This is the description of the C/C++ API bindings for the Master Brick. General information and technical specifications for the Master Brick are summarized in its hardware description.
An installation guide for the C/C++ API bindings is part of their general description.
The example code below is Public Domain (CC0 1.0).
Download (example_stack_status.c)
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 | #include <stdio.h>
#include "ip_connection.h"
#include "brick_master.h"
#define HOST "localhost"
#define PORT 4223
#define UID "aySDPZAhvvd" // Change to your UID
int main() {
// Create IP connection
IPConnection ipcon;
ipcon_create(&ipcon);
// Create device object
Master master;
master_create(&master, UID, &ipcon);
// Connect to brickd
if(ipcon_connect(&ipcon, HOST, PORT) < 0) {
fprintf(stderr, "Could not connect\n");
exit(1);
}
// Don't use device before ipcon is connected
// Get voltage and current from stack (in mV/mA)
uint16_t voltage;
master_get_stack_voltage(&master, &voltage);
uint16_t current;
master_get_stack_current(&master, ¤t);
printf("Stack Voltage: %f V\n", voltage/1000.0);
printf("Stack Current: %f A\n", current/1000.0);
printf("Press key to exit\n");
getchar();
ipcon_destroy(&ipcon); // Calls ipcon_disconnect internally
}
|
Every function of the C/C++ bindings returns an integer which describes an error code. Data returned from the device, when a getter is called, is handled via call by reference. These parameters are labeled with the ret_ prefix.
Possible error codes are:
as defined in ip_connection.h.
All functions listed below are thread-safe.
Creates the device object master with the unique device ID uid and adds it to the IPConnection ipcon:
Master master;
master_create(&master, "YOUR_DEVICE_UID", &ipcon);
This device object can be used after the IP connection has been connected (see examples above).
Removes the device object master from its IPConnection and destroys it. The device object cannot be used anymore afterwards.
Returns the stack voltage in mV. The stack voltage is the voltage that is supplied via the stack, i.e. it is given by a Step-Down or Step-Up Power Supply.
Returns the stack current in mA. The stack current is the current that is drawn via the stack, i.e. it is given by a Step-Down or Step-Up Power Supply.
Writes the extension type to the EEPROM of a specified extension. The extension is either 0 or 1 (0 is the on the bottom, 1 is the on on top, if only one extension is present use 0).
Possible extension types:
Type | Description |
---|---|
1 | Chibi |
2 | RS485 |
3 | WIFI |
4 | Ethernet |
The extension type is already set when bought and it can be set with the Brick Viewer, it is unlikely that you need this function.
The following defines are available for this function:
Returns the type for a given extension as set by master_set_extension_type().
The following defines are available for this function:
Returns true if a Chibi Extension is available to be used by the Master Brick.
Sets the address (1-255) belonging to the Chibi Extension.
It is possible to set the address with the Brick Viewer and it will be saved in the EEPROM of the Chibi Extension, it does not have to be set on every startup.
Returns the address as set by master_set_chibi_address().
Sets the address (1-255) of the Chibi Master. This address is used if the Chibi Extension is used as slave (i.e. it does not have a USB connection).
It is possible to set the address with the Brick Viewer and it will be saved in the EEPROM of the Chibi Extension, it does not have to be set on every startup.
Returns the address as set by master_set_chibi_master_address().
Sets up to 254 slave addresses. Valid addresses are in range 1-255. 0 has a special meaning, it is used as list terminator and not allowed as normal slave address. The address numeration (via num parameter) has to be used ascending from 0. For example: If you use the Chibi Extension in Master mode (i.e. the stack has an USB connection) and you want to talk to three other Chibi stacks with the slave addresses 17, 23, and 42, you should call with (0, 17), (1, 23), (2, 42) and (3, 0). The last call with (3, 0) is a list terminator and indicates that the Chibi slave address list contains 3 addresses in this case.
It is possible to set the addresses with the Brick Viewer, that will take care of correct address numeration and list termination.
The slave addresses will be saved in the EEPROM of the Chibi Extension, they don't have to be set on every startup.
Returns the slave address for a given num as set by master_set_chibi_slave_address().
Returns the signal strength in dBm. The signal strength updates every time a packet is received.
Returns underrun, CRC error, no ACK and overflow error counts of the Chibi communication. If these errors start rising, it is likely that either the distance between two Chibi stacks is becoming too big or there are interferences.
Sets the Chibi frequency range for the Chibi Extension. Possible values are:
Type | Description |
---|---|
0 | OQPSK 868MHz (Europe) |
1 | OQPSK 915MHz (US) |
2 | OQPSK 780MHz (China) |
3 | BPSK40 915MHz |
It is possible to set the frequency with the Brick Viewer and it will be saved in the EEPROM of the Chibi Extension, it does not have to be set on every startup.
The following defines are available for this function:
Returns the frequency value as set by master_set_chibi_frequency().
The following defines are available for this function:
Sets the channel used by the Chibi Extension. Possible channels are different for different frequencies:
Frequency | Possible Channels |
---|---|
OQPSK 868MHz (Europe) | 0 |
OQPSK 915MHz (US) | 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 |
OQPSK 780MHz (China) | 0, 1, 2, 3 |
BPSK40 915MHz | 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 |
It is possible to set the channel with the Brick Viewer and it will be saved in the EEPROM of the Chibi Extension, it does not have to be set on every startup.
Returns the channel as set by master_set_chibi_channel().
Returns true if a RS485 Extension is available to be used by the Master Brick.
Sets the address (0-255) belonging to the RS485 Extension.
Set to 0 if the RS485 Extension should be the RS485 Master (i.e. connected to a PC via USB).
It is possible to set the address with the Brick Viewer and it will be saved in the EEPROM of the RS485 Extension, it does not have to be set on every startup.
Returns the address as set by master_set_rs485_address().
Sets up to 255 slave addresses. Valid addresses are in range 1-255. 0 has a special meaning, it is used as list terminator and not allowed as normal slave address. The address numeration (via num parameter) has to be used ascending from 0. For example: If you use the RS485 Extension in Master mode (i.e. the stack has an USB connection) and you want to talk to three other RS485 stacks with the addresses 17, 23, and 42, you should call with (0, 17), (1, 23), (2, 42) and (3, 0). The last call with (3, 0) is a list terminator and indicates that the RS485 slave address list contains 3 addresses in this case.
It is possible to set the addresses with the Brick Viewer, that will take care of correct address numeration and list termination.
The slave addresses will be saved in the EEPROM of the Chibi Extension, they don't have to be set on every startup.
Returns the slave address for a given num as set by master_set_rs485_slave_address().
Returns CRC error counts of the RS485 communication. If this counter starts rising, it is likely that the distance between the RS485 nodes is too big or there is some kind of interference.
Sets the configuration of the RS485 Extension. Speed is given in baud. The Master Brick will try to match the given baud rate as exactly as possible. The maximum recommended baud rate is 2000000 (2Mbit/s). Possible values for parity are 'n' (none), 'e' (even) and 'o' (odd). Possible values for stop bits are 1 and 2.
If your RS485 is unstable (lost messages etc.), the first thing you should try is to decrease the speed. On very large bus (e.g. 1km), you probably should use a value in the range of 100000 (100kbit/s).
The values are stored in the EEPROM and only applied on startup. That means you have to restart the Master Brick after configuration.
The following defines are available for this function:
Returns the configuration as set by master_set_rs485_configuration().
The following defines are available for this function:
Returns true if a WIFI Extension is available to be used by the Master Brick.
Sets the configuration of the WIFI Extension. The ssid can have a max length of 32 characters. Possible values for connection are:
Value | Description |
---|---|
0 | DHCP |
1 | Static IP |
2 | Access Point: DHCP |
3 | Access Point: Static IP |
4 | Ad Hoc: DHCP |
5 | Ad Hoc: Static IP |
If you set connection to one of the static IP options then you have to supply ip, subnet_mask and gateway as an array of size 4 (first element of the array is the least significant byte of the address). If connection is set to one of the DHCP options then ip, subnet_mask and gateway are ignored, you can set them to 0.
The last parameter is the port that your program will connect to. The default port, that is used by brickd, is 4223.
The values are stored in the EEPROM and only applied on startup. That means you have to restart the Master Brick after configuration.
It is recommended to use the Brick Viewer to set the WIFI configuration.
The following defines are available for this function:
Returns the configuration as set by master_set_wifi_configuration().
The following defines are available for this function:
Sets the encryption of the WIFI Extension. The first parameter is the type of the encryption. Possible values are:
Value | Description |
---|---|
0 | WPA/WPA2 |
1 | WPA Enterprise (EAP-FAST, EAP-TLS, EAP-TTLS, PEAP) |
2 | WEP |
3 | No Encryption |
The key has a max length of 50 characters and is used if encryption is set to 0 or 2 (WPA/WPA2 or WEP). Otherwise the value is ignored.
For WPA/WPA2 the key has to be at least 8 characters long. If you want to set a key with more than 50 characters, see master_set_long_wifi_key().
For WEP the key has to be either 10 or 26 hexadecimal digits long. It is possible to set the WEP key_index (1-4). If you don't know your key_index, it is likely 1.
If you choose WPA Enterprise as encryption, you have to set eap_options and the length of the certificates (for other encryption types these parameters are ignored). The certificate length are given in byte and the certificates themselves can be set with master_set_wifi_certificate(). eap_options consist of the outer authentication (bits 1-2), inner authentication (bit 3) and certificate type (bits 4-5):
Option | Bits | Description |
---|---|---|
outer authentication | 1-2 | 0=EAP-FAST, 1=EAP-TLS, 2=EAP-TTLS, 3=EAP-PEAP |
inner authentication | 3 | 0=EAP-MSCHAP, 1=EAP-GTC |
certificate type | 4-5 | 0=CA Certificate, 1=Client Certificate, 2=Private Key |
Example for EAP-TTLS + EAP-GTC + Private Key: option = 2 | (1 << 2) | (2 << 3).
The values are stored in the EEPROM and only applied on startup. That means you have to restart the Master Brick after configuration.
It is recommended to use the Brick Viewer to set the Wi-Fi encryption.
The following defines are available for this function:
Returns the encryption as set by master_set_wifi_encryption().
The following defines are available for this function:
Returns the status of the WIFI Extension. The state is updated automatically, all of the other parameters are updated on startup and every time master_refresh_wifi_status() is called.
Possible states are:
State | Description |
---|---|
0 | Disassociated |
1 | Associated |
2 | Associating |
3 | Error |
255 | Not initialized yet |
The following defines are available for this function:
Refreshes the Wi-Fi status (see master_get_wifi_status()). To read the status of the Wi-Fi module, the Master Brick has to change from data mode to command mode and back. This transaction and the readout itself is unfortunately time consuming. This means, that it might take some ms until the stack with attached WIFI Extension reacts again after this function is called.
This function is used to set the certificate as well as password and username for WPA Enterprise. To set the username use index 0xFFFF, to set the password use index 0xFFFE. The max length of username and password is 32.
The certificate is written in chunks of size 32 and the index is used as the index of the chunk. data_length should nearly always be 32. Only the last chunk can have a length that is not equal to 32.
The starting index of the CA Certificate is 0, of the Client Certificate 10000 and for the Private Key 20000. Maximum sizes are 1312, 1312 and 4320 byte respectively.
The values are stored in the EEPROM and only applied on startup. That means you have to restart the Master Brick after uploading the certificate.
It is recommended to use the Brick Viewer to set the certificate, username and password.
Returns the certificate for a given index as set by master_set_wifi_certificate().
Sets the power mode of the WIFI Extension. Possible modes are:
Mode | Description |
---|---|
0 | Full Speed (high power consumption, high throughput) |
1 | Low Power (low power consumption, low throughput) |
The default value is 0 (Full Speed).
The following defines are available for this function:
Returns the power mode as set by master_set_wifi_power_mode().
The following defines are available for this function:
Returns informations about the Wi-Fi receive buffer. The Wi-Fi receive buffer has a max size of 1500 byte and if data is transfered too fast, it might overflow.
The return values are the number of overflows, the low watermark (i.e. the smallest number of bytes that were free in the buffer) and the bytes that are currently used.
You should always try to keep the buffer empty, otherwise you will have a permanent latency. A good rule of thumb is, that you can transfer 1000 messages per second without problems.
Try to not send more then 50 messages at a time without any kind of break between them.
Sets the regulatory domain of the WIFI Extension. Possible domains are:
Domain | Description |
---|---|
0 | FCC: Channel 1-11 (N/S America, Australia, New Zealand) |
1 | ETSI: Channel 1-13 (Europe, Middle East, Africa) |
2 | TELEC: Channel 1-14 (Japan) |
The default value is 1 (ETSI).
The following defines are available for this function:
Returns the regulatory domain as set by master_set_wifi_regulatory_domain().
The following defines are available for this function:
Returns the USB voltage in mV. Does not work with hardware version 2.1.
Sets a long Wi-Fi key (up to 63 chars, at least 8 chars) for WPA encryption. This key will be used if the key in master_set_wifi_encryption() is set to "-". In the old protocol, a payload of size 63 was not possible, so the maximum key length was 50 chars.
With the new protocol this is possible, since we didn't want to break API, this function was added additionally.
New in version 2.0.2 (Firmware).
Returns the encryption key as set by master_set_long_wifi_key().
New in version 2.0.2 (Firmware).
Sets the hostname of the WIFI Extension. The hostname will be displayed by access points as the hostname in the DHCP clients table.
Setting an empty String will restore the default hostname.
New in version 2.0.5 (Firmware).
Returns the hostname as set by master_get_wifi_hostname().
An empty String means, that the default hostname is used.
New in version 2.0.5 (Firmware).
Returns true if a Ethernet Extension is available to be used by the Master Brick.
New in version 2.1.0 (Firmware).
Sets the configuration of the Ethernet Extension. Possible values for connection are:
Value | Description |
---|---|
0 | DHCP |
1 | Static IP |
If you set connection to static IP options then you have to supply ip, subnet_mask and gateway as an array of size 4 (first element of the array is the least significant byte of the address). If connection is set to the DHCP options then ip, subnet_mask and gateway are ignored, you can set them to 0.
The last parameter is the port that your program will connect to. The default port, that is used by brickd, is 4223.
The values are stored in the EEPROM and only applied on startup. That means you have to restart the Master Brick after configuration.
It is recommended to use the Brick Viewer to set the Ethernet configuration.
The following defines are available for this function:
New in version 2.1.0 (Firmware).
Returns the configuration as set by master_set_ethernet_configuration().
The following defines are available for this function:
New in version 2.1.0 (Firmware).
Returns the status of the Ethernet Extension.
mac_address, ip, subnet_mask and gateway are given as an array. The first element of the array is the least significant byte of the address.
rx_count and tx_count are the number of bytes that have been received/send since last restart.
hostname is the currently used hostname.
New in version 2.1.0 (Firmware).
Sets the hostname of the Ethernet Extension. The hostname will be displayed by access points as the hostname in the DHCP clients table.
Setting an empty String will restore the default hostname.
The current hostname can be discovered with master_get_ethernet_status().
New in version 2.1.0 (Firmware).
Sets the MAC address of the Ethernet Extension. The Ethernet Extension should come configured with a valid MAC address, that is also written on a sticker of the extension itself.
The MAC address can be read out again with master_get_ethernet_status().
New in version 2.1.0 (Firmware).
Sets the Ethernet WebSocket configuration. The first parameter sets the number of socket connections that are reserved for WebSockets. The range is 0-7. The connections are shared with the plain sockets. Example: If you set the connections to 3, there will be 3 WebSocket and 4 plain socket connections available.
The second parameter is the port for the WebSocket connections. The port can not be the same as the port for the plain socket connections.
The values are stored in the EEPROM and only applied on startup. That means you have to restart the Master Brick after configuration.
It is recommended to use the Brick Viewer to set the Ethernet configuration.
The default values are 3 for the socket connections and 4280 for the port.
New in version 2.2.0 (Firmware).
Returns the configuration as set by master_set_ethernet_configuration().
New in version 2.2.0 (Firmware).
Sets the Ethernet authentication secret. The secret can be a string of up to 64 characters. An empty string disables the authentication.
See the authentication tutorial for more information.
The secret is stored in the EEPROM and only applied on startup. That means you have to restart the Master Brick after configuration.
It is recommended to use the Brick Viewer to set the Ethernet authentication secret.
The default value is an empty string (authentication disabled).
New in version 2.2.0 (Firmware).
Returns the authentication secret as set by master_set_ethernet_authentication_secret().
New in version 2.2.0 (Firmware).
Sets the WIFI authentication secret. The secret can be a string of up to 64 characters. An empty string disables the authentication.
See the authentication tutorial for more information.
The secret is stored in the EEPROM and only applied on startup. That means you have to restart the Master Brick after configuration.
It is recommended to use the Brick Viewer to set the WIFI authentication secret.
The default value is an empty string (authentication disabled).
New in version 2.2.0 (Firmware).
Returns the authentication secret as set by master_set_wifi_authentication_secret().
New in version 2.2.0 (Firmware).
Returns the version of the API definition (major, minor, revision) implemented by this API bindings. This is neither the release version of this API bindings nor does it tell you anything about the represented Brick or Bricklet.
Returns the response expected flag for the function specified by the function ID parameter. It is true if the function is expected to send a response, false otherwise.
For getter functions this is enabled by default and cannot be disabled, because those functions will always send a response. For callback configuration functions it is enabled by default too, but can be disabled by master_set_response_expected(). For setter functions it is disabled by default and can be enabled.
Enabling the response expected flag for a setter function allows to detect timeouts and other error conditions calls of this setter as well. The device will then send a response for this purpose. If this flag is disabled for a setter function then no response is send and errors are silently ignored, because they cannot be detected.
See master_set_response_expected() for the list of function ID defines available for this function.
Changes the response expected flag of the function specified by the function ID parameter. This flag can only be changed for setter (default value: false) and callback configuration functions (default value: true). For getter functions it is always enabled and callbacks it is always disabled.
Enabling the response expected flag for a setter function allows to detect timeouts and other error conditions calls of this setter as well. The device will then send a response for this purpose. If this flag is disabled for a setter function then no response is send and errors are silently ignored, because they cannot be detected.
The following function ID defines are available for this function:
Changes the response expected flag for all setter and callback configuration functions of this device at once.
Enables the status LED.
The status LED is the blue LED next to the USB connector. If enabled is is on and it flickers if data is transfered. If disabled it is always off.
The default state is enabled.
New in version 2.3.2 (Firmware).
Disables the status LED.
The status LED is the blue LED next to the USB connector. If enabled is is on and it flickers if data is transfered. If disabled it is always off.
The default state is enabled.
New in version 2.3.2 (Firmware).
Returns true if the status LED is enabled, false otherwise.
New in version 2.3.2 (Firmware).
Returns the firmware and protocol version and the name of the Bricklet for a given port.
This functions sole purpose is to allow automatic flashing of v1.x.y Bricklet plugins.
Returns the temperature in °C/10 as measured inside the microcontroller. The value returned is not the ambient temperature!
The temperature is only proportional to the real temperature and it has an accuracy of +-15%. Practically it is only useful as an indicator for temperature changes.
Calling this function will reset the Brick. Calling this function on a Brick inside of a stack will reset the whole stack.
After a reset you have to create new device objects, calling functions on the existing ones will result in undefined behavior!
Returns the UID, the UID where the Brick is connected to, the position, the hardware and firmware version as well as the device identifier.
The position can be '0'-'8' (stack position).
The device identifier numbers can be found here. There is also a constant for the device identifier of this Brick.
Registers a callback with ID id to the function callback. The user_data will be given as a parameter of the callback.
The available IDs with corresponding function signatures are listed below.
Sets the period in ms with which the MASTER_CALLBACK_STACK_CURRENT callback is triggered periodically. A value of 0 turns the callback off.
MASTER_CALLBACK_STACK_CURRENT is only triggered if the current has changed since the last triggering.
The default value is 0.
New in version 2.0.5 (Firmware).
Returns the period as set by SetCurrentCallbackPeriod().
New in version 2.0.5 (Firmware).
Sets the period in ms with which the MASTER_CALLBACK_STACK_VOLTAGE callback is triggered periodically. A value of 0 turns the callback off.
MASTER_CALLBACK_STACK_VOLTAGE is only triggered if the voltage has changed since the last triggering.
The default value is 0.
New in version 2.0.5 (Firmware).
Returns the period as set by master_set_stack_voltage_callback_period().
New in version 2.0.5 (Firmware).
Sets the period in ms with which the MASTER_CALLBACK_USB_VOLTAGE callback is triggered periodically. A value of 0 turns the callback off.
MASTER_CALLBACK_USB_VOLTAGE is only triggered if the voltage has changed since the last triggering.
The default value is 0.
New in version 2.0.5 (Firmware).
Returns the period as set by master_set_usb_voltage_callback_period().
New in version 2.0.5 (Firmware).
Sets the thresholds for the MASTER_CALLBACK_STACK_CURRENT_REACHED callback.
The following options are possible:
Option | Description |
---|---|
'x' | Callback is turned off |
'o' | Callback is triggered when the current is outside the min and max values |
'i' | Callback is triggered when the current is inside the min and max values |
'<' | Callback is triggered when the current is smaller than the min value (max is ignored) |
'>' | Callback is triggered when the current is greater than the min value (max is ignored) |
The default value is ('x', 0, 0).
The following defines are available for this function:
New in version 2.0.5 (Firmware).
Returns the threshold as set by master_set_stack_current_callback_threshold().
The following defines are available for this function:
New in version 2.0.5 (Firmware).
Sets the thresholds for the StackStackVoltageReached() callback.
The following options are possible:
Option | Description |
---|---|
'x' | Callback is turned off |
'o' | Callback is triggered when the voltage is outside the min and max values |
'i' | Callback is triggered when the voltage is inside the min and max values |
'<' | Callback is triggered when the voltage is smaller than the min value (max is ignored) |
'>' | Callback is triggered when the voltage is greater than the min value (max is ignored) |
The default value is ('x', 0, 0).
The following defines are available for this function:
New in version 2.0.5 (Firmware).
Returns the threshold as set by master_set_stack_voltage_callback_threshold().
The following defines are available for this function:
New in version 2.0.5 (Firmware).
Sets the thresholds for the MASTER_CALLBACK_USB_VOLTAGE_REACHED callback.
The following options are possible:
Option | Description |
---|---|
'x' | Callback is turned off |
'o' | Callback is triggered when the voltage is outside the min and max values |
'i' | Callback is triggered when the voltage is inside the min and max values |
'<' | Callback is triggered when the voltage is smaller than the min value (max is ignored) |
'>' | Callback is triggered when the voltage is greater than the min value (max is ignored) |
The default value is ('x', 0, 0).
The following defines are available for this function:
New in version 2.0.5 (Firmware).
Returns the threshold as set by master_set_usb_voltage_callback_threshold().
The following defines are available for this function:
New in version 2.0.5 (Firmware).
Sets the period in ms with which the threshold callbacks
are triggered, if the thresholds
keep being reached.
The default value is 100.
New in version 2.0.5 (Firmware).
Returns the debounce period as set by master_set_debounce_period().
New in version 2.0.5 (Firmware).
Callbacks can be registered to receive time critical or recurring data from the device. The registration is done with the master_register_callback() function. The parameters consist of the device object, the callback ID, the callback function and optional user data:
void my_callback(int p, void *user_data) { printf("parameter: %d\n", p); } master_register_callback(&master, MASTER_CALLBACK_EXAMPLE, (void *)my_callback, NULL);
The available constants with corresponding callback function signatures are described below.
Note
Using callbacks for recurring events is always preferred compared to using getters. It will use less USB bandwidth and the latency will be a lot better, since there is no round trip time.
void callback(uint16_t current, void *user_data)
This callback is triggered periodically with the period that is set by master_set_stack_current_callback_period(). The parameter is the current of the sensor.
MASTER_CALLBACK_STACK_CURRENT is only triggered if the current has changed since the last triggering.
New in version 2.0.5 (Firmware).
void callback(uint16_t voltage, void *user_data)
This callback is triggered periodically with the period that is set by master_set_stack_voltage_callback_period(). The parameter is the voltage of the sensor.
MASTER_CALLBACK_STACK_VOLTAGE is only triggered if the voltage has changed since the last triggering.
New in version 2.0.5 (Firmware).
void callback(uint16_t voltage, void *user_data)
This callback is triggered periodically with the period that is set by master_set_usb_voltage_callback_period(). The parameter is the USB voltage in mV.
MASTER_CALLBACK_USB_VOLTAGE is only triggered if the USB voltage has changed since the last triggering.
Does not work with hardware version 2.1.
New in version 2.0.5 (Firmware).
void callback(uint16_t current, void *user_data)
This callback is triggered when the threshold as set by master_set_stack_current_callback_threshold() is reached. The parameter is the stack current in mA.
If the threshold keeps being reached, the callback is triggered periodically with the period as set by master_set_debounce_period().
New in version 2.0.5 (Firmware).
void callback(uint16_t voltage, void *user_data)
This callback is triggered when the threshold as set by master_set_stack_voltage_callback_threshold() is reached. The parameter is the stack voltage in mV.
If the threshold keeps being reached, the callback is triggered periodically with the period as set by master_set_debounce_period().
New in version 2.0.5 (Firmware).
void callback(uint16_t voltage, void *user_data)
This callback is triggered when the threshold as set by master_set_usb_voltage_callback_threshold() is reached. The parameter is the voltage of the sensor.
If the threshold keeps being reached, the callback is triggered periodically with the period as set by master_set_debounce_period().
New in version 2.0.5 (Firmware).
This constant is used to identify a Master Brick.
The master_get_identity() function and the IPCON_CALLBACK_ENUMERATE callback of the IP Connection have a device_identifier parameter to specify the Brick's or Bricklet's type.