pub trait FilterExt<S>: Filter<S> {
    // Provided methods
    fn and<B>(self, other: B) -> And<Self, B, S>
       where Self: Sized,
             B: Filter<S> { ... }
    fn or<B>(self, other: B) -> Or<Self, B, S>
       where Self: Sized,
             B: Filter<S> { ... }
    fn not(self) -> Not<Self, S>
       where Self: Sized { ... }
    fn boxed(self) -> Box<dyn Filter<S> + Send + Sync + 'static>
       where Self: Sized + Send + Sync + 'static { ... }
}
Expand description

Extension trait adding combinators for combining Filter.

Provided Methods§

source

fn and<B>(self, other: B) -> And<Self, B, S>where Self: Sized, B: Filter<S>,

Combines this Filter with another Filter s so that spans and events are enabled if and only if both filters return true.

Examples

Enabling spans or events if they have both a particular target and are above a certain level:

use tracing_subscriber::{
    filter::{filter_fn, LevelFilter, FilterExt},
    prelude::*,
};

// Enables spans and events with targets starting with `interesting_target`:
let target_filter = filter_fn(|meta| {
    meta.target().starts_with("interesting_target")
});

// Enables spans and events with levels `INFO` and below:
let level_filter = LevelFilter::INFO;

// Combine the two filters together, returning a filter that only enables
// spans and events that *both* filters will enable:
let filter = target_filter.and(level_filter);

tracing_subscriber::registry()
    .with(tracing_subscriber::fmt::layer().with_filter(filter))
    .init();

// This event will *not* be enabled:
tracing::info!("an event with an uninteresting target");

// This event *will* be enabled:
tracing::info!(target: "interesting_target", "a very interesting event");

// This event will *not* be enabled:
tracing::debug!(target: "interesting_target", "interesting debug event...");
source

fn or<B>(self, other: B) -> Or<Self, B, S>where Self: Sized, B: Filter<S>,

Combines two Filters so that spans and events are enabled if either filter returns true.

Examples

Enabling spans and events at the INFO level and above, and all spans and events with a particular target:

use tracing_subscriber::{
    filter::{filter_fn, LevelFilter, FilterExt},
    prelude::*,
};

// Enables spans and events with targets starting with `interesting_target`:
let target_filter = filter_fn(|meta| {
    meta.target().starts_with("interesting_target")
});

// Enables spans and events with levels `INFO` and below:
let level_filter = LevelFilter::INFO;

// Combine the two filters together so that a span or event is enabled
// if it is at INFO or lower, or if it has a target starting with
// `interesting_target`.
let filter = level_filter.or(target_filter);

tracing_subscriber::registry()
    .with(tracing_subscriber::fmt::layer().with_filter(filter))
    .init();

// This event will *not* be enabled:
tracing::debug!("an uninteresting event");

// This event *will* be enabled:
tracing::info!("an uninteresting INFO event");

// This event *will* be enabled:
tracing::info!(target: "interesting_target", "a very interesting event");

// This event *will* be enabled:
tracing::debug!(target: "interesting_target", "interesting debug event...");

Enabling a higher level for a particular target by using or in conjunction with the and combinator:

use tracing_subscriber::{
    filter::{filter_fn, LevelFilter, FilterExt},
    prelude::*,
};

// This filter will enable spans and events with targets beginning with
// `my_crate`:
let my_crate = filter_fn(|meta| {
    meta.target().starts_with("my_crate")
});

let filter = my_crate
    // Combine the `my_crate` filter with a `LevelFilter` to produce a
    // filter that will enable the `INFO` level and lower for spans and
    // events with `my_crate` targets:
    .and(LevelFilter::INFO)
    // If a span or event *doesn't* have a target beginning with
    // `my_crate`, enable it if it has the `WARN` level or lower:
    .or(LevelFilter::WARN);

tracing_subscriber::registry()
    .with(tracing_subscriber::fmt::layer().with_filter(filter))
    .init();
source

fn not(self) -> Not<Self, S>where Self: Sized,

Inverts self, returning a filter that enables spans and events only if self would not enable them.

This inverts the values returned by the enabled and callsite_enabled methods on the wrapped filter; it does not invert event_enabled, as filters which do not implement filtering on event field values will return the default true even for events that their enabled method disables.

Consider a normal filter defined as:

// for spans
match callsite_enabled() {
    ALWAYS => on_span(),
    SOMETIMES => if enabled() { on_span() },
    NEVER => (),
}
// for events
match callsite_enabled() {
   ALWAYS => on_event(),
   SOMETIMES => if enabled() && event_enabled() { on_event() },
   NEVER => (),
}

and an inverted filter defined as:

// for spans
match callsite_enabled() {
    ALWAYS => (),
    SOMETIMES => if !enabled() { on_span() },
    NEVER => on_span(),
}
// for events
match callsite_enabled() {
    ALWAYS => (),
    SOMETIMES => if !enabled() { on_event() },
    NEVER => on_event(),
}

A proper inversion would do !(enabled() && event_enabled()) (or !enabled() || !event_enabled()), but because of the implicit && relation between enabled and event_enabled, it is difficult to short circuit and not call the wrapped event_enabled.

A combinator which remembers the result of enabled in order to call event_enabled only when enabled() == true is possible, but requires additional thread-local mutable state to support a very niche use case.

source

fn boxed(self) -> Box<dyn Filter<S> + Send + Sync + 'static>where Self: Sized + Send + Sync + 'static,

Boxes self, erasing its concrete type.

This is equivalent to calling Box::new, but in method form, so that it can be used when chaining combinator methods.

Examples

When different combinations of filters are used conditionally, they may have different types. For example, the following code won’t compile, since the if and else clause produce filters of different types:

use tracing_subscriber::{
    filter::{filter_fn, LevelFilter, FilterExt},
    prelude::*,
};

let enable_bar_target: bool = // ...

let filter = if enable_bar_target {
    filter_fn(|meta| meta.target().starts_with("foo"))
        // If `enable_bar_target` is true, add a `filter_fn` enabling
        // spans and events with the target `bar`:
        .or(filter_fn(|meta| meta.target().starts_with("bar")))
        .and(LevelFilter::INFO)
} else {
    filter_fn(|meta| meta.target().starts_with("foo"))
        .and(LevelFilter::INFO)
};

tracing_subscriber::registry()
    .with(tracing_subscriber::fmt::layer().with_filter(filter))
    .init();

By using boxed, the types of the two different branches can be erased, so the assignment to the filter variable is valid (as both branches have the type Box<dyn Filter<S> + Send + Sync + 'static>). The following code does compile:

use tracing_subscriber::{
    filter::{filter_fn, LevelFilter, FilterExt},
    prelude::*,
};

let enable_bar_target: bool = // ...

let filter = if enable_bar_target {
    filter_fn(|meta| meta.target().starts_with("foo"))
        .or(filter_fn(|meta| meta.target().starts_with("bar")))
        .and(LevelFilter::INFO)
        // Boxing the filter erases its type, so both branches now
        // have the same type.
        .boxed()
} else {
    filter_fn(|meta| meta.target().starts_with("foo"))
        .and(LevelFilter::INFO)
        .boxed()
};

tracing_subscriber::registry()
    .with(tracing_subscriber::fmt::layer().with_filter(filter))
    .init();

Implementors§

source§

impl<F, S> FilterExt<S> for Fwhere F: Filter<S>,