Linker-plugin-LTO
The -C linker-plugin-lto
flag allows for deferring the LTO optimization
to the actual linking step, which in turn allows for performing
interprocedural optimizations across programming language boundaries if
all the object files being linked were created by LLVM based toolchains.
The prime example here would be linking Rust code together with
Clang-compiled C/C++ code.
Usage
There are two main cases how linker plugin based LTO can be used:
- compiling a Rust
staticlib
that is used as a C ABI dependency - compiling a Rust binary where
rustc
invokes the linker
In both cases the Rust code has to be compiled with -C linker-plugin-lto
and
the C/C++ code with -flto
or -flto=thin
so that object files are emitted
as LLVM bitcode.
Rust staticlib
as dependency in C/C++ program
In this case the Rust compiler just has to make sure that the object files in
the staticlib
are in the right format. For linking, a linker with the
LLVM plugin must be used (e.g. LLD).
Using rustc
directly:
# Compile the Rust staticlib
rustc --crate-type=staticlib -Clinker-plugin-lto -Copt-level=2 ./lib.rs
# Compile the C code with `-flto=thin`
clang -c -O2 -flto=thin -o main.o ./main.c
# Link everything, making sure that we use an appropriate linker
clang -flto=thin -fuse-ld=lld -L . -l"name-of-your-rust-lib" -o main -O2 ./cmain.o
Using cargo
:
# Compile the Rust staticlib
RUSTFLAGS="-Clinker-plugin-lto" cargo build --release
# Compile the C code with `-flto=thin`
clang -c -O2 -flto=thin -o main.o ./main.c
# Link everything, making sure that we use an appropriate linker
clang -flto=thin -fuse-ld=lld -L . -l"name-of-your-rust-lib" -o main -O2 ./cmain.o
C/C++ code as a dependency in Rust
In this case the linker will be invoked by rustc
. We again have to make sure
that an appropriate linker is used.
Using rustc
directly:
# Compile C code with `-flto`
clang ./clib.c -flto=thin -c -o ./clib.o -O2
# Create a static library from the C code
ar crus ./libxyz.a ./clib.o
# Invoke `rustc` with the additional arguments
rustc -Clinker-plugin-lto -L. -Copt-level=2 -Clinker=clang -Clink-arg=-fuse-ld=lld ./main.rs
Using cargo
directly:
# Compile C code with `-flto`
clang ./clib.c -flto=thin -c -o ./clib.o -O2
# Create a static library from the C code
ar crus ./libxyz.a ./clib.o
# Set the linking arguments via RUSTFLAGS
RUSTFLAGS="-Clinker-plugin-lto -Clinker=clang -Clink-arg=-fuse-ld=lld" cargo build --release
Explicitly specifying the linker plugin to be used by rustc
If one wants to use a linker other than LLD, the LLVM linker plugin has to be
specified explicitly. Otherwise the linker cannot read the object files. The
path to the plugin is passed as an argument to the -Clinker-plugin-lto
option:
rustc -Clinker-plugin-lto="/path/to/LLVMgold.so" -L. -Copt-level=2 ./main.rs
Toolchain Compatibility
In order for this kind of LTO to work, the LLVM linker plugin must be able to
handle the LLVM bitcode produced by both rustc
and clang
.
Best results are achieved by using a rustc
and clang
that are based on the
exact same version of LLVM. One can use rustc -vV
in order to view the LLVM
used by a given rustc
version. Note that the version number given
here is only an approximation as Rust sometimes uses unstable revisions of
LLVM. However, the approximation is usually reliable.
The following table shows known good combinations of toolchain versions.
Rust Version | Clang Version |
---|---|
Rust 1.34 | Clang 8 |
Rust 1.35 | Clang 8 |
Rust 1.36 | Clang 8 |
Rust 1.37 | Clang 8 |
Rust 1.38 | Clang 9 |
Rust 1.39 | Clang 9 |
Rust 1.40 | Clang 9 |
Rust 1.41 | Clang 9 |
Rust 1.42 | Clang 9 |
Rust 1.43 | Clang 9 |
Rust 1.44 | Clang 9 |
Rust 1.45 | Clang 10 |
Rust 1.46 | Clang 10 |
Note that the compatibility policy for this feature might change in the future.