6 releases

0.1.5 Aug 20, 2023
0.1.4 Aug 20, 2023

#66 in #resolution

25 downloads per month
Used in macro-dep-test

MIT/Apache

2KB

Associated Proc Macro Pattern

It's a common pattern to provide a foo crate with trait definitions, and foo-derive crate with a proc-macro derive implementation. Typically, you want foo and foo-derive to be versioned in lockstep, because derive crates like to use #[doc(hidden)] non-semver-guarded API. Usually, this is solved by a derive feature, which makes foo depend on foo-derive with =x.y.z constraint.

This, however, is problematic for compile times! It means that compilation of foo-derive is sequenced before compilation of foo. As foo-derive is a derive macro, it needs to parse the Rust language. Rust is not a small language, so parsing it is fundamentally hard, and requires loads of code to do correctly. So it takes some time to compile foo-derive. What's worse, while normally Cargo pipelines compilation such that .rmeta files are all that's needed to unblock compilation of dependent crates, for proc macros Cargo really needs to link the whole .so!

The bottom line, while

foo = { version = "x.y.z", features = ["derive"] }

is easy to explain and works correctly, it could significantly reduce the amount of parallelism available during builds.

On the other hand, while

foo = { version = "x.y.z" }
foo-derive = { version = "x.y.z" }

provides better compilation time, it doesn't constrain foo and foo-derive to be the same version.

The pattern in this crate shows how to add that constraint! We can use the following declaration of dependencies in foo's Cargo.toml:

[package]
name = "foo"
version = "1.2.3"

[dependencies]
foo-derive = { version = "=1.2.3", optional = true }

[target.'cfg(any())'.dependencies] # <- the trick
foo-derive = { version = "=1.2.3" }

[features]
derive = ["dep:foo-derive"]

The trick is a target specific dependency with "impossible" any() cfg. This cfg is never true, so foo never actually depends on foo-derive (unless the derive feature flag is enabled). Non the less, this platform-specific dependency forces Cargo to include foo-derive into the lockfile, so the "no two semver-compatible versions of a crate" constraint kicks in.

Eg, if the user's tries to do

[dependencies]
foo = "=1.2.3"
foo-derive = "=1.2.2"

their build will (correctly) fail.

Crucially, because the cfg is never true, the foo crate doesn't actually depend on foo-derive, so it can be independently compiled. Similarly, although every lockfile gets a foo-derive, it isn't actually downloaded unless it is needed elsewhere in the crate graph (the situation is similar to having windows-specific deps in a lockfile of a linux-only crate).

Note that it's important that target-specific deps, rather features, are used here. With features, Cargo can look at the entires set of features of the root crate being compiled, deduce the precise set of features that could be activated for dependencies, and prune anything which is guaranteed to not be needed from Cargo.lock.

With target-specific dependencies (target.'cfg()'.dependencies syntax), Cargo has to assume that each cfg could be true, and so it has to conservatively include everything into a lockfile.

Important Clarification

So, does this actually work? I don't know! I don't think anyone tried this hack at scale, so it might be the case that something breaks HORRIBLY somewhere. We won't know without trying though :-) And it seems to work in this little experimient (there's a bunch of macro-dep-test and macro-dep-test-macros versions published to crates.io, so you could check for yourself )

No runtime deps