Client SDK to connect with ThingsBoard IoT Platform from various IoT devices (Arduino, Espressif, etc.)
This library provides access to the ThingsBoard platform over the MQTT
or HTTP(S)
protocols.
The SDK comes with a number of example sketches. See Files --> Examples --> ThingsBoard within the Arduino application.
Please review the complete guide for ESP32
Pico Kit GPIO
control and DHT22
sensor monitoring available here.
ThingsBoardArduinoSDK
does not directly depend on any specific MQTT Client
or HTTP Client
implementation, instead any implementation of the IMQTT_Client
or IHTTP Client
can be used. Because there are no further dependencies on Arduino
, besides the client that communicates it allows us to use this library with Arduino
, when using the Arduino_MQTT_Client
or with Espressif IDF
when using the Espressif_MQTT_Client
.
Example usage for Espressif
can be found in the examples/0014-espressif_esp32_send_data
folder, all other code portions can be implemented the same way only initialization of the needed dependencies is slightly different. Meaning internal call to ThingsBoard
works the same on both Espressif
and Arduino
.
This is also the case, because the only always used dependency that is remaining, is ArduinoJson
, which despite its name does not require any Arduino
component. Please Note: you must use v6.x.x
of this library as v7.x.x
is not yet supported. Please see this issue for details as to why.
This project can be built with either PlatformIO, ESP IDF Extension
or Arduino IDE.
The project can be found in the PlatformIO Registry, ESP Component registry or the Arduino libraries.
A description on how to include the library in you project can be found below for each of the aforementioned possible methods of integrating the project.
To add an external library, the most important portion is the lib_deps
specification, simply add thingsboard/ThingsBoard
.
There are multiple ways to define the version that should be fetched, but the most basic is simply getting the last released version, with the aforementioned line, to learn more see Package Specifications.
lib_deps=
thingsboard/ThingsBoard
To add an external library, what needs to be done differs between versions. If an ESP-IDF version after and including v3.2.0
is used
then the project can simply be added over the Component Manager.
To do that we can simply call idf.py add-dependency <DEPENDENCY>
, with the name of the dependency as an argument. Similar to PlatformIO
there are a multiple way to define the version that should be fetched, but the method below is the most basic to simply get the last released version, to learn more see Using Component Manager with a Project.
idf.py add-dependency "thingsboard/ThingsBoard"
If an ESP-IDF version prior to v3.2.0
is used then the component has to be added as a git submodule
.
Meaning the repository has to first be a git
project, if that is not the case already simply install git
and call git init
in the folder containing your project.
Similar to the other call there are a multiple way to define the version that should be fetched, but the method below is the most basic to simply get the last released version, to learn more see Git Submodule Help page.
git submodule add https://github.com/thingsboard/thingsboard-client-sdk.git components/ThingsBoard
To add an external library, we simply have to open Tools
-> Manage Libraries
and then search for ThingsBoard
then press the install
button for the wanted version. See how to install library on Arduino IDE for more detailed information and some troubleshooting if the aforementioned method does not work.
Following dependencies are installed automatically or must be installed, too:
Installed automatically:
- ArduinoJSON — needed for dealing with the
JSON
payload that is sent to and received byThingsBoard
. Please Note: you must usev6.x.x
of this library asv7.x.x
is not yet supported. Please see this issue for details as to why.
Needs to be installed manually:
- MQTT PubSub Client — for interacting with
MQTT
, when using theArduino_MQTT_Client
instance as an argument toThingsBoard
. - Arduino Http Client — for interacting with
HTTP/S
when using theArduino_HTTP_Client
instance as an argument toThingsBoardHttp
. - MbedTLS Library — needed to create hashes for the OTA update for non
Espressif
boards. - Arduino Timer - needed to create non-blocking callback timers for non
Espressif
boards. - WiFiEsp Client — needed when using a
Arduino Uno
with aESP8266
. - StreamUtils — needed when sending arbitrary amount of payload even if the buffer size is too small to hold that complete payload is wanted, aforementioned feature is automatically enabled if the library is installed.
Example implementations for all base features, mentioned above, can be found in the examples
folder. See the README.md
in each example folder, to see which boards are supported and which functionality the example shows.
All possible features are implemented over MQTT
over a specific IAPI_Implementation
instance:
- Telemetry data upload /
ThingsBoardSized
- Device attribute publish /
ThingsBoardSized
- Server-side RPC /
Server_Side_RPC
- Client-side RPC /
Client_Side_RPC
- Request attribute values /
Attribute_Request_Callback
- Attribute update subscription /
Shared_Attribute_Update
- Device provisioning /
Provision
- Device claiming /
ThingsBoardSized
- Firmware OTA update /
OTA_Firmware_Update
The remaining features have to be implemented by hand with the sendGetRequest
or sendPostRequest
method. See the ThingsBoard Documentation on how these features could be implemented. This is not done directly in the library, because most features require constant polling, whether an event occurred or not, this would cause massive overhead if it is done for all possible features and therefore not recommended.
This troubleshooting guide contains common issues that are well known and can occur if the library is used wrongly. Ensure to read this section before creating a new GitHub Issue
.
If the device is causing problems that are not already described in more detail below, it might be useful to enable internal debug messages, which will allow the library to print more information about sent and received messages as well as internal processes. This is disabled per default to decrease the amount of logs and memory for the log strings on the flash.
// If not set the value is 0 per default, meaning it will only print internal error messages,
// set to 1 to also print debugging messages which might help to discern the exact place where a method fails
#define THINGSBOARD_ENABLE_DEBUG 1
#include <ThingsBoard.h>
The buffer size for the serialized JSON is fixed to 64 bytes. The SDK will not send data if the size of it is bigger than the configured internal buffer size. Respective logs in the "Serial Monitor"
window will indicate the condition:
[TB] Buffer size (64) to small for the given payloads size (83), increase with setBufferSize accordingly or set THINGSBOARD_ENABLE_STREAM_UTILS to 1 before including ThingsBoard
If that's the case, the buffer size for serialization should be increased. To do so, setBufferSize()
method can be used or the bufferSize
passed to the constructor can be increased as illustrated below:
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Arduino_MQTT_Client mqttClient(espClient);
// The SDK setup with 64 bytes for JSON payload and 8 fields for JSON object
// ThingsBoard tb(mqttClient);
// The SDK setup with 128 bytes for JSON payload and 32 fields for JSON object
ThingsBoardSized<32> tb(mqttClient, 128);
void setup() {
// Increase internal buffer size after inital creation.
tb.setBufferSize(128);
}
Alternatively, it is possible to enable the mentioned THINGSBOARD_ENABLE_STREAM_UTILS
option, which sends messages that are bigger than the given buffer size with a method that skips the internal buffer, be aware tough this only works for sent messages. The internal buffer size still has to be big enough to receive the biggest possible message received by the client that is sent by the server.
For that the only thing that needs to be done is to install the required StreamUtils
library, see the Dependencies section.
All internal methods call attempt to utilize the stack as far as possible and completely minimize heap usage, that is the reason why there are places in the library where template arguments are required. If that memory being on the heap is not an issue, it is possible to remove the need to enter those template arguments altogether. Simply enable the THINGSBOARD_ENABLE_DYNAMIC
option like shown below.
// If not set the value is 0 per default,
// set to 1 if the MaxResponse template argument should be automatically deduced instead
#define THINGSBOARD_ENABLE_DYNAMIC 1
#include <ThingsBoard.h>
The sendAttributes
and sendTelemetry
methods, use the StaticJsonDocument
this requires the MaxKeyValuePairAmount
template argument to be passed in the method template list. If more key-value pairs are sent than specified, the "Serial Monitor"
window will get a respective log showing an error:
[TB] Unable to serialize key-value json
[TB] Attempt too enter to many JSON fields into StaticJsonDocument (5), increase (MaxKeyValuePairAmount) (3) accordingly
To fix the issue we simply have to increase the template argument for the method to the actually required amount.
Alternatively to remove the need for the MaxKeyValuePairAmount
template argument in the method template list and to ensure the size the method has is always enough to send messages, see the Dynamic ThingsBoard section section. This makes the library use the DynamicJsonDocument
instead of the default StaticJsonDocument
. Be aware though as this places the json structure onto the heap.
Additionally, the StaticJsonDocument
is also used to deserialize the received payload for every kind of response received by the server, besides the OTA
binary data.
This means that if the MaxResponse
template argument is smaller than the amount of received key-value pairs, the "Serial Monitor"
window will get a respective log showing an error:
[TB] Attempt too enter to many JSON fields into StaticJsonDocument (12), increase (MaxResponse) (8) accordingly
To fix the issue we simply have to increase the template argument for the method to the actually required amount.
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Arduino_MQTT_Client mqttClient(espClient);
// The SDK setup with 64 bytes for JSON payload and 8 fields for JSON object
// ThingsBoard tb(mqttClient);
// The SDK setup with 128 bytes for JSON payload and 32 fields for JSON object
ThingsBoardSized<32> tb(mqttClient, 128);
Alternatively to remove the need for the MaxResponse
template argument in the constructor template list and to ensure the size the buffer should have is always enough to hold received messages, see the Dynamic ThingsBoard section section. This makes the library use the DynamicJsonDocument
instead of the default StaticJsonDocument
. Be aware though as this places the json structure onto the heap.
The possible event subscription classes that are passed to internal methods, use arrays which reside on the stack those require the MaxSubscriptions
template argument to be passed in the constructor template list. The default value is 1, if the method call attempts to subscribe more than that many events in total, the "Serial Monitor"
window will get a respective log showing an error:
[TB] Too many shared attribute update subscriptions, increase MaxSubscriptions or unsubscribe
Important is that both server-side RPC and request attribute values are temporary, meaning once the request has been received it is deleted, and it is therefore possible to subscribe another event again. However, all other subscriptions like client-side RPC or attribute update subscription are permanent meaning once the event has been subscribed we can only unsubscribe all events to make more room.
Additionally, every aforementioned type of request has its own array meaning one type of event subscription (client-side RPC) does not affect the possible amount for another event subscription (attribute update subscription). Therefore, the only thing that needs to be done is to increase the size accordingly.
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Arduino_MQTT_Client mqttClient(espClient);
// Initialize used apis with Shared_Attribute_Update API with 1 maximum Shared_Attribute_Update subscription at once
// Shared_Attribute_Update shared_attr;
// Initialize used apis with Shared_Attribute_Update API with 2 maximum Shared_Attribute_Update subscription at once
Shared_Attribute_Update<2U> shared_attr;
const std::array<IAPI_Implementation*, 1U> apis = {
&shared_attr
};
// The SDK setup with 64 bytes for JSON payload and 8 fields for JSON object
// ThingsBoard tb(mqttClient, Default_Payload, apis);
// The SDK setup with 128 bytes for JSON payload and 32 fields for JSON object
ThingsBoardSized<32> tb(mqttClient, 128, apis);
Alternatively, to remove the need for the MaxSubscriptions
template argument in the constructor template list, see the Dynamic ThingsBoard section section. This will replace the internal implementation with a growing vector instead, meaning all the subscribed callback data will reside on the heap instead.
The possible attribute values that are passed to the Shared_Attribute_Callback
or Attribute_Request_Callback
, use arrays which reside on the stack those require the MaxAttributes
template argument to be passed in the constructor template list. The default value is 1, if we attempt to subscribe or request more attributes than that, the "Serial Monitor"
window will get a respective log showing a crash:
Assertion `m_size < Capacity' failed.
Therefore, the only thing that needs to be done is to increase the size accordingly.
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Arduino_MQTT_Client mqttClient(espClient);
// Initialize used apis with Shared_Attribute_Update API, 1 maximum Shared_Attribute_Update subscription at once, 1 maximum attribute subscribed per individual subscription
// Shared_Attribute_Update shared_attr;
// Initialize used apis with Shared_Attribute_Update API, 2 maximum Shared_Attribute_Update subscription at once, 5 maximum attribute subscribed per individual subscription
Shared_Attribute_Update<2U, 5U> shared_attr;
const std::array<IAPI_Implementation*, 1U> apis = {
&shared_attr
};
// The SDK setup with 64 bytes for JSON payload and 8 fields for JSON object
// ThingsBoard tb(mqttClient, Default_Payload, apis);
// The SDK setup with 128 bytes for JSON payload and 32 fields for JSON object
ThingsBoardSized<32> tb(mqttClient, 128, apis);
Alternatively, to remove the need for the MaxAttributes
template argument in the constructor template list, see the Dynamic ThingsBoard section section. This will replace the internal implementation with a growing vector instead, meaning all the subscribed attribute data will reside on the heap instead.
The possible response in subscribed RPC_Callback
methods, use the StaticJsonDocument
this requires the MaxRPC
template argument to be passed in the constructor template list. The default value is 0, if we attempt to return more key-value pairs in the JSON
than that, the "Serial Monitor"
window will get a respective log showing an error:
[TB] Server-side RPC response overflowed, increase MaxRPC (0)
The default size is only 0, because if a callback only uses the JsonDocument::set()
method, it does not require additional memory. This is only the case if we attempt to add key-value pairs to the JsonDocument
. Therefore, the only thing that needs to be done is to increase the size accordingly.
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Arduino_MQTT_Client mqttClient(espClient);
// Initialize used apis with Shared_Attribute_Update API, 1 maximum Shared_Attribute_Update subscription at once, 0 maximum attribute serialized in the response
// Shared_Attribute_Update shared_attr;
// Initialize used apis with Server_Side_RPC API, 2 maximum Server_Side_RPC subscription at once, 1 maximum attribute serialized in the response
Server_Side_RPC<2U, 1U> rpc;
const std::array<IAPI_Implementation*, 1U> apis = {
&rpc
};
// The SDK setup with 64 bytes for JSON payload and 8 fields for JSON object
// ThingsBoard tb(mqttClient, Default_Payload, apis);
// The SDK setup with 128 bytes for JSON payload and 32 fields for JSON object
ThingsBoardSized<32> tb(mqttClient, 128, apis);
Alternatively, to remove the need for the MaxRPC
template argument in the constructor template list, see the Dynamic ThingsBoard section section. This will instead expect an additional parameter response size in the RPC_Callback
constructor argument list, which shows the internal size the JsonDocument
needs to have to contain the response. Use JSON_OBJECT_SIZE()
and pass the amount of key value pair to calculate the estimated size. See https://arduinojson.org/v6/assistant/ for more information.
The possible request in subscribed RPC_Request_Callback
methods, use the StaticJsonDocument
this requires the MaxRequestRPC
template argument to be passed in the constructor template list. The default value is 1, if we attempt to send more key-value pairs in the JSON
than that, the "Serial Monitor"
window will get a respective log showing an error:
[TB] Client-side RPC request overflowed, increase MaxRequestRPC (2)
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Arduino_MQTT_Client mqttClient(espClient);
// Initialize used apis with Shared_Attribute_Update API, 1 maximum Shared_Attribute_Update subscription at once, 1 maximum attribute serialized in the request
// Shared_Attribute_Update shared_attr;
// Initialize used apis with Server_Side_RPC API, 2 maximum Server_Side_RPC subscription at once, 2 maximum attribute serialized in the request
Client_Side_RPC<2U, 2U> request_rpc;
const std::array<IAPI_Implementation*, 1U> apis = {
&request_rpc
};
// The SDK setup with 64 bytes for JSON payload and 8 fields for JSON object
// ThingsBoard tb(mqttClient, Default_Payload, apis);
// The SDK setup with 128 bytes for JSON payload and 32 fields for JSON object
ThingsBoardSized<32> tb(mqttClient, 128, apis);
Alternatively, to remove the need for the MaxRequestRPC
template argument in the constructor template list, see the Dynamic ThingsBoard section section. This makes the library use the DynamicJsonDocument
instead of the default StaticJsonDocument
. Be aware though as this copies the requests onto the heap.
The ThingsBoardSized
class instance only supports a minimal subset of the actual API, see the Supported ThingsBoard Features section. But with the usage of the IAPI_Implementation
base class, it is possible to write an own implementation that implements an additional API implementation or changes the behavior for an already existing API implementation.
For that a class
needs to inherit the API_Implemenatation
class and override
the needed methods shown below:
#ifndef Custom_API_Implementation_h
#define Custom_API_Implementation_h
// Local includes.
#include "IAPI_Implementation.h"
class Custom_API_Implementation : public IAPI_Implementation {
public:
API_Process_Type Get_Process_Type() override {
return API_Process_Type::JSON;
}
void Process_Response(char const * topic, uint8_t * payload, unsigned int length) override {
// Nothing to do
}
void Process_Json_Response(char const * topic, JsonDocument const & data) override {
// Nothing to do
}
bool Compare_Response_Topic(char const * topic) const override {
return true;
}
bool Unsubscribe() override {
return true;
}
bool Resubscribe_Topic() override {
return true;
}
#if !THINGSBOARD_USE_ESP_TIMER
void loop() override {
// Nothing to do
}
#endif // !THINGSBOARD_USE_ESP_TIMER
void Initialize() override {
// Nothing to do
}
void Set_Client_Callbacks(Callback<void, IAPI_Implementation &>::function subscribe_api_callback, Callback<bool, char const * const, JsonDocument const &, size_t const &>::function send_json_callback, Callback<bool, char const * const, char const * const>::function send_json_string_callback, Callback<bool, char const * const>::function subscribe_topic_callback, Callback<bool, char const * const>::function unsubscribe_topic_callback, Callback<uint16_t>::function get_size_callback, Callback<bool, uint16_t>::function set_buffer_size_callback, Callback<size_t *>::function get_request_id_callback) override {
// Nothing to do
}
};
#endif // Custom_API_Implementation_h
Once that has been done it can simply be passed to the ThingsBoard
instance, either using the constructor or using the Subscribe_IAPI_Implementation
method.
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Arduino_MQTT_Client mqttClient(espClient);
// Initialize used apis with Custom API
Custom_IAPI_Implementation custom_api;
const std::array<IAPI_Implementation*, 1U> apis = {
&custom_api
};
// The SDK setup with 64 bytes for JSON payload, 8 fields for JSON object and maximal 7 API endpoints subscribed at once
// ThingsBoard tb(mqttClient, Default_Payload, apis);
// The SDK setup with 128 bytes for JSON payload and 8 fields for JSON object and maximal 10 API endpoints subscribed at once
ThingsBoardSized<8, 10> tb(mqttClient, 128, apis);
// Optional alternative way to subscribe the Custom API ater the class instance has already been created
// tb.Subscribe_IAPI_Implementation(custom_api);
When using the ThingsBoard
class instance, the class used to flash the binary data onto the device is not hard coded,
but instead the OTA_Update_Callback
class expects an argument, the IUpdater
implementation.
Thanks to it being an interface it allows an arbitrary implementation,
meaning as long as the device can flash binary data and supports the C++ STL it supports OTA updates, with the ThingsBoard
library.
Currently, implemented in the library itself are the Arduino_ESP32_Updater
, which is used for flashing the binary data when using a ESP32
and Arduino
, the Arduino_ESP8266_Updater
which is used with the ESP8266
and Arduino
, the Espressif_Updater
which is used with the ESP32
and the Espressif IDF
tool chain and lastly the SDCard_Updater
which is used for both Arduino
and the Espressif IDF
to flash binary data onto an already initialized SD card.
If another device or feature wants to be supported, a custom interface implementation needs to be created.
For that a class
needs to inherit the IUpdater
interface and override
the needed methods shown below:
#include <IUpdater.h>
class Custom_Updater : public IUpdater {
public:
bool begin(size_t const & firmware_size) override {
return true;
}
size_t write(uint8_t * payload, size_t const & total_bytes) override {
return total_bytes;
}
void reset() override {
// Nothing to do
}
bool end() override {
return true;
}
};
Once that has been done it can simply be passed instead of the Espressif_Updater
, Arduino_ESP8266_Updater
, Arduino_ESP32_Updater
or SDCard_Updater
instance.
// Initalize the Updater client instance used to flash binary to flash memory
Custom_Updater updater;
const OTA_Update_Callback callback(CURRENT_FIRMWARE_TITLE, CURRENT_FIRMWARE_VERSION, &updater, &finished_callback, &progress_callback, &update_starting_callback, FIRMWARE_FAILURE_RETRIES, FIRMWARE_PACKET_SIZE);
When using the ThingsBoardHttp
class instance, the protocol used to send the data to the HTTP broker is not hard coded,
but instead the ThingsBoardHttp
class expects the argument to a IHTTP_Client
implementation.
Thanks to it being an interface it allows an arbitrary implementation,
meaning the underlying HTTP client can be whatever the user decides, so it can for example be used to support platforms using Arduino
or even Espressif IDF
.
Currently, implemented in the library itself is the Arduino_HTTP_Client
, which is simply a wrapper around the ArduinoHttpClient
, see dependencies for whether the board you are using is supported or not.
If another device or feature wants to be supported, a custom interface implementation needs to be created.
For that a class
needs to inherit the IHTTP_Client
interface and override
the needed methods shown below:
#include <IHTTP_Client.h>
class Custom_HTTP_Client : public IHTTP_Client {
public:
void set_keep_alive(bool keep_alive) override {
// Nothing to do
}
int connect(char const * host, uint16_t port) override {
return 0;
}
void stop() override {
// Nothing to do
}
int post(char const * url_path, char const * content_type, char const * request_body) override {
return 0;
}
int get_response_status_code() override {
return 200;
}
int get(char const * url_path) override {
return 0;
}
#if THINGSBOARD_ENABLE_STL
std::string get_response_body() override {
return std::string();
}
#else
String get_response_body() override {
return String();
}
#endif // THINGSBOARD_ENABLE_STL
};
Once that has been done it can simply be passed instead of the Arduino_HTTP_Client
instance.
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Http client instance
Custom_HTTP_Client httpClient(espClient, THINGSBOARD_SERVER, THINGSBOARD_PORT);
// The SDK setup with 8 fields for JSON object
ThingsBoardHttp tb(httpClient, TOKEN, THINGSBOARD_SERVER, THINGSBOARD_PORT);
When using the ThingsBoard
class instance, the protocol used to send the data to the MQTT broker is not hard coded,
but instead the ThingsBoard
class expects the argument to a IMQTT_Client
implementation.
Thanks to it being an interface it allows an arbitrary implementation,
meaning the underlying MQTT client can be whatever the user decides, so it can for example be used to support platforms using Arduino
or even Espressif IDF
.
Currently, implemented in the library itself is the Arduino_MQTT_Client
, which is simply a wrapper around the PubSubClient
, see compatible Hardware for whether the board you are using is supported or not, useful when using Arduino
. As well as the Espressif_MQTT_Client
, which is a simple wrapper around the esp-mqtt
, useful when using Espressif IDF
with a ESP32
.
If another device or feature wants to be supported, a custom interface implementation needs to be created.
For that a class
needs to inherit the IMQTT_Client
interface and override
the needed methods shown below:
#include <IMQTT_Client.h>
class Custom_MQTT_Client : public IMQTT_Client {
public:
void set_data_callback(Callback<void, char *, uint8_t *, unsigned int>::function callback) override {
// Nothing to do
}
void set_connect_callback(Callback<void>::function callback) override {
// Nothing to do
}
bool set_buffer_size(uint16_t buffer_size) override {
return true;
}
uint16_t get_buffer_size() override {
return 0U;
}
void set_server(char const * domain, uint16_t port) override {
// Nothing to do
}
bool connect(char const * client_id, char const * user_name, char const * password) override {
return true;
}
void disconnect() override {
// Nothing to do
}
bool loop() override {
return true;
}
bool publish(char const * topic, uint8_t const * payload, size_t const & length) override {
return true;
}
bool subscribe(char const * topic) override {
return true;
}
bool unsubscribe(char const * topic) override {
return true;
}
bool connected() override {
return true;
}
#if THINGSBOARD_ENABLE_STREAM_UTILS
bool begin_publish(char const * topic, size_t const & length) override {
return true;
}
bool end_publish() override {
return true;
}
//----------------------------------------------------------------------------
// Print interface
//----------------------------------------------------------------------------
size_t write(uint8_t payload_byte) override {
return 1U;
}
size_t write(uint8_t const * buffer, size_t const & size) override {
return size;
}
#endif // THINGSBOARD_ENABLE_STREAM_UTILS
};
Once that has been done it can simply be passed instead of the Arduino_MQTT_Client
or the Espressif_MQTT_Client
instance.
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Custom_MQTT_Client mqttClient(espClient);
// The SDK setup with 64 bytes for JSON payload and 8 fields for JSON object
// ThingsBoard tb(mqttClient);
// The SDK setup with 128 bytes for JSON payload and 32 fields for JSON object
ThingsBoardSized<32> tb(mqttClient, 128);
When using the ThingsBoard
class instance, the class used to print internal warning messages is not hard coded, but instead the ThingsBoard
class expects the template argument to a Logger
implementation. See the Enabling internal debug messages section if the logger should also receive debug messages.
Thanks to it being a template parameter it allows an arbitrary implementation, meaning the underlying Logger client can be whatever the user decides, so it can for example be used to print the messages onto a serial card instead of the serial console.
Currently, implemented in the library itself is the DefaultLogger
, which is simply a wrapper around a printf
call. If the functionality wants to be extended, a custom implementation needs to be created.
For that a class
needs to fulfill the contract and implement the needed methods shown below:
class CustomLogger {
public:
template<typename ...Args>
static int printfln(char const * format, Args const &... args) {
return 0;
}
static int println(char const * message) {
return 0;
}
};
Once that has been done it can simply be passed as the last template parameter.
// Initialize underlying client, used to establish a connection
WiFiClient espClient;
// Initalize the Mqtt client instance
Arduino_MQTT_Client mqttClient(espClient);
// The SDK setup with 64 bytes for JSON payload and 8 fields for JSON object
// ThingsBoard tb(mqttClient);
// The SDK setup with 128 bytes for JSON payload and 32 fields for JSON object
ThingsBoardSized<32, Default_Response_Amount, CustomLogger> tb(mqttClient, 128);
You are welcome in our issues and Q&A forum.
This code is released under the MIT License.