Expand description
A scoped, structured logging and diagnostics system.
Overview
tracing
is a framework for instrumenting Rust programs to collect
structured, event-based diagnostic information.
In asynchronous systems like Tokio, interpreting traditional log messages can
often be quite challenging. Since individual tasks are multiplexed on the same
thread, associated events and log lines are intermixed making it difficult to
trace the logic flow. tracing
expands upon logging-style diagnostics by
allowing libraries and applications to record structured events with additional
information about temporality and causality — unlike a log message, a span
in tracing
has a beginning and end time, may be entered and exited by the
flow of execution, and may exist within a nested tree of similar spans. In
addition, tracing
spans are structured, with the ability to record typed
data as well as textual messages.
The tracing
crate provides the APIs necessary for instrumenting libraries
and applications to emit trace data.
Compiler support: requires rustc
1.49+
Core Concepts
The core of tracing
’s API is composed of spans, events and
subscribers. We’ll cover these in turn.
Spans
To record the flow of execution through a program, tracing
introduces the
concept of spans. Unlike a log line that represents a moment in
time, a span represents a period of time with a beginning and an end. When a
program begins executing in a context or performing a unit of work, it
enters that context’s span, and when it stops executing in that context,
it exits the span. The span in which a thread is currently executing is
referred to as that thread’s current span.
For example:
use tracing::{span, Level};
let span = span!(Level::TRACE, "my_span");
// `enter` returns a RAII guard which, when dropped, exits the span. this
// indicates that we are in the span for the current lexical scope.
let _enter = span.enter();
// perform some work in the context of `my_span`...
The span
module’s documentation provides further details on how to
use spans.
Warning: In asynchronous code that uses async/await syntax,
Span::enter
may produce incorrect traces if the returned drop guard is held across an await point. See the method documentation for details.
Events
An Event
represents a moment in time. It signifies something that
happened while a trace was being recorded. Event
s are comparable to the log
records emitted by unstructured logging code, but unlike a typical log line,
an Event
may occur within the context of a span.
For example:
use tracing::{event, span, Level};
// records an event outside of any span context:
event!(Level::INFO, "something happened");
let span = span!(Level::INFO, "my_span");
let _guard = span.enter();
// records an event within "my_span".
event!(Level::DEBUG, "something happened inside my_span");
In general, events should be used to represent points in time within a span — a request returned with a given status code, n new items were taken from a queue, and so on.
The Event
struct documentation provides further details on using
events.
Subscribers
As Span
s and Event
s occur, they are recorded or aggregated by
implementations of the Subscriber
trait. Subscriber
s are notified
when an Event
takes place and when a Span
is entered or exited. These
notifications are represented by the following Subscriber
trait methods:
event
, called when anEvent
takes place,enter
, called when execution enters aSpan
,exit
, called when execution exits aSpan
In addition, subscribers may implement the enabled
function to filter
the notifications they receive based on metadata describing each Span
or Event
. If a call to Subscriber::enabled
returns false
for a given
set of metadata, that Subscriber
will not be notified about the
corresponding Span
or Event
. For performance reasons, if no currently
active subscribers express interest in a given set of metadata by returning
true
, then the corresponding Span
or Event
will never be constructed.
Usage
First, add this to your Cargo.toml
:
[dependencies]
tracing = "0.1"
Recording Spans and Events
Spans and events are recorded using macros.
Spans
The span!
macro expands to a Span
struct which is used to
record a span. The Span::enter
method on that struct records that the
span has been entered, and returns a RAII guard object, which will exit
the span when dropped.
For example:
use tracing::{span, Level};
// Construct a new span named "my span" with trace log level.
let span = span!(Level::TRACE, "my span");
// Enter the span, returning a guard object.
let _enter = span.enter();
// Any trace events that occur before the guard is dropped will occur
// within the span.
// Dropping the guard will exit the span.
The #[instrument]
attribute provides an easy way to
add tracing
spans to functions. A function annotated with #[instrument]
will create and enter a span with that function’s name every time the
function is called, with arguments to that function will be recorded as
fields using fmt::Debug
.
For example:
use tracing::{Level, event, instrument};
#[instrument]
pub fn my_function(my_arg: usize) {
// This event will be recorded inside a span named `my_function` with the
// field `my_arg`.
event!(Level::INFO, "inside my_function!");
// ...
}
For functions which don’t have built-in tracing support and can’t have
the #[instrument]
attribute applied (such as from an external crate),
the Span
struct has a in_scope()
method
which can be used to easily wrap synchonous code in a span.
For example:
use tracing::info_span;
let json = info_span!("json.parse").in_scope(|| serde_json::from_slice(&buf))?;
You can find more examples showing how to use this crate here.
Events
Event
s are recorded using the event!
macro:
use tracing::{event, Level};
event!(Level::INFO, "something has happened!");
Using the Macros
The span!
and event!
macros as well as the #[instrument]
attribute
use fairly similar syntax, with some exceptions.
Configuring Attributes
Both macros require a Level
specifying the verbosity of the span or
event. Optionally, the target and parent span may be overridden. If the
target and parent span are not overridden, they will default to the
module path where the macro was invoked and the current span (as determined
by the subscriber), respectively.
For example:
span!(target: "app_spans", Level::TRACE, "my span");
event!(target: "app_events", Level::INFO, "something has happened!");
let span = span!(Level::TRACE, "my span");
event!(parent: &span, Level::INFO, "something has happened!");
The span macros also take a string literal after the level, to set the name of the span.
Recording Fields
Structured fields on spans and events are specified using the syntax
field_name = field_value
. Fields are separated by commas.
// records an event with two fields:
// - "answer", with the value 42
// - "question", with the value "life, the universe and everything"
event!(Level::INFO, answer = 42, question = "life, the universe, and everything");
As shorthand, local variables may be used as field values without an assignment, similar to struct initializers. For example:
let user = "ferris";
span!(Level::TRACE, "login", user);
// is equivalent to:
span!(Level::TRACE, "login", user = user);
Field names can include dots, but should not be terminated by them:
let user = "ferris";
let email = "ferris@rust-lang.org";
span!(Level::TRACE, "login", user, user.email = email);
Since field names can include dots, fields on local structs can be used using the local variable shorthand:
let user = User {
name: "ferris",
email: "ferris@rust-lang.org",
};
// the span will have the fields `user.name = "ferris"` and
// `user.email = "ferris@rust-lang.org"`.
span!(Level::TRACE, "login", user.name, user.email);
Fields with names that are not Rust identifiers, or with names that are Rust reserved words, may be created using quoted string literals. However, this may not be used with the local variable shorthand.
// records an event with fields whose names are not Rust identifiers
// - "guid:x-request-id", containing a `:`, with the value "abcdef"
// - "type", which is a reserved word, with the value "request"
span!(Level::TRACE, "api", "guid:x-request-id" = "abcdef", "type" = "request");
The ?
sigil is shorthand that specifies a field should be recorded using
its fmt::Debug
implementation:
#[derive(Debug)]
struct MyStruct {
field: &'static str,
}
let my_struct = MyStruct {
field: "Hello world!"
};
// `my_struct` will be recorded using its `fmt::Debug` implementation.
event!(Level::TRACE, greeting = ?my_struct);
// is equivalent to:
event!(Level::TRACE, greeting = tracing::field::debug(&my_struct));
The %
sigil operates similarly, but indicates that the value should be
recorded using its fmt::Display
implementation:
// `my_struct.field` will be recorded using its `fmt::Display` implementation.
event!(Level::TRACE, greeting = %my_struct.field);
// is equivalent to:
event!(Level::TRACE, greeting = tracing::field::display(&my_struct.field));
The %
and ?
sigils may also be used with local variable shorthand:
// `my_struct.field` will be recorded using its `fmt::Display` implementation.
event!(Level::TRACE, %my_struct.field);
Additionally, a span may declare fields with the special value Empty
,
which indicates that that the value for that field does not currently exist
but may be recorded later. For example:
use tracing::{trace_span, field};
// Create a span with two fields: `greeting`, with the value "hello world", and
// `parting`, without a value.
let span = trace_span!("my_span", greeting = "hello world", parting = field::Empty);
// ...
// Now, record a value for parting as well.
span.record("parting", &"goodbye world!");
Note that a span may have up to 32 fields. The following will not compile:
let bad_span = span!(
Level::TRACE,
"too many fields!",
a = 1, b = 2, c = 3, d = 4, e = 5, f = 6, g = 7, h = 8, i = 9,
j = 10, k = 11, l = 12, m = 13, n = 14, o = 15, p = 16, q = 17,
r = 18, s = 19, t = 20, u = 21, v = 22, w = 23, x = 24, y = 25,
z = 26, aa = 27, bb = 28, cc = 29, dd = 30, ee = 31, ff = 32, gg = 33
);
Finally, events may also include human-readable messages, in the form of a
format string and (optional) arguments, after the event’s
key-value fields. If a format string and arguments are provided,
they will implicitly create a new field named message
whose value is the
provided set of format arguments.
For example:
let question = "the ultimate question of life, the universe, and everything";
let answer = 42;
// records an event with the following fields:
// - `question.answer` with the value 42,
// - `question.tricky` with the value `true`,
// - "message", with the value "the answer to the ultimate question of life, the
// universe, and everything is 42."
event!(
Level::DEBUG,
question.answer = answer,
question.tricky = true,
"the answer to {} is {}.", question, answer
);
Specifying a formatted message in this manner does not allocate by default.
Shorthand Macros
tracing
also offers a number of macros with preset verbosity levels.
The trace!
, debug!
, info!
, warn!
, and error!
behave
similarly to the event!
macro, but with the Level
argument already
specified, while the corresponding trace_span!
, debug_span!
,
info_span!
, warn_span!
, and error_span!
macros are the same,
but for the span!
macro.
These are intended both as a shorthand, and for compatibility with the log
crate (see the next section).
For log
Users
Users of the log
crate should note that tracing
exposes a set of
macros for creating Event
s (trace!
, debug!
, info!
, warn!
, and
error!
) which may be invoked with the same syntax as the similarly-named
macros from the log
crate. Often, the process of converting a project to
use tracing
can begin with a simple drop-in replacement.
Let’s consider the log
crate’s yak-shaving example:
use std::{error::Error, io};
use tracing::{debug, error, info, span, warn, Level};
// the `#[tracing::instrument]` attribute creates and enters a span
// every time the instrumented function is called. The span is named after the
// the function or method. Parameters passed to the function are recorded as fields.
#[tracing::instrument]
pub fn shave(yak: usize) -> Result<(), Box<dyn Error + 'static>> {
// this creates an event at the DEBUG level with two fields:
// - `excitement`, with the key "excitement" and the value "yay!"
// - `message`, with the key "message" and the value "hello! I'm gonna shave a yak."
//
// unlike other fields, `message`'s shorthand initialization is just the string itself.
debug!(excitement = "yay!", "hello! I'm gonna shave a yak.");
if yak == 3 {
warn!("could not locate yak!");
// note that this is intended to demonstrate `tracing`'s features, not idiomatic
// error handling! in a library or application, you should consider returning
// a dedicated `YakError`. libraries like snafu or thiserror make this easy.
return Err(io::Error::new(io::ErrorKind::Other, "shaving yak failed!").into());
} else {
debug!("yak shaved successfully");
}
Ok(())
}
pub fn shave_all(yaks: usize) -> usize {
// Constructs a new span named "shaving_yaks" at the TRACE level,
// and a field whose key is "yaks". This is equivalent to writing:
//
// let span = span!(Level::TRACE, "shaving_yaks", yaks = yaks);
//
// local variables (`yaks`) can be used as field values
// without an assignment, similar to struct initializers.
let _span = span!(Level::TRACE, "shaving_yaks", yaks).entered();
info!("shaving yaks");
let mut yaks_shaved = 0;
for yak in 1..=yaks {
let res = shave(yak);
debug!(yak, shaved = res.is_ok());
if let Err(ref error) = res {
// Like spans, events can also use the field initialization shorthand.
// In this instance, `yak` is the field being initalized.
error!(yak, error = error.as_ref(), "failed to shave yak!");
} else {
yaks_shaved += 1;
}
debug!(yaks_shaved);
}
yaks_shaved
}
In libraries
Libraries should link only to the tracing
crate, and use the provided
macros to record whatever information will be useful to downstream
consumers.
In executables
In order to record trace events, executables have to use a Subscriber
implementation compatible with tracing
. A Subscriber
implements a
way of collecting trace data, such as by logging it to standard output.
This library does not contain any Subscriber
implementations; these are
provided by other crates.
The simplest way to use a subscriber is to call the set_global_default
function:
extern crate tracing;
let my_subscriber = FooSubscriber::new();
tracing::subscriber::set_global_default(my_subscriber)
.expect("setting tracing default failed");
Warning: In general, libraries should not call
set_global_default()
! Doing so will cause conflicts when
executables that depend on the library try to set the default later.
This subscriber will be used as the default in all threads for the
remainder of the duration of the program, similar to setting the logger
in the log
crate.
In addition, the default subscriber can be set through using the
with_default
function. This follows the tokio
pattern of using
closures to represent executing code in a context that is exited at the end
of the closure. For example:
let my_subscriber = FooSubscriber::new();
tracing::subscriber::with_default(my_subscriber, || {
// Any trace events generated in this closure or by functions it calls
// will be collected by `my_subscriber`.
})
This approach allows trace data to be collected by multiple subscribers within different contexts in the program. Note that the override only applies to the currently executing thread; other threads will not see the change from with_default.
Any trace events generated outside the context of a subscriber will not be collected.
Once a subscriber has been set, instrumentation points may be added to the
executable using the tracing
crate’s macros.
log
Compatibility
The log
crate provides a simple, lightweight logging facade for Rust.
While tracing
builds upon log
’s foundation with richer structured
diagnostic data, log
’s simplicity and ubiquity make it the “lowest common
denominator” for text-based logging in Rust — a vast majority of Rust
libraries and applications either emit or consume log
records. Therefore,
tracing
provides multiple forms of interoperability with log
: tracing
instrumentation can emit log
records, and a compatibility layer enables
tracing
Subscriber
s to consume log
records as tracing
Event
s.
Emitting log
Records
This crate provides two feature flags, “log” and “log-always”, which will
cause spans and events to emit log
records. When the “log” feature is
enabled, if no tracing
Subscriber
is active, invoking an event macro or
creating a span with fields will emit a log
record. This is intended
primarily for use in libraries which wish to emit diagnostics that can be
consumed by applications using tracing
or log
, without paying the
additional overhead of emitting both forms of diagnostics when tracing
is
in use.
Enabling the “log-always” feature will cause log
records to be emitted
even if a tracing
Subscriber
is set. This is intended to be used in
applications where a log
Logger
is being used to record a textual log,
and tracing
is used only to record other forms of diagnostics (such as
metrics, profiling, or distributed tracing data). Unlike the “log” feature,
libraries generally should not enable the “log-always” feature, as doing
so will prevent applications from being able to opt out of the log
records.
See here for more details on this crate’s feature flags.
The generated log
records’ messages will be a string representation of the
span or event’s fields, and all additional information recorded by log
(target, verbosity level, module path, file, and line number) will also be
populated. Additionally, log
records are also generated when spans are
entered, exited, and closed. Since these additional span lifecycle logs have
the potential to be very verbose, and don’t include additional fields, they
will always be emitted at the Trace
level, rather than inheriting the
level of the span that generated them. Furthermore, they are are categorized
under a separate log
target, “tracing::span” (and its sub-target,
“tracing::span::active”, for the logs on entering and exiting a span), which
may be enabled or disabled separately from other log
records emitted by
tracing
.
Consuming log
Records
The tracing-log
crate provides a compatibility layer which
allows a tracing
Subscriber
to consume log
records as though they
were tracing
events. This allows applications using tracing
to record
the logs emitted by dependencies using log
as events within the context of
the application’s trace tree. See that crate’s documentation
for details.
Related Crates
In addition to tracing
and tracing-core
, the tokio-rs/tracing
repository
contains several additional crates designed to be used with the tracing
ecosystem.
This includes a collection of Subscriber
implementations, as well as utility
and adapter crates to assist in writing Subscriber
s and instrumenting
applications.
In particular, the following crates are likely to be of interest:
tracing-futures
provides a compatibility layer with thefutures
crate, allowing spans to be attached toFuture
s,Stream
s, andExecutor
s.tracing-subscriber
providesSubscriber
implementations and utilities for working withSubscriber
s. This includes aFmtSubscriber
FmtSubscriber
for logging formatted trace data to stdout, with similar filtering and formatting to theenv_logger
crate.tracing-log
provides a compatibility layer with thelog
crate, allowing log messages to be recorded astracing
Event
s within the trace tree. This is useful when a project usingtracing
have dependencies which uselog
. Note that if you’re usingtracing-subscriber
’sFmtSubscriber
, you don’t need to depend ontracing-log
directly.tracing-appender
provides utilities for outputting tracing data, including a file appender and non blocking writer.
Additionally, there are also several third-party crates which are not
maintained by the tokio
project. These include:
tracing-timing
implements inter-event timing metrics on top oftracing
. It provides a subscriber that records the time elapsed between pairs oftracing
events and generates histograms.tracing-opentelemetry
provides a subscriber for emitting traces to OpenTelemetry-compatible distributed tracing systems.tracing-honeycomb
Provides a layer that reports traces spanning multiple machines to honeycomb.io. Backed bytracing-distributed
.tracing-distributed
Provides a generic implementation of a layer that reports traces spanning multiple machines to some backend.tracing-actix-web
providestracing
integration for theactix-web
web framework.tracing-actix
providestracing
integration for theactix
actor framework.tracing-gelf
implements a subscriber for exporting traces in Greylog GELF format.tracing-coz
provides integration with the coz causal profiler (Linux-only).tracing-bunyan-formatter
provides a layer implementation that reports events and spans in bunyan format, enriched with timing information.tracing-wasm
provides aSubscriber
/Layer
implementation that reports events and spans via browserconsole.log
and User Timing API (window.performance
).tide-tracing
provides a tide middleware to trace all incoming requests and responses.test-log
takes care of initializingtracing
for tests, based on environment variables with anenv_logger
compatible syntax.tracing-unwrap
provides convenience methods to report failed unwraps onResult
orOption
types to aSubscriber
.diesel-tracing
provides integration withdiesel
database connections.tracing-tracy
provides a way to collect Tracy profiles in instrumented applications.tracing-elastic-apm
provides a layer for reporting traces to Elastic APM.tracing-etw
provides a layer for emitting Windows ETW events.tracing-fluent-assertions
provides a fluent assertions-style testing framework for validating the behavior oftracing
spans.sentry-tracing
provides a layer for reporting events and traces to Sentry.tracing-forest
provides a subscriber that preserves contextual coherence by grouping together logs from the same spans during writing.tracing-loki
provides a layer for shipping logs to Grafana Loki.
If you’re the maintainer of a tracing
ecosystem crate not listed above,
please let us know! We’d love to add your project to the list!
Note: Some of these ecosystem crates are currently unreleased and/or in earlier stages of development. They may be less stable thantracing
andtracing-core
.
Crate Feature Flags
The following crate feature flags are available:
-
A set of features controlling the static verbosity level.
-
log
: causes trace instrumentation points to emitlog
records as well as trace events, if a defaulttracing
subscriber has not been set. This is intended for use in libraries whose users may be using eithertracing
orlog
. -
log-always
: Emitlog
records from alltracing
spans and events, even if atracing
subscriber has been set. This should be set only by applications which intend to collect traces and logs separately; if an adapter is used to convertlog
records intotracing
events, this will cause duplicate events to occur. -
attributes
: Includes support for the#[instrument]
attribute. This is on by default, but does bring in thesyn
crate as a dependency, which may add to the compile time of crates that do not already use it. -
std
: Depend on the Rust standard library (enabled by default).no_std
users may disable this feature withdefault-features = false
:[dependencies] tracing = { version = "0.1.35", default-features = false }
Note:tracing
'sno_std
support requiresliballoc
.
Unstable Features
These feature flags enable unstable features. The public API may break in 0.1.x
releases. To enable these features, the --cfg tracing_unstable
must be passed to
rustc
when compiling.
The following unstable feature flags are currently available:
valuable
: Enables support for recording field values using thevaluable
crate.
Enabling Unstable Features
The easiest way to set the tracing_unstable
cfg is to use the RUSTFLAGS
env variable when running cargo
commands:
RUSTFLAGS="--cfg tracing_unstable" cargo build
Alternatively, the following can be added to the .cargo/config
file in a
project to automatically enable the cfg flag for that project:
[build]
rustflags = ["--cfg", "tracing_unstable"]
Supported Rust Versions
Tracing is built against the latest stable release. The minimum supported version is 1.49. The current Tracing version is not guaranteed to build on Rust versions earlier than the minimum supported version.
Tracing follows the same compiler support policies as the rest of the Tokio project. The current stable Rust compiler and the three most recent minor versions before it will always be supported. For example, if the current stable compiler version is 1.45, the minimum supported version will not be increased past 1.42, three minor versions prior. Increasing the minimum supported compiler version is not considered a semver breaking change as long as doing so complies with this policy.
Modules
Dispatches trace events to Subscriber
s.
Events represent single points in time during the execution of a program.
Span
and Event
key-value data.
Attach a span to a std::future::Future
.
Trace verbosity level filtering.
Spans represent periods of time in which a program was executing in a particular context.
Collects and records trace data.
Macros
Constructs an event at the debug level.
Constructs a span at the debug level.
Constructs an event at the error level.
Constructs a span at the error level.
Constructs a new Event
.
Tests whether an event with the specified level and target would be enabled.
Constructs an event at the info level.
Constructs a span at the info level.
Constructs a new span.
Tests whether a span with the specified level and target would be enabled.
Constructs an event at the trace level.
Constructs a span at the trace level.
Constructs an event at the warn level.
Constructs a span at the warn level.
Structs
Dispatch
trace data to a Subscriber
.
Event
s represent single points in time where something occurred during the
execution of a program.
Describes the level of verbosity of a span or event.
A handle representing a span, with the capability to enter the span if it exists.
Traits
Attaches spans to a std::future::Future
.
Trait representing the functions required to collect trace data.
A field value of an erased type.