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mirror of https://gitlab.com/libvirt/libvirt.git synced 2024-12-22 17:34:18 +03:00
libvirt/docs/strategy.rst
Peter Krempa 127b6d1267 docs: Convert 'strategy' to rST
Signed-off-by: Peter Krempa <pkrempa@redhat.com>
Reviewed-by: Ján Tomko <jtomko@redhat.com>
2022-03-08 17:40:47 +01:00

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================
Project Strategy
================
This document attempts to outline the libvirt project strategy for the near
future. Think of this as a high level vision or to-do list setting the direction
for the project and its developers to take.
Language consolidation
----------------------
At time of writing libvirt uses the following languages:
C
The core libvirt library, daemons, and helper tools are all written in the C
language.
Python
Various supporting build/test scripts are written in Python, with
compatibility for Python 3.
Perl
Various supporting build/test scripts are written in Perl. It is also used
for many syntax-check inline rules
Shell
Shell is used for some simple build/test scripts. At runtime libvirt avoids
shell except when using SSH tunnels to a remote host
XSLT
The website uses XSLT for its templating system. The API documentation is
also autogenerated from an XML description using XSLT
HTML
The website documentation is all written in plain HTML. Some HTML is also
auto-generated for API documentation
Meson
The core build system uses the new Meson build system
make
The syntax-check uses make recipes
awk/sed
A number of the syntax-check inline rules involve use of awk/sed scripts
POD
The command line manual pages are typically written in Perl's POD format, and
converted to troff
The wide range of languages used present a knowledge burden for developers
involved in libvirt, especially when there are multiple languages all used in
the same problem spaces. This is most notable in the build system which uses a
combination of Meson, shell, awk, sed, Perl and Python, with debugging requiring
understanding of the interactions between many languages. The popularity of Perl
has declined, while Python has become more popular. This directly influences the
amount and quality of contributions that can be expected for programs written in
the respective languages.
The C language has served libvirt well over the years, but its age shows giving
rise to limitations which negatively impact the project in terms of code
quality, reliability, and efficiency of development. Most notably its lack of
memory safety means that many code bugs become trivially exploitable security
flaws or denial of service. The lack of a high level portable runtime results in
a lot of effort being spent to ensure cross platform portability. The modern
languages Rust and Go provide viable options for low level systems programming,
in a way that is not practical with other common languages such as Python and
Java. There is thus a desire to make use of either Rust or Go, or a combination
of both, to incrementally replace existing use of C, and also for greenfield
development.
With this in mind the libvirt project has set a vision for language usage in the
future:
C
Large parts of the core libvirt library, daemons, and helper tools will
continue to make use in the C language. Integration of other languages will
be an incremental, targeted process where they can bring the greatest
benefit.
Rust / Go
Parts of the core libvirt library, daemons and helper tools are to leverage
Rust or Go or both to replace C.
Meson
The core build system is to be written in Meson.
Python
Various supporting build/test scripts are written in Python 3 compatible mode
only.
reStructuredText
The website and command man pages are to be written in RST, using Sphinx as
the engine to convert to end user formats like HTML, troff, etc
Some notable points from the above. Whether the core library / daemons will use
Rust or Go internally is still to be decided based on more detailed evaluation
to identify the best fit. The need to link and embed this functionality in other
processes has complex interactions both at a technical and non-technical level.
For standalone helper tools, either language is viable, but there are fewer
concerns around interactions with other in-process code from 3rd parties. Thus a
different decision may be made for daemons/libraries vs tools. Any rewrite
proposed for existing functionality will have to weigh up the benefits of the
new code, against the risk of introducing regressions with respect to the
previous code.
Using the RST format for documentation allows for the use of XSLT to be
eliminated from the build process. RST and the Sphinx toolkit are widely used,
as seen by the huge repository of content on `Read The
Docs <https://readthedocs.org/>`__. The ability to embed raw HTML in the RST
docs will greatly facilitate its adoption, avoiding the need for a big bang
conversion of existing content. Given the desire to eliminate Perl usage,
replacing the use of POD documentation for manual pages is an obvious followup
task. RST is the obvious choice to achieve alignment with the website, allowing
the man pages to be easily published online with other docs. It is further
anticipated that the current API docs generator which uses XSLT to convert the
XML API description would be converted to something which generates RST using
Python instead of XSLT.