Module tracing_subscriber::layer
source · Expand description
The Layer
trait, a composable abstraction for building Subscriber
s.
The Subscriber
trait in tracing-core
represents the complete set of
functionality required to consume tracing
instrumentation. This means that
a single Subscriber
instance is a self-contained implementation of a
complete strategy for collecting traces; but it also means that the
Subscriber
trait cannot easily be composed with other Subscriber
s.
In particular, Subscriber
s are responsible for generating span IDs and
assigning them to spans. Since these IDs must uniquely identify a span
within the context of the current trace, this means that there may only be
a single Subscriber
for a given thread at any point in time —
otherwise, there would be no authoritative source of span IDs.
On the other hand, the majority of the Subscriber
trait’s functionality
is composable: any number of subscribers may observe events, span entry
and exit, and so on, provided that there is a single authoritative source of
span IDs. The Layer
trait represents this composable subset of the
Subscriber
behavior; it can observe events and spans, but does not
assign IDs.
§Composing Layers
Since a Layer
does not implement a complete strategy for collecting
traces, it must be composed with a Subscriber
in order to be used. The
Layer
trait is generic over a type parameter (called S
in the trait
definition), representing the types of Subscriber
they can be composed
with. Thus, a Layer
may be implemented that will only compose with a
particular Subscriber
implementation, or additional trait bounds may be
added to constrain what types implementing Subscriber
a Layer
can wrap.
Layer
s may be added to a Subscriber
by using the SubscriberExt::with
method, which is provided by tracing-subscriber
’s prelude. This method
returns a Layered
struct that implements Subscriber
by composing the
Layer
with the Subscriber
.
For example:
use tracing_subscriber::Layer;
use tracing_subscriber::prelude::*;
use tracing::Subscriber;
pub struct MyLayer {
// ...
}
impl<S: Subscriber> Layer<S> for MyLayer {
// ...
}
pub struct MySubscriber {
// ...
}
impl Subscriber for MySubscriber {
// ...
}
let subscriber = MySubscriber::new()
.with(MyLayer::new());
tracing::subscriber::set_global_default(subscriber);
Multiple Layer
s may be composed in the same manner:
pub struct MyOtherLayer {
// ...
}
impl<S: Subscriber> Layer<S> for MyOtherLayer {
// ...
}
pub struct MyThirdLayer {
// ...
}
impl<S: Subscriber> Layer<S> for MyThirdLayer {
// ...
}
}
let subscriber = MySubscriber::new()
.with(MyLayer::new())
.with(MyOtherLayer::new())
.with(MyThirdLayer::new());
tracing::subscriber::set_global_default(subscriber);
The Layer::with_subscriber
constructs the Layered
type from a
Layer
and Subscriber
, and is called by SubscriberExt::with
. In
general, it is more idiomatic to use SubscriberExt::with
, and treat
Layer::with_subscriber
as an implementation detail, as with_subscriber
calls must be nested, leading to less clear code for the reader.
§Runtime Configuration With Layer
s
In some cases, a particular Layer
may be enabled or disabled based on
runtime configuration. This can introduce challenges, because the type of a
layered Subscriber
depends on which layers are added to it: if an if
or match
expression adds some Layer
implementation in one branch,
and other layers in another, the Subscriber
values returned by those
branches will have different types. For example, the following will not
work:
use std::fs::File;
use tracing_subscriber::{Registry, prelude::*};
let stdout_log = tracing_subscriber::fmt::layer().pretty();
let subscriber = Registry::default().with(stdout_log);
// The compile error will occur here because the if and else
// branches have different (and therefore incompatible) types.
let subscriber = if cfg.is_prod {
let file = File::create(cfg.path)?;
let layer = tracing_subscriber::fmt::layer()
.json()
.with_writer(Arc::new(file));
layer.with(subscriber)
} else {
layer
};
tracing::subscriber::set_global_default(subscriber)
.expect("Unable to set global subscriber");
However, a Layer
wrapped in an Option
also implements the Layer
trait. This allows individual layers to be enabled or disabled at
runtime while always producing a Subscriber
of the same type. For
example:
use std::fs::File;
use tracing_subscriber::{Registry, prelude::*};
let stdout_log = tracing_subscriber::fmt::layer().pretty();
let subscriber = Registry::default().with(stdout_log);
// if `cfg.is_prod` is true, also log JSON-formatted logs to a file.
let json_log = if cfg.is_prod {
let file = File::create(cfg.path)?;
let json_log = tracing_subscriber::fmt::layer()
.json()
.with_writer(file);
Some(json_log)
} else {
None
};
// If `cfg.is_prod` is false, then `json` will be `None`, and this layer
// will do nothing. However, the subscriber will still have the same type
// regardless of whether the `Option`'s value is `None` or `Some`.
let subscriber = subscriber.with(json_log);
tracing::subscriber::set_global_default(subscriber)
.expect("Unable to set global subscriber");
If a Layer
may be one of several different types, note that Box<dyn Layer<S> + Send + Sync>
implements Layer
.
This may be used to erase the type of a Layer
.
For example, a function that configures a Layer
to log to one of
several outputs might return a Box<dyn Layer<S> + Send + Sync + 'static>
:
use tracing_subscriber::{
Layer,
registry::LookupSpan,
prelude::*,
};
use std::{path::PathBuf, fs::File, io};
/// Configures whether logs are emitted to a file, to stdout, or to stderr.
pub enum LogConfig {
File(PathBuf),
Stdout,
Stderr,
}
impl LogConfig {
pub fn layer<S>(self) -> Box<dyn Layer<S> + Send + Sync + 'static>
where
S: tracing_core::Subscriber,
for<'a> S: LookupSpan<'a>,
{
// Shared configuration regardless of where logs are output to.
let fmt = tracing_subscriber::fmt::layer()
.with_target(true)
.with_thread_names(true);
// Configure the writer based on the desired log target:
match self {
LogConfig::File(path) => {
let file = File::create(path).expect("failed to create log file");
Box::new(fmt.with_writer(file))
},
LogConfig::Stdout => Box::new(fmt.with_writer(io::stdout)),
LogConfig::Stderr => Box::new(fmt.with_writer(io::stderr)),
}
}
}
let config = LogConfig::Stdout;
tracing_subscriber::registry()
.with(config.layer())
.init();
The Layer::boxed
method is provided to make boxing a Layer
more convenient, but Box::new
may be used as well.
When the number of Layer
s varies at runtime, note that a
Vec<L> where L: Layer
also implements Layer
. This
can be used to add a variable number of Layer
s to a Subscriber
:
use tracing_subscriber::{Layer, prelude::*};
struct MyLayer {
// ...
}
impl<S: tracing_core::Subscriber> Layer<S> for MyLayer {
// ...
}
/// Returns how many layers we need
fn how_many_layers() -> usize {
// ...
}
// Create a variable-length `Vec` of layers
let mut layers = Vec::new();
for _ in 0..how_many_layers() {
layers.push(MyLayer::new());
}
tracing_subscriber::registry()
.with(layers)
.init();
If a variable number of Layer
is needed and those Layer
s have
different types, a Vec
of boxed Layer
trait objects may
be used. For example:
use tracing_subscriber::{filter::LevelFilter, Layer, prelude::*};
use std::fs::File;
struct Config {
enable_log_file: bool,
enable_stdout: bool,
enable_stderr: bool,
// ...
}
let cfg = Config::from_config_file()?;
// Based on our dynamically loaded config file, create any number of layers:
let mut layers = Vec::new();
if cfg.enable_log_file {
let file = File::create("myapp.log")?;
let layer = tracing_subscriber::fmt::layer()
.with_thread_names(true)
.with_target(true)
.json()
.with_writer(file)
// Box the layer as a type-erased trait object, so that it can
// be pushed to the `Vec`.
.boxed();
layers.push(layer);
}
if cfg.enable_stdout {
let layer = tracing_subscriber::fmt::layer()
.pretty()
.with_filter(LevelFilter::INFO)
// Box the layer as a type-erased trait object, so that it can
// be pushed to the `Vec`.
.boxed();
layers.push(layer);
}
if cfg.enable_stdout {
let layer = tracing_subscriber::fmt::layer()
.with_target(false)
.with_filter(LevelFilter::WARN)
// Box the layer as a type-erased trait object, so that it can
// be pushed to the `Vec`.
.boxed();
layers.push(layer);
}
tracing_subscriber::registry()
.with(layers)
.init();
Finally, if the number of layers changes at runtime, a Vec
of
subscribers can be used alongside the reload
module to
add or remove subscribers dynamically at runtime.
§Recording Traces
The Layer
trait defines a set of methods for consuming notifications from
tracing instrumentation, which are generally equivalent to the similarly
named methods on Subscriber
. Unlike Subscriber
, the methods on
Layer
are additionally passed a Context
type, which exposes additional
information provided by the wrapped subscriber (such as the current span)
to the layer.
§Filtering with Layer
s
As well as strategies for handling trace events, the Layer
trait may also
be used to represent composable filters. This allows the determination of
what spans and events should be recorded to be decoupled from how they are
recorded: a filtering layer can be applied to other layers or
subscribers. Layer
s can be used to implement global filtering, where a
Layer
provides a filtering strategy for the entire subscriber.
Additionally, individual recording Layer
s or sets of Layer
s may be
combined with per-layer filters that control what spans and events are
recorded by those layers.
§Global Filtering
A Layer
that implements a filtering strategy should override the
register_callsite
and/or enabled
methods. It may also choose to implement
methods such as on_enter
, if it wishes to filter trace events based on
the current span context.
Note that the Layer::register_callsite
and Layer::enabled
methods
determine whether a span or event is enabled globally. Thus, they should
not be used to indicate whether an individual layer wishes to record a
particular span or event. Instead, if a layer is only interested in a subset
of trace data, but does not wish to disable other spans and events for the
rest of the layer stack should ignore those spans and events in its
notification methods.
The filtering methods on a stack of Layer
s are evaluated in a top-down
order, starting with the outermost Layer
and ending with the wrapped
Subscriber
. If any layer returns false
from its enabled
method, or
Interest::never()
from its register_callsite
method, filter
evaluation will short-circuit and the span or event will be disabled.
§Enabling Interest
Whenever an tracing event (or span) is emitted, it goes through a number of
steps to determine how and how much it should be processed. The earlier an
event is disabled, the less work has to be done to process the event, so
Layer
s that implement filtering should attempt to disable unwanted
events as early as possible. In order, each event checks:
register_callsite
, once per callsite (roughly: once per time thatevent!
orspan!
is written in the source code; this is cached at the callsite). SeeSubscriber::register_callsite
andtracing_core::callsite
for a summary of how this behaves.enabled
, once per emitted event (roughly: once per time thatevent!
orspan!
is executed), and only ifregister_callsite
regesters anInterest::sometimes
. This is the main customization point to globally filter events based on theirMetadata
. If an event can be disabled based only onMetadata
, it should be, as this allows the construction of the actualEvent
/Span
to be skipped.- For events only (and not spans),
event_enabled
is called just before processing the event. This gives layers one last chance to say that an event should be filtered out, now that the event’s fields are known.
§Per-Layer Filtering
Note: per-layer filtering APIs currently require the "registry"
crate
feature flag to be enabled.
Sometimes, it may be desirable for one Layer
to record a particular subset
of spans and events, while a different subset of spans and events are
recorded by other Layer
s. For example:
- A layer that records metrics may wish to observe only events including particular tracked values, while a logging layer ignores those events.
- If recording a distributed trace is expensive, it might be desirable to
only send spans with
INFO
and lower verbosity to the distributed tracing system, while logging more verbose spans to a file. - Spans and events with a particular target might be recorded differently from others, such as by generating an HTTP access log from a span that tracks the lifetime of an HTTP request.
The Filter
trait is used to control what spans and events are
observed by an individual Layer
, while still allowing other Layer
s to
potentially record them. The Layer::with_filter
method combines a
Layer
with a Filter
, returning a Filtered
layer.
This crate’s filter
module provides a number of types which implement
the Filter
trait, such as LevelFilter
, Targets
, and
FilterFn
. These Filter
s provide ready-made implementations of
common forms of filtering. For custom filtering policies, the FilterFn
and DynFilterFn
types allow implementing a Filter
with a closure or
function pointer. In addition, when more control is required, the Filter
trait may also be implemented for user-defined types.
//! Option<Filter>
also implements Filter
, which allows for an optional
filter. None
filters out nothing (that is, allows
everything through). For example:
fn setup_tracing<S: Subscriber>(filter_config: Option<&str>) {
let layer = MyLayer::<S>::new()
.with_filter(filter_config.map(|config| filter_fn(my_filter(config))));
//...
}
Warning: Currently, theRegistry
type defined in this crate is the only rootSubscriber
capable of supportingLayer
s with per-layer filters. In the future, new APIs will be added to allow other rootSubscriber
s to support per-layer filters.
For example, to generate an HTTP access log based on spans with
the http_access
target, while logging other spans and events to
standard out, a Filter
can be added to the access log layer:
use tracing_subscriber::{filter, prelude::*};
// Generates an HTTP access log.
let access_log = // ...
// Add a filter to the access log layer so that it only observes
// spans and events with the `http_access` target.
let access_log = access_log.with_filter(filter::filter_fn(|metadata| {
// Returns `true` if and only if the span or event's target is
// "http_access".
metadata.target() == "http_access"
}));
// A general-purpose logging layer.
let fmt_layer = tracing_subscriber::fmt::layer();
// Build a subscriber that combines the access log and stdout log
// layers.
tracing_subscriber::registry()
.with(fmt_layer)
.with(access_log)
.init();
Multiple layers can have their own, separate per-layer filters. A span or event will be recorded if it is enabled by any per-layer filter, but it will be skipped by the layers whose filters did not enable it. Building on the previous example:
use tracing_subscriber::{filter::{filter_fn, LevelFilter}, prelude::*};
let access_log = // ...
let fmt_layer = tracing_subscriber::fmt::layer();
tracing_subscriber::registry()
// Add the filter for the "http_access" target to the access
// log layer, like before.
.with(access_log.with_filter(filter_fn(|metadata| {
metadata.target() == "http_access"
})))
// Add a filter for spans and events with the INFO level
// and below to the logging layer.
.with(fmt_layer.with_filter(LevelFilter::INFO))
.init();
// Neither layer will observe this event
tracing::debug!(does_anyone_care = false, "a tree fell in the forest");
// This event will be observed by the logging layer, but not
// by the access log layer.
tracing::warn!(dose_roentgen = %3.8, "not great, but not terrible");
// This event will be observed only by the access log layer.
tracing::trace!(target: "http_access", "HTTP request started");
// Both layers will observe this event.
tracing::error!(target: "http_access", "HTTP request failed with a very bad error!");
A per-layer filter can be applied to multiple Layer
s at a time, by
combining them into a Layered
layer using Layer::and_then
, and then
calling Layer::with_filter
on the resulting Layered
layer.
Consider the following:
layer_a
andlayer_b
, which should only receive spans and events at theINFO
level and above.- A third layer,
layer_c
, which should receive spans and events at theDEBUG
level as well. The layers and filters would be composed thusly:
use tracing_subscriber::{filter::LevelFilter, prelude::*};
let layer_a = // ...
let layer_b = // ...
let layer_c = // ...
let info_layers = layer_a
// Combine `layer_a` and `layer_b` into a `Layered` layer:
.and_then(layer_b)
// ...and then add an `INFO` `LevelFilter` to that layer:
.with_filter(LevelFilter::INFO);
tracing_subscriber::registry()
// Add `layer_c` with a `DEBUG` filter.
.with(layer_c.with_filter(LevelFilter::DEBUG))
.with(info_layers)
.init();
If a Filtered
Layer
is combined with another Layer
Layer::and_then
, and a filter is added to the Layered
layer, that
layer will be filtered by both the inner filter and the outer filter.
Only spans and events that are enabled by both filters will be
observed by that layer. This can be used to implement complex filtering
trees.
As an example, consider the following constraints:
- Suppose that a particular target is used to indicate events that should be counted as part of a metrics system, which should be only observed by a layer that collects metrics.
- A log of high-priority events (
INFO
and above) should be logged to stdout, while more verbose events should be logged to a debugging log file. - Metrics-focused events should not be included in either log output.
In that case, it is possible to apply a filter to both logging layers to
exclude the metrics events, while additionally adding a LevelFilter
to the stdout log:
use tracing_subscriber::{filter, prelude::*};
use std::{fs::File, sync::Arc};
// A layer that logs events to stdout using the human-readable "pretty"
// format.
let stdout_log = tracing_subscriber::fmt::layer()
.pretty();
// A layer that logs events to a file.
let file = File::create("debug.log")?;
let debug_log = tracing_subscriber::fmt::layer()
.with_writer(Arc::new(file));
// A layer that collects metrics using specific events.
let metrics_layer = /* ... */ filter::LevelFilter::INFO;
tracing_subscriber::registry()
.with(
stdout_log
// Add an `INFO` filter to the stdout logging layer
.with_filter(filter::LevelFilter::INFO)
// Combine the filtered `stdout_log` layer with the
// `debug_log` layer, producing a new `Layered` layer.
.and_then(debug_log)
// Add a filter to *both* layers that rejects spans and
// events whose targets start with `metrics`.
.with_filter(filter::filter_fn(|metadata| {
!metadata.target().starts_with("metrics")
}))
)
.with(
// Add a filter to the metrics label that *only* enables
// events whose targets start with `metrics`.
metrics_layer.with_filter(filter::filter_fn(|metadata| {
metadata.target().starts_with("metrics")
}))
)
.init();
// This event will *only* be recorded by the metrics layer.
tracing::info!(target: "metrics::cool_stuff_count", value = 42);
// This event will only be seen by the debug log file layer:
tracing::debug!("this is a message, and part of a system of messages");
// This event will be seen by both the stdout log layer *and*
// the debug log file layer, but not by the metrics layer.
tracing::warn!("the message is a warning about danger!");
Structs§
- Represents information about the current context provided to
Layer
s by the wrappedSubscriber
. - A layer that does nothing.
Traits§
- A per-
Layer
filter that determines whether a span or event is enabled for an individual layer. - A composable handler for
tracing
events. - Extension trait adding a
with(Layer)
combinator toSubscriber
s.