Revision control

Copy as Markdown

Other Tools

// Copyright 2015 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! A lightweight logging facade.
//!
//! The `log` crate provides a single logging API that abstracts over the
//! actual logging implementation. Libraries can use the logging API provided
//! by this crate, and the consumer of those libraries can choose the logging
//! implementation that is most suitable for its use case.
//!
//! If no logging implementation is selected, the facade falls back to a "noop"
//! implementation that ignores all log messages. The overhead in this case
//! is very small - just an integer load, comparison and jump.
//!
//! A log request consists of a _target_, a _level_, and a _body_. A target is a
//! string which defaults to the module path of the location of the log request,
//! though that default may be overridden. Logger implementations typically use
//! the target to filter requests based on some user configuration.
//!
//! # Usage
//!
//! The basic use of the log crate is through the five logging macros: [`error!`],
//! [`warn!`], [`info!`], [`debug!`] and [`trace!`]
//! where `error!` represents the highest-priority log messages
//! and `trace!` the lowest. The log messages are filtered by configuring
//! the log level to exclude messages with a lower priority.
//! Each of these macros accept format strings similarly to [`println!`].
//!
//!
//! [`error!`]: ./macro.error.html
//! [`warn!`]: ./macro.warn.html
//! [`info!`]: ./macro.info.html
//! [`debug!`]: ./macro.debug.html
//! [`trace!`]: ./macro.trace.html
//!
//! Avoid writing expressions with side-effects in log statements. They may not be evaluated.
//!
//! ## In libraries
//!
//! Libraries should link only to the `log` crate, and use the provided
//! macros to log whatever information will be useful to downstream consumers.
//!
//! ### Examples
//!
//! ```
//! # #[derive(Debug)] pub struct Yak(String);
//! # impl Yak { fn shave(&mut self, _: u32) {} }
//! # fn find_a_razor() -> Result<u32, u32> { Ok(1) }
//! use log::{info, warn};
//!
//! pub fn shave_the_yak(yak: &mut Yak) {
//! info!(target: "yak_events", "Commencing yak shaving for {yak:?}");
//!
//! loop {
//! match find_a_razor() {
//! Ok(razor) => {
//! info!("Razor located: {razor}");
//! yak.shave(razor);
//! break;
//! }
//! Err(err) => {
//! warn!("Unable to locate a razor: {err}, retrying");
//! }
//! }
//! }
//! }
//! # fn main() {}
//! ```
//!
//! ## In executables
//!
//! Executables should choose a logging implementation and initialize it early in the
//! runtime of the program. Logging implementations will typically include a
//! function to do this. Any log messages generated before
//! the implementation is initialized will be ignored.
//!
//! The executable itself may use the `log` crate to log as well.
//!
//! ### Warning
//!
//! The logging system may only be initialized once.
//!
//! ## Structured logging
//!
//! If you enable the `kv` feature you can associate structured values
//! with your log records. If we take the example from before, we can include
//! some additional context besides what's in the formatted message:
//!
//! ```
//! # use serde::Serialize;
//! # #[derive(Debug, Serialize)] pub struct Yak(String);
//! # impl Yak { fn shave(&mut self, _: u32) {} }
//! # fn find_a_razor() -> Result<u32, std::io::Error> { Ok(1) }
//! # #[cfg(feature = "kv_serde")]
//! # fn main() {
//! use log::{info, warn};
//!
//! pub fn shave_the_yak(yak: &mut Yak) {
//! info!(target: "yak_events", yak:serde; "Commencing yak shaving");
//!
//! loop {
//! match find_a_razor() {
//! Ok(razor) => {
//! info!(razor; "Razor located");
//! yak.shave(razor);
//! break;
//! }
//! Err(e) => {
//! warn!(e:err; "Unable to locate a razor, retrying");
//! }
//! }
//! }
//! }
//! # }
//! # #[cfg(not(feature = "kv_serde"))]
//! # fn main() {}
//! ```
//!
//! See the [`kv`] module documentation for more details.
//!
//! # Available logging implementations
//!
//! In order to produce log output executables have to use
//! a logger implementation compatible with the facade.
//! There are many available implementations to choose from,
//! here are some of the most popular ones:
//!
//! * Simple minimal loggers:
//! * [env_logger]
//! * [colog]
//! * [simple_logger]
//! * [simplelog]
//! * [pretty_env_logger]
//! * [stderrlog]
//! * [flexi_logger]
//! * [call_logger]
//! * [structured-logger]
//! * Complex configurable frameworks:
//! * [log4rs]
//! * [fern]
//! * Adaptors for other facilities:
//! * [syslog]
//! * [slog-stdlog]
//! * [systemd-journal-logger]
//! * [android_log]
//! * [win_dbg_logger]
//! * [db_logger]
//! * [log-to-defmt]
//! * [logcontrol-log]
//! * For WebAssembly binaries:
//! * [console_log]
//! * For dynamic libraries:
//! * You may need to construct an FFI-safe wrapper over `log` to initialize in your libraries
//! * Utilities:
//! * [log_err]
//! * [log-reload]
//!
//! # Implementing a Logger
//!
//! Loggers implement the [`Log`] trait. Here's a very basic example that simply
//! logs all messages at the [`Error`][level_link], [`Warn`][level_link] or
//! [`Info`][level_link] levels to stdout:
//!
//! ```
//! use log::{Record, Level, Metadata};
//!
//! struct SimpleLogger;
//!
//! impl log::Log for SimpleLogger {
//! fn enabled(&self, metadata: &Metadata) -> bool {
//! metadata.level() <= Level::Info
//! }
//!
//! fn log(&self, record: &Record) {
//! if self.enabled(record.metadata()) {
//! println!("{} - {}", record.level(), record.args());
//! }
//! }
//!
//! fn flush(&self) {}
//! }
//!
//! # fn main() {}
//! ```
//!
//! Loggers are installed by calling the [`set_logger`] function. The maximum
//! log level also needs to be adjusted via the [`set_max_level`] function. The
//! logging facade uses this as an optimization to improve performance of log
//! messages at levels that are disabled. It's important to set it, as it
//! defaults to [`Off`][filter_link], so no log messages will ever be captured!
//! In the case of our example logger, we'll want to set the maximum log level
//! to [`Info`][filter_link], since we ignore any [`Debug`][level_link] or
//! [`Trace`][level_link] level log messages. A logging implementation should
//! provide a function that wraps a call to [`set_logger`] and
//! [`set_max_level`], handling initialization of the logger:
//!
//! ```
//! # use log::{Level, Metadata};
//! # struct SimpleLogger;
//! # impl log::Log for SimpleLogger {
//! # fn enabled(&self, _: &Metadata) -> bool { false }
//! # fn log(&self, _: &log::Record) {}
//! # fn flush(&self) {}
//! # }
//! # fn main() {}
//! use log::{SetLoggerError, LevelFilter};
//!
//! static LOGGER: SimpleLogger = SimpleLogger;
//!
//! pub fn init() -> Result<(), SetLoggerError> {
//! log::set_logger(&LOGGER)
//! .map(|()| log::set_max_level(LevelFilter::Info))
//! }
//! ```
//!
//! Implementations that adjust their configurations at runtime should take care
//! to adjust the maximum log level as well.
//!
//! # Use with `std`
//!
//! `set_logger` requires you to provide a `&'static Log`, which can be hard to
//! obtain if your logger depends on some runtime configuration. The
//! `set_boxed_logger` function is available with the `std` Cargo feature. It is
//! identical to `set_logger` except that it takes a `Box<Log>` rather than a
//! `&'static Log`:
//!
//! ```
//! # use log::{Level, LevelFilter, Log, SetLoggerError, Metadata};
//! # struct SimpleLogger;
//! # impl log::Log for SimpleLogger {
//! # fn enabled(&self, _: &Metadata) -> bool { false }
//! # fn log(&self, _: &log::Record) {}
//! # fn flush(&self) {}
//! # }
//! # fn main() {}
//! # #[cfg(feature = "std")]
//! pub fn init() -> Result<(), SetLoggerError> {
//! log::set_boxed_logger(Box::new(SimpleLogger))
//! .map(|()| log::set_max_level(LevelFilter::Info))
//! }
//! ```
//!
//! # Compile time filters
//!
//! Log levels can be statically disabled at compile time by enabling one of these Cargo features:
//!
//! * `max_level_off`
//! * `max_level_error`
//! * `max_level_warn`
//! * `max_level_info`
//! * `max_level_debug`
//! * `max_level_trace`
//!
//! Log invocations at disabled levels will be skipped and will not even be present in the
//! resulting binary. These features control the value of the `STATIC_MAX_LEVEL` constant. The
//! logging macros check this value before logging a message. By default, no levels are disabled.
//!
//! It is possible to override this level for release builds only with the following features:
//!
//! * `release_max_level_off`
//! * `release_max_level_error`
//! * `release_max_level_warn`
//! * `release_max_level_info`
//! * `release_max_level_debug`
//! * `release_max_level_trace`
//!
//! Libraries should avoid using the max level features because they're global and can't be changed
//! once they're set.
//!
//! For example, a crate can disable trace level logs in debug builds and trace, debug, and info
//! level logs in release builds with the following configuration:
//!
//! ```toml
//! [dependencies]
//! log = { version = "0.4", features = ["max_level_debug", "release_max_level_warn"] }
//! ```
//! # Crate Feature Flags
//!
//! The following crate feature flags are available in addition to the filters. They are
//! configured in your `Cargo.toml`.
//!
//! * `std` allows use of `std` crate instead of the default `core`. Enables using `std::error` and
//! `set_boxed_logger` functionality.
//! * `serde` enables support for serialization and deserialization of `Level` and `LevelFilter`.
//!
//! ```toml
//! [dependencies]
//! log = { version = "0.4", features = ["std", "serde"] }
//! ```
//!
//! # Version compatibility
//!
//! The 0.3 and 0.4 versions of the `log` crate are almost entirely compatible. Log messages
//! made using `log` 0.3 will forward transparently to a logger implementation using `log` 0.4. Log
//! messages made using `log` 0.4 will forward to a logger implementation using `log` 0.3, but the
//! module path and file name information associated with the message will unfortunately be lost.
//!
//! [`Log`]: trait.Log.html
//! [level_link]: enum.Level.html
//! [filter_link]: enum.LevelFilter.html
//! [`set_logger`]: fn.set_logger.html
//! [`set_max_level`]: fn.set_max_level.html
//! [`try_set_logger_raw`]: fn.try_set_logger_raw.html
//! [`shutdown_logger_raw`]: fn.shutdown_logger_raw.html
#![doc(
html_root_url = "https://docs.rs/log/0.4.22"
)]
#![warn(missing_docs)]
#![deny(missing_debug_implementations, unconditional_recursion)]
#![cfg_attr(all(not(feature = "std"), not(test)), no_std)]
#[cfg(any(
all(feature = "max_level_off", feature = "max_level_error"),
all(feature = "max_level_off", feature = "max_level_warn"),
all(feature = "max_level_off", feature = "max_level_info"),
all(feature = "max_level_off", feature = "max_level_debug"),
all(feature = "max_level_off", feature = "max_level_trace"),
all(feature = "max_level_error", feature = "max_level_warn"),
all(feature = "max_level_error", feature = "max_level_info"),
all(feature = "max_level_error", feature = "max_level_debug"),
all(feature = "max_level_error", feature = "max_level_trace"),
all(feature = "max_level_warn", feature = "max_level_info"),
all(feature = "max_level_warn", feature = "max_level_debug"),
all(feature = "max_level_warn", feature = "max_level_trace"),
all(feature = "max_level_info", feature = "max_level_debug"),
all(feature = "max_level_info", feature = "max_level_trace"),
all(feature = "max_level_debug", feature = "max_level_trace"),
))]
compile_error!("multiple max_level_* features set");
#[rustfmt::skip]
#[cfg(any(
all(feature = "release_max_level_off", feature = "release_max_level_error"),
all(feature = "release_max_level_off", feature = "release_max_level_warn"),
all(feature = "release_max_level_off", feature = "release_max_level_info"),
all(feature = "release_max_level_off", feature = "release_max_level_debug"),
all(feature = "release_max_level_off", feature = "release_max_level_trace"),
all(feature = "release_max_level_error", feature = "release_max_level_warn"),
all(feature = "release_max_level_error", feature = "release_max_level_info"),
all(feature = "release_max_level_error", feature = "release_max_level_debug"),
all(feature = "release_max_level_error", feature = "release_max_level_trace"),
all(feature = "release_max_level_warn", feature = "release_max_level_info"),
all(feature = "release_max_level_warn", feature = "release_max_level_debug"),
all(feature = "release_max_level_warn", feature = "release_max_level_trace"),
all(feature = "release_max_level_info", feature = "release_max_level_debug"),
all(feature = "release_max_level_info", feature = "release_max_level_trace"),
all(feature = "release_max_level_debug", feature = "release_max_level_trace"),
))]
compile_error!("multiple release_max_level_* features set");
#[cfg(all(not(feature = "std"), not(test)))]
extern crate core as std;
use std::cfg;
#[cfg(feature = "std")]
use std::error;
use std::str::FromStr;
use std::{cmp, fmt, mem};
#[macro_use]
mod macros;
mod serde;
#[cfg(feature = "kv")]
pub mod kv;
#[cfg(target_has_atomic = "ptr")]
use std::sync::atomic::{AtomicUsize, Ordering};
#[cfg(not(target_has_atomic = "ptr"))]
use std::cell::Cell;
#[cfg(not(target_has_atomic = "ptr"))]
use std::sync::atomic::Ordering;
#[cfg(not(target_has_atomic = "ptr"))]
struct AtomicUsize {
v: Cell<usize>,
}
#[cfg(not(target_has_atomic = "ptr"))]
impl AtomicUsize {
const fn new(v: usize) -> AtomicUsize {
AtomicUsize { v: Cell::new(v) }
}
fn load(&self, _order: Ordering) -> usize {
self.v.get()
}
fn store(&self, val: usize, _order: Ordering) {
self.v.set(val)
}
#[cfg(target_has_atomic = "ptr")]
fn compare_exchange(
&self,
current: usize,
new: usize,
_success: Ordering,
_failure: Ordering,
) -> Result<usize, usize> {
let prev = self.v.get();
if current == prev {
self.v.set(new);
}
Ok(prev)
}
}
// Any platform without atomics is unlikely to have multiple cores, so
// writing via Cell will not be a race condition.
#[cfg(not(target_has_atomic = "ptr"))]
unsafe impl Sync for AtomicUsize {}
// The LOGGER static holds a pointer to the global logger. It is protected by
// the STATE static which determines whether LOGGER has been initialized yet.
static mut LOGGER: &dyn Log = &NopLogger;
static STATE: AtomicUsize = AtomicUsize::new(0);
// There are three different states that we care about: the logger's
// uninitialized, the logger's initializing (set_logger's been called but
// LOGGER hasn't actually been set yet), or the logger's active.
const UNINITIALIZED: usize = 0;
const INITIALIZING: usize = 1;
const INITIALIZED: usize = 2;
static MAX_LOG_LEVEL_FILTER: AtomicUsize = AtomicUsize::new(0);
static LOG_LEVEL_NAMES: [&str; 6] = ["OFF", "ERROR", "WARN", "INFO", "DEBUG", "TRACE"];
static SET_LOGGER_ERROR: &str = "attempted to set a logger after the logging system \
was already initialized";
static LEVEL_PARSE_ERROR: &str =
"attempted to convert a string that doesn't match an existing log level";
/// An enum representing the available verbosity levels of the logger.
///
/// Typical usage includes: checking if a certain `Level` is enabled with
/// [`log_enabled!`](macro.log_enabled.html), specifying the `Level` of
/// [`log!`](macro.log.html), and comparing a `Level` directly to a
/// [`LevelFilter`](enum.LevelFilter.html).
#[repr(usize)]
#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Debug, Hash)]
pub enum Level {
/// The "error" level.
///
/// Designates very serious errors.
// This way these line up with the discriminants for LevelFilter below
// This works because Rust treats field-less enums the same way as C does:
Error = 1,
/// The "warn" level.
///
/// Designates hazardous situations.
Warn,
/// The "info" level.
///
/// Designates useful information.
Info,
/// The "debug" level.
///
/// Designates lower priority information.
Debug,
/// The "trace" level.
///
/// Designates very low priority, often extremely verbose, information.
Trace,
}
impl PartialEq<LevelFilter> for Level {
#[inline]
fn eq(&self, other: &LevelFilter) -> bool {
*self as usize == *other as usize
}
}
impl PartialOrd<LevelFilter> for Level {
#[inline]
fn partial_cmp(&self, other: &LevelFilter) -> Option<cmp::Ordering> {
Some((*self as usize).cmp(&(*other as usize)))
}
}
impl FromStr for Level {
type Err = ParseLevelError;
fn from_str(level: &str) -> Result<Level, Self::Err> {
LOG_LEVEL_NAMES
.iter()
.position(|&name| name.eq_ignore_ascii_case(level))
.into_iter()
.filter(|&idx| idx != 0)
.map(|idx| Level::from_usize(idx).unwrap())
.next()
.ok_or(ParseLevelError(()))
}
}
impl fmt::Display for Level {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.pad(self.as_str())
}
}
impl Level {
fn from_usize(u: usize) -> Option<Level> {
match u {
1 => Some(Level::Error),
2 => Some(Level::Warn),
3 => Some(Level::Info),
4 => Some(Level::Debug),
5 => Some(Level::Trace),
_ => None,
}
}
/// Returns the most verbose logging level.
#[inline]
pub fn max() -> Level {
Level::Trace
}
/// Converts the `Level` to the equivalent `LevelFilter`.
#[inline]
pub fn to_level_filter(&self) -> LevelFilter {
LevelFilter::from_usize(*self as usize).unwrap()
}
/// Returns the string representation of the `Level`.
///
/// This returns the same string as the `fmt::Display` implementation.
pub fn as_str(&self) -> &'static str {
LOG_LEVEL_NAMES[*self as usize]
}
/// Iterate through all supported logging levels.
///
/// The order of iteration is from more severe to less severe log messages.
///
/// # Examples
///
/// ```
/// use log::Level;
///
/// let mut levels = Level::iter();
///
/// assert_eq!(Some(Level::Error), levels.next());
/// assert_eq!(Some(Level::Trace), levels.last());
/// ```
pub fn iter() -> impl Iterator<Item = Self> {
(1..6).map(|i| Self::from_usize(i).unwrap())
}
}
/// An enum representing the available verbosity level filters of the logger.
///
/// A `LevelFilter` may be compared directly to a [`Level`]. Use this type
/// to get and set the maximum log level with [`max_level()`] and [`set_max_level`].
///
/// [`Level`]: enum.Level.html
/// [`max_level()`]: fn.max_level.html
/// [`set_max_level`]: fn.set_max_level.html
#[repr(usize)]
#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Debug, Hash)]
pub enum LevelFilter {
/// A level lower than all log levels.
Off,
/// Corresponds to the `Error` log level.
Error,
/// Corresponds to the `Warn` log level.
Warn,
/// Corresponds to the `Info` log level.
Info,
/// Corresponds to the `Debug` log level.
Debug,
/// Corresponds to the `Trace` log level.
Trace,
}
impl PartialEq<Level> for LevelFilter {
#[inline]
fn eq(&self, other: &Level) -> bool {
other.eq(self)
}
}
impl PartialOrd<Level> for LevelFilter {
#[inline]
fn partial_cmp(&self, other: &Level) -> Option<cmp::Ordering> {
Some((*self as usize).cmp(&(*other as usize)))
}
}
impl FromStr for LevelFilter {
type Err = ParseLevelError;
fn from_str(level: &str) -> Result<LevelFilter, Self::Err> {
LOG_LEVEL_NAMES
.iter()
.position(|&name| name.eq_ignore_ascii_case(level))
.map(|p| LevelFilter::from_usize(p).unwrap())
.ok_or(ParseLevelError(()))
}
}
impl fmt::Display for LevelFilter {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.pad(self.as_str())
}
}
impl LevelFilter {
fn from_usize(u: usize) -> Option<LevelFilter> {
match u {
0 => Some(LevelFilter::Off),
1 => Some(LevelFilter::Error),
2 => Some(LevelFilter::Warn),
3 => Some(LevelFilter::Info),
4 => Some(LevelFilter::Debug),
5 => Some(LevelFilter::Trace),
_ => None,
}
}
/// Returns the most verbose logging level filter.
#[inline]
pub fn max() -> LevelFilter {
LevelFilter::Trace
}
/// Converts `self` to the equivalent `Level`.
///
/// Returns `None` if `self` is `LevelFilter::Off`.
#[inline]
pub fn to_level(&self) -> Option<Level> {
Level::from_usize(*self as usize)
}
/// Returns the string representation of the `LevelFilter`.
///
/// This returns the same string as the `fmt::Display` implementation.
pub fn as_str(&self) -> &'static str {
LOG_LEVEL_NAMES[*self as usize]
}
/// Iterate through all supported filtering levels.
///
/// The order of iteration is from less to more verbose filtering.
///
/// # Examples
///
/// ```
/// use log::LevelFilter;
///
/// let mut levels = LevelFilter::iter();
///
/// assert_eq!(Some(LevelFilter::Off), levels.next());
/// assert_eq!(Some(LevelFilter::Trace), levels.last());
/// ```
pub fn iter() -> impl Iterator<Item = Self> {
(0..6).map(|i| Self::from_usize(i).unwrap())
}
}
#[derive(Copy, Clone, Eq, PartialEq, Ord, PartialOrd, Hash, Debug)]
enum MaybeStaticStr<'a> {
Static(&'static str),
Borrowed(&'a str),
}
impl<'a> MaybeStaticStr<'a> {
#[inline]
fn get(&self) -> &'a str {
match *self {
MaybeStaticStr::Static(s) => s,
MaybeStaticStr::Borrowed(s) => s,
}
}
}
/// The "payload" of a log message.
///
/// # Use
///
/// `Record` structures are passed as parameters to the [`log`][method.log]
/// method of the [`Log`] trait. Logger implementors manipulate these
/// structures in order to display log messages. `Record`s are automatically
/// created by the [`log!`] macro and so are not seen by log users.
///
/// Note that the [`level()`] and [`target()`] accessors are equivalent to
/// `self.metadata().level()` and `self.metadata().target()` respectively.
/// These methods are provided as a convenience for users of this structure.
///
/// # Example
///
/// The following example shows a simple logger that displays the level,
/// module path, and message of any `Record` that is passed to it.
///
/// ```
/// struct SimpleLogger;
///
/// impl log::Log for SimpleLogger {
/// fn enabled(&self, _metadata: &log::Metadata) -> bool {
/// true
/// }
///
/// fn log(&self, record: &log::Record) {
/// if !self.enabled(record.metadata()) {
/// return;
/// }
///
/// println!("{}:{} -- {}",
/// record.level(),
/// record.target(),
/// record.args());
/// }
/// fn flush(&self) {}
/// }
/// ```
///
/// [method.log]: trait.Log.html#tymethod.log
/// [`Log`]: trait.Log.html
/// [`log!`]: macro.log.html
/// [`level()`]: struct.Record.html#method.level
/// [`target()`]: struct.Record.html#method.target
#[derive(Clone, Debug)]
pub struct Record<'a> {
metadata: Metadata<'a>,
args: fmt::Arguments<'a>,
module_path: Option<MaybeStaticStr<'a>>,
file: Option<MaybeStaticStr<'a>>,
line: Option<u32>,
#[cfg(feature = "kv")]
key_values: KeyValues<'a>,
}
// This wrapper type is only needed so we can
// `#[derive(Debug)]` on `Record`. It also
// provides a useful `Debug` implementation for
// the underlying `Source`.
#[cfg(feature = "kv")]
#[derive(Clone)]
struct KeyValues<'a>(&'a dyn kv::Source);
#[cfg(feature = "kv")]
impl<'a> fmt::Debug for KeyValues<'a> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let mut visitor = f.debug_map();
self.0.visit(&mut visitor).map_err(|_| fmt::Error)?;
visitor.finish()
}
}
impl<'a> Record<'a> {
/// Returns a new builder.
#[inline]
pub fn builder() -> RecordBuilder<'a> {
RecordBuilder::new()
}
/// The message body.
#[inline]
pub fn args(&self) -> &fmt::Arguments<'a> {
&self.args
}
/// Metadata about the log directive.
#[inline]
pub fn metadata(&self) -> &Metadata<'a> {
&self.metadata
}
/// The verbosity level of the message.
#[inline]
pub fn level(&self) -> Level {
self.metadata.level()
}
/// The name of the target of the directive.
#[inline]
pub fn target(&self) -> &'a str {
self.metadata.target()
}
/// The module path of the message.
#[inline]
pub fn module_path(&self) -> Option<&'a str> {
self.module_path.map(|s| s.get())
}
/// The module path of the message, if it is a `'static` string.
#[inline]
pub fn module_path_static(&self) -> Option<&'static str> {
match self.module_path {
Some(MaybeStaticStr::Static(s)) => Some(s),
_ => None,
}
}
/// The source file containing the message.
#[inline]
pub fn file(&self) -> Option<&'a str> {
self.file.map(|s| s.get())
}
/// The source file containing the message, if it is a `'static` string.
#[inline]
pub fn file_static(&self) -> Option<&'static str> {
match self.file {
Some(MaybeStaticStr::Static(s)) => Some(s),
_ => None,
}
}
/// The line containing the message.
#[inline]
pub fn line(&self) -> Option<u32> {
self.line
}
/// The structured key-value pairs associated with the message.
#[cfg(feature = "kv")]
#[inline]
pub fn key_values(&self) -> &dyn kv::Source {
self.key_values.0
}
/// Create a new [`RecordBuilder`](struct.RecordBuilder.html) based on this record.
#[cfg(feature = "kv")]
#[inline]
pub fn to_builder(&self) -> RecordBuilder {
RecordBuilder {
record: Record {
metadata: Metadata {
level: self.metadata.level,
target: self.metadata.target,
},
args: self.args,
module_path: self.module_path,
file: self.file,
line: self.line,
key_values: self.key_values.clone(),
},
}
}
}
/// Builder for [`Record`](struct.Record.html).
///
/// Typically should only be used by log library creators or for testing and "shim loggers".
/// The `RecordBuilder` can set the different parameters of `Record` object, and returns
/// the created object when `build` is called.
///
/// # Examples
///
/// ```
/// use log::{Level, Record};
///
/// let record = Record::builder()
/// .args(format_args!("Error!"))
/// .level(Level::Error)
/// .target("myApp")
/// .file(Some("server.rs"))
/// .line(Some(144))
/// .module_path(Some("server"))
/// .build();
/// ```
///
/// Alternatively, use [`MetadataBuilder`](struct.MetadataBuilder.html):
///
/// ```
/// use log::{Record, Level, MetadataBuilder};
///
/// let error_metadata = MetadataBuilder::new()
/// .target("myApp")
/// .level(Level::Error)
/// .build();
///
/// let record = Record::builder()
/// .metadata(error_metadata)
/// .args(format_args!("Error!"))
/// .line(Some(433))
/// .file(Some("app.rs"))
/// .module_path(Some("server"))
/// .build();
/// ```
#[derive(Debug)]
pub struct RecordBuilder<'a> {
record: Record<'a>,
}
impl<'a> RecordBuilder<'a> {
/// Construct new `RecordBuilder`.
///
/// The default options are:
///
/// - `args`: [`format_args!("")`]
/// - `metadata`: [`Metadata::builder().build()`]
/// - `module_path`: `None`
/// - `file`: `None`
/// - `line`: `None`
///
/// [`Metadata::builder().build()`]: struct.MetadataBuilder.html#method.build
#[inline]
pub fn new() -> RecordBuilder<'a> {
RecordBuilder {
record: Record {
args: format_args!(""),
metadata: Metadata::builder().build(),
module_path: None,
file: None,
line: None,
#[cfg(feature = "kv")]
key_values: KeyValues(&None::<(kv::Key, kv::Value)>),
},
}
}
/// Set [`args`](struct.Record.html#method.args).
#[inline]
pub fn args(&mut self, args: fmt::Arguments<'a>) -> &mut RecordBuilder<'a> {
self.record.args = args;
self
}
/// Set [`metadata`](struct.Record.html#method.metadata). Construct a `Metadata` object with [`MetadataBuilder`](struct.MetadataBuilder.html).
#[inline]
pub fn metadata(&mut self, metadata: Metadata<'a>) -> &mut RecordBuilder<'a> {
self.record.metadata = metadata;
self
}
/// Set [`Metadata::level`](struct.Metadata.html#method.level).
#[inline]
pub fn level(&mut self, level: Level) -> &mut RecordBuilder<'a> {
self.record.metadata.level = level;
self
}
/// Set [`Metadata::target`](struct.Metadata.html#method.target)
#[inline]
pub fn target(&mut self, target: &'a str) -> &mut RecordBuilder<'a> {
self.record.metadata.target = target;
self
}
/// Set [`module_path`](struct.Record.html#method.module_path)
#[inline]
pub fn module_path(&mut self, path: Option<&'a str>) -> &mut RecordBuilder<'a> {
self.record.module_path = path.map(MaybeStaticStr::Borrowed);
self
}
/// Set [`module_path`](struct.Record.html#method.module_path) to a `'static` string
#[inline]
pub fn module_path_static(&mut self, path: Option<&'static str>) -> &mut RecordBuilder<'a> {
self.record.module_path = path.map(MaybeStaticStr::Static);
self
}
/// Set [`file`](struct.Record.html#method.file)
#[inline]
pub fn file(&mut self, file: Option<&'a str>) -> &mut RecordBuilder<'a> {
self.record.file = file.map(MaybeStaticStr::Borrowed);
self
}
/// Set [`file`](struct.Record.html#method.file) to a `'static` string.
#[inline]
pub fn file_static(&mut self, file: Option<&'static str>) -> &mut RecordBuilder<'a> {
self.record.file = file.map(MaybeStaticStr::Static);
self
}
/// Set [`line`](struct.Record.html#method.line)
#[inline]
pub fn line(&mut self, line: Option<u32>) -> &mut RecordBuilder<'a> {
self.record.line = line;
self
}
/// Set [`key_values`](struct.Record.html#method.key_values)
#[cfg(feature = "kv")]
#[inline]
pub fn key_values(&mut self, kvs: &'a dyn kv::Source) -> &mut RecordBuilder<'a> {
self.record.key_values = KeyValues(kvs);
self
}
/// Invoke the builder and return a `Record`
#[inline]
pub fn build(&self) -> Record<'a> {
self.record.clone()
}
}
impl<'a> Default for RecordBuilder<'a> {
fn default() -> Self {
Self::new()
}
}
/// Metadata about a log message.
///
/// # Use
///
/// `Metadata` structs are created when users of the library use
/// logging macros.
///
/// They are consumed by implementations of the `Log` trait in the
/// `enabled` method.
///
/// `Record`s use `Metadata` to determine the log message's severity
/// and target.
///
/// Users should use the `log_enabled!` macro in their code to avoid
/// constructing expensive log messages.
///
/// # Examples
///
/// ```
/// use log::{Record, Level, Metadata};
///
/// struct MyLogger;
///
/// impl log::Log for MyLogger {
/// fn enabled(&self, metadata: &Metadata) -> bool {
/// metadata.level() <= Level::Info
/// }
///
/// fn log(&self, record: &Record) {
/// if self.enabled(record.metadata()) {
/// println!("{} - {}", record.level(), record.args());
/// }
/// }
/// fn flush(&self) {}
/// }
///
/// # fn main(){}
/// ```
#[derive(Clone, Eq, PartialEq, Ord, PartialOrd, Hash, Debug)]
pub struct Metadata<'a> {
level: Level,
target: &'a str,
}
impl<'a> Metadata<'a> {
/// Returns a new builder.
#[inline]
pub fn builder() -> MetadataBuilder<'a> {
MetadataBuilder::new()
}
/// The verbosity level of the message.
#[inline]
pub fn level(&self) -> Level {
self.level
}
/// The name of the target of the directive.
#[inline]
pub fn target(&self) -> &'a str {
self.target
}
}
/// Builder for [`Metadata`](struct.Metadata.html).
///
/// Typically should only be used by log library creators or for testing and "shim loggers".
/// The `MetadataBuilder` can set the different parameters of a `Metadata` object, and returns
/// the created object when `build` is called.
///
/// # Example
///
/// ```
/// let target = "myApp";
/// use log::{Level, MetadataBuilder};
/// let metadata = MetadataBuilder::new()
/// .level(Level::Debug)
/// .target(target)
/// .build();
/// ```
#[derive(Eq, PartialEq, Ord, PartialOrd, Hash, Debug)]
pub struct MetadataBuilder<'a> {
metadata: Metadata<'a>,
}
impl<'a> MetadataBuilder<'a> {
/// Construct a new `MetadataBuilder`.
///
/// The default options are:
///
/// - `level`: `Level::Info`
/// - `target`: `""`
#[inline]
pub fn new() -> MetadataBuilder<'a> {
MetadataBuilder {
metadata: Metadata {
level: Level::Info,
target: "",
},
}
}
/// Setter for [`level`](struct.Metadata.html#method.level).
#[inline]
pub fn level(&mut self, arg: Level) -> &mut MetadataBuilder<'a> {
self.metadata.level = arg;
self
}
/// Setter for [`target`](struct.Metadata.html#method.target).
#[inline]
pub fn target(&mut self, target: &'a str) -> &mut MetadataBuilder<'a> {
self.metadata.target = target;
self
}
/// Returns a `Metadata` object.
#[inline]
pub fn build(&self) -> Metadata<'a> {
self.metadata.clone()
}
}
impl<'a> Default for MetadataBuilder<'a> {
fn default() -> Self {
Self::new()
}
}
/// A trait encapsulating the operations required of a logger.
pub trait Log: Sync + Send {
/// Determines if a log message with the specified metadata would be
/// logged.
///
/// This is used by the `log_enabled!` macro to allow callers to avoid
/// expensive computation of log message arguments if the message would be
/// discarded anyway.
///
/// # For implementors
///
/// This method isn't called automatically by the `log!` macros.
/// It's up to an implementation of the `Log` trait to call `enabled` in its own
/// `log` method implementation to guarantee that filtering is applied.
fn enabled(&self, metadata: &Metadata) -> bool;
/// Logs the `Record`.
///
/// # For implementors
///
/// Note that `enabled` is *not* necessarily called before this method.
/// Implementations of `log` should perform all necessary filtering
/// internally.
fn log(&self, record: &Record);
/// Flushes any buffered records.
///
/// # For implementors
///
/// This method isn't called automatically by the `log!` macros.
/// It can be called manually on shut-down to ensure any in-flight records are flushed.
fn flush(&self);
}
// Just used as a dummy initial value for LOGGER
struct NopLogger;
impl Log for NopLogger {
fn enabled(&self, _: &Metadata) -> bool {
false
}
fn log(&self, _: &Record) {}
fn flush(&self) {}
}
impl<T> Log for &'_ T
where
T: ?Sized + Log,
{
fn enabled(&self, metadata: &Metadata) -> bool {
(**self).enabled(metadata)
}
fn log(&self, record: &Record) {
(**self).log(record);
}
fn flush(&self) {
(**self).flush();
}
}
#[cfg(feature = "std")]
impl<T> Log for std::boxed::Box<T>
where
T: ?Sized + Log,
{
fn enabled(&self, metadata: &Metadata) -> bool {
self.as_ref().enabled(metadata)
}
fn log(&self, record: &Record) {
self.as_ref().log(record);
}
fn flush(&self) {
self.as_ref().flush();
}
}
#[cfg(feature = "std")]
impl<T> Log for std::sync::Arc<T>
where
T: ?Sized + Log,
{
fn enabled(&self, metadata: &Metadata) -> bool {
self.as_ref().enabled(metadata)
}
fn log(&self, record: &Record) {
self.as_ref().log(record);
}
fn flush(&self) {
self.as_ref().flush();
}
}
/// Sets the global maximum log level.
///
/// Generally, this should only be called by the active logging implementation.
///
/// Note that `Trace` is the maximum level, because it provides the maximum amount of detail in the emitted logs.
#[inline]
#[cfg(target_has_atomic = "ptr")]
pub fn set_max_level(level: LevelFilter) {
MAX_LOG_LEVEL_FILTER.store(level as usize, Ordering::Relaxed);
}
/// A thread-unsafe version of [`set_max_level`].
///
/// This function is available on all platforms, even those that do not have
/// support for atomics that is needed by [`set_max_level`].
///
/// In almost all cases, [`set_max_level`] should be preferred.
///
/// # Safety
///
/// This function is only safe to call when it cannot race with any other
/// calls to `set_max_level` or `set_max_level_racy`.
///
/// This can be upheld by (for example) making sure that **there are no other
/// threads**, and (on embedded) that **interrupts are disabled**.
///
/// It is safe to use all other logging functions while this function runs
/// (including all logging macros).
///
/// [`set_max_level`]: fn.set_max_level.html
#[inline]
pub unsafe fn set_max_level_racy(level: LevelFilter) {
// `MAX_LOG_LEVEL_FILTER` uses a `Cell` as the underlying primitive when a
// platform doesn't support `target_has_atomic = "ptr"`, so even though this looks the same
// as `set_max_level` it may have different safety properties.
MAX_LOG_LEVEL_FILTER.store(level as usize, Ordering::Relaxed);
}
/// Returns the current maximum log level.
///
/// The [`log!`], [`error!`], [`warn!`], [`info!`], [`debug!`], and [`trace!`] macros check
/// this value and discard any message logged at a higher level. The maximum
/// log level is set by the [`set_max_level`] function.
///
/// [`log!`]: macro.log.html
/// [`error!`]: macro.error.html
/// [`warn!`]: macro.warn.html
/// [`info!`]: macro.info.html
/// [`debug!`]: macro.debug.html
/// [`trace!`]: macro.trace.html
/// [`set_max_level`]: fn.set_max_level.html
#[inline(always)]
pub fn max_level() -> LevelFilter {
// Since `LevelFilter` is `repr(usize)`,
// this transmute is sound if and only if `MAX_LOG_LEVEL_FILTER`
// is set to a usize that is a valid discriminant for `LevelFilter`.
// Since `MAX_LOG_LEVEL_FILTER` is private, the only time it's set
// is by `set_max_level` above, i.e. by casting a `LevelFilter` to `usize`.
// So any usize stored in `MAX_LOG_LEVEL_FILTER` is a valid discriminant.
unsafe { mem::transmute(MAX_LOG_LEVEL_FILTER.load(Ordering::Relaxed)) }
}
/// Sets the global logger to a `Box<Log>`.
///
/// This is a simple convenience wrapper over `set_logger`, which takes a
/// `Box<Log>` rather than a `&'static Log`. See the documentation for
/// [`set_logger`] for more details.
///
/// Requires the `std` feature.
///
/// # Errors
///
/// An error is returned if a logger has already been set.
///
/// [`set_logger`]: fn.set_logger.html
#[cfg(all(feature = "std", target_has_atomic = "ptr"))]
pub fn set_boxed_logger(logger: Box<dyn Log>) -> Result<(), SetLoggerError> {
set_logger_inner(|| Box::leak(logger))
}
/// Sets the global logger to a `&'static Log`.
///
/// This function may only be called once in the lifetime of a program. Any log
/// events that occur before the call to `set_logger` completes will be ignored.
///
/// This function does not typically need to be called manually. Logger
/// implementations should provide an initialization method that installs the
/// logger internally.
///
/// # Availability
///
/// This method is available even when the `std` feature is disabled. However,
/// it is currently unavailable on `thumbv6` targets, which lack support for
/// some atomic operations which are used by this function. Even on those
/// targets, [`set_logger_racy`] will be available.
///
/// # Errors
///
/// An error is returned if a logger has already been set.
///
/// # Examples
///
/// ```
/// use log::{error, info, warn, Record, Level, Metadata, LevelFilter};
///
/// static MY_LOGGER: MyLogger = MyLogger;
///
/// struct MyLogger;
///
/// impl log::Log for MyLogger {
/// fn enabled(&self, metadata: &Metadata) -> bool {
/// metadata.level() <= Level::Info
/// }
///
/// fn log(&self, record: &Record) {
/// if self.enabled(record.metadata()) {
/// println!("{} - {}", record.level(), record.args());
/// }
/// }
/// fn flush(&self) {}
/// }
///
/// # fn main(){
/// log::set_logger(&MY_LOGGER).unwrap();
/// log::set_max_level(LevelFilter::Info);
///
/// info!("hello log");
/// warn!("warning");
/// error!("oops");
/// # }
/// ```
///
/// [`set_logger_racy`]: fn.set_logger_racy.html
#[cfg(target_has_atomic = "ptr")]
pub fn set_logger(logger: &'static dyn Log) -> Result<(), SetLoggerError> {
set_logger_inner(|| logger)
}
#[cfg(target_has_atomic = "ptr")]
fn set_logger_inner<F>(make_logger: F) -> Result<(), SetLoggerError>
where
F: FnOnce() -> &'static dyn Log,
{
match STATE.compare_exchange(
UNINITIALIZED,
INITIALIZING,
Ordering::Acquire,
Ordering::Relaxed,
) {
Ok(UNINITIALIZED) => {
unsafe {
LOGGER = make_logger();
}
STATE.store(INITIALIZED, Ordering::Release);
Ok(())
}
Err(INITIALIZING) => {
while STATE.load(Ordering::Relaxed) == INITIALIZING {
std::hint::spin_loop();
}
Err(SetLoggerError(()))
}
_ => Err(SetLoggerError(())),
}
}
/// A thread-unsafe version of [`set_logger`].
///
/// This function is available on all platforms, even those that do not have
/// support for atomics that is needed by [`set_logger`].
///
/// In almost all cases, [`set_logger`] should be preferred.
///
/// # Safety
///
/// This function is only safe to call when it cannot race with any other
/// calls to `set_logger` or `set_logger_racy`.
///
/// This can be upheld by (for example) making sure that **there are no other
/// threads**, and (on embedded) that **interrupts are disabled**.
///
/// It is safe to use other logging functions while this function runs
/// (including all logging macros).
///
/// [`set_logger`]: fn.set_logger.html
pub unsafe fn set_logger_racy(logger: &'static dyn Log) -> Result<(), SetLoggerError> {
match STATE.load(Ordering::Acquire) {
UNINITIALIZED => {
LOGGER = logger;
STATE.store(INITIALIZED, Ordering::Release);
Ok(())
}
INITIALIZING => {
// This is just plain UB, since we were racing another initialization function
unreachable!("set_logger_racy must not be used with other initialization functions")
}
_ => Err(SetLoggerError(())),
}
}
/// The type returned by [`set_logger`] if [`set_logger`] has already been called.
///
/// [`set_logger`]: fn.set_logger.html
#[allow(missing_copy_implementations)]
#[derive(Debug)]
pub struct SetLoggerError(());
impl fmt::Display for SetLoggerError {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.write_str(SET_LOGGER_ERROR)
}
}
// The Error trait is not available in libcore
#[cfg(feature = "std")]
impl error::Error for SetLoggerError {}
/// The type returned by [`from_str`] when the string doesn't match any of the log levels.
///
#[allow(missing_copy_implementations)]
#[derive(Debug, PartialEq, Eq)]
pub struct ParseLevelError(());
impl fmt::Display for ParseLevelError {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.write_str(LEVEL_PARSE_ERROR)
}
}
// The Error trait is not available in libcore
#[cfg(feature = "std")]
impl error::Error for ParseLevelError {}
/// Returns a reference to the logger.
///
/// If a logger has not been set, a no-op implementation is returned.
pub fn logger() -> &'static dyn Log {
// Acquire memory ordering guarantees that current thread would see any
// memory writes that happened before store of the value
// into `STATE` with memory ordering `Release` or stronger.
//
// Since the value `INITIALIZED` is written only after `LOGGER` was
// initialized, observing it after `Acquire` load here makes both
// write to the `LOGGER` static and initialization of the logger
// internal state synchronized with current thread.
if STATE.load(Ordering::Acquire) != INITIALIZED {
static NOP: NopLogger = NopLogger;
&NOP
} else {
unsafe { LOGGER }
}
}
// WARNING: this is not part of the crate's public API and is subject to change at any time
#[doc(hidden)]
pub mod __private_api;
/// The statically resolved maximum log level.
///
/// See the crate level documentation for information on how to configure this.
///
/// This value is checked by the log macros, but not by the `Log`ger returned by
/// the [`logger`] function. Code that manually calls functions on that value
/// should compare the level against this value.
///
/// [`logger`]: fn.logger.html
pub const STATIC_MAX_LEVEL: LevelFilter = match cfg!(debug_assertions) {
false if cfg!(feature = "release_max_level_off") => LevelFilter::Off,
false if cfg!(feature = "release_max_level_error") => LevelFilter::Error,
false if cfg!(feature = "release_max_level_warn") => LevelFilter::Warn,
false if cfg!(feature = "release_max_level_info") => LevelFilter::Info,
false if cfg!(feature = "release_max_level_debug") => LevelFilter::Debug,
false if cfg!(feature = "release_max_level_trace") => LevelFilter::Trace,
_ if cfg!(feature = "max_level_off") => LevelFilter::Off,
_ if cfg!(feature = "max_level_error") => LevelFilter::Error,
_ if cfg!(feature = "max_level_warn") => LevelFilter::Warn,
_ if cfg!(feature = "max_level_info") => LevelFilter::Info,
_ if cfg!(feature = "max_level_debug") => LevelFilter::Debug,
_ => LevelFilter::Trace,
};
#[cfg(test)]
mod tests {
use super::{Level, LevelFilter, ParseLevelError, STATIC_MAX_LEVEL};
#[test]
fn test_levelfilter_from_str() {
let tests = [
("off", Ok(LevelFilter::Off)),
("error", Ok(LevelFilter::Error)),
("warn", Ok(LevelFilter::Warn)),
("info", Ok(LevelFilter::Info)),
("debug", Ok(LevelFilter::Debug)),
("trace", Ok(LevelFilter::Trace)),
("OFF", Ok(LevelFilter::Off)),
("ERROR", Ok(LevelFilter::Error)),
("WARN", Ok(LevelFilter::Warn)),
("INFO", Ok(LevelFilter::Info)),
("DEBUG", Ok(LevelFilter::Debug)),
("TRACE", Ok(LevelFilter::Trace)),
("asdf", Err(ParseLevelError(()))),
];
for &(s, ref expected) in &tests {
assert_eq!(expected, &s.parse());
}
}
#[test]
fn test_level_from_str() {
let tests = [
("OFF", Err(ParseLevelError(()))),
("error", Ok(Level::Error)),
("warn", Ok(Level::Warn)),
("info", Ok(Level::Info)),
("debug", Ok(Level::Debug)),
("trace", Ok(Level::Trace)),
("ERROR", Ok(Level::Error)),
("WARN", Ok(Level::Warn)),
("INFO", Ok(Level::Info)),
("DEBUG", Ok(Level::Debug)),
("TRACE", Ok(Level::Trace)),
("asdf", Err(ParseLevelError(()))),
];
for &(s, ref expected) in &tests {
assert_eq!(expected, &s.parse());
}
}
#[test]
fn test_level_as_str() {
let tests = &[
(Level::Error, "ERROR"),
(Level::Warn, "WARN"),
(Level::Info, "INFO"),
(Level::Debug, "DEBUG"),
(Level::Trace, "TRACE"),
];
for (input, expected) in tests {
assert_eq!(*expected, input.as_str());
}
}
#[test]
fn test_level_show() {
assert_eq!("INFO", Level::Info.to_string());
assert_eq!("ERROR", Level::Error.to_string());
}
#[test]
fn test_levelfilter_show() {
assert_eq!("OFF", LevelFilter::Off.to_string());
assert_eq!("ERROR", LevelFilter::Error.to_string());
}
#[test]
fn test_cross_cmp() {
assert!(Level::Debug > LevelFilter::Error);
assert!(LevelFilter::Warn < Level::Trace);
assert!(LevelFilter::Off < Level::Error);
}
#[test]
fn test_cross_eq() {
assert!(Level::Error == LevelFilter::Error);
assert!(LevelFilter::Off != Level::Error);
assert!(Level::Trace == LevelFilter::Trace);
}
#[test]
fn test_to_level() {
assert_eq!(Some(Level::Error), LevelFilter::Error.to_level());
assert_eq!(None, LevelFilter::Off.to_level());
assert_eq!(Some(Level::Debug), LevelFilter::Debug.to_level());
}
#[test]
fn test_to_level_filter() {
assert_eq!(LevelFilter::Error, Level::Error.to_level_filter());
assert_eq!(LevelFilter::Trace, Level::Trace.to_level_filter());
}
#[test]
fn test_level_filter_as_str() {
let tests = &[
(LevelFilter::Off, "OFF"),
(LevelFilter::Error, "ERROR"),
(LevelFilter::Warn, "WARN"),
(LevelFilter::Info, "INFO"),
(LevelFilter::Debug, "DEBUG"),
(LevelFilter::Trace, "TRACE"),
];
for (input, expected) in tests {
assert_eq!(*expected, input.as_str());
}
}
#[test]
#[cfg_attr(not(debug_assertions), ignore)]
fn test_static_max_level_debug() {
if cfg!(feature = "max_level_off") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Off);
} else if cfg!(feature = "max_level_error") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Error);
} else if cfg!(feature = "max_level_warn") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Warn);
} else if cfg!(feature = "max_level_info") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Info);
} else if cfg!(feature = "max_level_debug") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Debug);
} else {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Trace);
}
}
#[test]
#[cfg_attr(debug_assertions, ignore)]
fn test_static_max_level_release() {
if cfg!(feature = "release_max_level_off") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Off);
} else if cfg!(feature = "release_max_level_error") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Error);
} else if cfg!(feature = "release_max_level_warn") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Warn);
} else if cfg!(feature = "release_max_level_info") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Info);
} else if cfg!(feature = "release_max_level_debug") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Debug);
} else if cfg!(feature = "release_max_level_trace") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Trace);
} else if cfg!(feature = "max_level_off") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Off);
} else if cfg!(feature = "max_level_error") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Error);
} else if cfg!(feature = "max_level_warn") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Warn);
} else if cfg!(feature = "max_level_info") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Info);
} else if cfg!(feature = "max_level_debug") {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Debug);
} else {
assert_eq!(STATIC_MAX_LEVEL, LevelFilter::Trace);
}
}
#[test]
#[cfg(feature = "std")]
fn test_error_trait() {
use super::SetLoggerError;
let e = SetLoggerError(());
assert_eq!(
&e.to_string(),
"attempted to set a logger after the logging system \
was already initialized"
);
}
#[test]
fn test_metadata_builder() {
use super::MetadataBuilder;
let target = "myApp";
let metadata_test = MetadataBuilder::new()
.level(Level::Debug)
.target(target)
.build();
assert_eq!(metadata_test.level(), Level::Debug);
assert_eq!(metadata_test.target(), "myApp");
}
#[test]
fn test_metadata_convenience_builder() {
use super::Metadata;
let target = "myApp";
let metadata_test = Metadata::builder()
.level(Level::Debug)
.target(target)
.build();
assert_eq!(metadata_test.level(), Level::Debug);
assert_eq!(metadata_test.target(), "myApp");
}
#[test]
fn test_record_builder() {
use super::{MetadataBuilder, RecordBuilder};
let target = "myApp";
let metadata = MetadataBuilder::new().target(target).build();
let fmt_args = format_args!("hello");
let record_test = RecordBuilder::new()
.args(fmt_args)
.metadata(metadata)
.module_path(Some("foo"))
.file(Some("bar"))
.line(Some(30))
.build();
assert_eq!(record_test.metadata().target(), "myApp");
assert_eq!(record_test.module_path(), Some("foo"));
assert_eq!(record_test.file(), Some("bar"));
assert_eq!(record_test.line(), Some(30));
}
#[test]
fn test_record_convenience_builder() {
use super::{Metadata, Record};
let target = "myApp";
let metadata = Metadata::builder().target(target).build();
let fmt_args = format_args!("hello");
let record_test = Record::builder()
.args(fmt_args)
.metadata(metadata)
.module_path(Some("foo"))
.file(Some("bar"))
.line(Some(30))
.build();
assert_eq!(record_test.target(), "myApp");
assert_eq!(record_test.module_path(), Some("foo"));
assert_eq!(record_test.file(), Some("bar"));
assert_eq!(record_test.line(), Some(30));
}
#[test]
fn test_record_complete_builder() {
use super::{Level, Record};
let target = "myApp";
let record_test = Record::builder()
.module_path(Some("foo"))
.file(Some("bar"))
.line(Some(30))
.target(target)
.level(Level::Error)
.build();
assert_eq!(record_test.target(), "myApp");
assert_eq!(record_test.level(), Level::Error);
assert_eq!(record_test.module_path(), Some("foo"));
assert_eq!(record_test.file(), Some("bar"));
assert_eq!(record_test.line(), Some(30));
}
#[test]
#[cfg(feature = "kv")]
fn test_record_key_values_builder() {
use super::Record;
use crate::kv::{self, VisitSource};
struct TestVisitSource {
seen_pairs: usize,
}
impl<'kvs> VisitSource<'kvs> for TestVisitSource {
fn visit_pair(
&mut self,
_: kv::Key<'kvs>,
_: kv::Value<'kvs>,
) -> Result<(), kv::Error> {
self.seen_pairs += 1;
Ok(())
}
}
let kvs: &[(&str, i32)] = &[("a", 1), ("b", 2)];
let record_test = Record::builder().key_values(&kvs).build();
let mut visitor = TestVisitSource { seen_pairs: 0 };
record_test.key_values().visit(&mut visitor).unwrap();
assert_eq!(2, visitor.seen_pairs);
}
#[test]
#[cfg(feature = "kv")]
fn test_record_key_values_get_coerce() {
use super::Record;
let kvs: &[(&str, &str)] = &[("a", "1"), ("b", "2")];
let record = Record::builder().key_values(&kvs).build();
assert_eq!(
"2",
record
.key_values()
.get("b".into())
.expect("missing key")
.to_borrowed_str()
.expect("invalid value")
);
}
// Test that the `impl Log for Foo` blocks work
// This test mostly operates on a type level, so failures will be compile errors
#[test]
fn test_foreign_impl() {
use super::Log;
#[cfg(feature = "std")]
use std::sync::Arc;
fn assert_is_log<T: Log + ?Sized>() {}
assert_is_log::<&dyn Log>();
#[cfg(feature = "std")]
assert_is_log::<Box<dyn Log>>();
#[cfg(feature = "std")]
assert_is_log::<Arc<dyn Log>>();
// Assert these statements for all T: Log + ?Sized
#[allow(unused)]
fn forall<T: Log + ?Sized>() {
#[cfg(feature = "std")]
assert_is_log::<Box<T>>();
assert_is_log::<&T>();
#[cfg(feature = "std")]
assert_is_log::<Arc<T>>();
}
}
}