# Logging Timers for Rust This crate provides a couple of simple timers that log messages indicating the elapsed time between their creation and dropping. Messages are output via the [log](https://crates.io/crates/log) crate. Timers have names, and the log messages are constructed in such a way that they contain the module, filename and line number of the place where the timer was constructed. # Using the Timer Attributes The simplest way to get started is to use one of the two attributes `time` or `stime` to instrument a function, the name of the function is used as the name of the timer: ```norun use logging_timer::{time, stime}; #[time] fn find_files(dir: PathBuf) -> Vec { let files = vec![]; // expensive operation here return files; } // 'TimerFinished' message is logged here ``` Both attributes accept two optional arguments, to specify the log level and a pattern into which the name of the function will be substituted. The pattern is helpful to disambiguate functions when you have many in the same module with the same name: `new` might occur many times on different structs, for example. ```norun #[time] // Use default log level of Debug #[time("info")] // Set custom log level #[time("info", "FirstStruct::{}")] // Logs "FirstStruct::new()" at Info #[time("info", "SecondStruct::{}")] // Logs "SecondStruct::new()" at Info #[time("ThirdStruct::{}")] // Logs "ThirdStruct::new()" at Debug #[time("never")] // Turn off instrumentation at compile time ``` Valid values for the log level are error, warn, info, debug and trace. Debug is the default. You can also specify 'never' to completely disable the instrumentation at compile time. The log level should appear first but as shown above can be omitted. The macros distinguish the log level from the pattern by looking for "{}". # Using the Inline Timers More flexibility, including logging extra information, is provided by the two function-like macro forms, `timer!` and `stimer!`. The difference is that `timer!` returns a timer that logs a message only when it is dropped, while `stimer!` returns a timer that logs a started message as soon as it is created, and a finished message when it is dropped. There are also two corresponding proc-macros called `time` and `stimer` which can be used to instrument functions with a timer. In this example "FIND_FILES" is the name of the timer (using all UPPERCASE for the timer name is optional but helps make the name stand out in the log) ```rs use logging_timer::{timer}; fn find_files(dir: PathBuf) -> Vec { let _tmr = timer!("FIND_FILES"); let files = vec![]; // expensive operation here return files; } // _tmr is dropped here and a 'TimerFinished' message is logged ``` You can replace `timer!` with `stimer!` to get a timer that logs a starting message as well, giving you a pair of 'bracketing' log messages. In addition, both timer macros accept [format_args!](https://doc.rust-lang.org/std/macro.format_args.html) style parameters, allowing you to include extra information in the log messages. ```rs let _tmr = timer!("FIND_FILES", "Directory = {}", dir); ``` # Outputting Intermediate Messages The `executing!` macro allows you to make the timer produce a message before it is dropped. You can call it as many times as you want. A pseudocode example: ```rs use logging_timer::{timer, executing}; fn find_files(dir: PathBuf) -> Vec { let tmr = timer!("FIND_FILES"); let files = vec![]; for dir in sub_dirs(dir) { // expensive operation executing!(tmr, "Processed {}", dir); } return files; } // tmr is dropped here and a 'TimerFinished' message is logged ``` # Controlling the Final Message The `finish!` macro also makes the timer log a message, but it also has the side effect of suppressing the normal drop message. `finish!` is useful when you want the final message to include some information that you did not have access to until the calculation had finished. ```rs use logging_timer::{timer, executing, finish}; fn find_files(dir: PathBuf) -> Vec { let tmr = timer!("FIND_FILES"); let files = vec![]; finish!(tmr, "Found {} files", files.len()); return files; } // tmr is dropped here but no message is produced. ``` # Setting the log level By default both `timer` and `stimer` log at `Debug` level. An optional first parameter to these macros allows you to set the log level. **To aid parsing of the macro arguments this first parameter is terminated by a semi-colon.** For example: ```rs let tmr1 = timer!(Level::Warn; "TIMER_AT_WARN"); let tmr2 = stimer!(Level::Info; "TIMER_AT_INFO"); ``` # Example of Timer Output The overall format will depend on how you customize the output format of the log crate, but as an illustrative example: ```text 2019-05-30T21:41:41.847982550Z DEBUG [TimerStarting] [dnscan/src/main.rs/63] DIRECTORY_ANALYSIS 2019-05-30T21:41:41.868690703Z INFO [dnlib::configuration] [dnlib/src/configuration.rs/116] Loaded configuration from "/home/phil/.dnscan/.dnscan.json" 2019-05-30T21:41:41.897609281Z DEBUG [TimerFinished] [dnlib/src/io.rs/67] FIND_FILES, Elapsed=28.835275ms, Dir="/home/phil/mydotnetprojects", NumSolutions=1 NumCsproj=45, NumOtherFiles=12 2019-05-30T21:41:41.955140835Z DEBUG [TimerFinished] [dnlib/src/analysis.rs/93] LOAD_SOLUTIONS, Elapsed=57.451736ms 2019-05-30T21:41:42.136762196Z DEBUG [TimerFinished] [dnlib/src/analysis.rs/108] LOAD_PROJECTS, Elapsed=181.563223ms, Found 43 linked projects and 2 orphaned projects 2019-05-30T21:41:42.136998556Z DEBUG [TimerStarting] [dnscan/src/main.rs/87] CALCULATE_PROJECT_GRAPH 2019-05-30T21:41:42.143072972Z DEBUG [TimerExecuting] [dnscan/src/main.rs/87] CALCULATE_PROJECT_GRAPH, Elapsed=6.075205ms, Individual graphs done 2019-05-30T21:41:42.149218039Z DEBUG [TimerFinished] [dnscan/src/main.rs/87] CALCULATE_PROJECT_GRAPH, Elapsed=12.219438ms, Found 19 redundant project relationships 2019-05-30T21:41:42.165724712Z DEBUG [TimerFinished] [dnscan/src/main.rs/108] WRITE_OUTPUT_FILES, Elapsed=16.459312ms 2019-05-30T21:41:42.166445Z INFO [TimerFinished] [dnscan/src/main.rs/63] DIRECTORY_ANALYSIS, Elapsed=318.48581ms ``` Here the `[Timer*]` blocks are the `target` field from log's [Record](https://docs.rs/log/0.4.6/log/struct.Record.html) struct and `[dnscan/src/main.rs/63]` is the filename and number from `Record` - this captures the place where the timer was instantiated. The module is also set, but is not shown in these examples. # What is Measured? The time that is logged is the **wall-clock time** - the difference between the start of execution of the function and the drop of the timer at the end of the function. The wall clock time is not necessarily length of time that the function spent executing on the CPU. This is true for a normal function due to thread pre-emption, but it especially true for `async` functions which may spend a large part of their lives suspended. For more sophisticated usage you may want to look into the [Tokio Tracing](https://github.com/tokio-rs/tracing) crate. # Code Examples There is also an example program in the examples folder which demonstrates all the different usages. To run, clone the repository and in Linux do ```sh RUST_LOG=debug cargo run --example logging_demo ``` If you're on Windows, in PowerShell you can do ```ps $env:RUST_LOG="debug" cargo run --example logging_demo ``` # History See the [CHANGELOG](CHANGELOG.md). # Performance The `timer` and `stimer` macros return an `Option`. The method [log_enabled](https://doc.rust-lang.org/1.1.0/log/macro.log_enabled!.html) is used to check whether logging is enabled at the requested level. If logging is not enabled then `None` is returned. This avoids most calculation in the case where the timer would be a no-op, such that the following loop will create and drop 1 million timers in about 4ms on my 2012-era Intel i7. ```rs for _ in 0..1_000_000 { let _tmr = stimer!("TEMP"); } ``` In comparison, v0.3 of the library would always return a `LoggingTimer`, and the loop took ten times longer. An `Option` is 104 bytes in size on 64-bit Linux.