tracing-actix-web
provides TracingLogger
, a middleware to collect telemetry data from applications built on top of the actix-web
framework.
tracing-actix-web
was initially developed for the telemetry chapter of Zero to Production In Rust, a hands-on introduction to backend development using the Rust programming language.
Getting started
How to install
Add tracing-actix-web
to your dependencies:
[]
# ...
= "0.7"
= "0.1"
= "4"
tracing-actix-web
exposes these feature flags:
opentelemetry_0_13
: attach OpenTelemetry's context to the root span usingopentelemetry
0.13;opentelemetry_0_14
: same as above but usingopentelemetry
0.14;opentelemetry_0_15
: same as above but usingopentelemetry
0.15;opentelemetry_0_16
: same as above but usingopentelemetry
0.16;opentelemetry_0_17
: same as above but usingopentelemetry
0.17;opentelemetry_0_18
: same as above but usingopentelemetry
0.18;opentelemetry_0_19
: same as above but usingopentelemetry
0.19;opentelemetry_0_20
: same as above but usingopentelemetry
0.20;opentelemetry_0_21
: same as above but usingopentelemetry
0.21;opentelemetry_0_22
: same as above but usingopentelemetry
0.22;opentelemetry_0_23
: same as above but usingopentelemetry
0.23;opentelemetry_0_24
: same as above but usingopentelemetry
0.24;opentelemetry_0_25
: same as above but usingopentelemetry
0.25;opentelemetry_0_26
: same as above but usingopentelemetry
0.26;opentelemetry_0_27
: same as above but usingopentelemetry
0.27;emit_event_on_error
: emit atracing
event when request processing fails with an error (enabled by default).uuid_v7
: use the UUID v7 implementation insideRequestId
instead of UUID v4 (disabled by default).
Quickstart
use ;
use TracingLogger;
Check out the examples on GitHub to get a taste of how TracingLogger
can be used to observe and monitor your
application.
From zero to hero: a crash course in observability
tracing
: who art thou?
TracingLogger
is built on top of tracing
, a modern instrumentation framework with
a vibrant ecosystem.
tracing-actix-web
's documentation provides a crash course in how to use tracing
to instrument an actix-web
application.
If you want to learn more check out "Are we observable yet?" -
it provides an in-depth introduction to the crate and the problems it solves within the bigger picture of observability.
The root span
tracing::Span
is the key abstraction in tracing
: it represents a unit of work in your system.
A tracing::Span
has a beginning and an end. It can include one or more child spans to represent sub-unit
of works within a larger task.
When your application receives a request, TracingLogger
creates a new span - we call it the root span.
All the spans created while processing the request will be children of the root span.
tracing
empowers us to attach structured properties to a span as a collection of key-value pairs.
Those properties can then be queried in a variety of tools (e.g. ElasticSearch, Honeycomb, DataDog) to
understand what is happening in your system.
Customisation via RootSpanBuilder
Troubleshooting becomes much easier when the root span has a rich context - e.g. you can understand most of what happened when processing the request just by looking at the properties attached to the corresponding root span.
You might have heard of this technique as the canonical log line pattern, popularised by Stripe. It is more recently discussed in terms of high-cardinality events by Honeycomb and other vendors in the observability space.
TracingLogger
gives you a chance to use the very same pattern: you can customise the properties attached
to the root span in order to capture the context relevant to your specific domain.
[TracingLogger::default
] is equivalent to:
use ;
// Two ways to initialise TracingLogger with the default root span builder
let default = default;
let another_way = new;
We are delegating the construction of the root span to DefaultRootSpanBuilder
.
DefaultRootSpanBuilder
captures, out of the box, several dimensions that are usually relevant when looking at an HTTP
API: method, version, route, etc. - check out its documentation for an extensive list.
You can customise the root span by providing your own implementation of the RootSpanBuilder
trait.
Let's imagine, for example, that our system cares about a client identifier embedded inside an authorization header.
We could add a client_id
property to the root span using a custom builder, DomainRootSpanBuilder
:
use MessageBody;
use ;
use Error;
use ;
use Span;
;
let custom_middleware = new;
There is an issue, though: client_id
is the only property we are capturing.
With DomainRootSpanBuilder
, as it is, we do not get any of that useful HTTP-related information provided by
DefaultRootSpanBuilder
.
We can do better!
use MessageBody;
use ;
use Error;
use ;
use Span;
;
let custom_middleware = new;
root_span!
is a macro provided by tracing-actix-web
: it creates a new span by combining all the HTTP properties tracked
by DefaultRootSpanBuilder
with the custom ones you specify when calling it (e.g. client_id
in our example).
We need to use a macro because tracing
requires all the properties attached to a span to be declared upfront, when the span is created.
You cannot add new ones afterwards. This makes it extremely fast, but it pushes us to reach for macros when we need some level of
composition.
root_span!
exposes more or less the same knob you can find on tracing
's span!
macro. You can, for example, customise
the span level:
use MessageBody;
use ;
use Error;
use ;
use Span;
;
let custom_middleware = new;
The RootSpan
extractor
It often happens that not all information about a task is known upfront, encoded in the incoming request.
You can use the RootSpan
extractor to grab the root span in your handlers and attach more information
to your root span as it becomes available:
use MessageBody;
use ;
use ;
use ;
use Span;
use get;
use RequestId;
use Uuid;
async
;
Unique identifiers
Request Id
tracing-actix-web
generates a unique identifier for each incoming request, the request id.
You can extract the request id using the RequestId
extractor:
use get;
use RequestId;
use Uuid;
async
The request id is meant to identify all operations related to a particular request within the boundary of your API.
If you need to trace a request across multiple services (e.g. in a microservice architecture), you want to look at the trace_id
field - see the next section on OpenTelemetry for more details.
Optionally, using the uuid_v7
feature flag will allow RequestId
to use UUID v7 instead of the currently used UUID v4.
Trace Id
To fulfill a request you often have to perform additional I/O operations - e.g. calls to other REST or gRPC APIs, database queries, etc.
Distributed tracing is the standard approach to trace a single request across the entirety of your stack.
tracing-actix-web
provides support for distributed tracing by supporting the OpenTelemetry standard.
tracing-actix-web
follows OpenTelemetry's semantic convention
for field names.
Furthermore, it provides an opentelemetry_0_17
feature flag to automatically performs trace propagation: it tries to extract the OpenTelemetry context out of the headers of incoming requests and, when it finds one, it sets it as the remote context for the current root span. The context is then propagated to your downstream dependencies if your HTTP or gRPC clients are OpenTelemetry-aware - e.g. using reqwest-middleware
and reqwest-tracing
if you are using reqwest
as your HTTP client.
You can then find all logs for the same request across all the services it touched by looking for the trace_id
, automatically logged by tracing-actix-web
.
If you add tracing-opentelemetry::OpenTelemetryLayer
in your tracing::Subscriber
you will be able to export the root span (and all its children) as OpenTelemetry spans.
Check out the relevant example in the GitHub repository for reference.
License
Licensed under either of Apache License, Version 2.0 or MIT license at your option.
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in tracing-actix-web
by you, as defined in the Apache-2.0 license, shall be
dual licensed as above, without any additional terms or conditions.