// Copyright 2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. /*! Utilities for program-wide and customizable logging ## Example ``` #![feature(phase)] #[phase(syntax, link)] extern crate log; fn main() { debug!("this is a debug {}", "message"); error!("this is printed by default"); if log_enabled!(log::INFO) { let x = 3 * 4; // expensive computation info!("the answer was: {}", x); } } ``` ## Logging Macros There are five macros that the logging subsystem uses: * `log!(level, ...)` - the generic logging macro, takes a level as a u32 and any related `format!` arguments * `debug!(...)` - a macro hard-wired to the log level of `DEBUG` * `info!(...)` - a macro hard-wired to the log level of `INFO` * `warn!(...)` - a macro hard-wired to the log level of `WARN` * `error!(...)` - a macro hard-wired to the log level of `ERROR` All of these macros use the same style of syntax as the `format!` syntax extension. Details about the syntax can be found in the documentation of `std::fmt` along with the Rust tutorial/manual. If you want to check at runtime if a given logging level is enabled (e.g. if the information you would want to log is expensive to produce), you can use the following macro: * `log_enabled!(level)` - returns true if logging of the given level is enabled ## Enabling logging Log levels are controlled on a per-module basis, and by default all logging is disabled except for `error!` (a log level of 1). Logging is controlled via the `RUST_LOG` environment variable. The value of this environment variable is a comma-separated list of logging directives. A logging directive is of the form: ```notrust path::to::module=log_level ``` The path to the module is rooted in the name of the crate it was compiled for, so if your program is contained in a file `hello.rs`, for example, to turn on logging for this file you would use a value of `RUST_LOG=hello`. Furthermore, this path is a prefix-search, so all modules nested in the specified module will also have logging enabled. The actual `log_level` is optional to specify. If omitted, all logging will be enabled. If specified, the it must be either a numeric in the range of 1-255, or it must be one of the strings `debug`, `error`, `info`, or `warn`. If a numeric is specified, then all logging less than or equal to that numeral is enabled. For example, if logging level 3 is active, error, warn, and info logs will be printed, but debug will be omitted. As the log level for a module is optional, the module to enable logging for is also optional. If only a `log_level` is provided, then the global log level for all modules is set to this value. Some examples of valid values of `RUST_LOG` are: ```notrust hello // turns on all logging for the 'hello' module info // turns on all info logging hello=debug // turns on debug logging for 'hello' hello=3 // turns on info logging for 'hello' hello,std::option // turns on hello, and std's option logging error,hello=warn // turn on global error logging and also warn for hello ``` ## Performance and Side Effects Each of these macros will expand to code similar to: ```rust,ignore if log_level <= my_module_log_level() { ::log::log(log_level, format!(...)); } ``` What this means is that each of these macros are very cheap at runtime if they're turned off (just a load and an integer comparison). This also means that if logging is disabled, none of the components of the log will be executed. */ #![crate_id = "log#0.11-pre"] #![license = "MIT/ASL2"] #![crate_type = "rlib"] #![crate_type = "dylib"] #![doc(html_logo_url = "http://www.rust-lang.org/logos/rust-logo-128x128-blk-v2.png", html_favicon_url = "http://www.rust-lang.org/favicon.ico", html_root_url = "http://static.rust-lang.org/doc/master")] #![feature(macro_rules)] #![deny(missing_doc, deprecated_owned_vector)] extern crate sync; use std::cast; use std::fmt; use std::io::LineBufferedWriter; use std::io; use std::local_data; use std::os; use std::rt; use std::slice; use sync::one::{Once, ONCE_INIT}; pub mod macros; mod directive; /// Maximum logging level of a module that can be specified. Common logging /// levels are found in the DEBUG/INFO/WARN/ERROR constants. pub static MAX_LOG_LEVEL: u32 = 255; /// The default logging level of a crate if no other is specified. static DEFAULT_LOG_LEVEL: u32 = 1; /// An unsafe constant that is the maximum logging level of any module /// specified. This is the first line of defense to determining whether a /// logging statement should be run. static mut LOG_LEVEL: u32 = MAX_LOG_LEVEL; static mut DIRECTIVES: *Vec = 0 as *Vec; /// Debug log level pub static DEBUG: u32 = 4; /// Info log level pub static INFO: u32 = 3; /// Warn log level pub static WARN: u32 = 2; /// Error log level pub static ERROR: u32 = 1; local_data_key!(local_logger: ~Logger:Send) /// A trait used to represent an interface to a task-local logger. Each task /// can have its own custom logger which can respond to logging messages /// however it likes. pub trait Logger { /// Logs a single message described by the `args` structure. The level is /// provided in case you want to do things like color the message, etc. fn log(&mut self, level: u32, args: &fmt::Arguments); } struct DefaultLogger { handle: LineBufferedWriter, } impl Logger for DefaultLogger { // by default, just ignore the level fn log(&mut self, _level: u32, args: &fmt::Arguments) { match fmt::writeln(&mut self.handle, args) { Err(e) => fail!("failed to log: {}", e), Ok(()) => {} } } } impl Drop for DefaultLogger { fn drop(&mut self) { // FIXME(#12628): is failure the right thing to do? match self.handle.flush() { Err(e) => fail!("failed to flush a logger: {}", e), Ok(()) => {} } } } /// This function is called directly by the compiler when using the logging /// macros. This function does not take into account whether the log level /// specified is active or not, it will always log something if this method is /// called. /// /// It is not recommended to call this function directly, rather it should be /// invoked through the logging family of macros. pub fn log(level: u32, args: &fmt::Arguments) { // Completely remove the local logger from TLS in case anyone attempts to // frob the slot while we're doing the logging. This will destroy any logger // set during logging. let mut logger = local_data::pop(local_logger).unwrap_or_else(|| { ~DefaultLogger { handle: io::stderr() } as ~Logger:Send }); logger.log(level, args); local_data::set(local_logger, logger); } /// Getter for the global log level. This is a function so that it can be called /// safely #[doc(hidden)] #[inline(always)] pub fn log_level() -> u32 { unsafe { LOG_LEVEL } } /// Replaces the task-local logger with the specified logger, returning the old /// logger. pub fn set_logger(logger: ~Logger:Send) -> Option<~Logger:Send> { let prev = local_data::pop(local_logger); local_data::set(local_logger, logger); return prev; } /// Tests whether a given module's name is enabled for a particular level of /// logging. This is the second layer of defense about determining whether a /// module's log statement should be emitted or not. #[doc(hidden)] pub fn mod_enabled(level: u32, module: &str) -> bool { static mut INIT: Once = ONCE_INIT; unsafe { INIT.doit(init); } // It's possible for many threads are in this function, only one of them // will peform the global initialization, but all of them will need to check // again to whether they should really be here or not. Hence, despite this // check being expanded manually in the logging macro, this function checks // the log level again. if level > unsafe { LOG_LEVEL } { return false } // This assertion should never get tripped unless we're in an at_exit // handler after logging has been torn down and a logging attempt was made. assert!(unsafe { !DIRECTIVES.is_null() }); enabled(level, module, unsafe { (*DIRECTIVES).iter() }) } fn enabled(level: u32, module: &str, iter: slice::Items) -> bool { // Search for the longest match, the vector is assumed to be pre-sorted. for directive in iter.rev() { match directive.name { Some(ref name) if !module.starts_with(*name) => {}, Some(..) | None => { return level <= directive.level } } } level <= DEFAULT_LOG_LEVEL } /// Initialize logging for the current process. /// /// This is not threadsafe at all, so initialization os performed through a /// `Once` primitive (and this function is called from that primitive). fn init() { let mut directives = match os::getenv("RUST_LOG") { Some(spec) => directive::parse_logging_spec(spec), None => Vec::new(), }; // Sort the provided directives by length of their name, this allows a // little more efficient lookup at runtime. directives.sort_by(|a, b| { let alen = a.name.as_ref().map(|a| a.len()).unwrap_or(0); let blen = b.name.as_ref().map(|b| b.len()).unwrap_or(0); alen.cmp(&blen) }); let max_level = { let max = directives.iter().max_by(|d| d.level); max.map(|d| d.level).unwrap_or(DEFAULT_LOG_LEVEL) }; unsafe { LOG_LEVEL = max_level; assert!(DIRECTIVES.is_null()); DIRECTIVES = cast::transmute(~directives); // Schedule the cleanup for this global for when the runtime exits. rt::at_exit(proc() { assert!(!DIRECTIVES.is_null()); let _directives: ~Vec = cast::transmute(DIRECTIVES); DIRECTIVES = 0 as *Vec; }); } } #[cfg(test)] mod tests { use super::enabled; use directive::LogDirective; #[test] fn match_full_path() { let dirs = [LogDirective { name: Some(~"crate2"), level: 3 }, LogDirective { name: Some(~"crate1::mod1"), level: 2 }]; assert!(enabled(2, "crate1::mod1", dirs.iter())); assert!(!enabled(3, "crate1::mod1", dirs.iter())); assert!(enabled(3, "crate2", dirs.iter())); assert!(!enabled(4, "crate2", dirs.iter())); } #[test] fn no_match() { let dirs = [LogDirective { name: Some(~"crate2"), level: 3 }, LogDirective { name: Some(~"crate1::mod1"), level: 2 }]; assert!(!enabled(2, "crate3", dirs.iter())); } #[test] fn match_beginning() { let dirs = [LogDirective { name: Some(~"crate2"), level: 3 }, LogDirective { name: Some(~"crate1::mod1"), level: 2 }]; assert!(enabled(3, "crate2::mod1", dirs.iter())); } #[test] fn match_beginning_longest_match() { let dirs = [LogDirective { name: Some(~"crate2"), level: 3 }, LogDirective { name: Some(~"crate2::mod"), level: 4 }, LogDirective { name: Some(~"crate1::mod1"), level: 2 }]; assert!(enabled(4, "crate2::mod1", dirs.iter())); assert!(!enabled(4, "crate2", dirs.iter())); } #[test] fn match_default() { let dirs = [LogDirective { name: None, level: 3 }, LogDirective { name: Some(~"crate1::mod1"), level: 2 }]; assert!(enabled(2, "crate1::mod1", dirs.iter())); assert!(enabled(3, "crate2::mod2", dirs.iter())); } #[test] fn zero_level() { let dirs = [LogDirective { name: None, level: 3 }, LogDirective { name: Some(~"crate1::mod1"), level: 0 }]; assert!(!enabled(1, "crate1::mod1", dirs.iter())); assert!(enabled(3, "crate2::mod2", dirs.iter())); } }