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OSRAM Lightify Binary Protocol Documentation

OSRAM Lightify is a smart home, connected lightning technology. Lights, switches and other paired devices are controlled using the Lightify gateway device. This gateway is an always-on, always-connected device which can be controlled using the official Lightify REST API on the Lightify Cloud. That, however, means that all commands need to be routed through the internet.

The official Lightify app, on the other hand, communicates directly with the gateway and uses a proprietary binary protocol which is not publicly specified.

This document is meant to create a public specification of the known facts about how to discover gateway devices, paired devices and zones/groups, as well as how to control those devices.

Disclaimer

All information in this document are collected using reverse engineering practices or are available by other implementations / people on the internet. Certain information might be incorrect, outdated or unspecific. Any help completing this document is appreciated, please file pull requests.

Using and/or implementing information in this document might brick your device, render it unfunctional, change behavior of any connected device and/or may void your warranty. Any action taken upon information in this document is strictly at your own risk. The author(s) are not liable for any losses and damages in connection with the use of this document.

The author(s) are not affiliated to OSRAM Light AG in any way. Furthermore is this document not official publicated or approved by OSRAM Licht AG.

Basics about the Protocol

The OSRAM Lightify gateway protocol is a binary protocol with a specified header.

The underlying protocol is a persistent TCP connection which does not seem to support multiplexing, therefore multiple requests should be sent one after another. To support multithreading, multiple connections should be used.

The TCP protocol works over port 4000 and discovery can be implemented using mDNS (multicast DNS, aka Bonjour). Further information in Lightify Gateway Discovery.

Multibyte values encoded using little-endian encoding and considered unsigned values.

String values are encoded using UTF-8 encoding and of fixed length. Unused bytes are filled with 0x00 and should be trimmed out to get the real string.

Headers

The protocol defines a common header for both requests and responses. The header consists of the packet’s length, a packet type and the command id.

Furthermore the header contains a request id which is recommended, but not required, to be monotonly increasing but must wrapping around to startover when surpassing 0xFFFFFFFF. The response will feature the same request id and can be used to correlate responses with requests.

Table 1. Packet Header
Byte(s) Description Data type

0-1

Length of the packet, excl header length

uint16_t

2

Packet type (flag)

uint8_t: enum {
0x00: Light Device
0x01: Device response?
0x02: Broadcast / Zone Command
0x03: Zone Response?
}

3

Command Id

uint8_t: See Lightify Commands

4-7

Unique, increasing request id

uint32_t

Response packets have an additional field in the header, which seems to return a status / error code for the request.

Table 2. Response Header Status Code
Byte(s) Description Data type

8

Status code?

uint8_t: enum {
0x00: No error?
0x01: Wrong (number of) parameter(s)?
0x14: ?
0x15: Command is not a broadcast?
0x16: Resync required (gateway expects the next packet to be PACKET_LIST_PAIRED_DEVICES) 0xA7: ?
0x0B: ?
0xC2: ?
0xD1: ?
0xFF: Unknown command?
}

If the packet is not a broadcast (addressing type != 0x02), the device or zone address header is following up right after the header. In case of a broadcast, the header is followed by the commands data. Addressing of specific zones or devices is defined in the following section.

Error Response

In case of an illegally addressed packet or any other type of error, an error response packet is returned from the gateway. The packet consists of the header only and the last byte seems to define an error code. See previous table for a list of known? error codes.

Device Types

The OSRAM Lightify gateway uses the Zigbee Light Link communication protocol, however it is also able to communicate with certain other device types of the Lightify series, such as switches, motion sensors and power plugs / sockets.

A device type is sent with status updates to identify the type of the device as well as the capabilities of a specific device.

Table 3. Device Type
Id Description

1

Bulb: Fixed white, dimmable, non-softswitch

2

Bulb: Tunable white, dimmable, soft-switchable

4

Bulb: Fixed white, dimmable, soft-switchable

10

Bulb: RGB, tunable white, dimmable, soft-switchable

16

Plug / Power socket

32

Motion Sensor

64

Switch (2 switches)

65

Switch (4 switches)

Device and Zone Addressing

Each paired device has a unique address (MAC). Multiple paired devices can be controlled at once by adding them to zones / groups, which are addressed using the zone’s id.

An address always contains 8 byte, no matter it’s adressing a device or zone and is directly followed by the command’s specific data.

Table 4. Addressing Header
Byte(s) Description Data type

8-15

Address

uint64_t: See the following specification

16-…​

Command specific data

See Lightify Commands

Device address

Devices are addressed by, what seems to be, a hardware address, similar to MAC addresses used in networking devices.

Table 5. Device Addressing
Byte(s) Description Data type

0-7

Device address

uint64_t

While discovering devices the device’s address is made known to the application, controlling the gateway, and the paired device can be addressed directly (whereas the command packet is still routed through the gateway).

Attention: Device addresses are transmitted as 8 bytes, not as strings!

Zone address

Zones are identified by their zone id. Addressing itself, however, is still using 8 bytes, even if zone ids seem to be limited to 0xFFFF. That said, the addressing is built as following:

Table 6. Zone Addressing
Byte Data type

1

uint8_t: lower significant byte

2

uint8_t: higher significant byte

3-7

uint8_t[6]: 0x00

Attention: Also note, that zone commands have a packet type of 0x02 at byte position 2 in the packet’s header.

Lightify Gateway Discovery

To discover the OSRAM Lightify gateway’s IP address, a mDNS (multicast DNS) request is used. mDNS is also known as Bonjour and is originally developed by Apple.

To find the gateway’s address a SSDP lookup request is sent to the UDP broadcast address 224.0.0.251 (IPv4) or FF02::FB (IPv6). The service type to search for is _http._tcp which will find a Lightify device named as Lightify-XXXXXXXX, where XXXXXXXX is a part of the gateway’s serial number (S/N: OSRXXXXXXXX-YY) which is also used in the gateway’s own SSID (last 6 numbers of the code).

Since more items, especially of other vendors, might be found, the instance name should be tested for starting with Lightify- to make sure only the Lightify gateway is discovered.

According to the search type and the mDNS response, there is supposed to be a HTTP service on port 80, which does not seem to exist. However, the gateway seems to communicate over QUIC to the OSRAM servers, so maybe the port 80 is also available using QUIC.

After discovering the gateway’s IP address, the communication port to use the described protocol is TCP/4000.

Lightify devices and zones will be discovered using the gateway binary protocol, using tge commands PACKET_LIST_PAIRED_DEVICES and PACKET_LIST_ZONES.

Lightify Commands

Lightify commands are either used for broadcasts, like device or zone discovery, or contain information to control a specfic device or zone.

The following table is most probably incomplete and more commands are available. Response packets often follow a very similar scheme, therefore it should be easy to find new packets and analyze their content.

Known command ids are put into the following list:

Table 7. Commands
Command Id Description Addressing Packet Definition

0x02

Unknown, 1 byte data ⇒ no error

BROADCAST?

???

0x0A

Unknown, byte data ⇒ no error

BROADCAST?

???

0x0B

Unknown, 1 byte data ⇒ error 0x01

BROADCAST?

???

0x13

List paired devices

BROADCAST

PACKET_LIST_PAIRED_DEVICES

0x15

Unknown, 1 byte data ⇒ no error

BROADCAST?

???

0x16

Unknown, error code 15 (wrong addressing)

ZONE?, DEVICE?

???

0x1C

Unknown, 1 byte data ⇒ error 0x0B, 0x19

BROADCAST?

???

0x1D

Unknown, 1 byte data ⇒ no error

BROADCAST?

???

0x1E

List configured zones

BROADCAST

PACKET_LIST_ZONES

0x1F

List defined scenes

BROADCAST

PACKET_LIST_SCENES

0x20

Add Device to Zone

DEVICE?

???

0x21

Remove Device from Zone

DEVICE?

???

0x26

Get Zone information

ZONE

PACKET_GET_ZONE_INFO

0x27

Set Zone name

ZONE?

???

0x28

Set Device name

DEVICE?

???

0x29

Unknown, 1 byte data ⇒ ~1k bytes returned (all zero)

BROADCAST?

???

0x31

Set luminance of light or zone

ZONE, DEVICE

PACKET_SET_LUMINANCE

0x32

Set power switch on/off (also set default???)

ZONE, DEVICE

PACKET_SET_SWITCH

0x33

Set white light temperature

ZONE, DEVICE

PACKET_SET_TEMPERATURE

0x34

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x36

Set light color (RGB)

ZONE, DEVICE

PACKET_SET_COLOR

0x37

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x38

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x51

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x52

Activate scene

BROADCAST

PACKET_ACTIVATE_SCENE

0x53

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x54

Unknown, returned actual data (uint16_t(0,0))

BROADCAST?

???

0x55

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x56

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x57

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x58

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x61

Unknown, retured unknown error code 0xD1, 0xC2

BROADCAST?

???

0x62

Unknown, retured unknown error code 0xD1

BROADCAST?

???

0x63

Unknown, retured unknown error code 0xD1

BROADCAST?

???

0x64

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x66

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x67

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x68

Get device information

DEVICE

PACKET_GET_DEVICE_INFO

0x6A

Unknown, retured unknown error code 0xD1

BROADCAST?

???

0x6B

Unknown, retured unknown error code 0xD1

BROADCAST?

???

0x6D

Unknown, retured unknown error code 0xD1

BROADCAST?

???

0x6F

Gateway Firmware version

BROADCAST

PACKET_GET_GATEWAY_FIRMWARE_VERSION

0x70

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x71

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x76

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x79

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x7A

Unknown, wrong addressing

ZONE?, DEVICE?

???

0x7B

Unknown, 1 byte data ⇒ no error

BROADCAST?

???

0x7C

Unknown, 1 byte data ⇒ wrong addressing

ZONE?, DEVICE?

???

0x7D

Unknown, retured unknown error code 0x16 - no return with data, maybe firmware update?

???

???

0x91

Unknown, retured unknown error code 0xA7, 0xC2

???

???

0xC0

Unknown, no error

BROADCAST?

???

0xC1

Unknown, no error

BROADCAST?

???

0xC3

Unknown, wrong addressing

ZONE?, DEVICE?

???

0xC4

Unknown, wrong addressing

ZONE?, DEVICE?

???

0xC6

Unknown, no error

BROADCAST?

???

0xC7

Unknown, wrong addressing

ZONE?, DEVICE?

???

0xC8

Unknown, wrong addressing

ZONE?, DEVICE?

???

0xD0

Unknown, retured unknown error code 0xD1

???

???

0xD1

Unknown, no response, system reset?

???

???

0xD2

Unknown, 1 byte data ⇒ 0xD1, crashed? needs restart

???

???

0xD3

Unknown, no answer (0x00), firmware update or more data?

???

???

0xD4

Unknown, no answer (0x00), firmware update or more data?

???

???

0xD5

Set Color Wheel? HSL?

ZONE?, DEVICE?

???

0xD6

Unknown, wrong addressing

ZONE?, DEVICE?

???

0xD8

Unknown, wrong addressing

ZONE?, DEVICE?

???

0xD9

Unknown, wrong addressing (scene builder???)

ZONE?, DEVICE?

???

0xDA

Unknown, wrong addressing

ZONE?, DEVICE?

???

0xDB

Soft on, wrong addressing

ZONE?, DEVICE?

???

0xDC

Soft off, wrong addressing

ZONE?, DEVICE?

???

0xDD

Remove all scenes and groups

ZONE?, BROADCAST?

???

0xD0

Unknown, no error (0x00)

BROADCAST?

???

0xE1

Unknown, wrong addressing

ZONE?, DEVICE?

???

0xE2

Unknown, no answer

BROADCAST?

???

0xE3

Get / Scan / Set Wifi Configuration

BROADCAST

PACKET_GET_WIFI_CONFIGURATION

0xE4

Unknown, activates light (with 1 byte data) - seems to reset the light

BROADCAST?

???

0xE5

Unknown, returned actual data (uint64_t(1,0,0,0))

BROADCAST?

???

0xE6

Unknown, returned actual data (uint16_t(1,15))

BROADCAST?

???

0xE6

Unknown, returned actual data (uint16_t(1,15))

BROADCAST?

???

0xE7

Unknown, no answer

BROADCAST?

???

0xE8

Unknown, retured unknown error code 0x16

BROADCAST?

???

0xE9

Unknown, retured unknown error code 0xD1

BROADCAST?

???

0xEA

Unknown, retured unknown error code 0xD1

BROADCAST?

???

As visible from the list, a lot of command ids seem either unused or, what is more presumable, unknown at the current point in time.

Command data

Most commands carry additional information starting after the header (for broadcast packets) or after the addressing header (non-broadcast packets).

The following sections define the packet’s structure after either of both headers, according to the command type.

PACKET_LIST_PAIRED_DEVICES

Returns a list of all paired devices.

Table 8. Request data
Byte(s) Description Data type

16

Unknown

uint8_t: always? 0x01

Table 9. Response data
Byte(s) Description Data type

9-10

Number of devices

uint16_t

…​50 bytes each device

Device status information

See following table

Table 10. Device status information
Byte(s) Description Data type

0-1

Device id?

uint16_t

2-9

Device address

uint64_t: See Device address

10

Device type?

uint8_t: See Device Types

11-14

Firmware version

uint8_t[5]: Translation into firmware version string →
{%02d, uint8_t[0]}{%02d, uint8_t[1]}{%02d, uint8_t[2]}+uint8_t[3]

15

Reachable

uint8_t: 0x00 online, 0xFF offline

16-17

Zone Id

uint16_t

18

Power switch status

uint8_t: bool

19

Luminance value / Battery value (Motion Detector)

uint8_t

20-21

Temparature value (in Kelvin)

uint16_t: 2,000 >= x ⇐ 6,500

22

Red value / Enabled value (Motion Detector)

uint8_t

23

Green value / Triggered value (Motion Detector)

uint8_t

24

Blue value

uint8_t

25

Alpha value

uint8_t: always? 0xFF

26-41

Device name

uint8_t[16]: UTF-8 encoded, zero terminated string

42-45

Time since last seen by gateway

uint32_t

46-49

Joining?

uint32_t

PACKET_LIST_ZONES

Returns a list of all configured zones.

Table 11. Request data
Byte(s) Description Data type

-

No additional information to send

-

Table 12. Response data
Byte(s) Description Data type

9-10

Number of zones

uint16_t

…​18 bytes each zone

Zone information

See following table

Table 13. Zone information
Byte(s) Description Data type

0-1

Zone id

uint16_t

2-17

Zone name

uint8_t[16]: UTF-8 encoded, zero terminated string

Assigned devices need to be discovered using PACKET_GET_ZONE_INFO after the zone id has been seen with this packet.

PACKET_LIST_SCENES

Returns a list of defined scenes.

Table 14. Request data
Byte(s) Description Data type

-

No additional information to send

-

Table 15. Response data
Byte(s) Description Data type

0-1

Number of Scenes

uint16_t

…​20 bytes each scene

Scene information

See following table

Table 16. Scene information
Byte(s) Description Data type

0

Scene id

uint8_t

1

Unknown, seems to always be 0x64 (@-sign)

uint8_t

2-17

Scene name

uint8_t[16]: UTF-8 encoded, zero terminated string

18-19

Unknown

uint16_t

20

Next Scene id (chaining scenes?)

uint8_t

PACKET_GET_ZONE_INFO

Returns information about the requested zone, including assigned devices.

Table 17. Request data
Byte(s) Description Data type

-

No additional information to send

-

Table 18. Response data
Byte(s) Description Data type

9-10

Zone id

uint32_t

11-27

Zone name

uint8_t[16]: UTF-8 encoded, zero terminated string

28

Number of assigned devices

uint8_t

…​8 bytes each device

Device addresses

See Device address

PACKET_SET_LUMINANCE

Sets the luminance value of the addressed device or zone.

Table 19. Request data
Byte(s) Description Data type

16

Luminance value

uint8_t

17-18

Transition time in millis

uint16_t

Table 20. Response data
Byte(s) Description Data type

9-10

Device or zone id

uint16_t

11-18

Device or zone address

uint64_t: See Device and Zone Addressing

PACKET_SET_SWITCH

Sets the power switch state of the addressed device or zone.

Table 21. Request data
Byte(s) Description Data type

16

Power switch state

uint8_t: bool

Table 22. Response data
Byte(s) Description Data type

9-10

WRONG:Device or zone id??? Number of devices changed?

uint16_t

11-18

Device or zone address

uint64_t: See Device and Zone Addressing

PACKET_SET_TEMPERATURE

Sets the white light temperature of the addressed device or zone between 2,000 and 6,500 Kelvin.

Table 23. Request data
Byte(s) Description Data type

16

White light temperature

uint16_t: 2,000 >= x ⇐ 6,500

17-18

Transition time in millis

uint16_t

Table 24. Response data
Byte(s) Description Data type

9-10

Device or zone id

uint16_t

11-18

Device or zone address

uint64_t: See Device and Zone Addressing

PACKET_SET_COLOR

Sets the RGB color value of the addressed device or zone.

Table 25. Request data
Byte(s) Description Data type

16

Red value

uint8_t

17

Green value

uint8_t

18

Blue value

uint8_t

19

Alpha value

uint8_t: always 0xFF?

20-21

Transition time in millis

uint16_t

Table 26. Response data
Byte(s) Description Data type

9-10

Device or zone id

uint16_t

11-18

Device or zone address

uint64_t: See Device and Zone Addressing

PACKET_ACTIVATE_SCENE

Activates a predefined scene on the addressed device or zone.

Table 27. Request data
Byte(s) Description Data type

16

Scene id

uint8_t: 0x00 to 0x0F for the different predefined scenes

Table 28. Response data
Byte(s) Description Data type

9-10

Device or zone id

uint16_t

11-18

Device or zone address

uint64_t: See Device and Zone Addressing

PACKET_GET_DEVICE_INFO

Returns information about the requested device.

Table 29. Request data
Byte(s) Description Possible values

-

No additional information to send

-

Table 30. Response data
Byte(s) Description Data type

9-10

Device id?

uint16_t

11-18

Device address

uint64_t: See Device address

19

Reachable

uint8_t: 0x00 online, 0xFF offline

20

Unknown

uint8_t: ???

21

Power switch status

uint8_t: bool

22

Luminance value / Battery value (Motion Detector)

uint8_t

23-24

Temparature value (in Kelvin)

uint16_t: 2,000 >= x ⇐ 6,500

25

Red value / Enabled value (Motion Detector)

uint8_t

26

Green value / Triggered value (Motion Detector)

uint8_t

27

Blue value

uint8_t

28

Alpha value

uint8_t: always 0xFF?

29-31

Unknown

uint8_t[3]: ???

If the response packet’s byte at index 19 is 0xFF (the device is offline / non-reachable) the packet is only those 20 bytes, otherwise the full packet comes back.

PACKET_GET_WIFI_CONFIGURATION

Retrieves or configures the wifi configuration.

Table 31. Request data
Byte(s) Description Data type

16

Subcommand

uint8_t: enum {
0x00: Get wifi configuration
0x01: Set wifi configuration
0x03: Scan wifi configuration
}

Table 32. Response data
Byte(s) Description Data type

9

Number of profiles

uint8_t

…​97 bytes each profile

Profile information

See following table

Table 33. Profile information
Byte(s) Description Data type

0-31

Profile Name

uint8_t[32]: UTF-8 encoded, zero terminated string

32-64

SSID

uint8_t[33]: UTF-8 encoded, zero terminated string

65-70

BSSID

uint8_t[6]: UTF-8 encoded, zero terminated string

71-74

Channel

uint32_t

75-76

Unknown

uint16_t: ???

77-80

IP Address

uint64_t: 4 bytes of IP address

81-84

Gateway

uint64_t: 4 bytes of IP address

85-88

Netmask

uint64_t: 4 bytes of IP address

89-92

DNS #1

uint64_t: 4 bytes of IP address

93-96

DNS #2

uint64_t: 4 bytes of IP address

PACKET_GET_GATEWAY_FIRMWARE_VERSION

Retrieves the current firmware version of the gateway.

Table 34. Request data
Byte(s) Description Data type

-

No additional information to send

-

Table 35. Response data
Byte(s) Description Data type

9-12

Firmware version

uint8_t[4]: Translation into firmware version string →
{%02d, uint8_t[0]}{%02d, uint8_t[1]}{%02d, uint8_t[2]}+{%02d, uint8_t[3]}

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