LWM2M Device API Reference

• Prerequisites
• LwM2M basics
• Getting started
  • Step 1. Upload LwM2M models
  • Step 2. Define LwM2M device profile
    • Step 2.1 Create the LwM2M profile.
    • Step 2.2 Choose LwM2M objects.
    • Step 2.3 Configure the mapping
  • Step 3. Define LwM2M device credentials
  • Step 4. Connect the device
• ThingsBoard LwM2M support
  • Read LwM2M resources to ThingsBoard attributes
  • Write LwM2M resource via ThingsBoard attributes update
  • Read LwM2M resources to time-series data
  • Execute LwM2M operation using the ThingsBoard RPC command
• RPC Commands
  • Read Operation
  • Discover Operation
  • Write Operation
  • Write-Attributes Operation
  • Read-Composite Operation
  • Write Composite Operation
  • Execute Operation
  • Delete Operation
  • Observe Operation
  • Cancel Observation Operation
  • Cancel All Observations Operation
  • Read All Observations Operation
  • Discover All Operation
• Firmware over-the-air updates
  • Push firmware update as binary file using Object 5 and Resource 0.
  • Auto-generate a unique CoAP URL to download the package and push the firmware package via Object 5 and Resource 1.
• Software over-the-air updates
  • Push software update as binary file using Object 9 and Resource 2.
  • Auto-generate a unique CoAP URL to download the package and push the software package via Object 9 and Resource 3.
• Advanced topics
  • Object and Resource attributes
  • DTLS configuration
    • 1. Pre-shared Key mode (PSK).
    • 2. Raw Public Key(RPK) mode.

Prerequisites

We assume you have completed the general Getting Started guide to get familiar with ThingsBoard.

LwM2M basics

LwM2M is a device management protocol designed for constrained devices and the demands of a machine-to-machine (M2M) environment. You can find more information about LwM2M here. Key advantage of the LwM2M protocol is a rich library of data structures that is called LwM2M Object and Resource Registry. The up-to-date list of available objects is available inside this Github repository.

The registry allows efficient serialization/deserialization of telemetry. LwM2M Protocol defines process of device registration, configuration, management and firmware/software updates.

The LwM2M device supplies the list of LwM2M Objects it supports during registration. The LwM2M Object has an ID, version and one or multiple instances. Each LwM2M Object instance has multiple resources.

The LwM2M resource is a key concept that represents some data you may get or write to device. For example, Resource “3.0.2” always represents the device serial number. Where “3” is the Object id, “0” is the Object instance and “2” is the resource id.

Each resource has the following main properties:

• Name - human readable name of the resource
• Type - data type: String, Integer, etc.
• Operations - R (read), RW (read-write), E (execute), etc.

Getting started

This part of documentation covers provisioning of your first LwM2M device in ThingsBoard. We will use Eclipse Wakaama test client to simulate LwM2M device.

Step 1. Upload LwM2M models

System administrator is able to upload LwM2M models using “Resource library” UI located in the “System settings” menu. One may upload multiple files at once. We recommend you to download list of available models from official github repo and import all of them.

Tenant administrator is able to use LwM2M models defined by system administrator or overwrite them for the specific tenant.

Step 2. Define LwM2M device profile

Once you upload the LwM2M models, you are ready to use them to define the device profile. See general device profile documentation for more info about device profiles.

Step 2.1 Create the LwM2M profile.

The important step is to chose LwM2M Transport type on the “Transport configuration” step. The Transport Configuration allows us to define list of the LwM2M Objects that your devices supports.

Step 2.2 Choose LwM2M objects.

Let’s define a profile that supports Device Object (id: 3), Connectivity (id: 4), Firmware Update (id: 5) and Location monitoring (id: 6):

Step 2.3 Configure the mapping

You may notice that Device Object supports Manufacturer, model, and serial numbers. Let’s configure ThingsBoard to fetch those data when device connects and store it as ThingsBoard attributes. Also we want to observe Radio Signal Strength, Link Quality and device location push it as ThingsBoard telemetry. Observe is a powerful LwM2M feature that will instruct a device to report changes of those values. You may also define conditions for reporting specific resource via LwM2M attributes. These settings are covered in the advanced documentation.

Note: if you un-check all items from the Object(Telemetry, Attributes, Observe) - this object will not be displayed in the device profile.

Transport Configuration also allows you to define bootstrap and other settings.

Step 3. Define LwM2M device credentials

We assume you have already created LwM2M device profile using the previous step.

Now, let’s create the device using our profile and configure LwM2M Credentials. ThingsBoard supports 4 different types of credentials: Pre-Shared Key (PSK), Raw Public Ket (RPK), X.509 Certificates and “No Security” mode.

For simplicity, we will connect device using plain UDP and “No Security” mode. To connect such a device we just need to specify it’s endpoint name in the device credentials.

You may use other types of credentials with the DTLS mode enabled. See DTLS configuration for more info.

Step 4. Connect the device

We assume you have already provisioned LwM2M device credentials using the previous step and also built Eclipse Wakaama test client. Now you are ready to turn on the device and observe the incoming telemetry.

Let’s launch the test client:

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./lwm2mclient -h lwm2m.thingsboard.cloud -n UniqueEndpointName -p 5685 -c

Where

• ‘lwm2m.thingsboard.cloud’ is the host name of the LwM2M server;
• ‘5685’ is the port of LwM2M server;
• ‘UniqueEndpointName’ is the unique name of your endpoint. Please replace this with IMEI or other unique ID.

The LwM2M transport implementation also stores the logs of communication with the device into telemetry. You should see the “transportLog” in the device telemetry tab.

ThingsBoard LwM2M support

ThingsBoard implements both LwM2M server and bootstrap server that supports plain UDP and DTLS (secure transport over UDP). As a platform user, you are able to provision and define the mapping between the LwM2M resources and ThingsBoard device attributes and time-series data. The mapping is configured in the corresponding device profile. We will use some screenshots of the LwM2M device profile below to explain the basics. See the Getting Started guide for a step-by-step instruction to create the device profile.

Read LwM2M resources to ThingsBoard attributes

You may configure device profile to read and observe certain LwM2M Resource. The values of the resource may be stored as the device attributes. To do this, select the “Attribute” checkbox for the corresponding Resource. You may optionally change the auto-generated key name, defining the attribute name in ThingsBoard. For example, let’s configure the platform to read the LwM2M Resource /3/0/2 (Device Serial Number) and store it as an attribute serialNumber in ThingsBoard:

ThingsBoard will read the attribute value during device registration (LwM2M “Register” operation) or during registration update (LwM2M “Update” operation).

Note:

We may optionally issue the “Observe” operation to make sure we subscribe to the updates of the LwM2M resource. To do this, select the “Observe” checkbox for the corresponding Resource. Let’s configure ThingsBoard to monitor the LwM2M Resource /3/0/15 (Timezone) and store it as the timezone attribute:

Using the above configuration, we will make sure that the attribute timezone will always contain the latest value of the Timezone resource.

Write LwM2M resource via ThingsBoard attributes update

ThingsBoard Shared Attributes are used to deliver the configuration updates to the device. You may change the shared attribute in multiple ways - via administration UI, dashboard widget, REST API, or rule engine node. Once you change the shared attribute, ThingsBoard will search for the mapping between the attribute key and LwM2M resource. If the resource is marked as an attribute, platform will send the LwM2M Write operation to the LwM2M client device.

See the Timezone example from the read attributes

Read LwM2M resources to time-series data

You may configure device profile to read and observe certain LwM2M Resource. The values of the resource may be stored as the device time-series data. To do this, select the “Telemetry” checkbox for the corresponding Resource. You may optionally change the auto-generated key name, defining the telemetry key in ThingsBoard. For example, let’s configure the platform to read the LwM2M Resources: /3/0/7 (Power Source Voltage), /3/0/8 (Power Source Current), /3/0/9 (Battery Level), and /3/0/10 (Memory Free), and to store them as time-series data in ThingsBoard:

Execute LwM2M operation using the ThingsBoard RPC command

ThingsBoard supports on-demand LwM2M operations using RPC(Remote Procedure Call) feature. We also use “command” to device instead of RPC for simplicity. You can send the command using REST API, dashboard widget, rule engine, or custom script. See the structure of the command is documented here.

Key properties of the command are method and params. The method defines the LwM2M operation and is one of the following:

• Execute - used by the LwM2M Server to initiate some action;
• Read - access the value of a Resource;
• Discover - discover LwM2M Resources available on an Objects or Object Instances;
• WriteUpdate - change the value of a Resource;
• WriteAttributes - change attribute of the Resource;
• ReadComposite - selectively read any combination of Objects;
• WriteComposite - change the values of a number of different Resources across different Instances of one or more Objects;
• Delete - delete an Object Instance within the LwM2M Client;
• Observe - initiates an observation request for changes of a specific Resource;
• ObserveCancel - ends an observation relationship that was previously created with an “Observe” operation;
• ObserveCancelAll - Thingsboard-specific operation and allows to cancel all observations on the device at once;
• ObserveReadAll - Thingsboard-specific operation and allows to get all observations that are set on the device;
• DiscoverAll - Thingsboard-specific operation and allows to get the object and resources hierarchy, instantiated on the client.

The params is typically a JSON that defines the resource id or multiple resources ids. For example, to reboot the device one should execute the resource /3/0/4 (Reboot).

So, the following RPC command need to be sent to ThingsBoard:

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{
   "method": "Execute",
   "params": {"id": "/3/0/4"}
}

We have prepared a simple dashboard with the ability to execute commands to device (/3/0/4 Reboot) and update device attributes (/3/0/15 Timezone). You may import the dashboard from gist, once you complete the “Getting started” guide below. Don’t forget to change the dashboard alias.

RPC Commands

LwM2M transport supports RPC commands that reflect subset of Device Management and Service Enablement Interface and Information Reporting interface.

The Device Management and Service Enablement Interface is used by the LwM2M Server to access Object Instances and Resources available from a registered LwM2M Client. The operations that a Resource supports are defined in the Object definition using the Object Template.

The Information Reporting Interface is used by a LwM2M Server to observe any changes in a Resource on a registered LwM2M Client, receiving notifications when new values are available. This observation relationship is initiated by sending an “Observe” or “Observe-Composite” operation to the L2M2M Client for an Object, an Object Instance or a Resource. An observation ends when a “Cancel Observation” or “Cancel Observation-Composite” operation is performed.

We will use the Debug Terminal widget to send commands to the device.

To execute attribute - oriented commands there are two ways to specify the target resource: by Resource ID and by the Key.

Resource ID is the combination of “/ObjectId/ObjectInstance/ResourceID” numbers, Where:

• ‘ObjectId’ Indicates the Object number. Objects used to group resources on the device, related to a certain functionality.
• ‘ObjectInstance’ Indicates the Object Instance to read.
• ‘ResourceID’ Indicates the Resource to read.

Example of plain RPC call example for REST API:

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{
   "method": "Read",
   "params": {"id": "/3/0/9"}
}

or

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{
   "method": "Read",
   "params": {"key": "batteryLevel"}
}

Example of corresponding input in the debug terminal:

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Read {"id":"/3/0/9"}

Key is a custom user-friendly name, assigned to a certain attribute:

Example for RPC debug terminal:

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Read {"key":"batteryLevel"}

To be able to use the Key, you have to assign it to the attribute in the Device Profile configuration section:

• Go to the Device Profiles page;
• Click the Profile name;
• Click the “pencil” button on the top-right corner to edit profile;
• Go to Transport configuration tab;
• Switch to LWM2M Model tab;
• Select the target object and expand the Attributes list;
• Tick the “Attribute” checkbox on the desired attribute and type the Key name;
• Click save.

Below you can find examples of usage for commands that are supported by the Thingsboard platform for LWM2M protocol. Please note that your target client may not support all of them, please refer to the client’s documentation for detailed information on supported commands.

Read Operation

The “Read” operation is used to access the value of a Resource, a Resource Instance, an array of Resource Instances, an Object Instance or all the Object Instances of an Object.

Example: Read the value of the resource by ID

Example of plain RPC call example for REST API:

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{
   "method": "Read",
   "params": {"id": "/3/0/9"}
}

Example of corresponding input in the debug terminal:

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# Request:
Read {"id":"/3/0/9"}

# Response:
{"result":"CONTENT","value":"LwM2mSingleResource [id=9, value=100, type=INTEGER]"}

More examples:

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# Request:
Read {"id":"/3_1.0/0/9"}

# Response:
{"result":"CONTENT","value":"LwM2mSingleResource [id=9, value=20, type=INTEGER]"}

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# Request:
Read {"key":"batteryLevel"}

# Response:
{"result":"CONTENT","value":"LwM2mSingleResource [id=9, value=27, type=INTEGER]"}

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# Request:
Read {"id":"/3/0"}

# Response:
{"result":"CONTENT","value":"LwM2mObjectInstance [id=0, resources={0=LwM2mSingleResource [id=0, value=Thingsboard Test Device, 
type=STRING], 1=LwM2mSingleResource [id=1, value=Model 500, type=STRING], 2=LwM2mSingleResource [id=2, value=TH-500-000-0001, 
type=STRING], 3=LwM2mSingleResource [id=3, value=TestThingsboard@TestMore1024_2.04, type=STRING], 6=LwM2mSingleResource [id=6, 
value=1, type=INTEGER], 7=LwM2mSingleResource [id=7, value=96, type=INTEGER], 8=LwM2mSingleResource [id=8, value=37, type=INTEGER], 
9=LwM2mSingleResource [id=9, value=75, type=INTEGER], 10=LwM2mSingleResource [id=10, value=110673, type=INTEGER], 
11=LwM2mMultipleResource [id=11, values={0=LwM2mResourceInstance [id=0, value=1, type=INTEGER]}, type=INTEGER], 13=LwM2mSingleResource 
[id=13, value=Thu Jul 01 16:39:49 EEST 2021, type=TIME], 14=LwM2mSingleResource [id=14, value=+03, type=STRING], 15=LwM2mSingleResource 
[id=15, value=Europe/Kiev, type=STRING], 16=LwM2mSingleResource [id=16, value=U, type=STRING], 17=LwM2mSingleResource
[id=17, value=smart meters, type=STRING], 18=LwM2mSingleResource [id=18, value=1.01, type=STRING], 19=LwM2mSingleResource [id=19, 
value=1.02, type=STRING], 20=LwM2mSingleResource [id=20, value=2, type=INTEGER], 21=LwM2mSingleResource [id=21, value=256000, type=INTEGER]}]"}

Discover Operation

The “Discover” operation is used to discover LwM2M Resources available on an Objects or Object Instances. This operation can be used to discover which Resources are instantiated in a given Object Instance. The returned payload is a list of application/link-format CoRE Links RFC6690 for each targeted Object, Object Instance, or Resource, along with their assigned or attached Attributes including the Object Version attribute if required.

Example of corresponding input in the debug terminal:

RPC call example for REST API:

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{
   "method": "Discover",
   "params": {"id": "/3"}
}

Example of corresponding input in the debug terminal:

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# Request:
Discover {"id":"/3"}

# Response:
{"result":"CONTENT","value":"</3>,</3/0/0>,</3/0/1>,</3/0/2>,</3/0/3>,</3/0/4>,</3/0/5>,</3/0/6>,</3/0/7>,</3/0/8>,</3/0/9>,</3/0/10>,</3/0/11>,</3/0/12>,</3/0/13>,</3/0/
14>,</3/0/15>,</3/0/16>"}

More examples:

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# Request:
Discover {"id":"/3/0"}

# Response:
{"result":"CONTENT","value":"</3/0>,</3/0/0>,</3/0/1>,</3/0/2>,</3/0/3>,</3/0/4>,</3/0/5>,</3/0/6>,</3/0/7>,</3/0/8>,</3/0/9>,</3/0/10>,</3/0/11>,</3/0/12>,</3/0/13>,</3/
0/14>,</3/0/15>,</3/0/16>"}

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# Request:
Discover {"id":"/3/0/1"}

# Response:
{"result":"CONTENT","value":"</3/0/1>"}

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# Request:
Discover {"key":"batteryLevel"}

# Response:
{"result":"CONTENT","value":"</3/0/9>"}

Write Operation

The “Write” operation is used to change the value of a Resource, the value of a Resource Instance, the values of an array of Resources Instances or the values of multiple Resources from an Object Instance. The “Write” operation can also be used to request the deletion or the allocation of specific Instances of a Multiple-Instance Resource.

The request includes the value to be written encoded in one of the data format defined in 7.4. Data Formats for Transferring Resource Information: plain text, opaque, TLV, JSON, CoRE Link, CBOR, SenML JSON, and SenML CBOR.

There are two mechanisms to change multiple Resources or an array of Resource Instances:

Replace: replaces the Object Instance or the Resource(s) with the new value provided in the “Write” operation. When the Resource is a Multiple-Instance Resource, the existing array of Resource Instances is replaced to the condition the LwM2M Client authorizes that operation.

Partial Update: updates Resources provided in the new value and leaves other existing Resources unchanged. When the Resource is a Multiple-Instance Resource, the existing array of Resource Instances is updated meaning some Instances may be created or overwritten to the condition the LwM2M Client authorizes such operations. Deleting via Partial Update is not possible.

Example: WriteUpdate Single ObjectInstance resource

RPC call example for REST API:

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{
   "method": "WriteUpdate",
   "params": {"id":"/3/0","value":{"14":"+5","15":"Kiyv/Europe"}}
}

Example of corresponding input in the debug terminal:

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# Request:
WriteUpdate  {"id":"/3/0","value":{"14":"+5","15":"Kiyv/Europe"}}

# Response:
{"result":"CHANGED"}

More examples:

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# Request:
WriteUpdate {"id": "/19/0","value": {"0":{"0":"00ad456756", "25":"25ad456756"}}}

# Response:
{"result":"CHANGED"}

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# Request:
WriteUpdate {"id": "/19/0/0","value": {"0":"00ad456756", "25":"25ad456756"}}

# Response:
{"result":"CHANGED"}

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# Request:
WriteReplace {"id":"/19/0/0","value":"0081"}

# Response:
{"result":"CHANGED"}

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# Request:
WriteReplace {"key":"timezone","value":"+10"}

# Response:
{"result":"CHANGED"}

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# Request:
WriteReplace {"id": "/19_1.1/0/0","value": {"0":"00ad456797", "25":"25ad456700"}}

# Response:
{"result":"CHANGED"}

Write-Attributes Operation

Only Attributes from the NOTIFICATION class MAY be changed in using the “Write-Attributes” operation. Object and Resource attributes section provides explanation on the Attributes supported by the “Write-Attributes” operation: Minimum Period, Maximum Period, Greater Than, Less Than, Step. The operation permits multiple Attributes to be modified within the same operation.

Example: Write multiple attributes

RPC call example for REST API:

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{
   "method": "WriteAttributes",
   "params": {"id":"/19/0/0","attributes":{"pmax":120, "pmin":10}}
}

Example of corresponding input in the debug terminal:

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# Request:
WriteAttributes {"id":"/19/0/0","attributes":{"pmax":120, "pmin":10}}

# Response:
{"result":"CHANGED"}

Read-Composite Operation

The LwM2M Client MAY support the “Read-Composite” operation. The “Read-Composite” operation can be used by the LwM2M Server to selectively read any combination of Objects, Object Instance(s), Resources, and/or Resource Instances of different or same Objects in a single request. The list of elements to be read are provided as SenML Pack where the records contain Base Name and/or Name Fields, but no Value fields. The Read-Composite operation is treated as non-atomic and handled as best effort by the client. That is, if any of the requested resources do not have a valid value to return, they will not be included in the response.

Example: Read multiple Objects

RPC call example for REST API:

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{
   "method": "ReadComposite",
   "params": {"ids":["/3/0/9", "/1_1.2"]}
}

Example of corresponding input in the debug terminal:

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# Request:
ReadComposite {"ids":["/3/0/9", "/1_1.2"]}

# Response:
{"result":"CONTENT","value":"{/3/0/9=LwM2mSingleResource [id=9, value=75, type=INTEGER], /1=LwM2mObject [id=1, instances={0=LwM2mObjectInstance [id=0, resources={0=LwM2mSingleResource [id=0, value=123, t
ype=INTEGER], 1=LwM2mSingleResource [id=1, value=300, type=INTEGER], 6=LwM2mSingleResource [id=6, value=false, type=BOOLEAN], 22=LwM2mSingleResource [id=22, value=U, type=STRING], 7=LwM2mSingleResource [
id=7, value=U, type=STRING]}]}]}"

More examples:

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# Request:
ReadComposite {"keys":["state", "updateResult", "pkgversion", "batteryLevel"]}

# Response:
{"result":"CONTENT","value":"{/5/0/7=LwM2mSingleResource [id=7, value=, type=STRING], /5/0/5=LwM2mSingleResource [id=5, value=0, 
type=INTEGER], /5/0/3=LwM2mSingleResource [id=3, value=0, type=INTEGER], /
3/0/9=LwM2mSingleResource [id=9, value=81, type=INTEGER]}"}

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# Request:
ReadComposite {"ids":["/3/0", "/1_1.2/0"]}

# Response:
{"result":"CONTENT","value":"{/3/0=LwM2mObjectInstance [id=0, resources={0=LwM2mSingleResource [id=0, value=Thingsboard Test Device, 
type=STRING], 1=LwM2mSingleResource [id=1, value=Model 500, type=STRING], 2=LwM2mSingleResource [id=2, value=TH-500-000-0001, type=STRING], 
3=LwM2mSingleResource [id=3, value=TestThingsboard@TestMore1024_2.04, type=STRING], 6=LwM2mSingleResource [id=6, value=1, type=INTEGE
R], 7=LwM2mSingleResource [id=7, value=2, type=INTEGER], 8=LwM2mSingleResource [id=8, value=61, type=INTEGER], 9=LwM2mSingleResource [id=9, 
value=25, type=INTEGER], 10=LwM2mSingleResource [id=10, value=102044, type=INTEGER], 11=LwM2mMultipleResource [id=11, 
values={0=LwM2mResourceInstance [id=0, value=1, type=INTEGER]}, type=INTEGER], 13=LwM2mSingleResource [id=13, 
value=Thu Jul 01 16:49:25 EEST 2021, type=TIME], 14=LwM2mSingleResource [id=14, value=+03, type=STRING], 15=LwM2mSingleResource [id=15, 
value=Europe/Kiev, type=STRING], 16=LwM2mSingleResource [id=16, value=U, type=STRING], 17=LwM2mSingleResource [id=17, value=smart meters, 
type=STRING], 18=LwM2mSingleResource [id=18, value=1.01, type=STRING], 19=LwM2mSingleResource [id=19, value=1.02, type=STRING], 
20=LwM2mSingleResource [id=20, value=1, type=INTEGER], 21=LwM2mSingleResource [id=21, value=256000, type=INTEGER]}], /1/0=LwM2mObjectInstance 
[id=0, resources={0=LwM2mSingleResource [id=0, value=123, type=INTEGER], 1=LwM2mSingleResource [id=1, value=300, type=INTEGER], 
6=LwM2mSingleResource [id=6, value=false, type=BOOLEAN], 22=LwM2mSingleResource [id=22, value=U, type=STRING], 7=LwM2mSingleResource [id=7, 
value=U, type=STRING]}]}"}

Write Composite Operation

The LwM2M Client MAY support the “Write-Composite” operation. In contrast to “Write” operation, the scope of which is limited to a Resource(s) of a single Instance of a single Object, the “Write-Composite” operation can be used by the Server to update values of a number of different Resources across different Instances of one or more Objects. The Write-Composite operation provides a list of all resources to be updated, and their new values, using the SenML JSON/CBOR format. Unlike for Write operation, the Resources that are not provided are not impacted by the operation.

The “Write-Composite” operation is atomic and cannot have partial success. That is, if the client supports this operation, it MUST reject a Server request where it cannot successfully write all the requested values to the requested list of Resources. Therefore, before processing Write-Composite, the client MUST ensure that all addressed objects exist and that the Server has write access to those Objects and Resources.

Example: WriteComposite to multiple Objects

RPC call example for REST API:

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{
   "method": "WriteComposite",
   "params": {"nodes":{"/3/0/14":"+04", "/1/0/2":100, "/5/0/1":"coap://localhost:5685"}}
}

Example of corresponding input in the debug terminal:

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# Request:
WriteComposite {"nodes":{"/3/0/14":"+04", "/1/0/2":100, "/5/0/1":"coap://localhost:5685"}}

# Response:
{"result":"CHANGED"}

More examples:

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# Request:
WriteComposite {"nodes":{"timezone":"+04", "defaultMinimumPeriod":100, "packageUri":"coap://localhost:5685"}}

# Response:
{"result":"CHANGED"}

Execute Operation

The “Execute” operation is used by the LwM2M Server to initiate some action, and can only be performed on individual Resources.

Example: Execute resource

RPC call example for REST API:

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{
   "method": "Execute",
   "params": {"id":"5/0/2"}
}

Example of corresponding input in the debug terminal:

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# Request:
Execute {"id":"5/0/2"}

# Response:
{"result":"CHANGED"}

Delete Operation

The “Delete” operation is used for LwM2M Server to delete an Object Instance within the LwM2M Client. The Object Instance that is deleted in the LwM2M Client by the LwM2M Server MUST be an Object Instance that is announced by the LwM2M Client to the LwM2M Server using the “Register” and “Update” operations of the Client Registration Interface.

The only exception concerns the single Instance of the mandatory Device Object (ID:3) which SHALL NOT be affected by any Delete operation.

Example: Delete an Object Instance

RPC call example for REST API:

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{
   "method": "Delete",
   "params": {"id":"/19/1"}
}

Example of corresponding input in the debug terminal:

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# Request:
Delete {"id":"/19/1"}

# Response:
{"result":"DELETE"}

Observe Operation

The LwM2M Server initiates an observation request for changes of a specific Resource, Resources within an Object Instance or for all the Object Instances of an Object within the LwM2M Client. Related parameters for “Observe” operation are described in Notification attributes Write-Attributes Operation and those parameters are configured by “Write-Attributes” operation.

Example: Observe resource

RPC call example for REST API:

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{
   "method": "Observe",
   "params": {"id":"/3/0/9"}
}

Example of corresponding input in the debug terminal:

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# Request:
Observe {"id":"/3/0/9"}

# Response:
{"result":"CONTENT","value":"LwM2mSingleResource [id=9, value=28, type=INTEGER]"}

More examples:

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# Request:
Observe {"id":"/3/0"}
 
# Response:
{"result":"CONTENT","value":"LwM2mObjectInstance [id=0, resources={0=LwM2mSingleResource [id=0, value=Thingsboard 
Test Device, type=STRING], 1=LwM2mSingleResource [id=1, value=Model 500, type=STRING], 2=LwM2mSingleResource [id=2, 
value=TH-500-000-0001, type=STRING], 3=LwM2mSingleResource [id=3, value=TestThingsboard@TestMore1024_2.04, type=STRING], 
6=LwM2mSingleResource [id=6, value=1, type=INTEGER], 7=LwM2mSingleResource [id=7, value=90, type=INTEGER], 8=LwM2mSingleResource 
[id=8, value=29, type=INTEGER], 9=LwM2mSingleResource [id=9, value=19, type=INTEGER], 10=LwM2mSingleResource [id=10, value=76962, 
type=INTEGER], 11=LwM2mMultipleResource [id=11, values={0=LwM2mResourceInstance [id=0, value=1, type=INTEGER]}, type=INTEGER], 
13=LwM2mSingleResource [id=13, value=Wed Jul 31 22:49:45 EET 1940, type=TIME], 14=LwM2mSingleResource [id=14, value=+5, type=STRING], 
15=LwM2mSingleResource [id=15, value=Kiyv/Europe, type=STRING], 16=LwM2mSingleResource [id=16, value=U, type=STRING], 
17=LwM2mSingleResource [id=17, value=smart meters, type=STRING], 18=LwM2mSingleResource [id=18, value=1.01, type=STRING], 
19=LwM2mSingleResource [id=19, value=1.02, type=STRING], 20=LwM2mSingleResource [id=20, value=6, type=INTEGER], 21=LwM2mSingleResource 
[id=21, value=256000, type=INTEGER]}]"}

Cancel Observation Operation

The “Cancel Observation” operation is sent from the LwM2M Server to the LwM2M Client to end an observation relationship that was previously created with an “Observe” operation

Example: Cancel Observation for resource by ID

RPC call example for REST API:

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{
   "method": "ObserveCancel",
   "params": {"id":"/5/0/7"}
}

Example of corresponding input in the debug terminal:

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# Request:
ObserveCancel {"id":"/5/0/7"}

# Response:
{"result":"CONTENT","value":"1"}

More examples:

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# Request:
ObserveCancel {"key":"updateResult"}

# Response:
{"result":"CONTENT","value":"1"}

Cancel All Observations Operation

The “Cancel All Observations” operation is Thingsboard-specific operation and allows to cancel all observations on the device at once

Example: Cancel All Observations

RPC call example for REST API:

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{
   "method": "ObserveCancelAll",
   "params": {}
}

Example of corresponding input in the debug terminal:

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# Request:
ObserveCancelAll

# Response:
{"result":"CONTENT","value":"8"} // - cancelled 8 observations

Read All Observations Operation

The “Read All Observations” operation is Thingsboard-specific operation and allows to get all observations that are set on the device.

Example: Read All Observations

RPC call example for REST API:

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{
   "method": "ObserveReadAll",
   "params": {}
}

Example of corresponding input in the debug terminal:

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# Request:
ObserveReadAll

# Response:
{"result":"CONTENT","value":"[\"/5/0/7\",\"/3/0/3\",\"/5/0/3\",\"/5/0/5\"]"}

Discover All Operation

The “Discover All Observations” operation is Thingsboard-specific operation and allows to get the object and resources hierarchy, instantiated on the client. When DiscoverAll is executed, it doesn’t send any request to the client device, instead it returns LwM2M model of the client device, which was created during the device connection to the server. This command is very useful for device setting up and troubleshooting, as it allows to see available objects and their versions.

Example: Discover all resources

RPC call example for REST API:

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{
   "method": "DiscoverAll",
   "params": {}
}

Example of corresponding input in the debug terminal:

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# Request:
DiscoverAll

# Response:
{"result":"CONTENT","value":"[{\"url\":\"/\",\"attributes\":{\"ct\":\"110\",\"rt\":\"\\\"oma.lwm2m\\\"\"}},
{\"url\":\"/1\",\"attributes\":{\"ver\":\"1.1\"}},{\"url\":\"/1/0\",\"attributes\":{}},{\"url\":\"/2/0\",
\"attributes\":{}},{\"url\":\"/3/0\",\"attributes\":{}},{\"url\":\"/4/0\",\"attributes\":{}},{\"url\":\"/5/0\",
\"attributes\":{}},{\"url\":\"/6/0\",\"attributes\":{}},{\"url\":\"/7/0\",\"attributes\":{}},{\"url\":\"/31024\",
\"attributes\":{\"ver\":\"1.0\"}},{\"url\":\"/31024/10\",\"attributes\":{}},{\"url\":\"/31024/11\",\"attributes\":{}},
{\"url\":\"/31024/12\",\"attributes\":{}}]"}

Firmware over-the-air updates

LwM2M protocol allows you to upload and distribute over-the-air(OTA) firmware updates to devices. Please read first the following article OTA updates to learn about uploading and managing firmware packages and the update process.

LwM2M defines Object 5: Firmware Update Object for the OTA purpose, which enables management of firmware image and includes resources for installing a firmware package, updating firmware, and performing actions after updating firmware.

Please note that Object 5 is an optional object, and may be not supported by some devices.

To be able to run the update using Object 5, you have to make sure that Object 5 is present in the Device profile LwM2M model and set up observations of following attributes on the device, which are used by the server to get feedback from the device on the status of the update process:

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"/3/0/3" - Firmware Version
"/5/0/3" - State
"/5/0/5" - Update Result
"/5/0/7" - PkgVersion

Firmware update process is illustrated here: Firmware Update Mechanisms described as a UML 2.0 state diagram. The state diagram consists of states, drawn as rounded rectangles, and transitions, drawn as arrows connecting the states.

There are several ways to run OTA firmware updates with LwM2M transport. You can choose the strategy in the device profile, so it will be applied for all devices of the profile:

Push firmware update as binary file using Object 5 and Resource 0.

The firmware package is pushed from the server directly to the device via the block-wise transfer to the Resource 0 of the Object 5. After the downloading is finished, the update process should be triggered using the executable resource “/5/0/2”. The full process is illustrated here: Example of a LwM2M Server pushing a firmware image to a LwM2M client.

Auto-generate a unique CoAP URL to download the package and push the firmware package via Object 5 and Resource 1.

This option allows running the firmware update with the image file located on the 3rd party storage. In this case the server generates a CoAP-URL and sends it to the client, and the client downloads firmware image from the external resource directly without transferring image to the server. After the downloading is finished, the update process should be triggered using the executable resource “/5/0/2”. The full process is illustrated here: Example of a client fetching a firmware image

Software over-the-air updates

LwM2M protocol allows you to upload and distribute over-the-air(OTA) software updates to devices. Please read first the following article OTA updates to learn about uploading and managing software packages and the update process.

Updating of the device software has some differences comparing to the firmware update process: the Software Management process is split in 2 sub-processes: a Package Installation Process and a Software Activation Process.

LwM2M defines Object 9: Software Management Object for the software management purpose, which enables remote software management in M2M devices and includes resources for delivering, execution of installation and activating software packages, and reporting states.

Please note that Object 9 is an optional object, and not may be supported by some devices.

To be able to run the update using Object 9, you have to make sure that Object 9 is present in the Device profile LwM2M model and set up observations of following attributes on the device, which are used by the server to get feedback from the device on the status of the update process:

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"/3/0/19" - Software Version
"/9/0/0" - PkgName
"/9/0/1" - PkgVersion
"/9/0/2" - Package ID
"/9/0/3" - Package URI
"/9/0/7" - Update State
"/9/0/9" - Update result

There are several ways to run OTA software updates with LwM2M transport. You can choose the strategy in the device profile, so it will be applied for all devices of the profile:

Push software update as binary file using Object 9 and Resource 2.

The software package is pushed from the server directly to the device via the block-wise transfer to the Resource 2 of the Object 9.

Auto-generate a unique CoAP URL to download the package and push the software package via Object 9 and Resource 3.

This option allows running the software update with the image file located on the 3rd party storage. In this case the server generates a CoAP-URL and sends it to the client, and the client downloads software image from the external resource directly without transferring image to the server.

Advanced topics

Object and Resource attributes

Please note that attributes in LwM2M context are different and not related to Server, Client or Shared attributes on the Thingsboard platform.

In LwM2M protocol, attributes are metadata which can be attached to an Object, an Object Instance, or a Resource. These attributes can fulfil various roles, from carrying information only to carrying parameters for setting up certain actions on the LwM2M Client (e.g., Notifications).

Attributes attached to Objects, Object Instances, Resources are respectively named O-Attribute, OI-Attribute, R-Attribute.

These Attributes MAY be carried in the message payload of Registration and Discover operations; they also MAY be updated - when writable - through the Write-Attributes operation.

There are two types of attributes:

PROPERTIES Class Attributes, or Object Attributes

The role of these Attributes is to provide metadata which may communicate helpful information to the LwM2M Server, for example easing data management. Thingsboard supports Object Version attribute, which indicates the version of the associated Object and is displayed in the results of DiscoverAll command.

You can find more details about all available in LwM2M Object attributes here: PROPERTIES Class Attributes

NOTIFICATION Class Attributes, or Resource Attributes

The role of these R-Attributes is to provide parameters to the “Notify” operation, which is used for the resource observation. Any readable Resource can have such R-attributes.

Following NOTIFICATION attributes are available on the TB Platform to configure observation parameters:

• “pmin” - Minimum period - indicates the minimum time in seconds the LwM2M Client MUST wait between two notifications. If a notification of an observed Resource is supposed to be generated but it is before pmin expiry, notification MUST be sent as soon as pmin expires. In the absence of this parameter, the Minimum Period is defined by the Default Minimum Period set in the LwM2M Server Account.

• “pmax” - Maximum period - indicates the maximum time in seconds the LwM2M Client MAY wait between two notifications. When this “Maximum Period” expires after the last notification, a new notification MUST be sent. In the absence of this parameter, the “Maximum Period” is defined by the Default Maximum Period when set in the LwM2M Server Account or considered as 0 otherwise. The value of 0, means pmax MUST be ignored. The maximum period parameter MUST be greater than the minimum period parameter otherwise pmax will be ignored for the Resource to which such inconsistent timing conditions are applied.

• “gt” - Greater than - defines a threshold high value. When this Attribute is present, the LwM2M Client MUST notify the Server each time the Observed Resource value crosses this threshold with respect to pmin parameter and valid “Change Value Conditions” (see Notification Conditions above).

• “lt” - Less than - defines a threshold low value. When this Attributes is present, the LwM2M Client MUST notify the Server each time the Observed Resource value crosses this threshold with respect to pmin parameter and valid “Change Value Conditions” (see Notification Conditions above).

• “st” - Step - defines a threshold low value. When this Attributes is present, the LwM2M Client MUST notify the Server each time the Observed Resource value crosses this threshold with respect to pmin parameter and valid “Change Value Conditions” (see Notification Conditions above).

Please find more more details about all available in LwM2M NOTIFICATION attributes here..

Notification attributes can be configured in the Device Profile, please follow the guide:

DTLS configuration

The Thingsboard platform supports secured connection using DTLS. DTLS, which stands for Datagram Transport Layer Security, is based on the Transport Layer Security (TLS) protocol and built on top of the User Datagram Protocol (UDP). Thingsboard allows the use of DTLS with the LwM2M transport connection for devices.

You can find detailed information about LWM2M DTLS-based Security here.

There are three authentication methods available on the Thingsboard for LwM2M DTLS: using the Pre-Shared Key(PSK), using the Raw Public Key(RPK) and using the X.509 certificate.

To use DTLS, the end-user device has to connect to the ThingsBoard server using secured port 5686.

For the demonstration purpose we will use Leshan Demo Client, please refer to the link for downloading and configuration: here

1. Pre-shared Key mode (PSK).

The pre-shared key profile offers the most resource-efficient solution for integration of DTLS into LwM2M since pre-shared ciphersuites recommended in [RFC7925] require a minimum amount of flash space as well as RAM in your device.

Symmetric cryptographic algorithms require only a minimal computational overhead. The size of the exchanged messages is also kept at a minimum. There is, however, a downside as well: symmetric keys need to be preconfigured to both communication endpoints.

You need only three strings to configure the connection in the Device profile:

• Endpoint client name: which is used to identify the device and can be any text string.
• Client identity (PSK identity) key: any text string.
• PSK key (security key): should be a random sequence in HexDec format and 32, 64 or 128 characters long.

Example of using Leshan Demo Client:

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Endpoint client name= "ClientPsk";
Client identity (PSK identity) = "ClientPskIdentity";
Client key (PSK key or PSK security key) = "0123456789ABCDEF0123456789ABCDEF";

Example command for start “Leshan client demo” in mode PSK:

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java -jar leshan-client-demo.jar -u localhost:5686 -lh 0.0.0.0 -lp 10004 -n ClientPsk -i ClientPskIdentity 
-p 0123456789ABCDEF0123456789ABCDEF
    
Leshan Client Demo Interactive Console :
...
DefaultRegistrationEngine 2021-09-30 19:09:52,789 [INFO] Trying to register to coaps://192.168.1.81:5686 ...
LeshanClientDemo 2021-09-30 19:09:52,830 [INFO] DTLS Full Handshake initiated by client : STARTED ...
LeshanClientDemo 2021-09-30 19:09:52,949 [INFO] DTLS Full Handshake initiated by client : SUCCEED
DefaultRegistrationEngine 2021-09-30 19:09:52,990 [INFO] Registered with location '/rd/vXMGfVFgQi'.
...

2. Raw Public Key(RPK) mode.

The raw public key profile offers features that sit between the pre-shared key and the certificate-based mode and combines the benefits of these two profiles. The use of asymmetric cryptography offers improved security but avoids the overhead associated with certificates and the public key infrastructure.

To configure the connection, you need to do following steps:

• Generate Client keys and copy-paste the Client Public key to the Device Credentials - Client Key on the Thingsboard platform.
• Generate Server keys and add them to the Server key-storage file lwm2mserver.jks, copy the file back to the server installation folder.
• Configure your client’s connection.

We will use OpenSSl tool and follow the guide from Leshan: here

Note: This step requires Linux-based OS with Java installed.

1. Create a separate folder where we will keep all generated keys.
2. Thingsboard keeps server keys in the key-storage file “lwm2mserver.jks”, please find and copy this file to our folder. Default key file location is:

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/common/transport/lwm2m/src/main/resources/credentials/lwm2mserver.jks

3. We will use the script below to generate all necessary keys. Just create a text file with any text editor, copy the script into it and save the file with *.sh extention, for example ‘generate-rpk.sh’

generate-rpk.sh

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#!/bin/bash
#
# Copyright © 2016-2021 The Thingsboard Authors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#
# RPK. Generation of the keys.
echo "====START RPK ========"
echo "Generating client keys..."

# Create EC key pair (private and public) using default openssl pem encoding:
openssl ecparam -out keysClient.pem -name prime256v1 -genkey

# Convert Client Private Key to PKCS#8 format (DER encoding):
openssl pkcs8 -topk8 -inform PEM -outform DER -in keysClient.pem -out cprik.der -nocrypt

# Output Client Public Key portion in SubjectPublicKeyInfo format (DER encoding):
openssl ec -in keysClient.pem -pubout -outform DER -out cpubk.der

echo "Client public key in base64 format. Copy this key to the Thingsboard - Client Key field in Device Credentials"
base64 cpubk.der

# get server keys

# Importing keystore lwm2mserver.jks alias="server" to scertServer.p12
keytool -importkeystore -srckeystore lwm2mserver.jks -alias server -destkeystore scertServer.p12 -deststoretype PKCS12

# Importing keystore lwm2mserver.jks to scert.p12...
# Enter destination keystore password:  server_ks_password
# Re-enter new password: server_ks_password
# Enter source keystore password:  server_ks_password

# Generating scertServer.pem:
openssl pkcs12 -in scertServer.p12  -nodes -nocerts -out scertServer.pem
echo Enter Import Password: server_ks_password

# Server public key in base64 format  (spubk.pem):
openssl ec -in scertServer.pem -pubout -outform DER -out spubk.der

Please note that script us using the default password for “lwm2mserver.jks” file. If you are going to use another password, please also update it in “thingsboard.yml” configuration file:

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...
lwm2m:
    ...
    server:
      ...
      security:
        ...
        key_alias: "${LWM2M_SERVER_KEY_ALIAS:server}"
        key_password: "${LWM2M_SERVER_KEY_PASSWORD:server_ks_password}"
        ...

4. To run the script, use following commands:

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chmod +x generate-rpk.sh
sudo ./generate-rpk.sh

This script will run keytool and ssh utilities. It will generate the following output files:

• lwm2mserver.jks - Server keystore file.
• keysClient.pem - Client Public \ Private Key pair
• cprik.der - Client Private Key in DER format with Base64 encryption
• cpubk.der - Client Public Key in DER format
• spubk.der - Server public key in DER format
• scertServer.pem - Server public key with no encryption

5. Configure Device on the Thingsboard platform:

• Endpoint name: input unique text string used to identify the client device
• Client key: In terminal, Open the cprik.der file using Base64 command and copy the code to Client key field:

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#command:
$ Base64 cpubk.der

#Output:
MFkwEwYHKoZIzj0CAQYIKoZIzj0DAQcDQgAEdvBZZ2vQRK9wgDhctj6B1c7bxR3Z0wYg1+YdoYFnVUKWb+rIfTTyYK9tmQJx5Vlb5fxdLnVv1RJOPiwsLIQbAA==

6. Example command to launch “Leshan demo client” in RPK mode:

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#command:
$ java -jar leshan-client-demo.jar -u localhost:5686 -lh 0.0.0.0 -lp 10004 -n ClientRpk -cpubk cpubk.der -cprik cprik.der -spubk spubk.der

#Output:
Leshan Client Demo Interactive Console :
 
Commands:
  help	Displays help information about the specified command
  create  Enable a new Object
  delete  Disable a new object
  update  Trigger a registration update.
  send	Send data to server
  move	Simulate client mouvement.
 
Press Ctl-C to exit.
 
              	LeshanClient 2021-10-27 10:37:21,196 [INFO] Starting Leshan client ...
   CaliforniumEndpointsManager 2021-10-27 10:37:21,470 [INFO] New endpoint created for server coaps://18.184.200.162:5686 at coaps://[0:0:0:0:0:0:0:0]:10004
              	LeshanClient 2021-10-27 10:37:21,472 [INFO] Leshan client[endpoint:leshan-rpkz] started.
 	DefaultRegistrationEngine 2021-10-27 10:37:21,474 [INFO] Trying to register to coaps://18.184.200.162:5686 ...
          	LeshanClientDemo 2021-10-27 10:37:21,549 [INFO] DTLS Full Handshake initiated by client : STARTED ...
          	LeshanClientDemo 2021-10-27 10:37:21,729 [INFO] DTLS Full Handshake initiated by client : SUCCEED
 	DefaultRegistrationEngine 2021-10-27 10:37:21,771 [INFO] Registered with location '/rd/yyIIQFyg6H'.
 	DefaultRegistrationEngine 2021-10-27 10:37:21,773 [INFO] Next registration update to coaps://18.184.200.162:5686 in 53s...