector without causing a
/// memory leak, and can be [upgraded] into a `Dispatch` temporarily when
/// the `Dispatch` must be accessed by the collector.
///
/// [`WeakDispatch`]: crate::dispatch::WeakDispatch
/// [upgraded]: crate::dispatch::WeakDispatch::upgrade
fn on_register_dispatch(&self, collector: &Dispatch) {
let _ = collector;
}
// === Span registry methods ==============================================
/// Registers a new [callsite] with this collector, returning whether or not
/// the collector is interested in being notified about the callsite.
///
/// By default, this function assumes that the collector's [filter]
/// represents an unchanging view of its interest in the callsite. However,
/// if this is not the case, collectors may override this function to
/// indicate different interests, or to implement behaviour that should run
/// once for every callsite.
///
/// This function is guaranteed to be called at least once per callsite on
/// every active collector. The collector may store the keys to fields it
/// cares about in order to reduce the cost of accessing fields by name,
/// preallocate storage for that callsite, or perform any other actions it
/// wishes to perform once for each callsite.
///
/// The collector should then return an [`Interest`], indicating
/// whether it is interested in being notified about that callsite in the
/// future. This may be `Always` indicating that the collector always
/// wishes to be notified about the callsite, and its filter need not be
/// re-evaluated; `Sometimes`, indicating that the collector may sometimes
/// care about the callsite but not always (such as when sampling), or
/// `Never`, indicating that the collector never wishes to be notified about
/// that callsite. If all active collectors return `Never`, a callsite will
/// never be enabled unless a new collector expresses interest in it.
///
/// `Collector`s which require their filters to be run every time an event
/// occurs or a span is entered/exited should return `Interest::sometimes`.
/// If a collector returns `Interest::sometimes`, then its' [`enabled`] method
/// will be called every time an event or span is created from that callsite.
///
/// For example, suppose a sampling collector is implemented by
/// incrementing a counter every time `enabled` is called and only returning
/// `true` when the counter is divisible by a specified sampling rate. If
/// that collector returns `Interest::always` from `register_callsite`, then
/// the filter will not be re-evaluated once it has been applied to a given
/// set of metadata. Thus, the counter will not be incremented, and the span
/// or event that corresponds to the metadata will never be `enabled`.
///
/// `Collector`s that need to change their filters occasionally should call
/// [`rebuild_interest_cache`] to re-evaluate `register_callsite` for all
/// callsites.
///
/// Similarly, if a `Collector` has a filtering strategy that can be
/// changed dynamically at runtime, it would need to re-evaluate that filter
/// if the cached results have changed.
///
/// A collector which manages fanout to multiple other collectors
/// should proxy this decision to all of its child collectors,
/// returning `Interest::never` only if _all_ such children return
/// `Interest::never`. If the set of collectors to which spans are
/// broadcast may change dynamically, the collector should also never
/// return `Interest::Never`, as a new collector may be added that _is_
/// interested.
///
/// See the [documentation on the callsite registry][cs-reg] for more
/// details on how and when the `register_callsite` method is called.
///
/// # Notes
///
/// This function may be called again when a new collector is created or
/// when the registry is invalidated.
///
/// If a collector returns `Interest::never` for a particular callsite, it
/// _may_ still see spans and events originating from that callsite, if
/// another collector expressed interest in it.
///
/// [callsite]: crate::callsite
/// [filter]: Self::enabled
/// [metadata]: super::metadata::Metadata
/// [`enabled`]: Self::enabled
/// [`rebuild_interest_cache`]: super::callsite::rebuild_interest_cache
/// [cs-reg]: crate::callsite#registering-callsites
fn register_callsite(&self, metadata: &'static Metadata<'static>) -> Interest {
if self.enabled(metadata) {
Interest::always()
} else {
Interest::never()
}
}
/// Returns true if a span or event with the specified [metadata] would be
/// recorded.
///
/// By default, it is assumed that this filter needs only be evaluated once
/// for each callsite, so it is called by [`register_callsite`] when each
/// callsite is registered. The result is used to determine if the collector
/// is always [interested] or never interested in that callsite. This is intended
/// primarily as an optimization, so that expensive filters (such as those
/// involving string search, et cetera) need not be re-evaluated.
///
/// However, if the collector's interest in a particular span or event may
/// change, or depends on contexts only determined dynamically at runtime,
/// then the `register_callsite` method should be overridden to return
/// [`Interest::sometimes`]. In that case, this function will be called every
/// time that span or event occurs.
///
/// [metadata]: super::metadata::Metadata
/// [interested]: Interest
/// [`register_callsite`]: Self::register_callsite
fn enabled(&self, metadata: &Metadata<'_>) -> bool;
/// Returns the highest [verbosity level][level] that this `Collector` will
/// enable, or `None`, if the collector does not implement level-based
/// filtering or chooses not to implement this method.
///
/// If this method returns a [`Level`][level], it will be used as a hint to
/// determine the most verbose level that will be enabled. This will allow
/// spans and events which are more verbose than that level to be skipped
/// more efficiently. collectors which perform filtering are strongly
/// encouraged to provide an implementation of this method.
///
/// If the maximum level the collector will enable can change over the
/// course of its lifetime, it is free to return a different value from
/// multiple invocations of this method. However, note that changes in the
/// maximum level will **only** be reflected after the callsite [`Interest`]
/// cache is rebuilt, by calling the [`callsite::rebuild_interest_cache`][rebuild]
/// function. Therefore, if the collector will change the value returned by
/// this method, it is responsible for ensuring that
/// [`rebuild_interest_cache`][rebuild] is called after the value of the max
/// level changes.
///
/// [level]: super::Level
/// [rebuild]: super::callsite::rebuild_interest_cache
fn max_level_hint(&self) -> Option<LevelFilter> {
None
}
/// Visit the construction of a new span, returning a new [span ID] for the
/// span being constructed.
///
/// The provided [`Attributes`] contains any field values that were provided
/// when the span was created. The collector may pass a [visitor] to the
/// `Attributes`' [`record` method] to record these values.
///
/// IDs are used to uniquely identify spans and events within the context of a
/// collector, so span equality will be based on the returned ID. Thus, if
/// the collector wishes for all spans with the same metadata to be
/// considered equal, it should return the same ID every time it is given a
/// particular set of metadata. Similarly, if it wishes for two separate
/// instances of a span with the same metadata to *not* be equal, it should
/// return a distinct ID every time this function is called, regardless of
/// the metadata.
///
/// Note that the collector is free to assign span IDs based on whatever
/// scheme it sees fit. Any guarantees about uniqueness, ordering, or ID
/// reuse are left up to the collector implementation to determine.
///
/// [span ID]: super::span::Id
/// [`Attributes`]: super::span::Attributes
/// [visitor]: super::field::Visit
/// [`record` method]: super::span::Attributes::record
fn new_span(&self, span: &span::Attributes<'_>) -> span::Id;
// === Notification methods ===============================================
/// Record a set of values on a span.
///
/// This method will be invoked when value is recorded on a span.
/// Recording multiple values for the same field is possible,
/// but the actual behaviour is defined by the collector implementation.
///
/// Keep in mind that a span might not provide a value
/// for each field it declares.
///
/// The collector is expected to provide a [visitor] to the `Record`'s
/// [`record` method] in order to record the added values.
///
/// # Example
/// "foo = 3" will be recorded when [`record`] is called on the
/// `Attributes` passed to `new_span`.
/// Since values are not provided for the `bar` and `baz` fields,
/// the span's `Metadata` will indicate that it _has_ those fields,
/// but values for them won't be recorded at this time.
///
/// ```rust,ignore
/// # use tracing::span;
///
/// let mut span = span!("my_span", foo = 3, bar, baz);
///
/// // `Collector::record` will be called with a `Record`
/// // containing "bar = false"
/// span.record("bar", &false);
///
/// // `Collector::record` will be called with a `Record`
/// // containing "baz = "a string""
/// span.record("baz", &"a string");
/// ```
///
/// [visitor]: super::field::Visit
/// [`record`]: super::span::Attributes::record
/// [`record` method]: super::span::Record::record
fn record(&self, span: &span::Id, values: &span::Record<'_>);
/// Adds an indication that `span` follows from the span with the id
/// `follows`.
///
/// This relationship differs somewhat from the parent-child relationship: a
/// span may have any number of prior spans, rather than a single one; and
/// spans are not considered to be executing _inside_ of the spans they
/// follow from. This means that a span may close even if subsequent spans
/// that follow from it are still open, and time spent inside of a
/// subsequent span should not be included in the time its precedents were
/// executing. This is used to model causal relationships such as when a
/// single future spawns several related background tasks, et cetera.
///
/// If the collector has spans corresponding to the given IDs, it should
/// record this relationship in whatever way it deems necessary. Otherwise,
/// if one or both of the given span IDs do not correspond to spans that the
/// collector knows about, or if a cyclical relationship would be created
/// (i.e., some span _a_ which proceeds some other span _b_ may not also
/// follow from _b_), it may silently do nothing.
fn record_follows_from(&self, span: &span::Id, follows: &span::Id);
/// Determine if an [`Event`] should be recorded.
///
/// By default, this returns `true` and collectors can filter events in
/// [`event`][Self::event] without any penalty. However, when `event` is
/// more complicated, this can be used to determine if `event` should be
/// called at all, separating out the decision from the processing.
fn event_enabled(&self, event: &Event<'_>) -> bool {
let _ = event;
true
}
/// Records that an [`Event`] has occurred.
///
/// This method will be invoked when an Event is constructed by
/// the `Event`'s [`dispatch` method]. For example, this happens internally
/// when an event macro from `tracing` is called.
///
/// The key difference between this method and `record` is that `record` is
/// called when a value is recorded for a field defined by a span,
/// while `event` is called when a new event occurs.
///
/// The provided `Event` struct contains any field values attached to the
/// event. The collector may pass a [visitor] to the `Event`'s
/// [`record` method] to record these values.
///
/// [`Event`]: super::event::Event
/// [visitor]: super::field::Visit
/// [`record` method]: super::event::Event::record
/// [`dispatch` method]: super::event::Event::dispatch
fn event(&self, event: &Event<'_>);
/// Records that a span has been entered.
///
/// When entering a span, this method is called to notify the collector
/// that the span has been entered. The collector is provided with the
/// [span ID] of the entered span, and should update any internal state
/// tracking the current span accordingly.
///
/// [span ID]: super::span::Id
fn enter(&self, span: &span::Id);
/// Records that a span has been exited.
///
/// When exiting a span, this method is called to notify the collector
/// that the span has been exited. The collector is provided with the
/// [span ID] of the exited span, and should update any internal state
/// tracking the current span accordingly.
///
/// Exiting a span does not imply that the span will not be re-entered.
///
/// [span ID]: super::span::Id
fn exit(&self, span: &span::Id);
/// Notifies the collector that a [span ID] has been cloned.
///
/// This function is guaranteed to only be called with span IDs that were
/// returned by this collector's `new_span` function.
///
/// Note that the default implementation of this function this is just the
/// identity function, passing through the identifier. However, it can be
/// used in conjunction with [`try_close`] to track the number of handles
/// capable of `enter`ing a span. When all the handles have been dropped
/// (i.e., `try_close` has been called one more time than `clone_span` for a
/// given ID), the collector may assume that the span will not be entered
/// again. It is then free to deallocate storage for data associated with
/// that span, write data from that span to IO, and so on.
///
/// For more unsafe situations, however, if `id` is itself a pointer of some
/// kind this can be used as a hook to "clone" the pointer, depending on
/// what that means for the specified pointer.
///
/// [span ID]: super::span::Id
/// [`try_close`]: Collect::try_close
fn clone_span(&self, id: &span::Id) -> span::Id {
id.clone()
}
/// **This method is deprecated.**
///
/// Using `drop_span` may result in collectors composed using
/// `tracing-subscriber` crate's `Subscriber` trait from observing close events.
/// Use [`try_close`] instead.
///
/// The default implementation of this function does nothing.
///
/// [`try_close`]: Collect::try_close
#[deprecated(since = "0.1.2", note = "use `Collector::try_close` instead")]
fn drop_span(&self, _id: span::Id) {}
/// Notifies the collector that a [`span ID`] has been dropped, and returns
/// `true` if there are now 0 IDs that refer to that span.
///
/// Higher-level libraries providing functionality for composing multiple
/// collector implementations may use this return value to notify any
/// "layered" collectors that this collector considers the span closed.
///
/// The default implementation of this method calls the collector's
/// [`drop_span`] method and returns `false`. This means that, unless the
/// collector overrides the default implementation, close notifications
/// will never be sent to any layered collectors. In general, if the
/// collector tracks reference counts, this method should be implemented,
/// rather than `drop_span`.
///
/// This function is guaranteed to only be called with span IDs that were
/// returned by this collector's `new_span` function.
///
/// It's guaranteed that if this function has been called once more than the
/// number of times `clone_span` was called with the same `id`, then no more
/// handles that can enter the span with that `id` exist. This means that it
/// can be used in conjunction with [`clone_span`] to track the number of
/// handles capable of `enter`ing a span. When all the handles have been
/// dropped (i.e., `try_close` has been called one more time than
/// `clone_span` for a given ID), the collector may assume that the span
/// will not be entered again, and should return `true`. It is then free to
/// deallocate storage for data associated with that span, write data from
/// that span to IO, and so on.
///
/// **Note**: since this function is called when spans are dropped,
/// implementations should ensure that they are unwind-safe. Panicking from
/// inside of a `try_close` function may cause a double panic, if the span
/// was dropped due to a thread unwinding.
///
/// [`span ID`]: super::span::Id
/// [`clone_span`]: Collect::clone_span
/// [`drop_span`]: Collect::drop_span
fn try_close(&self, id: span::Id) -> bool {
#[allow(deprecated)]
self.drop_span(id);
false
}
/// Returns a type representing this collector's view of the current span.
///
/// If collectors track a current span, they should return [`Current::new`]
/// if the thread from which this method is called is inside a span,
/// or [`Current::none`] if the thread is not inside a span.
///
/// [`Current::new`]: super::span::Current::new
/// [`Current::none`]: super::span::Current::none
fn current_span(&self) -> span::Current;
// === Downcasting methods ================================================
/// If `self` is the same type as the provided `TypeId`, returns an untyped
/// [`NonNull`] pointer to that type. Otherwise, returns `None`.
///
/// If you wish to downcast a `Collector`, it is strongly advised to use
/// the safe API provided by [`downcast_ref`] instead.
///
/// This API is required for `downcast_raw` to be a trait method; a method
/// signature like [`downcast_ref`] (with a generic type parameter) is not
/// object-safe, and thus cannot be a trait method for `Collector`. This
/// means that if we only exposed `downcast_ref`, `Collector`
/// implementations could not override the downcasting behavior
///
/// This method may be overridden by "fan out" or "chained" collector
/// implementations which consist of multiple composed types. Such
/// collectors might allow `downcast_raw` by returning references to those
/// component if they contain components with the given `TypeId`.
///
/// # Safety
///
/// The [`downcast_ref`] method expects that the pointer returned by
/// `downcast_raw` points to a valid instance of the type
/// with the provided `TypeId`. Failure to ensure this will result in
/// undefined behaviour, so implementing `downcast_raw` is unsafe.
///
/// [`downcast_ref`]: #method.downcast_ref
/// [`NonNull`]: core::ptr::NonNull
unsafe fn downcast_raw(&self, id: TypeId) -> Option<NonNull<()>> {
if id == TypeId::of::<Self>() {
Some(NonNull::from(self).cast())
} else {
None
}
}
}
impl dyn Collect {
/// Returns `true` if this `Collector` is the same type as `T`.
pub fn is<T: Any>(&self) -> bool {
self.downcast_ref::<T>().is_some()
}
/// Returns some reference to this `Collector` value if it is of type `T`,
/// or `None` if it isn't.
pub fn downcast_ref<T: Any>(&self) -> Option<&T> {
unsafe {
let raw = self.downcast_raw(TypeId::of::<T>())?;
Some(&*(raw.cast().as_ptr()))
}
}
}
impl dyn Collect + Send {
/// Returns `true` if this `Collector` is the same type as `T`.
pub fn is<T: Any>(&self) -> bool {
self.downcast_ref::<T>().is_some()
}
/// Returns some reference to this `Collector` value if it is of type `T`,
/// or `None` if it isn't.
pub fn downcast_ref<T: Any>(&self) -> Option<&T> {
unsafe {
let raw = self.downcast_raw(TypeId::of::<T>())?;
Some(&*(raw.cast().as_ptr()))
}
}
}
impl dyn Collect + Sync {
/// Returns `true` if this `Collector` is the same type as `T`.
pub fn is<T: Any>(&self) -> bool {
self.downcast_ref::<T>().is_some()
}
/// Returns some reference to this `Collector` value if it is of type `T`,
/// or `None` if it isn't.
pub fn downcast_ref<T: Any>(&self) -> Option<&T> {
unsafe {
let raw = self.downcast_raw(TypeId::of::<T>())?;
Some(&*(raw.cast().as_ptr()))
}
}
}
impl dyn Collect + Send + Sync {
/// Returns `true` if this `Collector` is the same type as `T`.
pub fn is<T: Any>(&self) -> bool {
self.downcast_ref::<T>().is_some()
}
/// Returns some reference to this `Collector` value if it is of type `T`,
/// or `None` if it isn't.
pub fn downcast_ref<T: Any>(&self) -> Option<&T> {
unsafe {
let raw = self.downcast_raw(TypeId::of::<T>())?;
Some(&*(raw.cast().as_ptr()))
}
}
}
/// Indicates a [`Collect`]'s interest in a particular callsite.
///
/// Collectors return an `Interest` from their [`register_callsite`] methods
/// in order to determine whether that span should be enabled or disabled.
///
/// [`Collect`]: super::Collect
/// [`register_callsite`]: super::Collect::register_callsite
#[derive(Clone, Debug)]
pub struct Interest(InterestKind);
#[derive(Copy, Clone, Debug, Eq, PartialEq, Ord, PartialOrd)]
enum InterestKind {
Never = 0,
Sometimes = 1,
Always = 2,
}
impl Interest {
/// Returns an `Interest` indicating that the collector is never interested
/// in being notified about a callsite.
///
/// If all active collectors are `never()` interested in a callsite, it will
/// be completely disabled unless a new collector becomes active.
#[inline]
pub fn never() -> Self {
Interest(InterestKind::Never)
}
/// Returns an `Interest` indicating the collector is sometimes interested
/// in being notified about a callsite.
///
/// If all active collectors are `sometimes` or `never` interested in a
/// callsite, the currently active collector will be asked to filter that
/// callsite every time it creates a span. This will be the case until a new
/// collector expresses that it is `always` interested in the callsite.
#[inline]
pub fn sometimes() -> Self {
Interest(InterestKind::Sometimes)
}
/// Returns an `Interest` indicating the collector is always interested in
/// being notified about a callsite.
///
/// If any collector expresses that it is `always()` interested in a given
/// callsite, then the callsite will always be enabled.
#[inline]
pub fn always() -> Self {
Interest(InterestKind::Always)
}
/// Returns `true` if the collector is never interested in being notified
/// about this callsite.
#[inline]
pub fn is_never(&self) -> bool {
matches!(self.0, InterestKind::Never)
}
/// Returns `true` if the collector is sometimes interested in being notified
/// about this callsite.
#[inline]
pub fn is_sometimes(&self) -> bool {
matches!(self.0, InterestKind::Sometimes)
}
/// Returns `true` if the collector is always interested in being notified
/// about this callsite.
#[inline]
pub fn is_always(&self) -> bool {
matches!(self.0, InterestKind::Always)
}
/// Returns the common interest between these two Interests.
///
/// If both interests are the same, this propagates that interest.
/// Otherwise, if they differ, the result must always be
/// `Interest::sometimes` --- if the two collectors differ in opinion, we
/// will have to ask the current collector what it thinks, no matter what.
// Only needed when combining interest from multiple collectors.
#[cfg(feature = "std")]
pub(crate) fn and(self, rhs: Interest) -> Self {
if self.0 == rhs.0 {
self
} else {
Interest::sometimes()
}
}
}
/// A no-op [collector](Collect).
///
/// [`NoCollector`] implements the [`Collect`] trait by never being enabled,
/// never being interested in any callsite, and drops all spans and events.
#[derive(Debug, Default, Copy, Clone)]
pub struct NoCollector(());
impl NoCollector {
/// Returns a new `NoCollector` instance.
///
/// This function is equivalent to calling `NoCollector::default()`, but
/// this is usable in `const fn` contexts.
pub const fn new() -> Self {
Self(())
}
}
impl Collect for NoCollector {
#[inline]
fn register_callsite(&self, _: &'static Metadata<'static>) -> Interest {
Interest::never()
}
fn new_span(&self, _: &span::Attributes<'_>) -> span::Id {
span::Id::from_u64(0xDEAD)
}
fn event(&self, _event: &Event<'_>) {}
fn record(&self, _span: &span::Id, _values: &span::Record<'_>) {}
fn record_follows_from(&self, _span: &span::Id, _follows: &span::Id) {}
#[inline]
fn enabled(&self, _metadata: &Metadata<'_>) -> bool {
false
}
fn current_span(&self) -> span::Current {
span::Current::none()
}
fn enter(&self, _span: &span::Id) {}
fn exit(&self, _span: &span::Id) {}
}
#[cfg(feature = "alloc")]
impl<C> Collect for alloc::boxed::Box<C>
where
C: Collect + ?Sized,
{
#[inline]
fn register_callsite(&self, metadata: &'static Metadata<'static>) -> Interest {
self.as_ref().register_callsite(metadata)
}
#[inline]
fn enabled(&self, metadata: &Metadata<'_>) -> bool {
self.as_ref().enabled(metadata)
}
#[inline]
fn max_level_hint(&self) -> Option<LevelFilter> {
self.as_ref().max_level_hint()
}
#[inline]
fn new_span(&self, span: &span::Attributes<'_>) -> span::Id {
self.as_ref().new_span(span)
}
#[inline]
fn record(&self, span: &span::Id, values: &span::Record<'_>) {
self.as_ref().record(span, values)
}
#[inline]
fn record_follows_from(&self, span: &span::Id, follows: &span::Id) {
self.as_ref().record_follows_from(span, follows)
}
#[inline]
fn event_enabled(&self, event: &Event<'_>) -> bool {
self.as_ref().event_enabled(event)
}
#[inline]
fn event(&self, event: &Event<'_>) {
self.as_ref().event(event)
}
#[inline]
fn enter(&self, span: &span::Id) {
self.as_ref().enter(span)
}
#[inline]
fn exit(&self, span: &span::Id) {
self.as_ref().exit(span)
}
#[inline]
fn clone_span(&self, id: &span::Id) -> span::Id {
self.as_ref().clone_span(id)
}
#[inline]
fn try_close(&self, id: span::Id) -> bool {
self.as_ref().try_close(id)
}
#[inline]
unsafe fn downcast_raw(&self, id: TypeId) -> Option<NonNull<()>> {
if id == TypeId::of::<Self>() {
return Some(NonNull::from(self).cast());
}
self.as_ref().downcast_raw(id)
}
fn current_span(&self) -> span::Current {
self.as_ref().current_span()
}
}
#[cfg(feature = "alloc")]
impl<C> Collect for alloc::sync::Arc<C>
where
C: Collect + ?Sized,
{
#[inline]
fn register_callsite(&self, metadata: &'static Metadata<'static>) -> Interest {
self.as_ref().register_callsite(metadata)
}
#[inline]
fn enabled(&self, metadata: &Metadata<'_>) -> bool {
self.as_ref().enabled(metadata)
}
#[inline]
fn max_level_hint(&self) -> Option<LevelFilter> {
self.as_ref().max_level_hint()
}
#[inline]
fn new_span(&self, span: &span::Attributes<'_>) -> span::Id {
self.as_ref().new_span(span)
}
#[inline]
fn record(&self, span: &span::Id, values: &span::Record<'_>) {
self.as_ref().record(span, values)
}
#[inline]
fn record_follows_from(&self, span: &span::Id, follows: &span::Id) {
self.as_ref().record_follows_from(span, follows)
}
#[inline]
fn event_enabled(&self, event: &Event<'_>) -> bool {
self.as_ref().event_enabled(event)
}
#[inline]
fn event(&self, event: &Event<'_>) {
self.as_ref().event(event)
}
#[inline]
fn enter(&self, span: &span::Id) {
self.as_ref().enter(span)
}
#[inline]
fn exit(&self, span: &span::Id) {
self.as_ref().exit(span)
}
#[inline]
fn clone_span(&self, id: &span::Id) -> span::Id {
self.as_ref().clone_span(id)
}
#[inline]
fn try_close(&self, id: span::Id) -> bool {
self.as_ref().try_close(id)
}
#[inline]
unsafe fn downcast_raw(&self, id: TypeId) -> Option<NonNull<()>> {
if id == TypeId::of::<Self>() {
return Some(NonNull::from(self).cast());
}
self.as_ref().downcast_raw(id)
}
fn current_span(&self) -> span::Current {
self.as_ref().current_span()
}
}