When reset the rx info of transport layer, the
rpl list will always cleared, and rpl stored
in the nvs will only be erased when erase flag
is true and BLE_MESH_SETTINGS is enabled.
Compared with the previous solution, it should
be more clear.
Since we have provided separate functions for deleting node
information with node's unicast address, device uuid, etc.
So we update the behavior of this function, which will only
be used to delete device information which is not provisioned
or just under provisioning.
- Previously when a model is initialized or deinitialized, in the
access layer, we need to check the model id with the ids in the
table in order to find the proper model operation function.
- Currently all the operation functions of each model will be set
during the mesh initialization. When the model is found, we can
directly use the corresponding callback for different operations.
- Currently only init/deinit operations are registered, later we
will add more operations.
Currently only keep func pointer for the followings:
- Invalid parameter (mesh btc & mesh stack)
- Out of memory (mesh btc & mesh stack)
- Unknown act (mesh btc)
- Invalid model user data (mesh stack)
- BT_DBG("%s", __func__) (mesh btc & mesh stack)
- A few other specific situations (buf ref debug, send status check)
Split mesh_util.h into mesh_byteorder.h, mesh_compiler.h,
mesh_ffs.h and mesh_util.h based on the classification of
Zephyr, which will make further porting more clear.
Until now the choice of reliable sending (segmented messages with
acks) was implicitly dependent on the size of the payload. Add a new
member to the bt_mesh_model_pub to force using segment acks even when
the payload would fit a single unsegmented message.
1. BLE Mesh Core
* Provisioning: Node Role
* PB-ADV and PB-GATT
* Authentication OOB
* Provisioning: Provisioner Role
* PB-ADV and PB-GATT
* Authentication OOB
* Networking
* Relay
* Segmentation and Reassembly
* Key Refresh
* IV Update
* Proxy Support
* Multiple Client Models Run Simultaneously
* Support multiple client models send packets to different nodes simultaneously
* No blocking between client model and server
* NVS Storage
* Store BLE Mesh node related information in flash
* Store BLE Mesh Provisioner related information in flash
2. BLE Mesh Models
* Foundation Models
* Configuration Server Model
* Configuration Client Model
* Health Server Model
* Health Client Model
* Generic
* Generic OnOff Server
* Generic OnOff Client
* Generic Level Server
* Generic Level Client
* Generic Default Transition Time Server
* Generic Default Transition Time Client
* Generic Power OnOff Server
* Generic Power OnOff Setup Server
* Generic Power OnOff Client
* Generic Power Level Server
* Generic Power Level Setup Server
* Generic Power Level Client
* Generic Battery Server
* Generic Battery Client
* Generic Location Server
* Generic Location Setup Server
* Generic Location Client
* Generic Admin Property Server
* Generic Manufacturer Property Server
* Generic User Property Server
* Generic Client Property Server
* Generic Property Client
* Sensor Server Model
* Sensor Server
* Sensor Setup Server
* Sensor Client
* Time and Scenes
* Time Server
* Time Setup Server
* Time Client
* Scene Server
* Scene Setup Server
* Scene Client
* Scheduler Server
* Scheduler Setup Server
* Scheduler Client
* Lighting
* Light Lightness Server
* Light Lightness Setup Server
* Light Lightness Client
* Light CTL Server
* Light CTL Setup Server
* Light CTL Client
* Light CTL Temperature Server
* Light HSL Server
* Light HSL Setup Server
* Light HSL Client
* Light HSL Hue Server
* Light HSL Saturation Server
* Light xyL Server
* Light xyL Setup Server
* Light xyL Client
* Light LC Server
* Light LC Setup Server
* Light LC Client
3. BLE Mesh Applications
* BLE Mesh Node
* OnOff Client Example
* OnOff Server Example
* BLE Mesh Provisioner
* Example
* Fast Provisioning
* Vendor Fast Prov Server Model
* Vendor Fast Prov Client Model
* Examples
* Wi-Fi & BLE Mesh Coexistence
* Example
* BLE Mesh Console Commands
* Examples
