WSL2-Linux-Kernel/Documentation/kbuild/gcc-plugins.rst

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=========================
GCC plugin infrastructure
=========================
Introduction
============
GCC plugins are loadable modules that provide extra features to the
compiler [1]_. They are useful for runtime instrumentation and static analysis.
We can analyse, change and add further code during compilation via
callbacks [2]_, GIMPLE [3]_, IPA [4]_ and RTL passes [5]_.
The GCC plugin infrastructure of the kernel supports building out-of-tree
modules, cross-compilation and building in a separate directory.
Plugin source files have to be compilable by a C++ compiler.
Currently the GCC plugin infrastructure supports only some architectures.
Grep "select HAVE_GCC_PLUGINS" to find out which architectures support
GCC plugins.
This infrastructure was ported from grsecurity [6]_ and PaX [7]_.
--
.. [1] https://gcc.gnu.org/onlinedocs/gccint/Plugins.html
.. [2] https://gcc.gnu.org/onlinedocs/gccint/Plugin-API.html#Plugin-API
.. [3] https://gcc.gnu.org/onlinedocs/gccint/GIMPLE.html
.. [4] https://gcc.gnu.org/onlinedocs/gccint/IPA.html
.. [5] https://gcc.gnu.org/onlinedocs/gccint/RTL.html
.. [6] https://grsecurity.net/
.. [7] https://pax.grsecurity.net/
Purpose
=======
GCC plugins are designed to provide a place to experiment with potential
compiler features that are neither in GCC nor Clang upstream. Once
their utility is proven, the goal is to upstream the feature into GCC
(and Clang), and then to finally remove them from the kernel once the
feature is available in all supported versions of GCC.
Specifically, new plugins should implement only features that have no
upstream compiler support (in either GCC or Clang).
When a feature exists in Clang but not GCC, effort should be made to
bring the feature to upstream GCC (rather than just as a kernel-specific
GCC plugin), so the entire ecosystem can benefit from it.
Similarly, even if a feature provided by a GCC plugin does *not* exist
in Clang, but the feature is proven to be useful, effort should be spent
to upstream the feature to GCC (and Clang).
After a feature is available in upstream GCC, the plugin will be made
unbuildable for the corresponding GCC version (and later). Once all
kernel-supported versions of GCC provide the feature, the plugin will
be removed from the kernel.
Files
=====
**$(src)/scripts/gcc-plugins**
This is the directory of the GCC plugins.
**$(src)/scripts/gcc-plugins/gcc-common.h**
This is a compatibility header for GCC plugins.
It should be always included instead of individual gcc headers.
**$(src)/scripts/gcc-plugins/gcc-generate-gimple-pass.h,
$(src)/scripts/gcc-plugins/gcc-generate-ipa-pass.h,
$(src)/scripts/gcc-plugins/gcc-generate-simple_ipa-pass.h,
$(src)/scripts/gcc-plugins/gcc-generate-rtl-pass.h**
These headers automatically generate the registration structures for
GIMPLE, SIMPLE_IPA, IPA and RTL passes.
They should be preferred to creating the structures by hand.
Usage
=====
You must install the gcc plugin headers for your gcc version,
e.g., on Ubuntu for gcc-10::
apt-get install gcc-10-plugin-dev
Or on Fedora::
dnf install gcc-plugin-devel
Enable the GCC plugin infrastructure and some plugin(s) you want to use
in the kernel config::
CONFIG_GCC_PLUGINS=y
CONFIG_GCC_PLUGIN_LATENT_ENTROPY=y
...
To compile the minimum tool set including the plugin(s)::
make scripts
or just run the kernel make and compile the whole kernel with
the cyclomatic complexity GCC plugin.
4. How to add a new GCC plugin
==============================
The GCC plugins are in scripts/gcc-plugins/. You need to put plugin source files
right under scripts/gcc-plugins/. Creating subdirectories is not supported.
It must be added to scripts/gcc-plugins/Makefile, scripts/Makefile.gcc-plugins
and a relevant Kconfig file.