The server side of GCM consists of 2 components:
- Google-provided GCM Connection Servers take messages from a 3rd-party application server and send them to a GCM-enabled Android application (the "client app") running on a device. For example, Google provides connection servers for HTTP and CCS (XMPP).
- A 3rd-party application server that you must implement. This application server sends data to a GCM-enabled Android application via the chosen GCM connection server.
Here are the basic steps you follow to implement your 3rd-party app server:
- Decide which GCM connection server(s) you want to use. Note that if you want to use upstream messaging from your client applications, you must use CCS. For a more detailed discussion of this, see Choosing a GCM Connection Server.
- Decide how you want to implement your app server. For example:
- If you decide to use the HTTP connection server, you can use the GCM server helper library and demo app to help in implementing your app server.
- If you decide to use the XMPP connection server, you can use the provided Python or Java Smack demo apps as a starting point.
- Note that Google AppEngine does not support connections to CCS.
A full GCM implementation requires both a client implementation and a server implementation. For more information about implementing the client side, see Implementing GCM Client.
Choosing a GCM Connection Server
Currently GCM provides two connection servers: HTTP and CCS (XMPP). You can use them separately or in tandem. CCS messaging differs from GCM HTTP messaging in the following ways:
- Upstream/Downstream messages
- GCM HTTP: Downstream only: cloud-to-device.
- CCS: Upstream and downstream (device-to-cloud, cloud-to-device).
- Asynchronous messaging
- GCM HTTP: 3rd-party app servers send messages as HTTP POST requests and wait for a response. This mechanism is synchronous and causes the sender to block before sending another message.
- CCS: 3rd-party app servers connect to Google infrastructure using a persistent XMPP connection and send/receive messages to/from all their devices at full line speed. CCS sends acknowledgment or failure notifications (in the form of special ACK and NACK JSON-encoded XMPP messages) asynchronously.
- JSON
- GCM HTTP: JSON messages sent as HTTP POST.
- CCS: JSON messages encapsulated in XMPP messages.
Role of the 3rd-party Application Server
Before you can write client Android applications that use the GCM feature, you must have an application server that meets the following criteria:
- Able to communicate with your client.
- Able to fire off properly formatted requests to the GCM server.
- Able to handle requests and resend them as needed, using exponential back-off.
- Able to store the API key and client registration IDs. The API key is included in the header of POST requests that send messages.
- Able to generate message IDs to uniquely identify each message it sends.
Sending Messages
Here is the general sequence of events that occurs when a 3rd-party application server sends a message:
- The application server sends a message to GCM servers.
- Google enqueues and stores the message in case the device is offline.
- When the device is online, Google sends the message to the device.
- On the device, the system broadcasts the message to the specified Android application via Intent broadcast with proper permissions, so that only the targeted Android application gets the message. This wakes the Android application up. The Android application does not need to be running beforehand to receive the message.
- The Android application processes the message.
The following sections describe the basic requirements for sending messages.
Target
Required. When your app server sends a message in GCM, it must specify a target.
For HTTP you must specify the target as one of:
registration_ids
: For sending to 1 or more devices (up to 1000). When you send a message to multiple registration IDs, that is called a multicast message.notification_key
: For sending to multiple devices owned by a single user.
For CCS (XMPP):
- You must specify the target as the "to" field, where the "to" field may contain a single registration ID or a notification key. CCS does not support multicast messaging.
Payload
Optional. If you are including a payload in the message, you use the data
parameter to include the payload. This applies for both HTTP and CCS.
Message parameters
The following table lists the parameters that a 3rd-party app server might include in the JSON messages it sends to a connection server. See the "Where Supported" column for information about which connection servers support that particular parameter.
Field | Description | Where Supported | to |
In CCS, used in place of registration_ids to specify the
recipient of a message. Its value must be a registration ID.
The value is a string. Required. |
CCS |
---|---|---|
message_id |
In CCS, uniquely identifies a message in an XMPP connection. The value is a string that uniquely identifies the associated message. The value is a string. Required. | CCS |
message_type |
In CCS, indicates a special status message, typically sent by the system. However, your app server also uses this parameter to send an 'ack' or 'nack' message back to the CCS connection server. For more discussion of this topic, see Cloud Connection Server. The value is a string. Optional. | CCS |
registration_ids |
A string array with the list of devices (registration IDs) receiving the
message. It must contain at least 1 and at most 1000 registration IDs. To send a
multicast message, you must use JSON. For sending a single message to a single
device, you could use a JSON object with just 1 registration id, or plain text
(see below). A request must include a recipient—this can be either a
registration ID, an array of registration IDs, or a notification_key .
Required. |
HTTP |
notification_key |
A string that maps a single user to multiple registration IDs associated
with that user. This allows a 3rd-party server to send a single message to
multiple app instances (typically on multiple devices) owned by a single user.
A 3rd-party server can use notification_key as the target for a message
instead of an individual registration ID (or array of registration IDs). The maximum
number of members allowed for a notification_key is 10. For more discussion
of this topic, see User Notifications. Optional.
|
HTTP. This feature is supported in CCS, but you use it by specifying a notification key in the "to" field. |
collapse_key |
An arbitrary string (such as "Updates Available") that is used
to collapse a group of like messages
when the device is offline, so that only the last message gets sent to the
client. This is intended to avoid sending too many messages to the phone when it
comes back online. Note that since there is no guarantee of the order in which
messages get sent, the "last" message may not actually be the last
message sent by the application server. Collapse keys are also called
send-to-sync messages.
Note: GCM allows a maximum of 4 different collapse keys to be used by the GCM server at any given time. In other words, the GCM server can simultaneously store 4 different send-to-sync messages per device, each with a different collapse key. If you exceed this number GCM will only keep 4 collapse keys, with no guarantees about which ones they will be. See Advanced Topics for more discussion of this topic. Optional. |
CCS, HTTP |
data |
A JSON object whose fields represents the key-value pairs of the message's
payload data. If present, the payload data it will be
included in the Intent as application data, with the key being the extra's name.
For instance, "data":{"score":"3x1"} would result in an intent extra
named score whose value is the string 3x1 .
There is no limit on the number of key/value pairs, though there is a limit on
the total size of the message (4kb). The values could be any JSON object, but we
recommend using strings, since the values will be converted to strings in the GCM
server anyway. If you want to include objects or other non-string data types
(such as integers or booleans), you have to do the conversion to string yourself.
Also note that the key cannot be a reserved word (from or any word
starting with google. ). To complicate things slightly, there are
some reserved words (such as collapse_key ) that are technically
allowed in payload data. However, if the request also contains the word, the
value in the request will overwrite the value in the payload data. Hence using
words that are defined as field names in this table is not recommended, even in
cases where they are technically allowed. Optional. |
CCS, HTTP |
delay_while_idle |
If included, indicates that the message should not be sent immediately
if the device is idle. The server will wait for the device to become active, and
then only the last message for each collapse_key value will be
sent. The default value is false , and must be a JSON boolean. Optional. |
CCS, HTTP |
time_to_live |
How long (in seconds) the message should be kept on GCM storage if the device is offline. Optional (default time-to-live is 4 weeks, and must be set as a JSON number). | CCS, HTTP |
restricted_package_name |
A string containing the package name of your application. When set, messages will only be sent to registration IDs that match the package name. Optional. | HTTP |
dry_run |
If included, allows developers to test their request without actually
sending a message. Optional. The default value is false , and must
be a JSON boolean.
|
HTTP |
If you want to test your request (either JSON or plain text) without delivering
the message to the devices, you can set an optional HTTP or JSON parameter called
dry_run
with the value true
. The result will be almost
identical to running the request without this parameter, except that the message
will not be delivered to the devices. Consequently, the response will contain fake
IDs for the message and multicast fields.
Plain text (HTTP only)
If you are using plain text instead of JSON, the message fields must be set as HTTP parameters sent in the body, and their syntax is slightly different, as described below:
Field | Description |
---|---|
registration_id |
Must contain the registration ID of the single device receiving the message. Required. |
collapse_key |
Same as JSON (see previous table). Optional. |
data.<key> |
Payload data, expressed as parameters prefixed with data. and
suffixed as the key. For instance, a parameter of data.score=3x1 would
result in an intent extra named score whose value is the string
3x1 . There is no limit on the number of key/value parameters, though
there is a limit on the total size of the message. Also note that the key cannot
be a reserved word (from or any word starting with
google. ). To complicate things slightly, there are some reserved words
(such as collapse_key ) that are technically allowed in payload data.
However, if the request also contains the word, the value in the request will
overwrite the value in the payload data. Hence using words that are defined as
field names in this table is not recommended, even in cases where they are
technically allowed. Optional. |
delay_while_idle |
Should be represented as 1 or true for
true , anything else for false . Optional. The default
value is false . |
time_to_live |
Same as JSON (see previous table). Optional. |
restricted_package_name |
Same as JSON (see previous table). Optional. |
dry_run |
Same as JSON (see previous table). Optional. |
Receiving Messages
This is the sequence of events that occurs when an Android application installed on a mobile device receives a message:
- The system receives the incoming message and extracts the raw key/value pairs from the message payload, if any.
- The system passes the key/value pairs to the targeted Android application
in a
com.google.android.c2dm.intent.RECEIVE
Intent as a set of extras. - The Android application extracts the raw data
from the
com.google.android.c2dm.intent.RECEIVE
See the documentation for each connection server for more detail on how it handles responses.