YANG Module Translation
Introduction
One key requirement for the FRR northbound architecture is that it should be possible to configure/monitor FRR using different sets of YANG models. This is especially important considering that the industry hasn’t reached a consensus to provide a single source of standard models for network management. At this moment both the IETF and OpenConfig models are widely implemented and are unlikely to converge, at least not in the short term. In the ideal scenario, management applications should be able to use either IETF or OpenConfig models to configure and monitor FRR programatically (or even both at the same time!).
But how can FRR support multiple sets of YANG models at the same time? There must be only a single source of truth that models the existing implementation accurately (the native models). Writing different code paths or callbacks for different models would be inviable, it would lead to a lot of duplicated code and extra maintenance overhead.
In order to support different sets of YANG modules without introducing the overhead of writing additional code, the solution is to create a mechanism that dynamically translates YANG instance data between non-native models to native models and vice-versa. Based on this idea, an experimental YANG module translator was implemented within the FRR northbound layer. The translator works by translating XPaths at runtime using translation tables provided by the user. The translator itself is modeled using YANG and users can create translators using simple JSON files.
A YANG module translator consists of two components: deviation modules and translation tables.
Deviation Modules
The first step when writing a YANG module translator is to create a deviations module for each module that is going be translated. This is necessary because in most cases it won’t be possible to create a perfect translator that covers the non-native models on their entirety. Some non-native modules might contain nodes that can’t be mapped to a corresponding node in the FRR native models. This is either because the corresponding functionality is not implemented in FRR or because it’s modeled in a different way that is incompatible.
An an example, ripd doesn’t have BFD support yet, so we need to create
a YANG deviation to modify the ietf-rip module and remove the bfd
container from it:
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:interfaces/ietf-rip:interface/ietf-rip:bfd" {
deviate not-supported;
}
In the example below, while both the frr-ripd and ietf-rip modules
support RIP authentication, they model the authentication data in
different ways, making translation not possible given the constraints of
the current module translator. A new deviation is necessary to remove
the authentication
container from the ietf-rip module:
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:interfaces/ietf-rip:interface/ietf-rip:authentication" {
deviate not-supported;
}
NOTE: it should be possible to translate the
ietf-rip:authentication
container if the frr-ripd module is modified to model the corresponding data in a compatible way. Another option is to improve the module translator to make more complex translations possible, instead of requiring one-to-one XPath mappings.
Sometimes creating a mapping between nodes from the native and
non-native models is possible, but the nodes have different properties
that need to be normalized to allow the translation. In the example
below, a YANG deviation is used to change the type and the default value
from a node from the ietf-rip
module.
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:timers/ietf-rip:flush-interval" {
deviate replace {
default "120";
}
deviate replace {
type uint32;
}
}
The deviation modules allow the management applications to know which parts of the custom modules (e.g. IETF/OC) can be used to configure and monitor FRR.
In order to facilitate the process of creating YANG deviation modules, the gen_yang_deviations tool was created to automate part of the process. This tool creates a “not-supported” deviation for all nodes from the given non-native module. Example:
$ tools/gen_yang_deviations ietf-rip > yang/ietf/frr-deviations-ietf-rip.yang
$ head -n 40 yang/ietf/frr-deviations-ietf-rip.yang
deviation "/ietf-rip:clear-rip-route" {
deviate not-supported;
}
deviation "/ietf-rip:clear-rip-route/ietf-rip:input" {
deviate not-supported;
}
deviation "/ietf-rip:clear-rip-route/ietf-rip:input/ietf-rip:rip-instance" {
deviate not-supported;
}
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip" {
deviate not-supported;
}
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:originate-default-route" {
deviate not-supported;
}
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:originate-default-route/ietf-rip:enabled" {
deviate not-supported;
}
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:originate-default-route/ietf-rip:route-policy" {
deviate not-supported;
}
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:default-metric" {
deviate not-supported;
}
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:distance" {
deviate not-supported;
}
deviation "/ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol/ietf-rip:rip/ietf-rip:triggered-update-threshold" {
deviate not-supported;
}
Once all existing nodes are listed in the deviation module, it’s easy to check the deviations that need to be removed or modified. This is more convenient than starting with a blank deviations module and listing manually all nodes that need to be deviated.
After removing and/or modifying the auto-generated deviations, the next step is to write the module XPath translation table as we’ll see in the next section. Before that, it’s possible to use the yanglint tool to check how the non-native module looks like after applying the deviations. Example:
$ yanglint -f tree yang/ietf/ietf-rip@2018-02-03.yang yang/ietf/frr-deviations-ietf-rip.yang
module: ietf-rip
augment /ietf-routing:routing/ietf-routing:control-plane-protocols/ietf-routing:control-plane-protocol:
+--rw rip
+--rw originate-default-route
| +--rw enabled? boolean <false>
+--rw default-metric? uint8 <1>
+--rw distance? uint8 <0>
+--rw timers
| +--rw update-interval? uint32 <30>
| +--rw holddown-interval? uint32 <180>
| +--rw flush-interval? uint32 <120>
+--rw interfaces
| +--rw interface* [interface]
| +--rw interface ietf-interfaces:interface-ref
| +--rw split-horizon? enumeration <simple>
+--ro ipv4
+--ro neighbors
| +--ro neighbor* [ipv4-address]
| +--ro ipv4-address ietf-inet-types:ipv4-address
| +--ro last-update? ietf-yang-types:date-and-time
| +--ro bad-packets-rcvd? ietf-yang-types:counter32
| +--ro bad-routes-rcvd? ietf-yang-types:counter32
+--ro routes
+--ro route* [ipv4-prefix]
+--ro ipv4-prefix ietf-inet-types:ipv4-prefix
+--ro next-hop? ietf-inet-types:ipv4-address
+--ro interface? ietf-interfaces:interface-ref
+--ro metric? uint8
rpcs:
+---x clear-rip-route
NOTE: the same output can be obtained using the
show yang module module-translator ietf ietf-rip tree
command in FRR once the ietf module translator is loaded.
In the example above, it can be seen that the vast majority of the
ietf-rip nodes were removed because of the “not-supported” deviations.
When a module translator is loaded, FRR calculates the coverage of the
translator by dividing the number of YANG nodes before applying the
deviations by the number of YANG nodes after applying the deviations.
The calculated coverage is displayed in the output of the
show yang module-translator
command:
ripd# show yang module-translator
Family Module Deviations Coverage (%)
-----------------------------------------------------------------------
ietf ietf-interfaces frr-deviations-ietf-interfaces 3.92
ietf ietf-routing frr-deviations-ietf-routing 1.56
ietf ietf-rip frr-deviations-ietf-rip 13.60
As it can be seen in the output above, the ietf module translator covers only ~13% of the original ietf-rip module. This is in part because the ietf-rip module models both RIPv2 and RIPng. Also, ietf-rip.yang contains several knobs that aren’t implemented in ripd yet (e.g. BFD support, per-interface timers, statistics, etc). Work can be done over time to increase the coverage to a more reasonable number.
Translation Tables
Below is an example of a translator for the IETF family of models:
{
"frr-module-translator:frr-module-translator": {
"family": "ietf",
"module": [
{
"name": "ietf-interfaces@2018-01-09",
"deviations": "frr-deviations-ietf-interfaces",
"mappings": [
{
"custom": "/ietf-interfaces:interfaces/interface[name='KEY1']",
"native": "/frr-interface:lib/interface[name='KEY1'][vrf='default']"
},
{
"custom": "/ietf-interfaces:interfaces/interface[name='KEY1']/description",
"native": "/frr-interface:lib/interface[name='KEY1'][vrf='default']/description"
}
]
},
{
"name": "ietf-routing@2018-01-25",
"deviations": "frr-deviations-ietf-routing",
"mappings": [
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']",
"native": "/frr-ripd:ripd/instance"
}
]
},
{
"name": "ietf-rip@2018-02-03",
"deviations": "frr-deviations-ietf-rip",
"mappings": [
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/default-metric",
"native": "/frr-ripd:ripd/instance/default-metric"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/distance",
"native": "/frr-ripd:ripd/instance/distance/default"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/originate-default-route/enabled",
"native": "/frr-ripd:ripd/instance/default-information-originate"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/timers/update-interval",
"native": "/frr-ripd:ripd/instance/timers/update-interval"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/timers/holddown-interval",
"native": "/frr-ripd:ripd/instance/timers/holddown-interval"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/timers/flush-interval",
"native": "/frr-ripd:ripd/instance/timers/flush-interval"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/interfaces/interface[interface='KEY1']",
"native": "/frr-ripd:ripd/instance/interface[.='KEY1']"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/interfaces/interface[interface='KEY1']/split-horizon",
"native": "/frr-interface:lib/interface[name='KEY1'][vrf='default']/frr-ripd:rip/split-horizon"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/ipv4/neighbors/neighbor[ipv4-address='KEY1']",
"native": "/frr-ripd:ripd/state/neighbors/neighbor[address='KEY1']"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/ipv4/neighbors/neighbor[ipv4-address='KEY1']/last-update",
"native": "/frr-ripd:ripd/state/neighbors/neighbor[address='KEY1']/last-update"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/ipv4/neighbors/neighbor[ipv4-address='KEY1']/bad-packets-rcvd",
"native": "/frr-ripd:ripd/state/neighbors/neighbor[address='KEY1']/bad-packets-rcvd"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/ipv4/neighbors/neighbor[ipv4-address='KEY1']/bad-routes-rcvd",
"native": "/frr-ripd:ripd/state/neighbors/neighbor[address='KEY1']/bad-routes-rcvd"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/ipv4/routes/route[ipv4-prefix='KEY1']",
"native": "/frr-ripd:ripd/state/routes/route[prefix='KEY1']"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/ipv4/routes/route[ipv4-prefix='KEY1']/next-hop",
"native": "/frr-ripd:ripd/state/routes/route[prefix='KEY1']/next-hop"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/ipv4/routes/route[ipv4-prefix='KEY1']/interface",
"native": "/frr-ripd:ripd/state/routes/route[prefix='KEY1']/interface"
},
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/ipv4/routes/route[ipv4-prefix='KEY1']/metric",
"native": "/frr-ripd:ripd/state/routes/route[prefix='KEY1']/metric"
},
{
"custom": "/ietf-rip:clear-rip-route",
"native": "/frr-ripd:clear-rip-route"
}
]
}
]
}
}
The main motivation to use YANG itself to model YANG module translators was a practical one: leverage libyang to validate the structure of the user input (JSON files) instead of doing that manually in the lib/yang_translator.c file (tedious and error-prone work).
Module translators can be loaded using the following CLI command:
ripd(config)# yang module-translator load /usr/local/share/yang/ietf/frr-ietf-translator.json
% Module translator "ietf" loaded successfully.
Module translators can also be loaded/unloaded programatically using the
yang_translator_load()/yang_translator_unload()
functions within the
northbound plugins. These functions are documented in the
lib/yang_translator.h file.
Each module translator must be assigned a “family” identifier (e.g. IETF, OpenConfig), and can contain mappings for multiple interrelated YANG modules. The mappings consist of pairs of custom/native XPath expressions that should be equivalent, despite belonging to different YANG modules.
Example:
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/default-metric",
"native": "/frr-ripd:ripd/instance/default-metric"
},
The nodes pointed by the custom and native XPaths must have compatible
types. In the case of the example above, both nodes point to a YANG leaf
of type uint8
, so the mapping is valid.
In the example below, the “custom” XPath points to a YANG list (typeless), and the “native” XPath points to a YANG leaf-list of strings. In this exceptional case, the types are also considered to be compatible.
{
"custom": "/ietf-routing:routing/control-plane-protocols/control-plane-protocol[type='ietf-rip:ripv2'][name='main']/ietf-rip:rip/interfaces/interface[interface='KEY1']",
"native": "/frr-ripd:ripd/instance/interface[.='KEY1']"
},
The KEY1..KEY4
values have a special meaning and are used to
preserve the list keys while performing the XPath translation.
Once a YANG module translator is loaded and validated at a syntactic level using libyang, further validations are performed to check for missing mappings (after loading the deviation modules) and incompatible YANG types. Example:
ripd(config)# yang module-translator load /usr/local/share/yang/ietf/frr-ietf-translator.json
% Failed to load "/usr/local/share/yang/ietf/frr-ietf-translator.json"
Please check the logs for more details.
2018/09/03 15:18:45 RIP: yang_translator_validate_cb: YANG types are incompatible (xpath: "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/default-metric")
2018/09/03 15:18:45 RIP: yang_translator_validate_cb: missing mapping for "/ietf-routing:routing/control-plane-protocols/control-plane-protocol/ietf-rip:rip/distance"
2018/09/03 15:18:45 RIP: yang_translator_validate: failed to validate "ietf" module translator: 2 error(s)
Overall, this translation mechanism based on XPath mappings is simple and functional, but only to a certain extent. The native models need to be reasonably similar to the models that are going be translated, otherwise the translation is compromised and a good coverage can’t be achieved. Other translation techniques must be investigated to address this shortcoming and make it possible to create more powerful YANG module translators.
YANG module translators can be evaluated based on the following metrics:
Translation potential: is it possible to make complex translations, taking several variables into account?
Complexity: measure of how easy or hard it is to write a module translator.
Speed: measure of how fast the translation can be achieved. Translation speed is of fundamental importance, especially for operational data.
Robustness: can the translator be checked for inconsistencies at load time? A module translator based on scripts wouldn’t fare well on this metric.
Round-trip conversions: can the translated data be translated back to the original format without information loss?
CLI Demonstration
As of now the only northbound client that supports the YANG module translator is the FRR embedded CLI. The confd and sysrepo plugins need to be extended to support the module translator, which might be used not only for configuration data, but also for operational data, RPCs and notifications.
In this demonstration, we’ll use the CLI configuration load
command
to load the following JSON configuration file specified using the IETF
data hierarchy:
{
"ietf-interfaces:interfaces": {
"interface": [
{
"description": "Engineering",
"name": "eth0"
}
]
},
"ietf-routing:routing": {
"control-plane-protocols": {
"control-plane-protocol": [
{
"name": "main",
"type": "ietf-rip:ripv2",
"ietf-rip:rip": {
"default-metric": "2",
"distance": "80",
"interfaces": {
"interface": [
{
"interface": "eth0",
"split-horizon": "poison-reverse"
}
]
},
"originate-default-route": {
"enabled": "true"
},
"timers": {
"flush-interval": "241",
"holddown-interval": "181",
"update-interval": "31"
}
}
}
]
}
}
}
In order to load this configuration file, it’s necessary to load the
IETF module translator first. Then, when entering the
configuration load
command, the translate ietf
parameters must
be given to specify that the input needs to be translated using the
previously loaded ietf
module translator. Example:
ripd(config)# configuration load file json /mnt/renato/git/frr/yang/example/ietf-rip.json
% Failed to load configuration:
Unknown element "interfaces".
ripd(config)#
ripd(config)# yang module-translator load /usr/local/share/yang/ietf/frr-ietf-translator.json
% Module translator "ietf" loaded successfully.
ripd(config)#
ripd(config)# configuration load file json translate ietf /mnt/renato/git/frr/yang/example/ietf-rip.json
Now let’s check the candidate configuration to see if the configuration file was loaded successfully:
ripd(config)# show configuration candidate
Configuration:
!
frr version 5.1-dev
frr defaults traditional
!
interface eth0
description Engineering
ip rip split-horizon poisoned-reverse
!
router rip
default-metric 2
distance 80
network eth0
default-information originate
timers basic 31 181 241
!
end
ripd(config)# show configuration candidate json
{
"frr-interface:lib": {
"interface": [
{
"name": "eth0",
"vrf": "default",
"description": "Engineering",
"frr-ripd:rip": {
"split-horizon": "poison-reverse"
}
}
]
},
"frr-ripd:ripd": {
"instance": {
"default-metric": 2,
"distance": {
"default": 80
},
"interface": [
"eth0"
],
"default-information-originate": true,
"timers": {
"flush-interval": 241,
"holddown-interval": 181,
"update-interval": 31
}
}
}
}
As it can be seen, the candidate configuration is identical to the one defined in the ietf-rip.json file, only the structure is different. This means that the ietf-rip.json file was translated successfully.
The ietf
module translator can also be used to do the translation in
other direction: transform data from the native format to the IETF
format. This is shown below by altering the output of the
show configuration candidate json
command using the
translate ietf
parameter:
ripd(config)# show configuration candidate json translate ietf
{
"ietf-interfaces:interfaces": {
"interface": [
{
"name": "eth0",
"description": "Engineering"
}
]
},
"ietf-routing:routing": {
"control-plane-protocols": {
"control-plane-protocol": [
{
"type": "ietf-rip:ripv2",
"name": "main",
"ietf-rip:rip": {
"interfaces": {
"interface": [
{
"interface": "eth0",
"split-horizon": "poison-reverse"
}
]
},
"default-metric": 2,
"distance": 80,
"originate-default-route": {
"enabled": true
},
"timers": {
"flush-interval": 241,
"holddown-interval": 181,
"update-interval": 31
}
}
}
]
}
}
}
As expected, this output is exactly identical to the configuration defined in the ietf-rip.json file. The module translator was able to do a round-trip conversion without information loss.
Implementation Details
A different libyang context is allocated for each YANG module translator. This is important to avoid collisions and ensure that non-native data can’t be instantiated in the running and candidate configurations.