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Enable message notification service

The message notification service can inform your server of Agora product events through HTTP/HTTPS protocol requests. This service integrates some events of the Cloud Recording, Media Push and Media Pull products. You can use this service by providing configuration information to Agora.

User configuration

Contact support@agora.io enable the message notification service with the following information:

  • HTTP/HTTPS server address (URL) to receive notification callbacks.
  • The product that you want to use the notification service.
  • Events that you want to be notified, see Cloud Recording Event Type.
  • Set whether or not to enable the notification Retry option. If you enable this option, the notification server resends the notification callback up to three times after it fails to send the first notification callback in the following situations:
    • Your server does not respond in 10 seconds.
    • The HTTP status code received from your server is not 200.

After the configuration is completed, the message notification service will take effect after 5 minutes. Therefore, your server needs to respond to the notification server immediately. The response body must be in JSON format.

After configuring the message notification service, we will automatically generate the secret. The secret is a string type key that can be used to generate a signature. You need to save this key for signature verification. See Signature verification for details.

Notification callback format

The notification callback is sent to your server as an HTTP/HTTPS POST request with the body in JSON format. The character encoding is UTF-8.

The header of the notification callback contains the following fields:

Field NameValue
Content-Typeapplication/json
Agora-SignatureThe signature generated by Agora using the secrect key and the HMAC/SHA1 algorithm. You need to use the secret key and HMAC/SHA1 algorithm to verify the signature value. See Signature verification for details.
Agora-Signature-V2The signature generated by Agora using the secrect key and the HMAC/SHA256 algorithm. You need to use the secret key and HMAC/SHA256 algorithm to verify the signature value. See Signature verification for details.

The body of the notification callback contains the following fields:

Field nameTypeDescription
noticeIdStringNotification ID, identifying the notification callback when the event occurs.
productIdNumberProduct ID:
  • 2: Media Push 3.0 (Client-side SDK API)
  • 3: Cloud Recording and Extension Service
  • 4: Media Pull
  • 5: Media Push (Server-side RESTful API)
  • eventTypeNumberThe event type, see Cloud Recording Event Type, Media Push Event Type and Cloud Player Event Type.
    notifyMsNumberThe Unix time (ms) when the notification server requests to your server, which is updated each time it resends the notification callback.
    payloadJSON ObjectThe content of the events, see Cloud Recording payload Field, Media Push payload Field and Cloud Player payload Field.

    Signature verification

    We generate the key directly. After using the HMAC/SHA1 and HMAC/SHA256 algorithms, we generate the Agora-Signature and Agora-Signature-V2. You can use the saved key to verify Agora-Signature with the HMAC/SHA1 algorithm or verify Agora-Signature-V2 with the HMAC/SHA256 algorithm. The signature verification sample code is as follows:

    • Python

    HMAC/sha1


    _9
    #!/usr/bin/env python2
    _9
    # !-*- coding: utf-8 -*-
    _9
    import hashlib
    _9
    import hmac
    _9
    # Get the raw request body of the notification callback to calculate the signature. request_body in the following code is a binary byte array before deserialization and not a dictionary after deserialization.
    _9
    request_body = '{"eventMs":1560408533119,"eventType":10,"noticeId":"4eb720f0-8da7-11e9-a43e-53f411c2761f","notifyMs":1560408533119,"payload":{"a":"1","b":2},"productId":1}'
    _9
    secret = 'secret'
    _9
    signature = hmac.new(secret, request_body, hashlib.sha1).hexdigest()
    _9
    print(signature) # 033c62f40f687675f17f0f41f91a40c71c0f134c

    HMAC/sha256


    _9
    #!/usr/bin/env python2
    _9
    # !-*- coding: utf-8 -*-
    _9
    import hashlib
    _9
    import hmac
    _9
    # Get the raw request body of the notification callback to calculate the signature. request_body in the following code is a binary byte array before deserialization and not a dictionary after deserialization.
    _9
    request_body = '{"eventMs":1560408533119,"eventType":10,"noticeId":"4eb720f0-8da7-11e9-a43e-53f411c2761f","notifyMs":1560408533119,"payload":{"a":"1","b":2},"productId":1}'
    _9
    secret = 'secret'
    _9
    signature2 = hmac.new(secret, request_body, hashlib.sha256).hexdigest()
    _9
    print(signature2) # 6d3320c60b11101395b7fc8f9068748808a0aa1bfa064438e39d1bc2c7d74d99

    • Node.js

    HMAC/sha1


    _6
    const crypto = require('crypto')
    _6
    // Get the raw request body of the notification callback to calculate the signature. requestBody in the following code is a binary byte array before deserialization, not an object after deserialization.
    _6
    const requestBody = '{"eventMs":1560408533119,"eventType":10,"noticeId":"4eb720f0-8da7-11e9-a43e-53f411c2761f","notifyMs":1560408533119,"payload":{"a":"1","b":2},"productId":1}'
    _6
    const secret = 'secret'
    _6
    const signature = crypto.createHmac('sha1', secret).update(requestBody, 'utf8').digest('hex')
    _6
    console.log(signature) // 033c62f40f687675f17f0f41f91a40c71c0f134c

    HMAC/sha256


    _6
    const crypto = require('crypto')
    _6
    // Get the raw request body of the notification callback to calculate the signature. requestBody in the following code is a binary byte array before deserialization, not an object after deserialization.
    _6
    const requestBody = '{"eventMs":1560408533119,"eventType":10,"noticeId":"4eb720f0-8da7-11e9-a43e-53f411c2761f","notifyMs":1560408533119,"payload":{"a":"1","b":2},"productId":1}'
    _6
    const secret = 'secret'
    _6
    const signature2 = crypto.createHmac('sha256', secret).update(requestBody, 'utf8').digest('hex')
    _6
    console.log(signature2) // 6d3320c60b11101395b7fc8f9068748808a0aa1bfa064438e39d1bc2c7d74d99

    • Java

    HMAC/sha1


    _36
    import javax.crypto.Mac;
    _36
    import javax.crypto.SecretKey;
    _36
    import javax.crypto.spec.SecretKeySpec;
    _36
    public class HmacSha {
    _36
    // Convert an encrypted byte array into a hex string.
    _36
    public static String bytesToHex(byte[] bytes) {
    _36
    StringBuffer sb = new StringBuffer();
    _36
    for (int i = 0; i < bytes.length; i++) {
    _36
    String hex = Integer.toHexString(bytes[i] & 0xFF);
    _36
    if (hex.length() < 2) {
    _36
    sb.append(0);
    _36
    }
    _36
    sb.append(hex);
    _36
    }
    _36
    return sb.toString();
    _36
    }
    _36
    // Use the HMAC/SHA1 algorithm and get the encrypted hex string.
    _36
    public static String hmacSha1(String message, String secret) {
    _36
    try {
    _36
    SecretKeySpec signingKey = new SecretKeySpec(secret.getBytes(
    _36
    "utf-8"), "HmacSHA1");
    _36
    Mac mac = Mac.getInstance("HmacSHA1");
    _36
    mac.init(signingKey);
    _36
    byte[] rawHmac = mac.doFinal(message.getBytes("utf-8"));
    _36
    return bytesToHex(rawHmac);
    _36
    } catch (Exception e) {
    _36
    throw new RuntimeException(e);
    _36
    }
    _36
    }
    _36
    public static void main(String[] args) {
    _36
    // Get the raw request body of the notification callback to calculate the signature. request_body in the following code is a binary byte array before deserialization and not an object after deserialization.
    _36
    String request_body = "{\"eventMs\":1560408533119,\"eventType\":10,\"noticeId\":\"4eb720f0-8da7-11e9-a43e-53f411c2761f\",\"notifyMs\":1560408533119,\"payload\":{\"a\":\"1\",\"b\":2},\"productId\":1}";
    _36
    String secret = "secret";
    _36
    System.out.println(hmacSha1(request_body, secret)); //033c62f40f687675f17f0f41f91a40c71c0f134c
    _36
    }
    _36
    }

    HMAC/sha256


    _36
    import javax.crypto.Mac;
    _36
    import javax.crypto.SecretKey;
    _36
    import javax.crypto.spec.SecretKeySpec;
    _36
    public class HmacSha {
    _36
    // Convert an encrypted byte array into a hex string.
    _36
    public static String bytesToHex(byte[] bytes) {
    _36
    StringBuffer sb = new StringBuffer();
    _36
    for (int i = 0; i < bytes.length; i++) {
    _36
    String hex = Integer.toHexString(bytes[i] & 0xFF);
    _36
    if (hex.length() < 2) {
    _36
    sb.append(0);
    _36
    }
    _36
    sb.append(hex);
    _36
    }
    _36
    return sb.toString();
    _36
    }
    _36
    // Use the HMAC/SHA256 algorithm and get the encrypted hex string.
    _36
    public static String hmacSha256(String message, String secret) {
    _36
    try {
    _36
    SecretKeySpec signingKey = new SecretKeySpec(secret.getBytes(
    _36
    "utf-8"), "HmacSHA256");
    _36
    Mac mac = Mac.getInstance("HmacSHA256");
    _36
    mac.init(signingKey);
    _36
    byte[] rawHmac = mac.doFinal(message.getBytes("utf-8"));
    _36
    return bytesToHex(rawHmac);
    _36
    } catch (Exception e) {
    _36
    throw new RuntimeException(e);
    _36
    }
    _36
    }
    _36
    public static void main(String[] args) {
    _36
    // Get the raw request body of the notification callback to calculate the signature. request_body in the following code is a binary byte array before deserialization and not an object after deserialization.
    _36
    String request_body = "{\"eventMs\":1560408533119,\"eventType\":10,\"noticeId\":\"4eb720f0-8da7-11e9-a43e-53f411c2761f\",\"notifyMs\":1560408533119,\"payload\":{\"a\":\"1\",\"b\":2},\"productId\":1}";
    _36
    String secret = "secret";
    _36
    System.out.println(hmacSha256(request_body, secret)); //033c62f40f687675f17f0f41f91a40c71c0f134c
    _36
    }
    _36
    }

    Considerations

    • Your server does not receive messages in the same order as events occur.
    • For the reliability of the notification callbacks, the notification server may send at least two notification callbacks when the event occurs. Hence, your server should be able to handle duplicate messages.

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