12-Telemetry Configuration Guide

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01-gRPC configuration
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Contents

Configuring gRPC·· 1

About gRPC· 1

gRPC protocol stack layers· 1

Network architecture· 1

Telemetry technology based on gRPC· 1

Telemetry modes· 2

Protocols· 2

FIPS compliance· 2

Restrictions and guidelines: gRPC configuration· 2

Configuring the gRPC dial-in mode· 3

gRPC dial-in mode configuration tasks at a glance· 3

Configuring the gRPC service· 3

Specifying the PKI domain for secure communication with collectors· 3

Configuring a gRPC user 4

Enabling gRPC logging in dial-in mode· 4

Configuring the gRPC dial-out mode· 5

gRPC dial-out mode configuration tasks at a glance· 5

Enabling the gRPC service· 5

Specifying the PKI domain for secure communication with collectors· 5

Configuring sensors· 6

Configuring collectors· 6

Configuring a subscription· 7

Enabling gRPC logging in dial-out mode· 7

Display and maintenance commands for gRPC· 8

gRPC configuration examples· 8

Example: Configuring the gRPC dial-in mode· 8

Example: Configuring the gRPC dial-out mode· 9

Protocol buffer code· 11

Protocol buffer code format 11

Proto definition files· 12

Proto definition files in dial-in mode· 12

Proto definition file in dial-out mode· 14

Obtaining proto definition files· 15

Example: Developing a gRPC collector-side application· 15

Prerequisites· 15

Generating the C++ code for the proto definition files· 15

Developing the collector-side application (dial-in mode) 15

Developing the collector-side application (dial-out mode) 28

Appendix: Methods and attributes for gNMI operations· 29

 


Configuring gRPC

About gRPC

gRPC is an open source remote procedure call (RPC) system initially developed at Google. It uses HTTP 2.0 and provides network device configuration and management methods that support multiple programming languages.

gRPC protocol stack layers

Table 1 describes the gRPC protocol stack layers.

Table 1 gRPC protocol stack layers

Layer

Description

Content layer

Defines the data of the service module.

Two peers must notify each other of the data models that they are using.

Protocol buffer encoding layer

Encodes data by using the protocol buffer code format.

gRPC layer

Defines the protocol interaction format for remote procedure calls.

HTTP 2.0 layer

Carries gRPC.

TCP layer

Provides connection-oriented reliable data links.

 

Network architecture

As shown in Figure 1, the gRPC network uses the client/server model. It uses HTTP 2.0 for packet transport.

Figure 1 gRPC network architecture

 

The gRPC network uses the following mechanism:

1.     The gRPC server listens to connection requests from clients at the gRPC service port.

2.     A user runs the gRPC client application to log in to the gRPC server, and uses methods provided in the .proto file to send requests.

3.     The gRPC server responds to requests from the gRPC client.

The device can act as the gRPC server or client.

Telemetry technology based on gRPC

Telemetry is a remote data collection technology for monitoring device performance and operating status. H3C telemetry technology uses gRPC to push data from the device to the collectors on the NMSs. As shown in Figure 2, after a gRPC connection is established between the device and NMSs, the NMSs can subscribe to data of modules on the device.

Figure 2 Telemetry technology based on gRPC

 

Telemetry modes

The device supports the following telemetry modes:

·     Dial-in mode—The device acts as a gRPC server and the collectors act as gRPC clients. A collector initiates a gRPC connection to the device to subscribe to device data.

Dial-in mode applies to small networks where collectors need to deploy configurations to devices.

Dial-in mode supports the following operations:

¡     Get—Obtains device status and settings.

¡     CLI—Executes commands on the device.

¡     gNMI—gRPC Network Management Interface operations, which include the following subtypes of operations:

-     gNMI Capabilities—Obtains the capacities of the device.

-     gNMI Get—Obtains the status and settings of the device.

-     gNMI Set—Deploys settings to the device.

-     gNMI Subscribe—Subscribes to data push services provided by the device. The data might be generated by periodical sampling or event-triggered sampling. The functionality of this operation is similar to the functionality of the dial-out mode.

·     Dial-out mode—The device acts as a gRPC client and the collectors act as gRPC servers. The device initiates gRPC connections to the collectors and pushes device data to the collectors as configured.

Dial-out mode applies to larger networks where a large number of devices need to be monitored.

Protocols

RFC 7540, Hypertext Transfer Protocol version 2 (HTTP/2)

FIPS compliance

The device supports the FIPS mode that complies with NIST FIPS 140-2 requirements. Support for features, commands, and parameters might differ in FIPS mode and non-FIPS mode. For more information about FIPS mode, see Security Configuration Guide.

gRPC is not supported in FIPS mode.

Restrictions and guidelines: gRPC configuration

Disabling the gRPC service deletes all gRPC-related settings.

Configuring the gRPC dial-in mode

gRPC dial-in mode configuration tasks at a glance

To configure the gRPC dial-in mode, perform the following tasks:

1.     Configuring the gRPC service

2.     (Optional.) Specifying the PKI domain for secure communication with collectors

3.     Configuring a gRPC user

4.     (Optional.) Enabling gRPC logging in dial-in mode

Configuring the gRPC service

1.     Enter system view.

system-view

2.     Enable the gRPC service.

grpc enable

By default, the gRPC service is disabled.

3.     (Optional.) Set the gRPC service port number.

grpc port port-number

By default, the gRPC service port number is 50051.

4.     (Optional.) Set the gRPC session idle timeout timer.

grpc idle-timeout minutes

By default, the gRPC session idle timeout timer is 5 minutes.

Specifying the PKI domain for secure communication with collectors

About this task

By default, the gRPC connection between the device and a collector does not provide data encryption service or require authentication. After you specify a PKI domain, the device and the collector will use TLS for data encryption and bidirectional certificate-based authentication to improve communication security.

Restrictions and guidelines

The specified PKI domain must already exist and has correct certificate and key settings. For more information about PKI domains, see PKI configuration in Security Configuration Guide.

After you specify the PKI domain, the gRPC service will reboot, closing the connections to collectors. The collectors must re-initiate the connections.

Procedure

1.     Enter system view.

system-view

2.     Specify the PKI domain for secure communication with collectors.

grpc pki domain domain-name

By default, no PKI domain is specified for secure communication with collectors.

Configuring a gRPC user

About this task

For gRPC clients to establish gRPC sessions with the device, you must configure local users for the gRPC clients.

Procedure

1.     Enter system view.

system-view

2.     Add a local user with the device management right.

local-user user-name [ class manage ]

3.     Configure a password for the user.

password [ { hash | simple } password ]

By default, no password is configured for a local user. A non-password-protected user can pass authentication after providing the correct username and passing attribute checks.

4.     Assign user role network-admin to the user.

authorization-attribute user-role user-role

By default, a local user is assigned the network-operator role.

5.     Authorize the user to use the HTTPS service.

service-type https

By default, no service types are authorized to a local user.

For more information about the local-user, password, authorization-attribute, and service-type commands, see AAA configuration in Security Command Reference.

Enabling gRPC logging in dial-in mode

About this task

To identify gRPC issues, enable gRPC operations logging in dial-in mode.

This feature generates gRPC operation logs in dial-in mode and sends them to the information center.

With the information center, you can configure log destinations and output rules. For more information about the information center, see Network Management and Monitoring Configuration Guide.

Restrictions and guidelines

gRPC operation logging might degrade device performance if gRPC operations are frequent. As a best practice, use gRPC operation logging only when necessary and log only gRPC operations of interest if gRPC operation logging is enabled.

Procedure

1.     Enter system view.

system-view

2.     Enable gRPC logging in dial-in mode. Choose the options to configure as needed:

¡     Enable gRPC logging for RPC operations in dial-in mode.

grpc log dial-in rpc { all | { cli | get }* }

By default, gRPC logging is disabled for RPC operations in dial-in mode.

¡     Enable gRPC logging for gNMI operations in dial-in mode.

grpc log dial-in gnmi { all | { capabilities | get | set | subscribe }* }

By default, gRPC logging is enabled for gNMI Set operations and disabled for other gNMI operations in dial-in mode.

Configuring the gRPC dial-out mode

gRPC dial-out mode configuration tasks at a glance

To configure the gRPC dial-out mode, perform the following tasks:

1.     Enabling the gRPC service

2.     (Optional.) Specifying the PKI domain for secure communication with collectors

3.     Configuring sensors

4.     Configuring collectors

5.     Configuring a subscription

6.     (Optional.) Enabling gRPC logging in dial-out mode

Enabling the gRPC service

1.     Enter system view.

system-view

2.     Enable the gRPC service.

grpc enable

By default, the gRPC service is disabled.

Specifying the PKI domain for secure communication with collectors

About this task

By default, the gRPC connection between the device and a collector does not provide data encryption service or require authentication. After you specify a PKI domain, the device and the collector will use TLS for data encryption and bidirectional certificate-based authentication to improve communication security.

Restrictions and guidelines

The specified PKI domain must already exist and has correct certificate and key settings. For more information about PKI domains, see PKI configuration in Security Configuration Guide.

After you specify the PKI domain, the gRPC service will reboot, closing the connections to collectors. The device will automatically re-initiate the connections.

Procedure

1.     Enter system view.

system-view

2.     Specify the PKI domain for secure communication with collectors.

grpc pki domain domain-name

By default, no PKI domain is specified for secure communication with collectors.

Configuring sensors

About this task

The device uses sensors to sample data. A sensor path indicates a data source.

Supported data sampling types include:

·     Event-triggered sampling—Sensors in a sensor group sample data when certain events occur. For sensor paths of this data sampling type, see NETCONF XML API Event Reference for the module.

·     Periodic sampling—Sensors in a sensor group sample data at intervals. For sensor paths of this data sampling type, see the NETCONF XML API references for the module except for NETCONF XML API Event Reference.

Procedure

1.     Enter system view.

system-view

2.     Enter telemetry view.

telemetry

3.     Create a sensor group and enter sensor group view.

sensor-group group-name

4.     Specify a sensor path.

sensor path path

To specify multiple sensor paths, execute this command multiple times.

Configuring collectors

About this task

Collectors are used to receive sampled data from network devices. For the device to communicate with collectors, you must create a destination group and add collectors to the destination group.

Restrictions and guidelines

As a best practice, configure a maximum of five destination groups. If you configure too many destination groups, system performance might degrade.

Prerequisites

To configure a collector that resides in a VPN instance, configure the VPN instance first.

Procedure

1.     Enter system view.

system-view

2.     Enter telemetry view.

telemetry

3.     Create a destination group and enter destination group view.

destination-group group-name

4.     Specify a collector.

IPv4:

ipv4-address ipv4-address [ port port-number ] [ vpn-instance vpn-instance-name ]

IPv6:

ipv6-address ipv6-address [ port port-number ] [ vpn-instance vpn-instance-name ]

The IPv6 address cannot be a link-local address. For more information about link-local addresses, see IPv6 basics configuration in Layer 3—IP Services Configuration Guide.

To specify multiple collectors, execute this command multiple times. One collector must have a different address, port, or VPN instance than the other collectors.

Configuring a subscription

About this task

A subscription binds sensor groups to destination groups. Then, the device pushes data from the specified sensors to the collectors.

Procedure

1.     Enter system view.

system-view

2.     Enter telemetry view.

telemetry

3.     Create a subscription and enter subscription view.

subscription subscription-name

4.     (Optional.) Set the DSCP value for packets sent to collectors.

dscp dscp-value

By default, the DSCP value for packets sent to collectors is 0.

A greater DSCP value represents a higher priority.

5.     (Optional.) Specify the source IP address for packets sent to collectors.

source-address { ipv4-address | interface interface-type interface-number | ipv6 ipv6-address }

By default, the device uses the primary IPv4 address of the output interface for the route to the collectors as the source address.

Changing the source IP address for packets sent to collectors causes the device to re-establish the connection to the gRPC server.

6.     Specify a sensor group.

sensor-group group-name [ sample-interval [ msec ] interval ]

Specify the sample-interval interval option for periodic sensor paths and only for periodic sensor paths.

¡     If you specify the option for event-triggered sensor paths, the sensor paths do not take effect.

¡     If you do not specify the option for periodic sensor paths, the device does not sample or push data.

7.     Specify a destination group.

destination-group group-name

Enabling gRPC logging in dial-out mode

About this task

To identify gRPC issues, enable gRPC sampling logging in dial-out mode.

This feature generates gRPC sampling logs in dial-out mode and sends them to the information center.

With the information center, you can configure log destinations and output rules. For more information about the information center, see Network Management and Monitoring Configuration Guide.

Procedure

1.     Enter system view.

system-view

2.     Enable gRPC logging in dial-out mode.

grpc log dial-out { all | { event | sample }* }

By default, gRPC logging is disabled in dial-out mode.

Display and maintenance commands for gRPC

Execute display commands in any view.

 

Task

Command

Display gRPC dial-in mode information.

display grpc

 

gRPC configuration examples

These configuration examples describe only CLI configuration tasks on the device. The collectors need to run an extra application. For information about collector-side application development, see "Developing the collector-side application."

Example: Configuring the gRPC dial-in mode

Network configuration

As shown in Figure 3, configure the gRPC dial-in mode on the device so the device acts as the gRPC server and the gRPC client can subscribe to LLDP events on the device.

Figure 3 Network diagram

 

Procedure

1.     Assign IP addresses to interfaces on the gRPC server and client and configure routes. Make sure the server and client can reach each other.

2.     Configure the device as the gRPC server:

# Enable the gRPC service.

<Device> system-view

[Device] grpc enable

# Create a local user named test. Set the password to test, and assign user role network-admin and the HTTPS service to the user.

[Device] local-user test

[Device-luser-manage-test] password simple test

[Device-luser-manage-test] authorization-attribute user-role network-admin

[Device-luser-manage-test] service-type https

[Device-luser-manage-test] quit

3.     Configure the gRPC client.

a.     Prepare a PC and install the gRPC environment on the PC. For more information, see the user guide for the gRPC environment.

b.     Obtain the H3C proto definition file and uses the protocol buffer compiler to generate code of a specific language, for example, Java, Python, C/C++, or Go.

c.     Create a client application to call the generated code.

d.     Start the application to log in to the gRPC server.

Verifying the configuration

When an LLDP event occurs on the gRPC server, verify that the gRPC client receives the event.

Example: Configuring the gRPC dial-out mode

Network configuration

As shown in Figure 4, the device is connected to a collector. The collector uses port 50050.

Configure gRPC dial-out mode on the device so the device pushes the device capability information of its interface module to the collector at 10-second intervals.

Figure 4 Network diagram

 

Procedure

# Configure IP addresses as required so the device and the collector can reach each other. (Details not shown.)

# Enable the gRPC service.

<Device> system-view

[Device] grpc enable

# Create a sensor group named test, and add sensor path ifmgr/devicecapabilities/.

[Device] telemetry

[Device-telemetry] sensor-group test

[Device-telemetry-sensor-group-test] sensor path ifmgr/devicecapabilities/

[Device-telemetry-sensor-group-test] quit

# Create a destination group named collector1. Specify a collector that uses IPv4 address 192.168.2.1 and port number 50050.

[Device-telemetry] destination-group collector1

[Device-telemetry-destination-group-collector1] ipv4-address 192.168.2.1 port 50050

[Device-telemetry-destination-group-collector1] quit

# Configure a subscription named A to bind sensor group test with destination group collector1. Set the sampling interval to 10 seconds.

[Device-telemetry] subscription A

[Device-telemetry-subscription-A] sensor-group test sample-interval 10

[Device-telemetry-subscription-A] destination-group collector1

[Device-telemetry-subscription-A] quit

Verifying the configuration

# Verify that the collector receives the device capability information of the interface module from the device at 10-second intervals. (Details not shown.)

 


Protocol buffer code

Protocol buffer code format

Google Protocol Buffers provide a flexible mechanism for serializing structured data. Different from XML code and JSON code, the protocol buffer code is binary and provides higher performance.

Table 2 compares a protocol buffer code format example and the corresponding JSON code format example.

Table 2 Protocol buffer and JSON code format examples

Protocol buffer code format example

Corresponding JSON code format example

{

1:“H3C”

2:“H3C”

3:“H3C Simware”

4:“Syslog/LogBuffer”

5:"notification": {

"Syslog": {

"LogBuffer": {

"BufferSize": 512,

"BufferSizeLimit": 1024,

"DroppedLogsCount": 0,

"LogsCount": 100,

"LogsCountPerSeverity": {

"Alert": 0,

"Critical": 1,

"Debug": 0,

"Emergency": 0,

"Error": 3,

"Informational": 80,

"Notice": 15,

"Warning": 1

},

"OverwrittenLogsCount": 0,

"State": "enable"

}

},

"Timestamp": "1527206160022"

}

}

{

"producerName": "H3C",

"deviceName": "H3C",

"deviceModel": "H3C Simware",

"sensorPath": "Syslog/LogBuffer",

"jsonData": {

"notification": {

"Syslog": {

"LogBuffer": {

"BufferSize": 512,

"BufferSizeLimit": 1024,

"DroppedLogsCount": 0,

"LogsCount": 100,

"LogsCountPerSeverity": {

"Alert": 0,

"Critical": 1,

"Debug": 0,

"Emergency": 0,

"Error": 3,

"Informational": 80,

"Notice": 15,

"Warning": 1

},

"OverwrittenLogsCount": 0,

"State": "enable"

}

},

"Timestamp": "1527206160022"

}

}

}

 

Proto definition files

You can define data structures in a proto definition file. Then, you can compile the file with utility protoc to generate code in a programing language such as Java and C++. Using the generated code, you can develop an application for a collector to communicate with the device.

H3C provides proto definition files for both dial-in mode and dial-out mode.

Proto definition files in dial-in mode

Public proto definition files

Dial-in mode supports the following public proto definition files:

·     grpc_service.proto—Defines the public RPC methods in dial-in mode.

·     gnmi.proto—Defines the public RPC methods for gNMI operations.

·     gnmi_ext.proto—Defines the extended message structures required by file gnmi.proto.

Files gnmi.proto and gnmi_ext.proto are from Google. For information about the download paths, see "Obtaining proto definition files."

The grpc_service.proto file is provided by H3C. The following are the contents of the file:

syntax = "proto2";

package grpc_service;

message GetJsonReply { // Reply to the Get method

    required string result = 1;

}

message SubscribeReply { // Subscription result

    required string result = 1;

}

message ConfigReply {   // Configuration result

    required string result = 1;

}

message ReportEvent {   // Subscribed event

    required string token_id = 1;   // Login token_id

    required string stream_name = 2; // Event stream name

    required string event_name = 3;     // Event name

    required string json_text = 4;  // Subscription result, a JSON string

}

message GetReportRequest{ // Obtains the event subscription result

    required string token_id = 1; // Returns the token_id upon a successful login

}

message LoginRequest {  // Login request parameters

    required string user_name = 1; // Username

    required string password = 2; // Password

}

message LoginReply {  // Reply to a login request

    required string token_id = 1; // Returns the token_id upon a successful login

}

message LogoutRequest { // Logout parameter

    required string token_id = 1; // token_id

}

message LogoutReply { // Reply to a logout request

    required string result = 1; // Logout result

}

message SubscribeRequest { // Event stream name

    required string stream_name = 1;

}

message CliConfigArgs { // Sends a configuration command and the parameters to the device

    required int64 ReqId = 1; // Command request ID

    required string cli = 2;  // Command string

}

message CliConfigReply { // Reply to a configuration command execution request

    required int64 ResReqId = 1; // Request ID, which corresponds to that in CliConfigArgs

  required string output = 2;    // Output from the command

    required string errors = 3;  // Command execution result

}

message DisplayCmdArgs { // Sends a display command and the parameters to the device

    required int64 ReqId = 1; // Command request ID

    required string cli = 2;  // Command string

}

message DisplayCmdReply { // Reply to a display command execution request

    required int64 ResReqId =1;  // Request ID, which corresponds to that in DisplayCmdArgs

    required string output = 2;  // Output from the command

    required string errors = 3;  // Command execution result

}

service GrpcService {   // gRPC methods

    rpc Login (LoginRequest) returns (LoginReply) {}    // Login method

    rpc Logout (LogoutRequest) returns (LogoutReply) {}     // Logout method

    rpc SubscribeByStreamName (SubscribeRequest) returns (SubscribeReply) {} // Event subscription method

    rpc GetEventReport (GetReportRequest) returns (stream ReportEvent) {} // Method for obtaining the subscribed event

    rpc CliConfig (CliConfigArgs)  returns (stream CliConfigReply) {} // Method for executing a configuration command and returning the execution result

    rpc DisplayCmdTextOutput(DisplayCmdArgs)  returns(stream DisplayCmdReply) {} // Method for executing a display command and returning the execution result

}

Proto definition files for service modules

The dial-in mode supports proto definition files for the following service modules: Device, Ifmgr, IPFW, LLDP, and Syslog.

The following are the contents of the Device.proto file, which defines the RPC methods for the Device module:

syntax = "proto2";

import "grpc_service.proto";

package  device;

message DeviceBase { // Structure for obtaining basic device information

    optional string HostName = 1;   // Device name

    optional string HostOid = 2;    // sysoid

    optional uint32 MaxChassisNum = 3; // Maximum number of chassis

    optional uint32 MaxSlotNum = 4;     // Maximum number of slots

    optional string HostDescription = 5; // Device description

}

message DevicePhysicalEntities {    // Structure for obtaining physical entity information of the device

    message Entity {

        optional uint32 PhysicalIndex = 1; // Entity index

        optional string VendorType = 2;         // Vendor type

        optional uint32 EntityClass = 3;        // Entity class

        optional string SoftwareRev = 4;        // Software version

        optional string SerialNumber = 5;   // Serial number

        optional string Model = 6;          // Model

    }

    repeated Entity entity = 1;

}

service DeviceService { // RPC methods

    rpc GetJsonDeviceBase(DeviceBase) returns (grpc_service.GetJsonReply) {} // Method for obtaining basic device information

    rpc GetJsonDevicePhysicalEntities(DevicePhysicalEntities) returns (grpc_service.GetJsonReply) {}    // Method for obtaining physical entity information of the device

}

Proto definition file in dial-out mode

The grpc_dialout.proto file defines the public RPC methods in dial-out mode. The following are the contents of the file:

syntax = "proto2";

package grpc_dialout;

message DeviceInfo{     // Pushed device information

    required string producerName = 1; // Vendor name

    required string deviceName = 2;      // Device name

    required string deviceModel = 3;  // Device model

}

message DialoutMsg{   // Format of the pushed data

    required DeviceInfo deviceMsg = 1; // Device information described by DeviceInfo

    required string sensorPath = 2; // Sensor path, which corresponds to xpath in NETCONF

    required string jsonData = 3;  // Sampled data, a JSON string

}

message DialoutResponse{  // Response from the collector. Reserved. The value is not processed.

    required string response = 1;

}

service GRPCDialout {  // Data push method

    rpc Dialout(stream DialoutMsg) returns (DialoutResponse);

}

Obtaining proto definition files

To obtain files gnmi.proto and gnmi_ext.proto, download them from the following websites:

·     https://github.com/openconfig/gnmi/tree/master/proto/gnmi/gnmi.proto

·     https://github.com/openconfig/gnmi/tree/master/proto/gnmi_ext/gnmi_ext.proto

To obtain other proto definition files, contact H3C Technical Support.

Example: Developing a gRPC collector-side application

Use a language (for example, C++) to develop a gRPC collector-side application on Linux to achieve the following goals:

·     Collect device data by using Get, gNMI Capabilities, gNMI Get, or gNMI Subscribe operations in dial-in mode or by using dial-out mode.

·     Send settings to the device by using gNMI Set or CLI operations in dial-in mode.

Prerequisites

1.     Obtain proto definition files.

¡     For Get operations in dial-in mode, obtain the grpc_service.proto file and proto definition files for service modules.

¡     For gNMI operations in dial-in mode, obtain files grpc_service.proto, gnmi.proto, and gnmi_ext.proto.

¡     For CLI operations in dial-in mode, obtain the grpc_service.proto file.

¡     For dial-out mode, obtain the grpc_dialout.proto file.

2.     Obtain utility protoc from https://github.com/google/protobuf/releases.

3.     Obtain the protobuf plug-in for C++ (protobuf-cpp) from https://github.com/google/protobuf/releases.

Generating the C++ code for the proto definition files

Dial-in mode

# Copy the required proto definition files to the current directory, for example, grpc_service.proto and BufferMonitor.proto.

$protoc --plugin=./grpc_cpp_plugin  --grpc_out=. --cpp_out=. *.proto

Dial-out mode

# Copy proto definition file grpc_dialout.proto to the current directory.

$ protoc --plugin=./grpc_cpp_plugin  --grpc_out=.  --cpp_out=. *.proto

Developing the collector-side application (dial-in mode)

In dial-in mode, the application needs to provide the code to be run on the gRPC client.

The C++ code generated from the proto definition files already encapsulates the service classes. For the gRPC client to initiate RPC requests, you only need to call the RPC method in the application.

The application performs the following operations:

·     Log in to obtain the token_id.

·     Prepare parameters for the RPC method, use the service classes generated from the proto definition files to call the RPC method, and resolve the returned result.

·     Log out.

Using Get operations

Service classes GrpcService and BufferMonitorService are used in this example.

To develop the collector-side application in dial-in mode:

1.     Create a GrpcServiceTest class.

# In the class, use the GrpcService::Stub class generated from grpc_service.proto. Implement login and logout with the Login and Logout methods generated from grpc_service.proto.

class GrpcServiceTest

{

public:

    /* Constructor functions */

   GrpcServiceTest(std::shared_ptr<Channel> channel): GrpcServiceStub(GrpcService::NewStub(channel))  {}

 

    /* Member functions */

    int Login(const std::string& username, const std::string& password);

   void Logout();

   void listen();

Status listen(const std::string& command);

 

    /* Member variable */

   std::string token;

 

private:  

   std::unique_ptr<GrpcService::Stub> GrpcServiceStub;  // Use the GrpcService::Stub class generated from grpc_service.proto.

};

2.     Customize the Login method.

# Call the Login method of the GrpcService::Stub class to allow a user who provides the correct the username and password to log in.

int GrpcServiceTest::Login(const std::string& username, const std::string& password)

{

    LoginRequest request;   // Username and password.

    request.set_user_name(username);

    request.set_password(password);

 

LoginReply reply;      

ClientContext context;

 

   // Call the Login method.

   Status status = GrpcServiceStub->Login(&context, request, &reply);

   if (status.ok())

    {

       std::cout << "login ok!" << std::endl;

        std::cout <<"token id is :" << reply.token_id() << std::endl;

       token = reply.token_id();  // The login succeeds. The token is obtained.

        return 0;

    }

    else{                                       

       std::cout << status.error_code() << ": " << status.error_message()

                   << ". Login failed!" << std::endl;

        return -1;

    }

}

3.     Initiate an RPC request to the device. In this example, the application subscribes to interface packet drop events.

rpc SubscribePortQueDropEvent(PortQueDropEvent) returns (grpc_service.SubscribeReply) {}

4.     Create the BufMon_GrpcClient class to encapsulate the RPC method.

# Use the BufferMonitorService::Stub class generated from BufferMonitor.proto to call the RPC method.

class BufMon_GrpcClient

{

public:

    BufMon_GrpcClient(std::shared_ptr<Channel> channel): mStub(BufferMonitorService::NewStub(channel))

    {}

   

    std::string BufMon_Sub_AllEvent(std::string token);

    std::string BufMon_Sub_BoardEvent(std::string token);

    std::string BufMon_Sub_PortOverrunEvent(std::string token);

    std::string BufMon_Sub_PortDropEvent(std::string token);

 

    /* Get entries */

    std::string BufMon_Sub_GetStatistics(std::string token);

    std::string BufMon_Sub_GetGlobalCfg(std::string token);

    std::string BufMon_Sub_GetBoardCfg(std::string token);

    std::string BufMon_Sub_GetNodeQueCfg(std::string token);

    std::string BufMon_Sub_GetPortQueCfg(std::string token);

 

private:

   std::unique_ptr<BufferMonitorService::Stub> mStub; // Use the class generated from BufferMonitor.proto.

};

5.     Use std::string BufMon_Sub_PortDropEvent(std::string token) to implement interface packet drop event subscription.

std::string BufMon_GrpcClient::BufMon_Sub_PortDropEvent(std::string token)

{

    std::cout << "-------BufMon_Sub_PortDropEvent-------- " << std::endl;

 

   PortQueDropEvent stNodeEvent;

   PortQueDropEvent_PortQueDrop* pstParam = stNodeEvent.add_portquedrop();

 

    UINT uiIfIndex = 0;

    UINT uiQueIdx = 0;

    UINT uiAlarmType = 0;

 

    std::cout<<"Please input interface queue info : ifIndex queIdx alarmtype " << std::endl;

    cout<<"alarmtype : 1 for ingress; 2 for egress; 3 for port headroom"<<endl;

 

    std::cin>>uiIfIndex>>uiQueIdx>>uiAlarmType; // Set the subscription parameters and interface index.

   pstParam->set_ifindex(uiIfIndex);

    pstParam->set_queindex(uiQueIdx);

    pstParam->set_alarmtype(uiAlarmType);

 

    ClientContext context;

 

   /* Token needs to be added to context */ // Set the token_id to be returned after a successful login

   std::string key = "token_id";

   std::string value = token;

   context.AddMetadata(key, value);

  

   SubscribeReply reply;

   Status status = mStub->SubscribePortQueDropEvent(&context,stNodeEvent,&reply); // Call the RPC method.

 

   return reply.result();

}

6.     Use a loop to listen for event reports.

# Implement this method in the GrpcServiceTest class.

void GrpcServiceTest::listen()

{

    GetReportRequest reportRequest;

    ClientContext context;

    ReportEvent reportedEvent;

  

   /* Add the token to the request */

   reportRequest.set_token_id(token);

 

    std::unique_ptr< ClientReader< ReportEvent>> reader(GrpcServiceStub->GetEventReport(&context, reportRequest)); // Use GetEventReport (which is generated from grpc_service.proto) to obtain event information.

 

    std::string streamName;   

    std::string eventName;

    std::string jsonText;

   std::string token;

 

    JsonFormatTool jsonTool;

 

   std::cout << "Listen to server for Event" << std::endl;

    while(reader->Read(&reportedEvent) ) // Read the received event report.

    {

        streamName = reportedEvent.stream_name();

        eventName = reportedEvent.event_name();

       jsonText = reportedEvent.json_text();

       token = reportedEvent.token_id();

 

         std::cout << "/***********EVENT COME**************/" << std::endl;

       std::cout << "TOKEN: " << token << std::endl;

       std::cout << "StreamName: "<< streamName << std::endl;

       std::cout << "EventName: " << eventName << std::endl;

       std::cout << "JsonText without format: " << std::endl << jsonText << std::endl;

        std::cout << std::endl;

       std::cout << "JsonText Formated: " << jsonTool.formatJson(jsonText) << std::endl;

        std::cout << std::endl;

    }

 

    Status status = reader->Finish();

    std::cout << "Status Message:" << status.error_message() << "ERROR code :" << status.error_code();

}  // Login and RPC request finished.

7.     Call the Logout method to log out.

void GrpcServiceTest:: Logout ()

{

    LogoutRequest request;

   request.set_token_id(token);

   LogoutReply reply;

   ClientContext context;

   Status status = mStub->Logout(&context, request, &reply);

std::cout << "Logout! :" << reply.result() << std::endl;

}

Using gNMI Capabilities operations

1.     Create a GrpcServiceTest class.

See step 1 in "Using Get operations."

2.     Customize the Login method.

See step 2 in "Using Get operations."

3.     Initiate an RPC request to the device.

rpc Capabilities(CapabilityRequest) returns (CapabilityResponse);

4.     Create the gnmi_client class to encapsulate the RPC method.

class gnmi_client

{

public:

   explicit gnmi_client(const std::string &address,const std::string &tokenId);

 

   bool TestCapabilities();

   bool TestGet();

   bool TestSet();

   bool TestSubscribePool();

   bool TestSubscribeOnce();

   bool TestSubscribeStream();

   bool TestSubscribeStreamWithAlias();

 

 

private:

   void PrintCapabilityResponse(const gnmi::CapabilityResponse &response);

   void PrintGetResponse(const gnmi::GetResponse &response);

   void PrintSubscribeResponse(const gnmi::SubscribeResponse &response);

   void PrintSubscribeRequest(const gnmi::SubscribeRequest &request);

   void PrintGetRequest(const gnmi::GetRequest &request);

   void PrintSetRequest(const gnmi::SetRequest &request);

 

   void FillGetRequest(gnmi::GetRequest &request);

   void FillSetRequest(gnmi::SetRequest &request);

   void FillSubscribeRequestByOnce(gnmi::SubscribeRequest &request);

   void FillSubscribeRequestByPool(gnmi::SubscribeRequest &request);

   void FillSubscribeRequestByStream(gnmi::SubscribeRequest &request);

   void FillSubscribePool(gnmi::SubscribeRequest &request);

   void FillSubscribeAlias(gnmi::SubscribeRequest &request);

 

private:

   std::unique_ptr<gnmi::gNMI::Stub> mStubGnmiService;

   std::string mTokenID;  

};

5.     Use the TestCapabilities() method to obtain the capabilities.

bool gnmi_client::TestCapabilities()

{

   CapabilityRequest request;

   CapabilityResponse response;

   ClientContext context;

 

  context.AddMetadata("token_id", mTokenID);

 

   std::cout << std::endl << "CapabilitiesRequest => " << std::endl;

   Status ret = mStubGnmiService->Capabilities(&context,request,&response);

 

   if( StatusCode::OK != ret.error_code() )

   {

       cout << "TestCapabilities ErrorMessage:" << ret.error_message() << endl;

       return false;

   }

   else

   {

       PrintCapabilityResponse(response);

       return true;

   }

}

6.     Call the Logout method to log out.

See step 7 in "Using Get operations."

Using gNMI Get operations

1.     Create a GrpcServiceTest class.

See step 1 in "Using Get operations."

2.     Customize the Login method.

See step 2 in "Using Get operations."

3.     Initiate an RPC request to the device.

rpc Get(GetRequest) returns (GetResponse);

4.     Create the gnmi_client class to encapsulate the RPC method.

See step 4 in "Using gNMI Capabilities operations."

5.     Use the TestGet() method to obtain the Device/Base/HostName.

bool gnmi_client::TestGet()

{

  GetRequest request;

  FillGetRequest(request);

  PrintGetRequest(request);

  GetResponse response;

  ClientContext context;

 

  context.AddMetadata("token_id", mTokenID);

 

  Status ret = mStubGnmiService->Get(&context,request,&response);

 

  if( StatusCode::OK != ret.error_code() )

  {

    cout << "TestGet ErrorMessage:" << ret.error_message() << endl;

    return false;

  }

  else

  {

    PrintGetResponse(response);

    return true;

  }

}

 

void gnmi_client::FillGetRequest(gnmi::GetRequest &request)

{

   auto prefix = request.mutable_prefix();

   auto pathelem01 = prefix->add_elem();

   pathelem01->set_name("Device");

 

   auto path1 = request.add_path();

   auto pathelem02 = path1->add_elem();

   pathelem02->set_name("Base");

   auto pathelem03 = path1->add_elem();

   pathelem03->set_name("HostName");

}

6.     Call the Logout method to log out.

See step 7 in "Using Get operations."

Using gNMI Set operations

1.     Create a GrpcServiceTest class.

See step 1 in "Using Get operations."

2.     Customize the Login method.

See step 2 in "Using Get operations."

3.     Initiate an RPC request to the device.

This example uses the Device module.

rpc Set(SetRequest) returns (SetResponse)

4.     Create a gNMITest class to encapsulate the RPC method.

Use the gNMI::Stub class that is automatically created by gnmi.proto to call the RPC method.

class gNMITest

{

public:

gNMITest(std::shared_ptr<Channel> channel, const std::string tokenId ):

                                             mStubGrpcService(GrpcService::NewStub(channel)),

                                             mStubgNMIService(gNMI::NewStub(channel)),

                                             mTokenID(tokenId ){}

     SetResponse TestSetResponseInformation(SetRequest &request, const std::string tokenId);

/*---delete: Device/Base/HostName. Restore the default for HostName -----------*/

SetResponse DeleteDeviceBaseHostName();    /* delete: Device Base/HostName*/

 

/* update: Device/Base/HostName, string_val("string_hostname") */

SetResponse UpdateDeviceBaseHostNameStringVal();

 

/* replace: Device/Base/HostName, string_val("string_hostname") */

REPL_001 SetResponse ReplaceDeviceBaseHostNameStringVal();

 

private:

std::unique_ptr<GrpcService::Stub> mStubGrpcService;

std::unique_ptr<gNMI::Stub> mStubgNMIService;

std::string mTokenID;

};

5.     Use customized methods to perform gNMI Set operations on service data, for example, on the Device module.

// Call the Set method to implement communication between client and server and get the response.

SetResponse gNMITest::TestSetResponseInformation(SetRequest &request, const std::string tokenId)

{

SetResponse reply;

ClientContext context;

context.AddMetadata("token_id", tokenId);

   

/* Call the Set method */

Status ret = mStubgNMIService->Set(&context,request,&reply);

if( StatusCode::OK != ret.error_code())

{

std::cout<<"error: "<<ret.error_message()<<std::endl;

}

return reply; 

}

// Delete operation

SetResponse gNMITest:: DeleteDeviceBaseHostName ()     /* prefix == Device/Base */

{

SetRequest request;

/* SetRequest->prefix */

Path       *path01 = request.mutable_prefix();

PathElem   *pathelem01 = path01->add_elem();  

pathelem01->set_name("Device");

PathElem   *pathelem02 = path01->add_elem();

pathelem02->set_name("Base");

      

/* SetRequest->delete */

Path       *path02 = request.add_delete_();

PathElem   *pathelem03 = path02->add_elem();

pathelem03->set_name("HostName");

/* Gather response info. */

return TestSetResponseInformation(request, mTokenID); 

}

// Update operation

SetResponse gNMITest::UpdateDeviceBaseHostNameStringVal()

{

SetRequest request;

  

/* SetRequest->prefix */

Path       *path01 = request.mutable_prefix();

PathElem   *pathelem01 = path01->add_elem();  

pathelem01->set_name("Device");

PathElem   *pathelem02 = path01->add_elem();

pathelem02->set_name("Base");

  

/* SetRequest->update */

Update     *update01 = request.add_update();

Path       *path02 = update01->mutable_path();

PathElem   *pathelem03 = path02->add_elem();

pathelem03->set_name("HostName");

  

TypedValue *typevalue01 = update01->mutable_val();

typevalue01->set_string_val("string_hostname");

  

/* Gather response info. */

return TestSetResponseInformation(request, mTokenID);

}

// Replace operation

SetResponse gNMITest::ReplaceDeviceBaseHostNameStringVal()

{

SetRequest request;

  

/* SetRequest->prefix */

Path       *path01 = request.mutable_prefix();

PathElem   *pathelem01 = path01->add_elem();  

pathelem01->set_name("Device");

PathElem   *pathelem02 = path01->add_elem();

pathelem02->set_name("Base");

  

/* SetRequest->replace */

Update     *replace01 = request.add_replace();

Path       *path02 = replace01->mutable_path();

PathElem   *pathelem03 = path02->add_elem();

pathelem03->set_name("HostName");

  

TypedValue *typevalue01 = replace01->mutable_val();

typevalue01->set_string_val("string_hostname");

 

/* Gather response info. */

return TestSetResponseInformation(request, mTokenID);

}

6.     Call the Logout method to log out.

See step 7 in "Using Get operations."

Using gNMI Subscribe operations

1.     Create a GrpcServiceTest class.

See step 1 in "Using Get operations."

2.     Customize the Login method.

See step 2 in "Using Get operations."

3.     Initiate an RPC request to the device.

rpc Subscribe(stream SubscribeRequest) returns (stream SubscribeResponse);

4.     Create the gnmi_client class to encapsulate the RPC method.

See step 4 in "Using gNMI Capabilities operations."

5.     Create a subscribe method.

void gnmi_client::FillSubscribeRequestByOnce(gnmi::SubscribeRequest &request)

{

  auto subscribeList = request.mutable_subscribe();

 

  auto prefix = subscribeList->mutable_prefix();

  auto pathelem01 = prefix->add_elem();

  pathelem01->set_name("LLDP");

 

  auto subscribe = subscribeList->add_subscription();

 

  auto path = subscribe->mutable_path();

  auto pathelem02 = path->add_elem();

  pathelem02->set_name("NeighborEvent");

 

  auto pathelem03 = path->add_elem();

  pathelem03->set_name("Neighbor");

  (*pathelem03->mutable_key())["IfName"] = "xxx";

 

   subscribeList->set_mode(::gnmi::SubscriptionList_Mode_ONCE);

   subscribeList->set_encoding(::gnmi::JSON);

}

 

void gnmi_client::FillSubscribeRequestByPool(gnmi::SubscribeRequest &request)

{

   auto subscribeList =  request.mutable_subscribe();

 

   auto prefix = subscribeList->mutable_prefix();

   auto pathelem01 = prefix->add_elem();

   pathelem01->set_name("Device");

 

   auto subscribe = subscribeList->add_subscription();

  

   auto path = subscribe->mutable_path();

   auto pathelem02 = path->add_elem();

   pathelem02->set_name("CPUs");

   auto pathelem03 = path->add_elem();

   pathelem03->set_name("CPU");

   auto pathelem04 = path->add_elem();

   pathelem04->set_name("CPUUsage");

 

   subscribeList->set_mode(::gnmi::SubscriptionList_Mode_POLL);

   subscribeList->set_encoding(::gnmi::JSON);

}

 

void gnmi_client::FillSubscribeRequestByStream(gnmi::SubscribeRequest &request)

{

    auto subscribeList =  request.mutable_subscribe();

 

    auto prefix = subscribeList->mutable_prefix();

    auto pathelem01 = prefix->add_elem();

    pathelem01->set_name("Diagnostic");

 

    auto subscribe = subscribeList->add_subscription();

    

    auto path = subscribe->mutable_path();

    auto pathelem02 = path->add_elem();

    pathelem02->set_name("CPUEvent");

    auto pathelem03 = path->add_elem();

    pathelem03->set_name("CPU");

    (*pathelem03->mutable_key())["Chassis#condition"] = "equal:1";

    subscribe->set_mode(::gnmi::ON_CHANGE);

    subscribe->set_sample_interval(1000);

    subscribe->set_suppress_redundant(false);

    subscribe->set_heartbeat_interval(1000);

    

    subscribeList->set_mode(::gnmi::SubscriptionList_Mode_STREAM);

    subscribeList->set_encoding(::gnmi::JSON);

}

 

void gnmi_client::FillSubscribeAlias(gnmi::SubscribeRequest &request)

{

   auto aliases = request.mutable_aliases();

   auto alias = aliases->add_alias();

 

   auto path = alias->mutable_path();

   auto pathelem01 = path->add_elem();

   pathelem01->set_name("Device");

   auto pathelem02 = path->add_elem();

   pathelem02->set_name("CPUs");

   auto pathelem03 = path->add_elem();

   pathelem03->set_name("CPU");

   auto pathelem04 = path->add_elem();

   pathelem04->set_name("CPUUsage");

 

   alias->set_alias("#cpu_usage");

}

6.     Call the Logout method to log out.

See step 7 in "Using Get operations."

Using CLI operations

1.     Create a GrpcServiceTest class.

See step 1 in "Using Get operations."

2.     Customize the Login method.

See step 2 in "Using Get operations."

3.     Initiate an RPC request to the device.

This example uses the CliConfig method in file grpc_service.proto.

rpc CliConfig (CliConfigArgs)  returns (stream CliConfigReply) {}

4.     Use the GrpcServiceTest class to encapsulate the RPC method in the same way you do for Get operations.

5.     Use a customized method to support CliConfig operations.

// Make a thread to listen to the sever and get messages

Status GrpcServiceTest::listen(const std::string& command)

{

CliConfigArgs reportRequest;

ClientContext context;

CliConfigReply reportedEvent;

std::string key = "token_id";

std::string value = token;

context.AddMetadata(key, value);

/* Add token to request */

reportRequest.set_reqid(12345678);

reportRequest.set_cli(command);

 

std::unique_ptr< ClientReader< CliConfigReply>> reader(mStub->CliConfig(&context, reportRequest));

  

std::string streamName;

std::string output;

int64 resreqid;

 

std::cout << "Command result" << std::endl;

while( reader->Read(&reportedEvent) )

{

streamName = reportedEvent.errors();

output = reportedEvent.output();

resreqid = reportedEvent.resreqid();

std::cout << "resreqid: "<< resreqid << std::endl;

std::cout << "errors: "<< streamName << std::endl;

std::cout << "output: \n"<< output << "\n"<< std::endl;

}

Status status = reader->Finish();

return status;

}

6.     Use a loop in the main function to wait for commands.

Use the GrpcServiceTest class.

int main(int argc, char *argv[])

{

const char *cmd;

unsigned int i = 0;

unsigned int cycle = 0;

  

if (4 == argc)

{

g_server_address = argv[1];

g_username = argv[2];

g_password = argv[3];

std::cout << "server_address: " << g_server_address <<std::endl;

std::cout << "username: " << g_username << " " << "password: " << g_password << std::endl;

auto channel = grpc::CreateChannel(g_server_address,grpc::InsecureChannelCredentials());

 // 1. Log in

GrpcServiceTest reporter(channel);

if(0 != reporter.Login(g_username, g_password))

       {

           return 0;

       }

       while(1)

       {// 2. Read a command and execute the command

               std::cout<<"\n\nPlease Input Command:\n";

               getline(std::cin,g_command);            // Read a command

               Status status = reporter.listen(g_command);

               if (!status.ok())

              {

                   std::cout << status.error_code() << ": " << status.error_message() << std::endl;

                   break;

              }

       }

    } 

   std::cout<<"Complete exec Command."<<std::endl;

   return 0;

}

7.     Call the Logout method to log out.

See step 7 in "Using Get operations."

Developing the collector-side application (dial-out mode)

In dial-out mode, the application needs to provide the gRPC server code so the collector can receive and resolve data obtained from the device.

The application performs the following operations:

·     Inherit the automatically generated GRPCDialout::Service class, reload the automatically generated RPC Dialout service, and resolve the fields.

·     Register the RPC service with the specified listening port.

To develop the collector-side application in dial-out mode:

1.     Inherit and overload RPC service Dialout.

# Create class DialoutTest and inherit GRPCDialout::Service.

class DialoutTest final : public GRPCDialout::Service { // Overload the automatically generated abstract class.

    Status Dialout(ServerContext* context, ServerReader< DialoutMsg>* reader, DialoutResponse* response) override; // Implement RPC method Dialout.

};

2.     Register the DialoutTest service as a gRPC service and specify the listening port.

using grpc::Server;

using grpc::ServerBuilder;

std::string server_address("0.0.0.0:60057"); // Specify the address and port to listen to.

DialoutTest dialout_test; // Define the object declared in step 1.

ServerBuilder builder;

builder.AddListeningPort(server_address, grpc::InsecureServerCredentials());// Add the listening port.

builder.RegisterService(&dialout_test); // Register the service.

std::unique_ptr<Server> server(builder.BuildAndStart()); // Start the service.

server->Wait();

3.     Implement the Dialout method and data resolution.

Status DialoutTest::Dialout(ServerContext* context, ServerReader< DialoutMsg>* reader, DialoutResponse* response)

{

        DialoutMsg msg;

 

        while( reader->Read(&msg))

        {

            const DeviceInfo &device_msg = msg.devicemsg();

            std::cout<< "Producer-Name: " << device_msg.producername() << std::endl;

            std::cout<< "Device-Name: " << device_msg.devicename() << std::endl;

            std::cout<< "Device-Model: " << device_msg.devicemodel() << std::endl;

            std::cout<<"Sensor-Path: " << msg.sensorpath()<<std::endl;

            std::cout<<"Json-Data: " << msg.jsondata()<<std::endl;

            std::cout<<std::endl;

        }

        response->set_response("test");

 

        return Status::OK;

}

4.     After obtaining the DialoutMsg object (generated from the proto definition file) through the Read method, call the method to obtain the field values.

Appendix: Methods and attributes for gNMI operations

gNMI operations are intended for data tables and event tables.

·     Some data tables are periodically reported and some data tables are reported only when triggered. The latter data tables are not supported in the current software version.

·     All event tables are reported only when triggered.

Methods for adding columns in gNMI operations

Table 3 describes the methods for adding columns in gNMI operations.

Table 3 Methods for adding columns in gNMI operations

Request description

Sample request

Sample client-side code

Set a column of the key.
For example:
ifTypeExt=colvalue

path:
<
    elem:
    <
     name:"Interface"
     key:
     <
        name:"ifTypeExt"
        value:"colvalue"
     >
    >
>

  auto pathelem01 = path->add_elem();
  pathelem01->set_name("Interface");
  (*pathelem01->mutable_key())["ifTypeExt"] = "colvalue";

Set an attribute for a column of the key.
For example, set the attr attribute of ifTypeExt:
attr=attrvalue

path:
<
    elem:
    <
     name:"Interface"
     key:
     <
        name:"ifTypeExt#attr"
        value:"attrvalue"
     >
    >
>

  auto pathelem01 = path->add_elem();
  pathelem01->set_name("Interface");
  (*pathelem01->mutable_key())["ifTypeExt#attr"] = "attrvalue";

Set a column in a group of the key.
For example, set the Upper column of the Broadcast group:
Upper=colvalue

path:
<
    elem:
    <
     name:"Interface"
     key:
     <
        name:"Broadcast:Upper"
        value:"colvalue"
     >
    >
>

  auto pathelem01 = path->add_elem();
  pathelem01->set_name("Interface");
  (*pathelem01->mutable_key())["Broadcast:Upper"] = "colvalue";

Set an attribute for a column in a group of the key.
For example, set the attr attribute of the Upper column of the Broadcast group:
attr=attrvalue

path:
<
    elem:
    <
     name:"Interface"
     key:
     <
        name:"Broadcast:Upper#attr"
        value:"attrvalue"
     >
    >
>

  auto pathelem01 = path->add_elem();
  pathelem01->set_name("Interface");
  (*pathelem01->mutable_key())["Broadcast:Upper#attr"] = "attrvalue";

Set an attribute of a column through the key:
For example, set the attr attribute of Interface:
attr=attrvalue

path:
<
    elem:
    <
     name:"Interface"
     key:
     <
        name:"#attr"
        value:"attrvalue"
     >
    >
>

  auto pathelem01 = path->add_elem();
  pathelem01->set_name("Interface");
  (*pathelem01->mutable_key())["#attr"] = "attrvalue";

Set a column or column attribute in JSON:
For example:
Set Upper to colvalue and set the attr attribute of Upper to attrvalue.

{
 "Upper": {
  "#text": "colvalue",
  "@#attr": "attrvalue"
 }
}

{
 "Upper": {
  "#text": "colvalue",
  "@#attr": "attrvalue"
 }
}

Different YANG modules might use the same top-level node identifier in their respective namespaces. To identify the top-level node in a particular module namespace, add the prefix of that namespace in front of the node identifier and separate them with a colon (:). If you do not specify the module namespace, the system will go to the first node that it finds.

For example, the namespace prefix for the interfaces YANG module published by OpenConfig is oc-if. To identify the interfaces node in this module, add prefix oc-if: to the node identifier.

path:
<
    elem:
    <
     name:"oc-if:interfaces"
    >
>

  auto pathelem01 = path->add_elem();
  pathelem01->set_name("oc-if:interfaces");

 

gNMI Get operation attributes

gNMI Get operations support the following attributes:

·     regExp—Regular expression.

To implement a complex filtering with characters, you can add a regExp attribute for a specific column.

The following example obtains the interface descriptions that contain only characters in upper case:

auto prefix = request.mutable_prefix();

 auto pathelem01 = prefix->add_elem();

 pathelem01->set_name("Ifmgr");

 

 auto path1 = request.add_path();

 auto pathelem02 = path1->add_elem();

 pathelem02->set_name("Interfaces");

 auto pathelem03 = path1->add_elem();

 pathelem03->set_name("Interface");

 auto pathelem04 = path1->add_elem();

 pathelem04->set_name("Description");

 (*pathelem04->mutable_key())["#regExp"] = "^[A-Z]*$";

·     match—Conditional match.

Table 4 describes the conditional match operators.

Table 4 Conditional match operators

Operation

Operator

Description

More than

match="more:value"

More than the specified value. The supported data types include date, digit, and character string.

Less than

match="less:value"

Less than the specified value. The supported data types include date, digit, and character string.

Not less than

match="notLess:value"

Not less than the specified value. The supported data types include date, digit, and character string.

Not more than

match="notMore:value"

Not more than the specified value. The supported data types include date, digit, and character string.

Equal to

match="equal:value"

Equal to the specified value. The supported data types include date, digit, character string, OID, and BOOL.

Not equal to

match="notEqual:value"

Not equal to the specified value. The supported data types include date, digit, character string, OID, and BOOL.

Include

match="include:string"

Includes the specified string. The supported data types include only character string.

Not include

match="exclude:string"

Excludes the specified string. The supported data types include only character string.

Start with

match="startWith:string"

Starts with the specified string. The supported data types include character string and OID.

End with

match="endWith:string"

Ends with the specified string. The supported data types include only character string.

 

The following example obtains extension information about the entity whose CPU usage is more than 50%:

auto prefix = request.mutable_prefix();

 auto pathelem01 = prefix->add_elem();

 pathelem01->set_name("Device");

 

 auto path1 = request.add_path();

 auto pathelem02 = path1->add_elem();

 pathelem02->set_name("ExtPhysicalEntities");

 auto pathelem03 = path1->add_elem();

 pathelem03->set_name("Entity");

 auto pathelem04 = path1->add_elem();

 pathelem04->set_name("CpuUsage");

 (*pathelem04->mutable_key())["#match"] = "more:50";

·     valuetype—Attribute value type.

When obtaining interface information, the device cannot identify whether an integer value for the IfIndex or vrfindex column represents an interface name or index. To resolve the issue, you can use the valuetype attribute to specify the value type.

The valuetype attribute has the following values:

 

Value

Description

name

The column is carrying a name.

index

The column is carrying an index.

auto

Default value. The device uses the value of the column as a name for interface matching. If no match is found, the device uses the value as an index for interface matching.

 

The following example sets the valuetype attribute to index and set the index to 1 for IfIndex:

auto prefix = request.mutable_prefix();

 auto pathelem01 = prefix->add_elem();

 pathelem01->set_name("VLAN");

 

 auto path1 = request.add_path();

 auto pathelem02 = path1->add_elem();

 pathelem02->set_name("TrunkInterfaces");

 auto pathelem03 = path1->add_elem();

 pathelem03->set_name("Interface");

(*pathelem03->mutable_key())["IfIndex"] = "1";

(*pathelem03->mutable_key())["IfIndex#valuetype"] = "index";

·     count—Specifies the data entry quantity.

The example sets the count attribute:

auto prefix = request.mutable_prefix();

 auto pathelem01 = prefix->add_elem();

 pathelem01->set_name("Syslog");

 

 auto path1 = request.add_path();

 auto pathelem02 = path1->add_elem();

 pathelem02->set_name("Logs");

(*pathelem03->mutable_key())["count"] = "5";

 auto pathelem03 = path1->add_elem();

 pathelem03->set_name("Log");

(*pathelem03->mutable_key())["Index"] = "10";

·     Value filtering

You can specify a value for a column in a table to implement full match filtering. If you specify values for multiple columns, the system returns the data that matches all the specified values.

The following example obtains information about interface whose IfIndex is 1.

auto prefix = request.mutable_prefix();

 auto pathelem01 = prefix->add_elem();

 pathelem01->set_name("VLAN");

 

 auto path1 = request.add_path();

 auto pathelem02 = path1->add_elem();

 pathelem02->set_name("TrunkInterfaces");

 auto pathelem03 = path1->add_elem();

 pathelem03->set_name("Interface");

(*pathelem03->mutable_key())["IfIndex"] = "1";

gNMI Set operation attributes

gNMI Set operations support the following attributes:

·     incremental—Adds configuration data to a column without affecting the original data. This attribute applies to a list column such as the vlan permitlist column.

This example adds VLANs 1 through 10 to an untagged VLAN list that has untagged VLANs 12 through 15.

Path       *path01 = request.mutable_prefix();

PathElem   *pathelem01 = path01->add_elem();  

pathelem01->set_name("VLAN"); 

PathElem   *pathelem02 = path01->add_elem();

pathelem02->set_name("HybridInterfaces");

  

Update *Update01 = request.add_update();

Path       *path02 = Update01->mutable_path();

PathElem   *pathelem03 = path02->add_elem();

pathelem03->set_name("Interface");

(*pathelem03->mutable_key())["IfName"] = "262";

(*pathelem03->mutable_key())["UntaggedVlanList#incremental"] = "true";

(*pathelem03->mutable_key())["UntaggedVlanList"] = "1-10";

·     valuetype—Attribute value type.

When configuring an interface, the device cannot identify whether an integer value for the IfIndex or vrfindex column represents an interface name or index. To resolve the issue, you can use the valuetype attribute to specify the value type.

The valuetype attribute has the following values:

 

Value

Description

name

The column is carrying a name.

index

The column is carrying an index.

auto

Default value. The device uses the value of the column as a name for interface matching. If no match is found, the device uses the value as an index for interface matching.

 

The following example sets the valuetype attribute to index and set the index to 1 for IfIndex:

   Path        *path01 = request.mutable_prefix();

   PathElem    *pathelem01 = path01->add_elem();  

   pathelem01->set_name("VLAN");  

   PathElem    *pathelem02 = path01->add_elem();

   pathelem02->set_name("TrunkInterfaces");

 

   /* SetRequest->delete */

   Path        *path02 = request.add_delete_();   

   PathElem    *pathelem04 = path02->add_elem();

   pathelem04->set_name("Interface ");

(*pathelem04->mutable_key())["IfIndex"] = "1";

(*pathelem04->mutable_key())["IfIndex#valuetype"] = "index";

gNMI Subscribe operation attributes

gNMI Subscribe operations support the following attributes:

·     All gNMI Get operation attributes. See "gNMI Get operation attributes."

These attributes are used for subscription to periodically reported data tables.

·     condition—Data pushing condition.

This attribute is used for event table subscription. Values for this attribute are as follows:

¡     more—More than.

¡     less—Less than.

¡     notLess—Not less than.

¡     notMore—Not more than.

¡     equal—Equal to.

¡     notEqual—Not equal to.

¡     include—Include.

¡     exclude—Not include.

¡     startWith—Start with.

¡     endWith—End with.

The following example monitors LLDP events:

  auto prefix = subscribeList->mutable_prefix();

  auto pathelem01 = prefix->add_elem();

  pathelem01->set_name("LLDP");

 

  auto subscribe = subscribeList->add_subscription();

  auto path = subscribe->mutable_path();

  auto pathelem02 = path->add_elem();

  pathelem02->set_name("NeighborEvent");

  auto pathelem03 = path->add_elem();

  pathelem03->set_name("Neighbor");

  (*pathelem03->mutable_key())["IfName"] = "Ten-GigabitEthernet1/0/1";

  (*pathelem03->mutable_key())["IfName#condition"] = "equal";

·     match—Conditional match.

This attribute is used for data table subscription.

The matching object can be a fixed value or another column. The latter supports only data tables that are reported only when triggered.

Table 4 describes the conditional match operators for matching a fixed value. Attribute values for matching another column are as follows:

¡     refMore—More than.

¡     refLess—Less than.

¡     refNotLess—Not less than.

¡     refNotMore—Not more than.

¡     refEqual—Equal to.

¡     refNotEqual—Not equal to.

In the following example, a report is triggered only if the current-usage column has a greater value than the alarm-threshold column:

  auto subscribe = subscribeList->add_subscription();

  auto path = subscribe->mutable_path();

  auto pathelem02 = path->add_elem();

  pathelem02->set_name("queue");

  auto pathelem03 = path->add_elem();

  pathelem03->set_name("state");

  (*pathelem03->mutable_key())["current-usage#match"] = "refMore:alarm-threshold";

·     select—Reports certain columns in a data table that is reported only when triggered

The following example reports only the current-usage column and the available-usage column:

  auto subscribe = subscribeList->add_subscription();

  auto path = subscribe->mutable_path();

  auto pathelem02 = path->add_elem();

  pathelem02->set_name("queue");

  auto pathelem03 = path->add_elem();

  pathelem03->set_name("state");

  (*pathelem03->mutable_key())["current-usage#select"] = "";

  (*pathelem03->mutable_key())["available-usage#select"] = "";

 

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