![Tracing — Structured, application-level diagnostics][splash] [splash]: https://raw.githubusercontent.com/tokio-rs/tracing/master/assets/splash.svg # tracing Application-level tracing for Rust. [![Crates.io][crates-badge]][crates-url] [![Documentation][docs-badge]][docs-url] [![Documentation (master)][docs-master-badge]][docs-master-url] [![MIT licensed][mit-badge]][mit-url] [![Build Status][actions-badge]][actions-url] [![Discord chat][discord-badge]][discord-url] [Documentation][docs-url] | [Chat][discord-url] [crates-badge]: https://img.shields.io/crates/v/tracing.svg [crates-url]: https://crates.io/crates/tracing [docs-badge]: https://docs.rs/tracing/badge.svg [docs-url]: https://docs.rs/tracing [docs-master-badge]: https://img.shields.io/badge/docs-master-blue [docs-master-url]: https://tracing-rs.netlify.com/tracing [mit-badge]: https://img.shields.io/badge/license-MIT-blue.svg [mit-url]: LICENSE [actions-badge]: https://github.com/tokio-rs/tracing/workflows/CI/badge.svg [actions-url]:https://github.com/tokio-rs/tracing/actions?query=workflow%3ACI [discord-badge]: https://img.shields.io/discord/500028886025895936?logo=discord&label=discord&logoColor=white [discord-url]: https://discord.gg/EeF3cQw ## 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` 1.63+][msrv]* [msrv]: #supported-rust-versions ## Usage (The examples below are borrowed from the `log` crate's yak-shaving [example](https://docs.rs/log/0.4.10/log/index.html#examples), modified to idiomatic `tracing`.) ### In Applications 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. [`tracing_subscriber`](https://docs.rs/tracing-subscriber/)'s [`fmt` module](https://docs.rs/tracing-subscriber/0.3/tracing_subscriber/fmt/index.html) provides reasonable defaults. Additionally, `tracing-subscriber` is able to consume messages emitted by `log`-instrumented libraries and modules. The simplest way to use a subscriber is to call the `set_global_default` function. ```rust use tracing::{info, Level}; use tracing_subscriber::FmtSubscriber; fn main() { // a builder for `FmtSubscriber`. let subscriber = FmtSubscriber::builder() // all spans/events with a level higher than TRACE (e.g, debug, info, warn, etc.) // will be written to stdout. .with_max_level(Level::TRACE) // completes the builder. .finish(); tracing::subscriber::set_global_default(subscriber) .expect("setting default subscriber failed"); let number_of_yaks = 3; // this creates a new event, outside of any spans. info!(number_of_yaks, "preparing to shave yaks"); let number_shaved = yak_shave::shave_all(number_of_yaks); info!( all_yaks_shaved = number_shaved == number_of_yaks, "yak shaving completed." ); } ``` ```toml [dependencies] tracing = "0.1" tracing-subscriber = "0.3.0" ``` This subscriber will be used as the default in all threads for the remainder of the duration of the program, similar to how loggers work in the `log` crate. In addition, you can locally override the default subscriber. For example: ```rust use tracing::{info, Level}; use tracing_subscriber::FmtSubscriber; fn main() { let subscriber = tracing_subscriber::FmtSubscriber::builder() // all spans/events with a level higher than TRACE (e.g, debug, info, warn, etc.) // will be written to stdout. .with_max_level(Level::TRACE) // builds the subscriber. .finish(); tracing::subscriber::with_default(subscriber, || { info!("This will be logged to stdout"); }); info!("This will _not_ be logged to stdout"); } ``` 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. ### In Libraries Libraries should only rely on the `tracing` crate and use the provided macros and types to collect whatever information might be useful to downstream consumers. ```rust 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> { // 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 initialized. error!(yak, error = error.as_ref(), "failed to shave yak!"); } else { yaks_shaved += 1; } debug!(yaks_shaved); } yaks_shaved } ``` ```toml [dependencies] tracing = "0.1" ``` Note: Libraries should *NOT* call `set_global_default()`, as this will cause conflicts when executables try to set the default later. ### In Asynchronous Code If you are instrumenting code that make use of [`std::future::Future`](https://doc.rust-lang.org/stable/std/future/trait.Future.html) or async/await, avoid using the `Span::enter` method. The following example _will not_ work: ```rust async { let _s = span.enter(); // ... } ``` ```rust async { let _s = tracing::span!(...).entered(); // ... } ``` The span guard `_s` will not exit until the future generated by the `async` block is complete. Since futures and spans can be entered and exited _multiple_ times without them completing, the span remains entered for as long as the future exists, rather than being entered only when it is polled, leading to very confusing and incorrect output. For more details, see [the documentation on closing spans](https://tracing.rs/tracing/span/index.html#closing-spans). There are two ways to instrument asynchronous code. The first is through the [`Future::instrument`](https://docs.rs/tracing/latest/tracing/trait.Instrument.html#method.instrument) combinator: ```rust use tracing::Instrument; let my_future = async { // ... }; my_future .instrument(tracing::info_span!("my_future")) .await ``` `Future::instrument` attaches a span to the future, ensuring that the span's lifetime is as long as the future's. The second, and preferred, option is through the [`#[instrument]`](https://docs.rs/tracing/0.1.41/tracing/attr.instrument.html) attribute: ```rust use tracing::{info, instrument}; use tokio::{io::AsyncWriteExt, net::TcpStream}; use std::io; #[instrument] async fn write(stream: &mut TcpStream) -> io::Result { let result = stream.write(b"hello world\n").await; info!("wrote to stream; success={:?}", result.is_ok()); result } ``` Under the hood, the `#[instrument]` macro performs the same explicit span attachment that `Future::instrument` does. ### Concepts This crate provides macros for creating `Span`s and `Event`s, which represent periods of time and momentary events within the execution of a program, respectively. As a rule of thumb, _spans_ should be used to represent discrete units of work (e.g., a given request's lifetime in a server) or periods of time spent in a given context (e.g., time spent interacting with an instance of an external system, such as a database). In contrast, _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. `Span`s are constructed using the `span!` macro, and then _entered_ to indicate that some code takes place within the context of that `Span`: ```rust use tracing::{span, Level}; // Construct a new span named "my span". let mut span = span!(Level::INFO, "my span"); span.in_scope(|| { // Any trace events in this closure or code called by it will occur within // the span. }); // Dropping the span will close it, indicating that it has ended. ``` The [`#[instrument]`](https://docs.rs/tracing/0.1.41/tracing/attr.instrument.html) attribute macro can reduce some of this boilerplate: ```rust use tracing::{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`. tracing::info!("inside my_function!"); // ... } ``` The `Event` type represent an event that occurs instantaneously, and is essentially a `Span` that cannot be entered. They are created using the `event!` macro: ```rust use tracing::{event, Level}; event!(Level::INFO, "something has happened!"); ``` 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. ## Supported Rust Versions Tracing is built against the latest stable release. The minimum supported version is 1.42. 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. ## Ecosystem ### 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 the `futures` crate, allowing spans to be attached to `Future`s, `Stream`s, and `Executor`s. - [`tracing-subscriber`] provides `Subscriber` implementations and utilities for working with `Subscriber`s. This includes a [`FmtSubscriber`] `FmtSubscriber` for logging formatted trace data to stdout, with similar filtering and formatting to the [`env_logger`] crate. - [`tracing-log`] provides a compatibility layer with the [`log`] crate, allowing log messages to be recorded as `tracing` `Event`s within the trace tree. This is useful when a project using `tracing` have dependencies which use `log`. Note that if you're using `tracing-subscriber`'s `FmtSubscriber`, you don't need to depend on `tracing-log` directly. 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 of `tracing`. It provides a subscriber that records the time elapsed between pairs of `tracing` 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 by [`tracing-distributed`]. - [`tracing-distributed`] Provides a generic implementation of a layer that reports traces spanning multiple machines to some backend. - [`tracing-actix`] provides `tracing` integration for the `actix` actor framework. - [`axum-insights`] provides `tracing` integration and Application insights export for the `axum` web framework. - [`tracing-gelf`] implements a subscriber for exporting traces in Greylog GELF format. - [`tracing-coz`] provides integration with the [coz] causal profiler (Linux-only). - [`test-log`] takes care of initializing `tracing` for tests, based on environment variables with an `env_logger` compatible syntax. - [`tracing-unwrap`] provides convenience methods to report failed unwraps on `Result` or `Option` types to a `Subscriber`. - [`diesel-tracing`] provides integration with [`diesel`] 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 of `tracing` spans. - [`sentry-tracing`] provides a layer for reporting events and traces to [Sentry]. - [`tracing-loki`] provides a layer for shipping logs to [Grafana Loki]. - [`tracing-logfmt`] provides a layer that formats events and spans into the logfmt format. - [`json-subscriber`] provides a layer for emitting JSON logs. The output can be customized much more than with [`FmtSubscriber`]'s JSON output. 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! [`tracing-timing`]: https://crates.io/crates/tracing-timing [`tracing-opentelemetry`]: https://crates.io/crates/tracing-opentelemetry [OpenTelemetry]: https://opentelemetry.io/ [`tracing-honeycomb`]: https://crates.io/crates/tracing-honeycomb [`tracing-distributed`]: https://crates.io/crates/tracing-distributed [honeycomb.io]: https://www.honeycomb.io/ [`tracing-actix`]: https://crates.io/crates/tracing-actix [`axum-insights`]: https://crates.io/crates/axum-insights [`tracing-gelf`]: https://crates.io/crates/tracing-gelf [`tracing-coz`]: https://crates.io/crates/tracing-coz [coz]: https://github.com/plasma-umass/coz [`test-log`]: https://crates.io/crates/test-log [`tracing-unwrap`]: https://docs.rs/tracing-unwrap [`diesel`]: https://crates.io/crates/diesel [`diesel-tracing`]: https://crates.io/crates/diesel-tracing [`tracing-tracy`]: https://crates.io/crates/tracing-tracy [Tracy]: https://github.com/wolfpld/tracy [`tracing-elastic-apm`]: https://crates.io/crates/tracing-elastic-apm [Elastic APM]: https://www.elastic.co/apm [`tracing-etw`]: https://github.com/microsoft/tracing-etw [ETW]: https://docs.microsoft.com/en-us/windows/win32/etw/about-event-tracing [`tracing-fluent-assertions`]: https://crates.io/crates/tracing-fluent-assertions [`sentry-tracing`]: https://crates.io/crates/sentry-tracing [Sentry]: https://sentry.io/welcome/ [`tracing-loki`]: https://crates.io/crates/tracing-loki [Grafana Loki]: https://grafana.com/oss/loki/ [`tracing-logfmt`]: https://crates.io/crates/tracing-logfmt [`json-subscriber`]: https://crates.io/crates/json-subscriber **Note:** that some of the ecosystem crates are currently unreleased and undergoing active development. They may be less stable than `tracing` and `tracing-core`. [`log`]: https://docs.rs/log/0.4.6/log/ [`tokio-rs/tracing`]: https://github.com/tokio-rs/tracing [`tracing-futures`]: https://github.com/tokio-rs/tracing/tree/master/tracing-futures [`tracing-subscriber`]: https://github.com/tokio-rs/tracing/tree/master/tracing-subscriber [`tracing-log`]: https://github.com/tokio-rs/tracing/tree/master/tracing-log [`env_logger`]: https://crates.io/crates/env_logger [`FmtSubscriber`]: https://docs.rs/tracing-subscriber/latest/tracing_subscriber/fmt/struct.Subscriber.html [`examples`]: https://github.com/tokio-rs/tracing/tree/master/examples ## Supported Rust Versions Tracing is built against the latest stable release. The minimum supported version is 1.63. 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 1.69, the minimum supported version will not be increased past 1.66, 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. ## License This project is licensed under the [MIT license](LICENSE). ### Contribution Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in Tokio by you, shall be licensed as MIT, without any additional terms or conditions.