Enabling Link Time Optimization (LTO) with MMTk
MMTk's API is designed with an assumption that LTO will be enabled for a performant build.
It is essential to allow the Rust compiler to optimize across the crate boundary between the binding crate and mmtk-core.
LTO allows inlining for both directions (from mmtk-core to the binding, and from the binding to mmtk-core),
and allows further optimization such as specializing and constant folding for the VMBinding trait.
We suggest enabling LTO for the release build in the binding's manifest (Cargo.toml) by adding a profile for the release build,
so LTO is always enabled for a release build.
[profile.release]
lto = true
If your binding project is a Rust binary (e.g. the VM is written in Rust), this should be enough. However, if your binding project is a library, there are some limitations with cargo that you should be aware of.
Binding as a library
Cargo only allows LTO for certain crate types. You will need to specify the crate type properly, otherwise cargo may skip LTO without any warning or error.
[lib]
...
# be careful - LTO is only allowed for certain crate types
crate-type = ["cdylib"]
At the time of writing, cargo has some limitations about LTO with different crate types:
- LTO is only allowed with
cdylibandstaticlib(other thanbin). Check the code ofcan_ltofor your Rust version to clarify. - If the
crate-typefield includes any type that LTO is not allowed, LTO will be skipped for all the libraries generated (https://github.com/rust-lang/rust/issues/51009). For example, if you havecrate-type = ["cdylib", "rlib"]and cargo cannot do LTO forrlib, LTO will be skipped forcdylibas well. So only keep the crate type that you actually need in thecrate-typefield.