.. _netconf-user-guide: .. |ss| raw:: html .. |se| raw:: html NETCONF User Guide ================== Overview -------- NETCONF is an XML-based protocol used for configuration and monitoring devices in the network. The base NETCONF protocol is described in `RFC-6241 `__. **NETCONF in OpenDaylight:.** OpenDaylight supports the NETCONF protocol as a northbound server as well as a southbound plugin. It also includes a set of test tools for simulating NETCONF devices and clients. Southbound (netconf-connector) ------------------------------ The NETCONF southbound plugin is capable of connecting to remote NETCONF devices and exposing their configuration/operational datastores, RPCs and notifications as MD-SAL mount points. These mount points allow applications and remote users (over RESTCONF) to interact with the mounted devices. In terms of RFCs, the connector supports: - `RFC-6241 `__ - `RFC-5277 `__ - `RFC-6022 `__ - `draft-ietf-netconf-yang-library-06 `__ **Netconf-connector is fully model-driven (utilizing the YANG modeling language) so in addition to the above RFCs, it supports any data/RPC/notifications described by a YANG model that is implemented by the device.** .. tip:: NETCONF southbound can be activated by installing ``odl-netconf-connector-all`` Karaf feature. Netconf-connector configuration ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ NETCONF connectors are configured directly through the usage of the network-topology model. You can configure new NETCONF connectors both through the NETCONF server for MD-SAL (port 2830) or RESTCONF. This guide focuses on RESTCONF. .. important:: There are 2 different endpoints related to RESTCONF protocols: - | ``http://localhost:8181/restconf`` is related to `draft-bierman-netconf-restconf-02 `__, | can be activated by installing ``odl-restconf-nb-bierman02`` Karaf feature. | This user guide uses this approach. - | ``http://localhost:8181/rests`` is related to `RFC-8040 `__, | can be activated by installing ``odl-restconf-nb-rfc8040`` Karaf feature. | In case of `RFC-8040 `__ resources for configuration and operational datastores start ``/rests/data/``, | e. g. GET http://localhost:8181/rests/data/network-topology:network-topology with response of both datastores. It's allowed to use query parameters to distinguish between them. | e. g. GET http://localhost:8181/rests/data/network-topology:network-topology?content=config for configuration datastore | and GET http://localhost:8181/rests/data/network-topology:network-topology?content=nonconfig for operational datastore. | Also in case of `RFC-8040 `__, if a data node in the path expression is a YANG leaf-list or list node, the path segment has to be constructed by having leaf-list or list node name, followed by an "=" character, then followed by the leaf-list or list value. Any reserved characters must be percent-encoded. | e. g. GET http://localhost:8181/rests/data/network-topology:network-topology/topology=topology-netconf?content=config for retrieving data from configuration datastore for topology-netconf value of topology list is equivalent to the deprecated request | |ss| GET |se| http://localhost:8181/restconf/config/network-topology:network-topology/topology/topology-netconf, which is related to `draft-bierman-netconf-restconf-02 `__. Examples in the `Spawning new NETCONF connectors`_ section include both bierman02 and rfc8040 formats Preconditions ^^^^^^^^^^^^^ 1. OpenDaylight is running 2. In Karaf, you must have the ``odl-netconf-topology`` or ``odl-netconf-clustered-topology`` feature installed. 3. Feature ``odl-restconf`` must be installed Spawning new NETCONF connectors ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ To create a new NETCONF connector you need to send the following PUT request to RESTCONF: .. list-table:: :widths: 1 5 * - bierman02 - http://localhost:8181/restconf/config/network-topology:network-topology/topology/topology-netconf/node/new-netconf-device * - rfc8040 - http://localhost:8181/rests/data/network-topology:network-topology/topology=topology-netconf/node=new-netconf-device You could use the same body to create the new NETCONF connector with a POST without specifying the node in the URL: .. list-table:: :widths: 1 5 * - bierman02 - http://localhost:8181/restconf/config/network-topology:network-topology/topology/topology-netconf * - rfc8040 - http://localhost:8181/rests/data/network-topology:network-topology/topology=topology-netconf Payload: .. tabs:: .. tab:: XML **Content-type:** ``application/xml`` **Accept:** ``application/xml`` **Authentication:** ``admin:admin`` .. code-block:: xml new-netconf-device 127.0.0.1 17830 admin admin false false 20000 0 2000 1.5 120 .. tab:: JSON **Content-type:** ``application/json`` **Accept:** ``application/json`` **Authentication:** ``admin:admin`` .. code-block:: json { "node": [ { "node-id": "new-netconf-device", "netconf-node-topology:port": 17830, "netconf-node-topology:reconnect-on-changed-schema": false, "netconf-node-topology:connection-timeout-millis": 20000, "netconf-node-topology:tcp-only": false, "netconf-node-topology:max-connection-attempts": 0, "netconf-node-topology:username": "admin", "netconf-node-topology:password": "admin", "netconf-node-topology:sleep-factor": 1.5, "netconf-node-topology:host": "127.0.0.1", "netconf-node-topology:between-attempts-timeout-millis": 2000, "netconf-node-topology:keepalive-delay": 120 } ] } Note that the device name in element must match the last element of the restconf URL. Reconfiguring an existing connector ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ The steps to reconfigure an existing connector are exactly the same as when spawning a new connector. The old connection will be disconnected and a new connector with the new configuration will be created. This needs to be done with a PUT request because the node already exists. A POST request will fail for that reason. Additionally, a PATCH request can be used to modify an existing configuration. Currently, only yang-patch (`RFC-8072 `__) is supported. The URL would be the same as the above PUT examples. Using JSON for the body, the headers needed for the request would be: Headers: - Accept: application/yang.patch-status+json - Content-Type: application/yang.patch+json Example JSON payload to modify the password entry: :: { "ietf-restconf:yang-patch" : { "patch-id" : "0", "edit" : [ { "edit-id" : "edit1", "operation" : "merge", "target" : "", "value" : { "node": [ { "node-id": "new-netconf-device", "netconf-node-topology:password" : "newpassword" } ] } } ] } } Deleting an existing connector ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ To remove an already configured NETCONF connector you need to send a DELETE request to the same PUT request URL that was used to create the device: .. list-table:: :widths: 1 5 * - bierman02 - http://localhost:8181/restconf/config/network-topology:network-topology/topology/topology-netconf/node/new-netconf-device * - rfc8040 - http://localhost:8181/rests/data/network-topology:network-topology/topology=topology-netconf/node=new-netconf-device .. note:: No body is needed to delete the node/device Connecting to a device not supporting NETCONF monitoring ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ The netconf-connector in OpenDaylight relies on ietf-netconf-monitoring support when connecting to remote NETCONF device. The ietf-netconf-monitoring support allows netconf-connector to list and download all YANG schemas that are used by the device. NETCONF connector can only communicate with a device if it knows the set of used schemas (or at least a subset). However, some devices use YANG models internally but do not support NETCONF monitoring. Netconf-connector can also communicate with these devices, but you have to side load the necessary yang models into OpenDaylight’s YANG model cache for netconf-connector. In general there are 2 situations you might encounter: **1. NETCONF device does not support ietf-netconf-monitoring but it does list all its YANG models as capabilities in HELLO message** This could be a device that internally uses only ietf-inet-types YANG model with revision 2010-09-24. In the HELLO message that is sent from this device there is this capability reported: :: urn:ietf:params:xml:ns:yang:ietf-inet-types?module=ietf-inet-types&revision=2010-09-24 **For such devices you only need to put the schema into folder cache/schema inside your Karaf distribution.** .. important:: The file with YANG schema for ietf-inet-types has to be called ietf-inet-types@2010-09-24.yang. It is the required naming format of the cache. **2. NETCONF device does not support ietf-netconf-monitoring and it does NOT list its YANG models as capabilities in HELLO message** Compared to device that lists its YANG models in HELLO message, in this case there would be no capability with ietf-inet-types in the HELLO message. This type of device basically provides no information about the YANG schemas it uses so its up to the user of OpenDaylight to properly configure netconf-connector for this device. Netconf-connector has an optional configuration attribute called yang-module-capabilities and this attribute can contain a list of "YANG module based" capabilities. So by setting this configuration attribute, it is possible to override the "yang-module-based" capabilities reported in HELLO message of the device. To do this, we need to modify the configuration of netconf-connector like in the example below: .. tabs:: .. tab:: XML **Content-type:** ``application/xml`` **Accept:** ``application/xml`` **Authentication:** ``admin:admin`` .. code-block:: xml r5 127.0.0.1 8305 root root false 30 true urn:ietf:params:xml:ns:yang:ietf-inet-types?module=ietf-inet-types&revision=2013-07-15 .. tab:: JSON **Content-type:** ``application/json`` **Accept:** ``application/json`` **Authentication:** ``admin:admin`` .. code-block:: json { "node": [ { "node-id": "device", "netconf-node-topology:host": "127.0.0.1", "netconf-node-topology:password": "root", "netconf-node-topology:username": "root", "netconf-node-topology:yang-module-capabilities": { "override": true, "capability": [ "urn:ietf:params:xml:ns:yang:ietf-inet-types?module=ietf-inet-types&revision=2013-07-15" ] }, "netconf-node-topology:port": 8305, "netconf-node-topology:tcp-only": false, "netconf-node-topology:keepalive-delay": 30 } ] } **Remember to also put the YANG schemas into the cache folder.** .. note:: For putting multiple capabilities, you just need to replicate the capability element inside yang-module-capability element. Capability element is modeled as a leaf-list. With this configuration, we would make the remote device report usage of ietf-inet-types in the eyes of netconf-connector. Connecting to a device supporting only NETCONF 1.0 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ OpenDaylight is schema-based distribution and heavily depends on YANG models. However some legacy NETCONF devices are not schema-based and implement just RFC 4741. This type of device does not utilize YANG models internally and OpenDaylight does not know how to communicate with such devices, how to validate data, or what the semantics of data are. NETCONF connector can communicate also with these devices, but the trade-offs are worsened possibilities in utilization of NETCONF mountpoints. Using RESTCONF with such devices is not suported. Also communicating with schemaless devices from application code is slightly different. To connect to schemaless device, there is a optional configuration option in netconf-node-topology model called schemaless. You have to set this option to true. Clustered NETCONF connector ~~~~~~~~~~~~~~~~~~~~~~~~~~~ To spawn NETCONF connectors that are cluster-aware you need to install the ``odl-netconf-clustered-topology`` karaf feature. .. warning:: The ``odl-netconf-topology`` and ``odl-netconf-clustered-topology`` features are considered **INCOMPATIBLE**. They both manage the same space in the datastore and would issue conflicting writes if installed together. Configuration of clustered NETCONF connectors works the same as the configuration through the topology model in the previous section. When a new clustered connector is configured the configuration gets distributed among the member nodes and a NETCONF connector is spawned on each node. From these nodes a master is chosen which handles the schema download from the device and all the communication with the device. You will be able to read/write to/from the device from all slave nodes due to the proxy data brokers implemented. You can use the ``odl-netconf-clustered-topology`` feature in a single node scenario as well but the code that uses akka will be used, so for a scenario where only a single node is used, ``odl-netconf-topology`` might be preferred. Netconf-connector utilization ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Once the connector is up and running, users can utilize the new mount point instance. By using RESTCONF or from their application code. This chapter deals with using RESTCONF and more information for app developers can be found in the developers guide or in the official tutorial application **ncmount** that can be found in the coretutorials project: - https://github.com/opendaylight/coretutorials/tree/master/ncmount Reading data from the device ^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Just invoke (no body needed): GET http://localhost:8080/restconf/operational/network-topology:network-topology/topology/topology-netconf/node/new-netconf-device/yang-ext:mount/ This will return the entire content of operation datastore from the device. To view just the configuration datastore, change **operational** in this URL to **config**. Writing configuration data to the device ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ In general, you cannot simply write any data you want to the device. The data have to conform to the YANG models implemented by the device. In this example we are adding a new interface-configuration to the mounted device (assuming the device supports Cisco-IOS-XR-ifmgr-cfg YANG model). In fact this request comes from the tutorial dedicated to the **ncmount** tutorial app. POST http://localhost:8181/restconf/config/network-topology:network-topology/topology/topology-netconf/node/new-netconf-device/yang-ext:mount/Cisco-IOS-XR-ifmgr-cfg:interface-configurations :: act mpls Interface description 32 Should return 200 response code with no body. .. tip:: This call is transformed into a couple of NETCONF RPCs. Resulting NETCONF RPCs that go directly to the device can be found in the OpenDaylight logs after invoking ``log:set TRACE org.opendaylight.controller.sal.connect.netconf`` in the Karaf shell. Seeing the NETCONF RPCs might help with debugging. This request is very similar to the one where we spawned a new netconf device. That’s because we used the loopback netconf-connector to write configuration data into config-subsystem datastore and config-subsystem picked it up from there. Invoking custom RPC ^^^^^^^^^^^^^^^^^^^ Devices can implement any additional RPC and as long as it provides YANG models for it, it can be invoked from OpenDaylight. Following example shows how to invoke the get-schema RPC (get-schema is quite common among netconf devices). Invoke: POST http://localhost:8181/restconf/operations/network-topology:network-topology/topology/topology-netconf/node/new-netconf-device/yang-ext:mount/ietf-netconf-monitoring:get-schema :: ietf-yang-types 2013-07-15 This call should fetch the source for ietf-yang-types YANG model from the mounted device. Netconf-connector + Netopeer ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ `Netopeer `__ (an open-source NETCONF server) can be used for testing/exploring NETCONF southbound in OpenDaylight. Netopeer installation ^^^^^^^^^^^^^^^^^^^^^ A `Docker `__ container with netopeer will be used in this guide. To install Docker and start the `netopeer image `__ perform following steps: 1. Install docker http://docs.docker.com/linux/step_one/ 2. Start the netopeer image: :: docker run --rm -t -p 1831:830 dockeruser/netopeer 3. Verify netopeer is running by invoking (netopeer should send its HELLO message right away: :: ssh root@localhost -p 1831 -s netconf (password root) Mounting netopeer NETCONF server ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Preconditions: - OpenDaylight is started with features ``odl-restconf-all`` and ``odl-netconf-connector-all``. - Netopeer is up and running in docker Now just follow the section: `Spawning new NETCONF connectors`_. In the payload change the: - name, e.g., to netopeer - username/password to your system credentials - ip to localhost - port to 1831. After netopeer is mounted successfully, its configuration can be read using RESTCONF by invoking: GET http://localhost:8181/restconf/config/network-topology:network-topology/topology/topology-netconf/node/netopeer/yang-ext:mount/ Northbound (NETCONF servers) ---------------------------- OpenDaylight provides 2 types of NETCONF servers: - **NETCONF server for config-subsystem (listening by default on port 1830)** - Serves as a default interface for config-subsystem and allows users to spawn/reconfigure/destroy modules (or applications) in OpenDaylight - **NETCONF server for MD-SAL (listening by default on port 2830)** - Serves as an alternative interface for MD-SAL (besides RESTCONF) and allows users to read/write data from MD-SAL’s datastore and to invoke its rpcs (NETCONF notifications are not available in the Boron release of OpenDaylight) .. note:: The reason for having 2 NETCONF servers is that config-subsystem and MD-SAL are 2 different components of OpenDaylight and require different approach for NETCONF message handling and data translation. These 2 components will probably merge in the future. .. note:: Since Nitrogen release, there is performance regression in NETCONF servers accepting SSH connections. While opening a connection takes less than 10 seconds on Carbon, on Nitrogen time can increase up to 60 seconds. Please see https://bugs.opendaylight.org/show_bug.cgi?id=9020 NETCONF server for config-subsystem ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ This NETCONF server is the primary interface for config-subsystem. It allows the users to interact with config-subsystem in a standardized NETCONF manner. In terms of RFCs, these are supported: - `RFC-6241 `__ - `RFC-5277 `__ - `RFC-6470 `__ - (partially, only the schema-change notification is available in Boron release) - `RFC-6022 `__ For regular users it is recommended to use RESTCONF + the controller-config loopback mountpoint instead of using pure NETCONF. How to do that is spesific for each component/module/application in OpenDaylight and can be found in their dedicated user guides. NETCONF server for MD-SAL ~~~~~~~~~~~~~~~~~~~~~~~~~ This NETCONF server is just a generic interface to MD-SAL in OpenDaylight. It uses the stadard MD-SAL APIs and serves as an alternative to RESTCONF. It is fully model driven and supports any data and rpcs that are supported by MD-SAL. In terms of RFCs, these are supported: - `RFC-6241 `__ - `RFC-6022 `__ - `draft-ietf-netconf-yang-library-06 `__ Notifications over NETCONF are not supported in the Boron release. .. tip:: Install NETCONF northbound for MD-SAL by installing feature: ``odl-netconf-mdsal`` in karaf. Default binding port is **2830**. Configuration ^^^^^^^^^^^^^ The default configuration can be found in file: *08-netconf-mdsal.xml*. The file contains the configuration for all necessary dependencies and a single SSH endpoint starting on port 2830. There is also a (by default disabled) TCP endpoint. It is possible to start multiple endpoints at the same time either in the initial configuration file or while OpenDaylight is running. The credentials for SSH endpoint can also be configured here, the defaults are admin/admin. Credentials in the SSH endpoint are not yet managed by the centralized AAA component and have to be configured separately. Verifying MD-SAL’s NETCONF server ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ After the NETCONF server is available it can be examined by a command line ssh tool: :: ssh admin@localhost -p 2830 -s netconf The server will respond by sending its HELLO message and can be used as a regular NETCONF server from then on. Mounting the MD-SAL’s NETCONF server ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ To perform this operation, just spawn a new netconf-connector as described in `Spawning new NETCONF connectors`_. Just change the ip to "127.0.0.1" port to "2830" and its name to "controller-mdsal". Now the MD-SAL’s datastore can be read over RESTCONF via NETCONF by invoking: GET http://localhost:8181/restconf/operational/network-topology:network-topology/topology/topology-netconf/node/controller-mdsal/yang-ext:mount .. note:: This might not seem very useful, since MD-SAL can be accessed directly from RESTCONF or from Application code, but the same method can be used to mount and control other OpenDaylight instances by the "master OpenDaylight". NETCONF stress/performance measuring tool ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ This is basically a NETCONF client that puts NETCONF servers under heavy load of NETCONF RPCs and measures the time until a configurable amount of them is processed. RESTCONF stress-performance measuring tool ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Very similar to NETCONF stress tool with the difference of using RESTCONF protocol instead of NETCONF. YANGLIB remote repository ------------------------- There are scenarios in NETCONF deployment, that require for a centralized YANG models repository. YANGLIB plugin provides such remote repository. To start this plugin, you have to install odl-yanglib feature. Then you have to configure YANGLIB either through RESTCONF or NETCONF. We will show how to configure YANGLIB through RESTCONF. YANGLIB configuration through RESTCONF ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ You have to specify what local YANG modules directory you want to provide. Then you have to specify address and port whre you want to provide YANG sources. For example, we want to serve yang sources from folder /sources on localhost:5000 adress. The configuration for this scenario will be as follows: :: PUT http://localhost:8181/restconf/config/network-topology:network-topology/topology/topology-netconf/node/controller-config/yang-ext:mount/config:modules/module/yanglib:yanglib/example Headers: - Accept: application/xml - Content-Type: application/xml Payload: :: example prefix:yanglib prefix:binding-broker-osgi-registry binding-osgi-broker /sources localhost 5000 This should result in a 2xx response and new YANGLIB instance should be created. This YANGLIB takes all YANG sources from /sources folder and for each generates URL in form: :: http://localhost:5000/schemas/{modelName}/{revision} On this URL will be hosted YANG source for particular module. YANGLIB instance also write this URL along with source identifier to ietf-netconf-yang-library/modules-state/module list. Netconf-connector with YANG library as fallback ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ There is an optional configuration in netconf-connector called yang-library. You can specify YANG library to be plugged as additional source provider into the mount's schema repository. Since YANGLIB plugin is advertising provided modules through yang-library model, we can use it in mount point's configuration as YANG library. To do this, we need to modify the configuration of netconf-connector by adding this XML :: http://localhost:8181/restconf/operational/ietf-yang-library:modules-state admin admin This will register YANGLIB provided sources as a fallback schemas for particular mount point. NETCONF Call Home ----------------- Call Home Installation ~~~~~~~~~~~~~~~~~~~~~~ ODL Call-Home server is installed in Karaf by installing karaf feature ``odl-netconf-callhome-ssh``. RESTCONF feature is recommended for configuring Call Home & testing its functionality. :: feature:install odl-netconf-callhome-ssh .. note:: In order to test Call Home functionality we recommend Netopeer or Netopeer2. See `Netopeer Call Home `__ or `Netopeer2 `__ to learn how to enable call-home on Netopeer. Northbound Call-Home API ~~~~~~~~~~~~~~~~~~~~~~~~ The northbound Call Home API is used for administering the Call-Home Server. The following describes this configuration. Global Configuration ^^^^^^^^^^^^^^^^^^^^ .. important:: The global configuration is not a part of the `RFC 8071 `__ and, therefore, subject to change. Configuring global credentials '''''''''''''''''''''''''''''' ODL Call-Home server allows user to configure global credentials, which will be used for connected over SSH transport protocol devices which does not have device-specific credentials configured. This is done by creating ``/odl-netconf-callhome-server:netconf-callhome-server/global/credentials`` with username and passwords specified. *Configuring global username & passwords to try* .. code-block:: PUT /restconf/config/odl-netconf-callhome-server:netconf-callhome-server/global/credentials HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "credentials": { "username": "example", "passwords": [ "first-password-to-try", "second-password-to-try" ] } } Configuring to accept any ssh server key using global credentials ''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''' By default Netconf Call-Home Server accepts only incoming connections from allowed devices ``/odl-netconf-callhome-server:netconf-callhome-server/allowed-devices``, if user desire to allow all incoming connections, it is possible to set ``accept-all-ssh-keys`` to ``true`` in ``/odl-netconf-callhome-server:netconf-callhome-server/global``. The name of this devices in ``netconf-topology`` will be in format ``ip-address:port``. For naming devices see Device-Specific Configuration. *Allowing unknown devices to connect* This is a debug feature and should not be used in production. Besides being an obvious security issue, this also causes the Call-Home Server to drastically increase its output to the log. .. code-block:: POST /restconf/config/odl-netconf-callhome-server:netconf-callhome-server/global HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "global": { "accept-all-ssh-keys": "true" } } Device-Specific Configuration ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Netconf Call Home server supports both of the secure transports used by the Network Configuration Protocol (NETCONF) - Secure Shell (SSH), and Transport Layer Security (TLS). Configure device to connect over SSH protocol ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Netconf Call Home Server uses device provided SSH server key (host key) to identify device. The pairing of name and server key is configured in ``/odl-netconf-callhome-server:netconf-callhome-server/allowed-devices``. This list is colloquially called a whitelist. If the Call-Home Server finds the SSH host key in the whitelist, it continues to negotiate a NETCONF connection over an SSH session. If the SSH host key is not found, the connection between the Call Home server and the device is dropped immediately. In either case, the device that connects to the Call home server leaves a record of its presence in the operational store. Configuring Device with Device-specific Credentials ''''''''''''''''''''''''''''''''''''''''''''''''''' Adding specific device to the allowed list is done by creating ``/odl-netconf-callhome-server:netconf-callhome-server/allowed-devices/device/{device}`` with device-id and connection parameters inside the ssh-client-params container. *Configuring Device with Credentials* .. code-block:: PUT /restconf/config/odl-netconf-callhome-server:netconf-callhome-server/allowed-devices/device/example HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "device": { "unique-id": "example", "ssh-client-params": { "credentials": { "username": "example", "passwords": [ "password" ] }, "ssh-host-key": "AAAAB3NzaC1yc2EAAAADAQABAAABAQDHoH1jMjltOJnCt999uaSfc48ySutaD3ISJ9fSECe1Spdq9o9mxj0kBTTTq+2V8hPspuW75DNgN+V/rgJeoUewWwCAasRx9X4eTcRrJrwOQKzb5Fk+UKgQmenZ5uhLAefi2qXX/agFCtZi99vw+jHXZStfHm9TZCAf2zi+HIBzoVksSNJD0VvPo66EAvLn5qKWQD4AdpQQbKqXRf5/W8diPySbYdvOP2/7HFhDukW8yV/7ZtcywFUIu3gdXsrzwMnTqnATSLPPuckoi0V2jd8dQvEcu1DY+rRqmqu0tEkFBurlRZDf1yhNzq5xWY3OXcjgDGN+RxwuWQK3cRimcosH" } } } Configuring Device with Global Credentials ''''''''''''''''''''''''''''''''''''''''''''''''''' It is possible to omit 'username' and 'password' for ssh-client-params, in such case values from global credentials will be used. *Example of configuring device* .. code-block:: PUT /restconf/config/odl-netconf-callhome-server:netconf-callhome-server/allowed-devices/device/example HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "device": { "unique-id": "example", "ssh-client-params": { "host-key": "AAAAB3NzaC1yc2EAAAADAQABAAABAQDHoH1jMjltOJnCt999uaSfc48ySutaD3ISJ9fSECe1Spdq9o9mxj0kBTTTq+2V8hPspuW75DNgN+V/rgJeoUewWwCAasRx9X4eTcRrJrwOQKzb5Fk+UKgQmenZ5uhLAefi2qXX/agFCtZi99vw+jHXZStfHm9TZCAf2zi+HIBzoVksSNJD0VvPo66EAvLn5qKWQD4AdpQQbKqXRf5/W8diPySbYdvOP2/7HFhDukW8yV/7ZtcywFUIu3gdXsrzwMnTqnATSLPPuckoi0V2jd8dQvEcu1DY+rRqmqu0tEkFBurlRZDf1yhNzq5xWY3OXcjgDGN+RxwuWQK3cRimcosH" } } } Deprecated configuration models for devices accessed with SSH protocol '''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''''' With `RFC 8071 `__ alignment and adding support for TLS transport following configuration models has been marked deprecated. Configuring Device with Global Credentials ''''''''''''''''''''''''''''''''''''''''''''''''''' *Example of configuring device* .. code-block:: PUT /restconf/config/odl-netconf-callhome-server:netconf-callhome-server/allowed-devices/device/example HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "device": { "unique-id": "example", "ssh-host-key": "AAAAB3NzaC1yc2EAAAADAQABAAABAQDHoH1jMjltOJnCt999uaSfc48ySutaD3ISJ9fSECe1Spdq9o9mxj0kBTTTq+2V8hPspuW75DNgN+V/rgJeoUewWwCAasRx9X4eTcRrJrwOQKzb5Fk+UKgQmenZ5uhLAefi2qXX/agFCtZi99vw+jHXZStfHm9TZCAf2zi+HIBzoVksSNJD0VvPo66EAvLn5qKWQD4AdpQQbKqXRf5/W8diPySbYdvOP2/7HFhDukW8yV/7ZtcywFUIu3gdXsrzwMnTqnATSLPPuckoi0V2jd8dQvEcu1DY+rRqmqu0tEkFBurlRZDf1yhNzq5xWY3OXcjgDGN+RxwuWQK3cRimcosH" } } Configuring Device with Device-specific Credentials ''''''''''''''''''''''''''''''''''''''''''''''''''' Call Home Server also allows to configure credentials per device basis, this is done by introducing ``credentials`` container into device-specific configuration. Format is same as in global credentials. *Configuring Device with Credentials* .. code-block:: PUT /restconf/config/odl-netconf-callhome-server:netconf-callhome-server/allowed-devices/device/example HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "device": { "unique-id": "example", "credentials": { "username": "example", "passwords": [ "password" ] }, "ssh-host-key": "AAAAB3NzaC1yc2EAAAADAQABAAABAQDHoH1jMjltOJnCt999uaSfc48ySutaD3ISJ9fSECe1Spdq9o9mxj0kBTTTq+2V8hPspuW75DNgN+V/rgJeoUewWwCAasRx9X4eTcRrJrwOQKzb5Fk+UKgQmenZ5uhLAefi2qXX/agFCtZi99vw+jHXZStfHm9TZCAf2zi+HIBzoVksSNJD0VvPo66EAvLn5qKWQD4AdpQQbKqXRf5/W8diPySbYdvOP2/7HFhDukW8yV/7ZtcywFUIu3gdXsrzwMnTqnATSLPPuckoi0V2jd8dQvEcu1DY+rRqmqu0tEkFBurlRZDf1yhNzq5xWY3OXcjgDGN+RxwuWQK3cRimcosH" } } Configure device to connect over TLS protocol ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Netconf Call Home Server allows devices to use TLS transport protocol to establish a connection towards the NETCONF device. This communication requires proper setup to make two-way TLS authentication possible for client and server. The initial step is to configure certificates and keys for two-way TLS by storing them within the netconf-keystore. *Adding a client private key credential to the netconf-keystore* .. code-block:: POST /rests/operations/netconf-keystore:add-keystore-entry HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "input": { "key-credential": [ { "key-id": "example-client-key-id", "private-key": "base64encoded-private-key", "passphrase": "passphrase" } ] } } *Associate a private key with a client and CA certificates chain* .. code-block:: POST /rests/operations/netconf-keystore:add-private-key HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "input": { "private-key": [ { "name": "example-client-key-id", "data": "key-data", "certificate-chain": [ "certificate-data" ] } ] } } *Add a list of trusted CA and server certificates* .. code-block:: POST /rests/operations/netconf-keystore:add-trusted-certificate HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "input": { "trusted-certificate": [ { "name": "example-ca-certificate", "certificate": "ca-certificate-data" }, { "name": "example-server-certificate", "certificate": "server-certificate-data" } ] } } In a second step, it is required to create an allowed device associated with a server certificate and client key. The server certificate will be used to identify and pin the NETCONF device during SSL handshake and should be unique among the allowed devices. *Add device configuration for TLS protocol to allowed devices list* .. code-block:: PUT /restconf/config/odl-netconf-callhome-server:netconf-callhome-server/allowed-devices/device/example-device HTTP/1.1 Content-Type: application/json Accept: application/json .. code-block:: json { "device": { "unique-id": "example-device", "tls-client-params": { "key-id": "example-client-key-id", "certificate-id": "example-server-certificate" } } } Operational Status ^^^^^^^^^^^^^^^^^^ Once an entry is made into the config side of "allowed-devices", the Call-Home Server will populate an corresponding operational device that is the same as the config device but has an additional status. By default, this status is *DISCONNECTED*. Once a device calls home, this status will change to one of: *CONNECTED* — The device is currently connected and the NETCONF mount is available for network management. *FAILED_AUTH_FAILURE* — The last attempted connection was unsuccessful because the Call-Home Server was unable to provide the acceptable credentials of the device. The device is also disconnected and not available for network management. *FAILED_NOT_ALLOWED* — The last attempted connection was unsuccessful because the device was not recognized as an acceptable device. The device is also disconnected and not available for network management. *FAILED* — The last attempted connection was unsuccessful for a reason other than not allowed to connect or incorrect client credentials. The device is also disconnected and not available for network management. *DISCONNECTED* — The device is currently disconnected. Rogue Devices ''''''''''''' Devices which are not on the whitelist might try to connect to the Call-Home Server. In these cases, the server will keep a record by instantiating an operational device. There will be no corresponding config device for these rogues. They can be identified readily because their device id, rather than being user-supplied, will be of the form "address:port". Note that if a device calls back multiple times, there will only be a single operatinal entry (even if the port changes); these devices are recognized by their unique host key. Southbound Call-Home API ~~~~~~~~~~~~~~~~~~~~~~~~ The Call-Home Server listens for incoming TCP connections and assumes that the other side of the connection is a device calling home via a NETCONF connection with SSH for management. The server uses port 6666 by default and this can be configured via a blueprint configuration file. The device **must** initiate the connection and the server will not try to re-establish the connection in case of a drop. By requirement, the server cannot assume it has connectivity to the device due to NAT or firewalls among others. Reading data with selected fields --------------------------------- Overview ~~~~~~~~ If user would like to read only selected fields from NETCONF device, it is possible to use fields query parameter that is described by RFC-8040. RESTCONF parses content of query parameter into format that is accepted by NETCONF subtree filtering - filtering of data is done on NETCONF server, not on NETCONF client side. This approach optimizes network traffic load, because data in which user doesn't have interest, is not transferred over network. Next advantages: * using single RESTCONF request and single NETCONF RPC for reading multiple subtrees * possibility to read only selected fields under list node across multiple hierarchies (it cannot be done without proper selection API) .. note:: More information about fields query parameter: `RFC 8071 `__ Preparation of data ~~~~~~~~~~~~~~~~~~~ Mounting NETCONF device that runs on NETCONF testtool: .. code-block:: bash curl --location --request PUT 'http://127.0.0.1:8181/rests/data/network-topology:network-topology/topology=topology-netconf/node=testtool' \ --header 'Authorization: Basic YWRtaW46YWRtaW4=' \ --header 'Content-Type: application/json' \ --data-raw '{ "node": [ { "node-id": "testtool", "netconf-node-topology:host": "127.0.0.1", "netconf-node-topology:port": 36000, "netconf-node-topology:keepalive-delay": 100, "netconf-node-topology:tcp-only": false, "netconf-node-topology:username": "admin", "netconf-node-topology:password": "admin" } ] }' Setting initial configuration on NETCONF device: .. code-block:: bash curl --location --request PUT 'http://127.0.0.1:8181/rests/data/network-topology:network-topology/topology=topology-netconf/node=testtool/yang-ext:mount/test-module:root' \ --header 'Authorization: Basic YWRtaW46YWRtaW4=' \ --header 'Content-Type: application/json' \ --data-raw '{ "root": { "simple-root": { "leaf-a": "asddhg", "leaf-b": "ffffff", "ll": [ "str1", "str2", "str3" ], "nested": { "sample-x": true, "sample-y": false } }, "list-root": { "branch-ab": 5, "top-list": [ { "key-1": "ka", "key-2": "kb", "next-data": { "switch-1": [ null ], "switch-2": [ null ] }, "nested-list": [ { "identifier": "f1", "foo": 1 }, { "identifier": "f2", "foo": 10 }, { "identifier": "f3", "foo": 20 } ] }, { "key-1": "kb", "key-2": "ka", "next-data": { "switch-1": [ null ] }, "nested-list": [ { "identifier": "e1", "foo": 1 }, { "identifier": "e2", "foo": 2 }, { "identifier": "e3", "foo": 3 } ] }, { "key-1": "kc", "key-2": "ke", "next-data": { "switch-2": [ null ] }, "nested-list": [ { "identifier": "q1", "foo": 13 }, { "identifier": "q2", "foo": 14 }, { "identifier": "q3", "foo": 15 } ] } ] } } }' Examples -------- 1. Reading whole leaf-list 'll' and leaf 'nested/sample-x' under 'simple-root' container. RESTCONF request: .. code-block:: bash curl --location --request GET 'http://localhost:8181/rests/data/network-topology:network-topology/topology=topology-netconf/node=testtool/yang-ext:mount/test-module:root/simple-root?content=config&fields=ll;nested/sample-x' \ --header 'Authorization: Basic YWRtaW46YWRtaW4=' \ --header 'Cookie: JSESSIONID=node01h4w82eorc1k61866b71qjgj503.node0' Generated NETCONF RPC request: .. code-block:: xml .. note:: Using fields query parameter it is also possible to read whole leaf-list or list without necessity to specify value / key predicate (without reading parent entity). Such scenario is not permitted in RFC-8040 paths alone - fields query parameter can be used as workaround for this case. RESTCONF response: .. code-block:: json { "test-module:simple-root": { "ll": [ "str3", "str1", "str2" ], "nested": { "sample-x": true } } } 2. Reading all identifiers of 'nested-list' under all elements of 'top-list'. RESTCONF request: .. code-block:: bash curl --location --request GET 'http://localhost:8181/rests/data/network-topology:network-topology/topology=topology-netconf/node=testtool/yang-ext:mount/test-module:root/list-root?content=config&fields=top-list(nested-list/identifier)' \ --header 'Authorization: Basic YWRtaW46YWRtaW4=' \ --header 'Cookie: JSESSIONID=node01h4w82eorc1k61866b71qjgj503.node0' Generated NETCONF RPC request: .. code-block:: xml .. note:: NETCONF client automatically fetches values of list keys since they are required for correct deserialization of NETCONF response and at the end serialization of response to RESTCONF response (JSON/XML). RESTCONF response: .. code-block:: json { "test-module:list-root": { "top-list": [ { "key-1": "ka", "key-2": "kb", "nested-list": [ { "identifier": "f3" }, { "identifier": "f2" }, { "identifier": "f1" } ] }, { "key-1": "kb", "key-2": "ka", "nested-list": [ { "identifier": "e3" }, { "identifier": "e2" }, { "identifier": "e1" } ] }, { "key-1": "kc", "key-2": "ke", "nested-list": [ { "identifier": "q3" }, { "identifier": "q2" }, { "identifier": "q1" } ] } ] } } 3. Reading value of leaf 'branch-ab' and all values of leaves 'switch-1' that are placed under 'top-list' list elements. RESTCONF request: .. code-block:: bash curl --location --request GET 'http://localhost:8181/rests/data/network-topology:network-topology/topology=topology-netconf/node=testtool/yang-ext:mount/test-module:root/list-root?content=config&fields=branch-ab;top-list/next-data/switch-1' \ --header 'Authorization: Basic YWRtaW46YWRtaW4=' \ --header 'Cookie: JSESSIONID=node01jx6o5thwae9t1ft7c2zau5zbz4.node0' Generated NETCONF RPC request: .. code-block:: xml RESTCONF response: .. code-block:: json { "test-module:list-root": { "branch-ab": 5, "top-list": [ { "key-1": "ka", "key-2": "kb", "next-data": { "switch-1": [ null ] } }, { "key-1": "kb", "key-2": "ka", "next-data": { "switch-1": [ null ] } }, { "key-1": "kc", "key-2": "ke" } ] } }