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YANG-based configuration and operational state data store for Unix/Linux applications

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Sysrepo

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Sysrepo is a YANG-based configuration and operational state data store for Unix/Linux applications.

Applications can use sysrepo to store their configuration modeled by provided YANG model instead of using e.g. flat configuration files. Sysrepo will ensure data consistency of the data stored in the datastore and enforce data constraints defined by YANG model. Applications can currently use C language API of sysrepo Client Library to access the configuration in the datastore, but the support for other programming languages is planed for later, too.

Sysrepo can be easily integrated with management agents such as NETCONF or RESTCONF servers, using the same client library API that applications use to access their configuration. As of now, sysrepo is integrated with the Netopeer 2 NETCONF server. This means that applications that use sysrepo to store their configuration can automatically benefit from the ability to being controlled via NETCONF.

Branches

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.

Compatibility Between Versions

When upgrading Sysrepo to a newer major SO version, look into the compatibility directory for a summary of changes. Each directory describes the changes between the specific SO versions. Be aware that they do not match project versions.

Provided Features

  • Ability to store / retrieve YANG-modeled data elements adressed by XPath
  • Startup, running, candidate, and operational datastore support
  • Data consistency and constraints enforcement according to YANG models
  • No single point of failure design (is just a library)
  • Full transaction and concurrency support
  • Notifications of subscribed applications about the changes made in the datastore
  • Commit verifiers (change verification by subscribed applications)
  • Operational data support (publishing of application's state/configuration data to sysrepo)
  • YANG 1.1 support
  • Custom RPC, Event Notifications, YANG 1.1 Actions support
  • Notification store & notification replay
  • Factory Default Datastore support (RFC 8808)

Packages

Binary RPM or DEB packages of the latest release can be built locally using apkg, look into README in the distro directory.

Security Notes

Sysrepo does not have any master process that could enforce complex access control. So instead, it relies on and utilizes standard file system permissions but there are some things to bear in mind.

To prevent any sensitive data from being accessible by unauthorized processes, it is imperative to always set correct permissions and owner for all YANG modules being installed. The utility sysrepoctl can help with both displaying all the permissions (--list) and modifying them (--change <module>) in addition to this functionality being available in the API.

Having made certain of this, the default configuration should be suitable for a reasonably secure machine that has no malicious running processes. Specifically, it is trivial for such a process to completely break sysrepo by writing into shared files that must be accessible for all the processes linked with sysrepo. Also, with some reverse engineering, it may even be possible to access data by an unathorized process when they are being communicated in these shared files.

In order to avoid all such security issues, there are 2 cmake variables SYSREPO_UMASK and SYSREPO_GROUP that should be adjusted. Generally, a new system group should be created and set for SYSREPO_GROUP and then all outside access frobidden by setting SYSREPO_UMASK to 00007. If then all the users executing sysrepo processes belong to this group, none of sysrepo files and no sensitive information should be accessible to other users.

Requirements

Build Requirements

  • C compiler (gcc >= 4.8.4, clang >= 3.0, ...)
  • cmake >= 2.8.12
  • libyang
  • tar(1)

Optional

  • pkg-config & libsystemd (to support sysrepo-plugind systemd service)
  • doxygen (for generating documentation)
  • cmocka >= 1.0.1 (for tests only, see Tests)
  • valgrind (for enhanced testing)
  • gcov (for code coverage)
  • lcov (for code coverage)
  • genhtml (for code coverage)

Building

$ mkdir build; cd build
$ cmake ..
$ make
# make install

Plugin development documentation

Another markdown document aimed at plugin developers is available in plugin_dev_doc.md. The goal of the document is to provide a single place where a complete overview of information required to start developing plugins is available. The document describes the basics of Sysrepo plugin development and the technologies required to work with Sysrepo like YANG, XPath, NETCONF and others.

Useful CMake sysrepo Options

Set custom repository path:

-DREPO_PATH=/opt/sysrepo/my_repository

Set custom sysrepo DS and NTF plugins path:

-DSR_PLUGINS_PATH=/opt/sysrepo/plugins

Set custom sysrepo-plugind plugins path:

-DSRPD_PLUGINS_PATH=/opt/sysrepo-plugind/plugins

Set global umask for all sysrepo file and directory creation:

-DSYSREPO_UMASK=00007

Set system group to own all sysrepo-related files:

-DSYSREPO_GROUP=sysrepo

Set systemd system service unit path:

-DSYSTEMD_UNIT_DIR=/usr/lib/systemd/system

Set NACM recovery username with unrestricted access:

-DNACM_RECOVERY_USER=root

Set NACM configuration data and 'sysrepo-monitoring' default permissions:

-DNACM_SRMON_DATA_PERM=000

Set startup and factory-default datastore data for internal modules (such as ietf-netconf-acm):

-DINTERNAL_MODULE_DATA_PATH=/etc/config/factory_default_config.xml

Useful CMake Build Options

Changing Compiler

Set CC variable:

$ CC=/usr/bin/clang cmake ..

Changing Install Path

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.

Build Modes

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" ..

Code Coverage

Based on the tests run, it is possible to generate code coverage report. But it must be enabled and these commands are needed to generate the report:

$ cmake -DENABLE_COVERAGE=ON ..
$ make
$ make coverage

Usage

All basic Sysrepo functions are available via the main header:

#include <sysrepo.h>

To compile your program with libsysrepo, it is necessary to link it using the following linker parameters:

-lsysrepo

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 it must be specified to the linker. To help with setting all the compiler's options, there is sysrepo.pc file for pkg-config(1) available in the source tree. The file is installed with the library.

Utils

There are additional utility functions available as part of Sysrepo but their headers need to be included manually. They are:

#include <sysrepo/error_format.h>

Implements basic creation and retrieval of well-known Sysrepo errors generated by callbacks. Currently, the only supported error format is NETCONF.

#include <sysrepo/netconf_acm.h>

NETCONF Access Control Module with configuration data in ietf-netconf-acm YANG module is implemented as part of sysrepo. By default, no users other than the recovery user (default root) will be allowed to write any data but should be granted read and execute permissions unless the access was modified by a NACM extension.

#include <sysrepo/subscribed_notifications.h>

This header provides additional functionality to simplify implementing ietf-subscribed-notifications and ietf-yang-push YANG modules. But these modules need to be installed manually and can be found with all their imports in modules/subscribed_notifications.

#include <sysrepo/values.h>

Utility header for working with sr_val_t Sysrepo value structures. Note that these are generally considered deprecated and libyang struct lyd_node should be used instead.

#include <sysrepo/xpath.h>

More complex handling of XPath expressions that has lots of features at the cost of efficiency.

Used run-time enviromental variables

It is possible to change the repository path by setting SYSREPO_REPOSITORY_PATH variable. Also, if SYSREPO_SHM_PREFIX is defined, it is used for all SHM files created. This way everal sysrepo instances can effectively be run simultanously on one machine.

CLI

There are 2 simple binaries sysrepoctl(1) and sysrepocfg(1) included that can execute commands related to managed YANG modules and stored YANG data, respectively. Full CLI is available only as separate projects such as:

Factory Default

The factory-default datastore contents of a module are automatically populated by the initial data used when installing the specific module and cannot be changed (unless the module is reinstalled). There is an internal subscription to the /ietf-factory-default:factory-reset RPC which performs the copying of factory-default data into all the other datastores. This RPC has a priority 10 so applications are able to subscribe to it with higher or lower priority and perform any other tasks required for a device to be rest to its factory settings.

Examples

See examples directory, which contains an example for basic API functions.

Bindings

There are no bindings for other languages directly in this project but they are available separately.

Tests

There are several tests included and 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_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

Perf

There is a performance measurement tool included that prints information about the time required to execute common use-cases of working with large YANG instance data.

To enable this test, use an option and to get representative results, enable Release build type:

$ cmake -DCMAKE_BUILD_TYPE=Release -DENABLE_PERF_TESTS=ON ..

and to run the test with seeing its output run:

$ make
$ ctest -V -R sr_perf

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