Astarte ESP32 SDK lets you connect your ESP32 device to Astarte.
The SDK simplifies all the low-level operations like credentials generation, pairing and so on, and exposes a high-level API to publish data from your device.
Have a look at the examples for a usage example showing how to send and receive data.
The generated Doxygen documentation is available in the Astarte Documentation website.
The SDK is tested against these versions of esp-idf
:
v4.4
v5.x
Previous versions of esp-idf
are not guaranteed to work. If you find a problem using a later
version of esp-idf
, please open an
issue.
The Astarte ESP32 Device interacts internally with the Free RTOS APIs. As such some factors should be taken into account when integrating this component into a larger system.
The following tasks are spawned directly by the Astarte ESP32 Device:
credentials_init_task
: Initializes the credentials for the MQTT communication. This task is created when calling theastarte_credentials_init()
function. This should be done before initializing the Astarte ESP32 Device. It will use16384
words from the stack and will be deleted before exiting theastarte_credentials_init()
function.astarte_device_reinit_task
: Reinitializes the device in case of a TLS error coming from an expired certificate. This task is created upon device initialization and runs constantly for the life of the device. It will use6000
words from the stack.
All of the tasks are spawned with the lowest priority and rely on the time-slicing functionality of freertos to run concurrently with the main task.
The device's Astarte credentials are always stored in the NVM. This means that credentials will be preserved in between reboots.
Two storage methods can be used for the credentials. A FAT32 file system or the standard
non-volatile storage (NVS) library provided by the ESP32. The FAT32 is the default storage choice.
If you want to use NVS storage, add the
astarte_credentials_use_nvs_storage
function before initializing astarte_credentials
.
astarte_credentials_use_nvs_storage(NVS_PARTITION);
However, note that even when FAT32 is used, the device credential secret is always stored using
the NVS library. This will require devices configured as using FAT32 to have two partitions,
one using as name the macro NVS_DEFAULT_PART_NAME
(NVS) and one named astarte
(FAT32).
Furthermore, if you whish to use flash encryption for your device the only supported option is NVS.
As a side effect of NVM usage, credentials will be preserved also between device flashes using
idf.py
.
N.B. The device will first check if valid credentials are stored in the NVM, and only in case
of a negative result will use the Astarte SDK
component configuration to obtain fresh credentials.
Most of the time during development the device credentials remain unchanged between firmware
flashes and the old ones stored in the NVM can be reused.
However, when changing elements of the Astarte SDK
component configuration the old credentials
should be discarded by erasing the NMV.
This can be done using the following command:
idf.py (ESP-IDF v5.x) | idf.py (ESP-IDF v4.x) |
---|---|
idf.py -p <DEVICE_PORT> erase-flash |
idf.py -p <DEVICE_PORT> erase_flash |
N.B. Do not ignore TLS certificates errors in production!
Ignoring TLS certificates errors can be useful when trying out the device libraries in a prototyping context. For example when using a local Astarte instance with self signed certificates.
To disable the TLS certificates checks in the device libraries add the following to your
sdkconfig.defaults
file:
#
# ESP-TLS
#
CONFIG_ESP_TLS_INSECURE=y
CONFIG_ESP_TLS_SKIP_SERVER_CERT_VERIFY=y
# end of ESP-TLS
#
# Certificate Bundle
#
CONFIG_MBEDTLS_CERTIFICATE_BUNDLE=n
# end of Certificate Bundle
If you are not using an sdkconfig.defaults
file, run idf.py menuconfig
and set the three options
listed above manually. The insecure and skip certificate options can be found in the ESP-TLS
component. While the bundle option can be found in the mbedTLS component.
The Astarte ESP32 Device uses the ESP x509 Certificate Bundle to verify the Astarte instance certificates.
If your Astarte instance uses a custom CA you can disable the default certificate bundle and add
your own certificates.
This can be done directly in esp-idf
using the menuconfig
command, or adding a
sdkconfig.defaults
file to your project.
Below an example configuration is presented. It adds a locally stored custom certificate.
#
# Certificate Bundle
#
CONFIG_MBEDTLS_CERTIFICATE_BUNDLE=y
# CONFIG_MBEDTLS_CERTIFICATE_BUNDLE_DEFAULT_FULL is not set
# CONFIG_MBEDTLS_CERTIFICATE_BUNDLE_DEFAULT_CMN is not set
CONFIG_MBEDTLS_CERTIFICATE_BUNDLE_DEFAULT_NONE=y
CONFIG_MBEDTLS_CUSTOM_CERTIFICATE_BUNDLE=y
CONFIG_MBEDTLS_CUSTOM_CERTIFICATE_BUNDLE_PATH="/path/to/certificate/file/astarte_instance.pem"
# end of Certificate Bundle
The data exchange with an Astarte instance is encoded in the BSON format. This library provides utility functions for serializing and deserializing BSONs. Handling BSON directly is only required when dealing with interfaces with object aggregation. Sending and receiving on individually aggregated interfaces can be done using standard C types and structures.
Note that not all the element types defined by the BSON 1.1 specification are supported by Astarte. The subset of the supported element types can be found in the Astarte MQTT v1 protocol specification.
Serializing data to a BSON format should be used during transmission of aggregates to Astarte.
The serialization utility is exposed by the astarte_bson_serializer.h
header.
A BSON object can be created using the astarte_bson_serializer_new
function. Which will return an
empty BSON document that can be filled by appending new elements using one of the
astarte_bson_serializer_append_*
functions. Once all the required elements have been added to the
document it must be terminated using the astarte_bson_serializer_append_end_of_document
function.
The serialized document can then be extracted using the astarte_bson_serializer_get_document
function. This function will return a buffer that will live for as long as the BSON object.
Since the memory for the BSON document is dynamically allocated it should be freed once the document
is no longer required. This can be done with the astarte_bson_serializer_get_document
function.
A simple usage example is reported here.
#include "astarte_bson_serializer.h"
astarte_bson_serializer_handle_t bson = astarte_bson_serializer_new();
astarte_bson_serializer_append_double(bson, "co2", 4.0);
astarte_bson_serializer_append_int64(bson, "temperature", 42);
astarte_bson_serializer_append_string(bson, "identifier", "si383o33dm2");
astarte_bson_serializer_append_end_of_document(bson);
int serialized_doc_size;
const void *serialized_doc = astarte_bson_serializer_get_document(bson, &serialized_doc_size);
// Use the returned serialized document before destroy call
// For example send the buffer to Astarte by calling astarte_device_stream_aggregate()
astarte_bson_serializer_destroy(bson);
Deserializing data from the BSON format is required when receiving aggregates from Astarte.
The deserialization utility is exposed by the astarte_bson_deserializer.h
header.
A BSON object can be initialized from a buffer containing serialized data using the function
astarte_bson_deserializer_init_doc
. This will return a document object of type
astarte_bson_document_t
, which provides information regarding the document such as its
total size.
Accessing the list of elements in the BSON document can be performed
in two ways. By looping over all the elements using the astarte_bson_deserializer_first_element
and astarte_bson_deserializer_next_element
functions or, when the required element name is known,
by lookup using the function astarte_bson_deserializer_element_lookup
. Both functions return an
element object of the type astarte_bson_element_t
, which provides information regarding the
element such as its type and name.
To extract the data contained in a single element one of the
astarte_bson_deserializer_element_to_*
functions should be used.
A common use case of the deserializer is in the Astarte data_event_callback
.
This function exposes the received data though the member bson_element
of the parameter struct
event
. The bson_element
variable is a BSON element object of the type astarte_bson_element_t
.
The BSON deserializer utility will not perform dynamic allocation of memory but will use directly the buffer passed during initialization. Make sure the buffer remains valid throughout the deserialization process.
Two deserialization examples are reported here. The first one is a very simple deserialization example for a BSON containing a single element of double type.
#include "astarte_bson_deserializer.h"
astarte_bson_document_t doc = astarte_bson_deserializer_init_doc(input_buffer);
astarte_bson_element_t element;
astarte_err_t astarte_err = astarte_bson_deserializer_element_lookup(doc, "name", &element);
if ((astarte_err != ASTARTE_OK) || (element.type != BSON_TYPE_DOUBLE)) {
abort();
}
double element_value = astarte_bson_deserializer_element_to_double(element);
The second is a more complex example of a document containing an array of elements of type double and a single boolean element.
#include "astarte_bson_deserializer.h"
astarte_err_t astarte_err;
// Initializing the document from a raw buffer
astarte_bson_document_t doc = astarte_bson_deserializer_init_doc(input_buffer);
// Extracting the element with name `boolean` using lookup
astarte_bson_element_t element_bool;
astarte_err = astarte_bson_deserializer_element_lookup(doc, "boolean", &element_bool);
if ((astarte_err != ASTARTE_OK) || (element_bool.type != BSON_TYPE_BOOLEAN)) {
abort();
}
bool value_bool = astarte_bson_deserializer_element_to_bool(element_bool);
// Extracting the element with name `array` using lookup
astarte_bson_element_t element_arr;
astarte_err = astarte_bson_deserializer_element_lookup(doc, "array", &element_arr);
if ((astarte_err != ASTARTE_OK) || (element_arr.type != BSON_TYPE_ARRAY)) {
abort();
}
// Arrays are just special documents in the BSON specification
astarte_bson_document_t arr_doc = astarte_bson_deserializer_element_to_document(element_arr);
// Extract the first element
astarte_bson_element_t element_arr_0;
astarte_err = astarte_bson_deserializer_first_element(arr_doc, &element_arr_0);
if ((astarte_err != ASTARTE_OK) || (element_arr_0.type != BSON_TYPE_DOUBLE)) {
abort();
}
double element_arr_0_value = astarte_bson_deserializer_element_to_double(element_arr_0);
// Extract each of the successive elements
astarte_bson_element_t element_arr_prev = element_arr_0;
astarte_bson_element_t element_arr_next;
while (1) {
astarte_err = astarte_bson_deserializer_next_element(
arr_doc, element_arr_prev, &element_arr_next);
if (astarte_err == ASTARTE_ERR_NOT_FOUND) {
break;
}
if ((astarte_err != ASTARTE_OK) || (element_arr_next.type != BSON_TYPE_DOUBLE)) {
abort();
}
double element_arr_X_value = astarte_bson_deserializer_element_to_double(element_arr_next);
element_arr_prev = element_arr_next;
}