libyang is a YANG data modelling language parser and toolkit written (and providing API) in C. The library is used e.g. in libnetconf2, Netopeer2, sysrepo and FRRouting projects.
- Parsing (and validating) schemas in YANG format.
- Parsing (and validating) schemas in YIN format.
- Parsing, validating and printing instance data in XML format.
- Parsing, validating and printing instance data in JSON format (RFC 7951).
- Manipulation with the instance data.
- Support for default values in the instance data (RFC 6243).
- Support for YANG extensions.
- Support for YANG Metadata (RFC 7952).
- yanglint - feature-rich YANG tool.
Current implementation covers YANG 1.0 (RFC 6020) as well as YANG 1.1 (RFC 7950).
The project uses 2 main branches master
and devel
. Other branches should not be cloned. In master
there are files of the
last official release. Any latest improvements and changes, which were tested at least briefly are found in devel
. On every
new release, devel
is merged into master
.
This means that when only stable official releases are to be used, either master
can be used or specific releases downloaded.
If all the latest bugfixes should be applied, devel
branch is the one to be used. Note that whenever a new issue is created
and it occurs on the master
branch, the first response will likely be to use devel
before any further provided support.
We are using openSUSE Build Service to automaticaly prepare binary packages for number of GNU/Linux distros.
The libyang
packages are always build from current master
branch (latest release). If you are interested in any other packages
(such as devel or C++ and Python bindings), you can browse
all packages from our repository.
- C compiler (gcc >= 4.8.4, clang >= 3.0, ...)
- cmake >= 2.8.12
- libpcre (devel package)
- note, that PCRE is supposed to be compiled with unicode support (configure's options
--enable-utf
and--enable-unicode-properties
) - cmocka >= 1.0.0 (for tests only, see Tests)
- doxygen (for generating documentation)
- valgrind (for enhanced testing)
- libpcre
$ mkdir build; cd build
$ cmake ..
$ make
# make install
The library documentation can be generated directly from the source codes using Doxygen tool:
$ make doc
$ google-chrome ../doc/html/index.html
The documentation is also built hourly and available at netopeer.liberouter.org.
Set CC
variable:
$ CC=/usr/bin/clang cmake ..
To change the prefix where the library, headers and any other files are installed,
set CMAKE_INSTALL_PREFIX
variable:
$ cmake -DCMAKE_INSTALL_PREFIX:PATH=/usr ..
Default prefix is /usr/local
.
There are two build modes:
- Release. This generates library for the production use without any debug information.
- Debug. This generates library with the debug information and disables optimization of the code.
The Debug
mode is currently used as the default one. to switch to the
Release
mode, enter at the command line:
$ cmake -D CMAKE_BUILD_TYPE:String="Release" ..
As for YANG extensions, libyang allows loading extension plugins. By default, the directory to store the plugins is LIBDIR/libyang. To change it, use the following cmake option with the value specifying the desired directory:
$ cmake -DPLUGINS_DIR:PATH=`pwd`"/src/extensions/" ..
The directory path can be also changed runtime via environment variable, e.g.:
$ LIBYANG_EXTENSIONS_PLUGINS_DIR=`pwd`/my/relative/path yanglint
Whenever the latest revision of a schema is supposed to be loaded (import without specific revision), it is performed in the standard way, the first time. By default, every other time when the latest revision of the same schema is needed, the one initially loaded is reused. If you know this can cause problems meaning the latest available revision of a schema can change during operation, you can force libyang to always search for the schema anew by:
$ cmake -DENABLE_LATEST_REVISIONS=OFF ..
Also, it can be efficient to store certain information about schemas that is generated during parsing so that it does not need to be generated every time the schema is used, but it will consume some additional space. You can enable this cache with:
$ cmake -DENABLE_CACHE=ON ..
Note that, with CMake, if you want to change the compiler or its options after you already ran CMake, you need to clear its cache first - the most simple way to do it is to remove all content from the 'build' directory.
All libyang functions are available via the main header:
#include <libyang/libyang.h>
To compile your program with libyang, it is necessary to link it with libyang using the following linker parameters:
-lyang
Note, that it may be necessary to call ldconfig(8)
after library installation and if the
library was installed into a non-standard path, the path to libyang must be specified to the
linker. To help with setting all the compiler's options, there is libyang.pc
file for
pkg-config(1)
available in the source tree. The file is installed with the library.
If you are using cmake
in you project, it is also possible to use the provided
FindLibYANG.cmake
file to detect presence of the libyang library in the system.
libyang project includes a feature-rich tool called yanglint(1)
for validation
and conversion of the schemas and YANG modeled data. The source codes are
located at /tools/lint
and can be used to explore how an
application is supposed to use the libyang library. yanglint(1)
binary as
well as its man page are installed together with the library itself.
There is also README describing some examples of
using yanglint
.
libyang supports YANG extensions via a plugin mechanism. Some of the plugins (for
NACM or Metadata) are available out of the box and installed together with libyang.
However, when libyang is not installed and yanglint(1)
is used from the build
directory, the plugins are not available. There are two options:
- Install libyang.
# make install
- Set environment variable
LIBYANG_EXTENSIONS_PLUGINS_DIR
to contain path to the built extensions plugin (./src/extensions
from the build directory).
$ LIBYANG_EXTENSIONS_PLUGINS_DIR="`pwd`/src/extensions" ./yanglint
libyang includes several tests built with cmocka. The tests
can be found in tests
subdirectory and they are designed for checking library
functionality after code changes.
The tests are by default built in the Debug
build mode by running
$ make
In case of the Release
mode, the tests are not built by default (it requires
additional dependency), but they can be enabled via cmake option:
$ cmake -DENABLE_BUILD_TESTS=ON ..
Note that if the necessary cmocka headers are not present in the system include paths, tests are not available despite the build mode or cmake's options.
Tests can be run by the make's test
target:
$ make test
Simple fuzzing targets, fuzzing instructions and a Dockerfile that builds the fuzz targets
and the AFL fuzzer are available in the tests/fuzz
directory.
The tests/fuzz
directory also contains a README file that describes the whole process in more detail.
We provide bindings for high-level languages using SWIG generator. The bindings are optional and to enable building of the specific binding, the appropriate cmake option must be enabled, for example:
$ cmake -DJAVASCRIPT_BINDING=ON ..
More information about the specific binding can be found in their README files.
Currently supported bindings are:
- JavaScript
- cmake option:
JAVASCRIPT_BINDING
- README
- cmake option:
- Python SWIG (uses SWIG, enabled by default if
GEN_LANGUAGE_BINDINGS
is set)- cmake option:
GEN_PYTHON_BINDINGS
(depends onGEN_CPP_BINDINGS
) - README
- cmake option:
- Python CFFI (more "pythonic" API, not enabled by default)
- cmake option:
GEN_PYTHON_CFFI_BINDINGS
- README
- cmake option:
Project is hosted on GitHub where you can find additional information and contact developers via the project's issue tracker. If you are interested in future plans announcements, please subscribe to the Future Plans issue.