Reporting build timings

The --timings option gives some information about how long each compilation takes, and tracks concurrency information over time.

cargo build --timings

This writes an HTML report in target/cargo-timings/cargo-timing.html. This also writes a copy of the report to the same directory with a timestamp in the filename, if you want to look at older runs.

Reading the graphs

There are two graphs in the output. The “unit” graph shows the duration of each unit over time. A “unit” is a single compiler invocation. There are lines that show which additional units are “unlocked” when a unit finishes. That is, it shows the new units that are now allowed to run because their dependencies are all finished. Hover the mouse over a unit to highlight the lines. This can help visualize the critical path of dependencies. This may change between runs because the units may finish in different orders.

The “codegen” times are highlighted in a lavender color. In some cases, build pipelining allows units to start when their dependencies are performing code generation. This information is not always displayed (for example, binary units do not show when code generation starts).

The “custom build” units are build.rs scripts, which when run are highlighted in orange.

The second graph shows Cargo’s concurrency over time. The background indicates CPU usage. The three lines are:

  • “Waiting” (red) — This is the number of units waiting for a CPU slot to open.
  • “Inactive” (blue) — This is the number of units that are waiting for their dependencies to finish.
  • “Active” (green) — This is the number of units currently running.

Note: This does not show the concurrency in the compiler itself. rustc coordinates with Cargo via the “job server” to stay within the concurrency limit. This currently mostly applies to the code generation phase.

Tips for addressing compile times:

  • Look for slow dependencies.
    • Check if they have features that you may wish to consider disabling.
    • Consider trying to remove the dependency completely.
  • Look for a crate being built multiple times with different versions. Try to remove the older versions from the dependency graph.
  • Split large crates into smaller pieces.
  • If there are a large number of crates bottlenecked on a single crate, focus your attention on improving that one crate to improve parallelism.