Lucian Corduneanu
Multitech xDot Utils
MultitechDot.cpp
- Committer:
- lucian@1.0.0.127.in-addr.arpa
- Date:
- 2017-05-15
- Revision:
- 0:a5748bc6e3e1
- Child:
- 1:73cea350269e
File content as of revision 0:a5748bc6e3e1:
#include "MultitechDot.h"
void MultitechDot::config(uint8_t *network_address, uint8_t *network_session_key, uint8_t *data_session_key,
uint8_t frequency_sub_band, bool public_network, uint8_t ack) {
if (!this->getStandbyFlag()) {
logInfo("mbed-os library version: %d", MBED_LIBRARY_VERSION);
// start from a well-known state
logInfo("defaulting Dot configuration");
this->resetConfig();
this->resetNetworkSession();
// make sure library logging is turned on
this->setLogLevel(mts::MTSLog::INFO_LEVEL);
// update configuration if necessary
if (this->getJoinMode() != this->MANUAL) {
logInfo("changing network join mode to MANUAL");
if (this->setJoinMode(this->MANUAL) != this->MDOT_OK) {
logError("failed to set network join mode to MANUAL");
}
}
// in MANUAL join mode there is no join request/response transaction
// as long as the Dot is configured correctly and provisioned correctly on the gateway, it should be able to communicate
// network address - 4 bytes (00000001 - FFFFFFFE)
// network session key - 16 bytes
// data session key - 16 bytes
// to provision your Dot with a Conduit gateway, follow the following steps
// * ssh into the Conduit
// * provision the Dot using the lora-query application: http://www.multitech.net/developer/software/lora/lora-network-server/
// lora-query -a 01020304 A 0102030401020304 <your Dot's device ID> 01020304010203040102030401020304 01020304010203040102030401020304
// * if you change the network address, network session key, or data session key, make sure you update them on the gateway
// to provision your Dot with a 3rd party gateway, see the gateway or network provider documentation
this->update_manual_config(network_address, network_session_key, data_session_key, frequency_sub_band,
public_network, ack);
// save changes to configuration
logInfo("saving configuration");
if (!this->saveConfig()) {
logError("failed to save configuration");
}
// display configuration
this->display_config();
} else {
// restore the saved session if the dot woke from deepsleep mode
// useful to use with deepsleep because session info is otherwise lost when the dot enters deepsleep
logInfo("restoring network session from NVM");
this->restoreNetworkSession();
}
}
void MultitechDot::display_config() {
// display configuration and library version information
logInfo("=====================");
logInfo("general configuration");
logInfo("=====================");
logInfo("version ------------------ %s", this->getId().c_str());
logInfo("device ID/EUI ------------ %s", mts::Text::bin2hexString(this->getDeviceId()).c_str());
logInfo("frequency band ----------- %s", this->FrequencyBandStr(this->getFrequencyBand()).c_str());
if (this->getFrequencySubBand() != this->FB_EU868) {
logInfo("frequency sub band ------- %u", this->getFrequencySubBand());
}
logInfo("public network ----------- %s", this->getPublicNetwork() ? "on" : "off");
logInfo("=========================");
logInfo("credentials configuration");
logInfo("=========================");
logInfo("device class ------------- %s", this->getClass().c_str());
logInfo("network join mode -------- %s", this->JoinModeStr(this->getJoinMode()).c_str());
if (this->getJoinMode() == this->MANUAL || this->getJoinMode() == this->PEER_TO_PEER) {
logInfo("network address ---------- %s", mts::Text::bin2hexString(this->getNetworkAddress()).c_str());
logInfo("network session key------- %s", mts::Text::bin2hexString(this->getNetworkSessionKey()).c_str());
logInfo("data session key---------- %s", mts::Text::bin2hexString(this->getDataSessionKey()).c_str());
} else {
logInfo("network name ------------- %s", this->getNetworkName().c_str());
logInfo("network phrase ----------- %s", this->getNetworkPassphrase().c_str());
logInfo("network EUI -------------- %s", mts::Text::bin2hexString(this->getNetworkId()).c_str());
logInfo("network KEY -------------- %s", mts::Text::bin2hexString(this->getNetworkKey()).c_str());
}
logInfo("========================");
logInfo("communication parameters");
logInfo("========================");
if (this->getJoinMode() == this->PEER_TO_PEER) {
logInfo("TX frequency ------------- %lu", this->getTxFrequency());
} else {
logInfo("acks --------------------- %s, %u attempts", this->getAck() > 0 ? "on" : "off", this->getAck());
}
logInfo("TX datarate -------------- %s", this->DataRateStr(this->getTxDataRate()).c_str());
logInfo("TX power ----------------- %lu dBm", this->getTxPower());
logInfo("atnenna gain ------------- %u dBm", this->getAntennaGain());
}
void MultitechDot::update_ota_config_name_phrase(std::string network_name, std::string network_passphrase,
uint8_t frequency_sub_band, bool public_network, uint8_t ack) {
std::string current_network_name = this->getNetworkName();
std::string current_network_passphrase = this->getNetworkPassphrase();
uint8_t current_frequency_sub_band = this->getFrequencySubBand();
bool current_public_network = this->getPublicNetwork();
uint8_t current_ack = this->getAck();
if (current_network_name != network_name) {
logInfo("changing network name from \"%s\" to \"%s\"", current_network_name.c_str(), network_name.c_str());
if (this->setNetworkName(network_name) != this->MDOT_OK) {
logError("failed to set network name to \"%s\"", network_name.c_str());
}
}
if (current_network_passphrase != network_passphrase) {
logInfo("changing network passphrase from \"%s\" to \"%s\"", current_network_passphrase.c_str(),
network_passphrase.c_str());
if (this->setNetworkPassphrase(network_passphrase) != this->MDOT_OK) {
logError("failed to set network passphrase to \"%s\"", network_passphrase.c_str());
}
}
if (current_frequency_sub_band != frequency_sub_band) {
logInfo("changing frequency sub band from %u to %u", current_frequency_sub_band, frequency_sub_band);
if (this->setFrequencySubBand(frequency_sub_band) != this->MDOT_OK) {
logError("failed to set frequency sub band to %u", frequency_sub_band);
}
}
if (current_public_network != public_network) {
logInfo("changing public network from %s to %s", current_public_network ? "on" : "off",
public_network ? "on" : "off");
if (this->setPublicNetwork(public_network) != this->MDOT_OK) {
logError("failed to set public network to %s", public_network ? "on" : "off");
}
}
if (current_ack != ack) {
logInfo("changing acks from %u to %u", current_ack, ack);
if (this->setAck(ack) != this->MDOT_OK) {
logError("failed to set acks to %u", ack);
}
}
}
void MultitechDot::update_ota_config_id_key(uint8_t *network_id, uint8_t *network_key, uint8_t frequency_sub_band,
bool public_network, uint8_t ack) {
std::vector<uint8_t> current_network_id = this->getNetworkId();
std::vector<uint8_t> current_network_key = this->getNetworkKey();
uint8_t current_frequency_sub_band = this->getFrequencySubBand();
bool current_public_network = this->getPublicNetwork();
uint8_t current_ack = this->getAck();
std::vector<uint8_t> network_id_vector(network_id, network_id + 8);
std::vector<uint8_t> network_key_vector(network_key, network_key + 16);
if (current_network_id != network_id_vector) {
logInfo("changing network ID from \"%s\" to \"%s\"", mts::Text::bin2hexString(current_network_id).c_str(),
mts::Text::bin2hexString(network_id_vector).c_str());
if (this->setNetworkId(network_id_vector) != this->MDOT_OK) {
logError("failed to set network ID to \"%s\"", mts::Text::bin2hexString(network_id_vector).c_str());
}
}
if (current_network_key != network_key_vector) {
logInfo("changing network KEY from \"%s\" to \"%s\"", mts::Text::bin2hexString(current_network_key).c_str(),
mts::Text::bin2hexString(network_key_vector).c_str());
if (this->setNetworkKey(network_key_vector) != this->MDOT_OK) {
logError("failed to set network KEY to \"%s\"", mts::Text::bin2hexString(network_key_vector).c_str());
}
}
if (current_frequency_sub_band != frequency_sub_band) {
logInfo("changing frequency sub band from %u to %u", current_frequency_sub_band, frequency_sub_band);
if (this->setFrequencySubBand(frequency_sub_band) != this->MDOT_OK) {
logError("failed to set frequency sub band to %u", frequency_sub_band);
}
}
if (current_public_network != public_network) {
logInfo("changing public network from %s to %s", current_public_network ? "on" : "off",
public_network ? "on" : "off");
if (this->setPublicNetwork(public_network) != this->MDOT_OK) {
logError("failed to set public network to %s", public_network ? "on" : "off");
}
}
if (current_ack != ack) {
logInfo("changing acks from %u to %u", current_ack, ack);
if (this->setAck(ack) != this->MDOT_OK) {
logError("failed to set acks to %u", ack);
}
}
}
void MultitechDot::update_manual_config(
uint8_t *network_address, uint8_t *network_session_key, uint8_t *data_session_key,
uint8_t frequency_sub_band, bool public_network, uint8_t ack
) {
std::vector<uint8_t> current_network_address = this->getNetworkAddress();
std::vector<uint8_t> current_network_session_key = this->getNetworkSessionKey();
std::vector<uint8_t> current_data_session_key = this->getDataSessionKey();
uint8_t current_frequency_sub_band = this->getFrequencySubBand();
bool current_public_network = this->getPublicNetwork();
uint8_t current_ack = this->getAck();
std::vector<uint8_t> network_address_vector(network_address, network_address + 4);
std::vector<uint8_t> network_session_key_vector(network_session_key, network_session_key + 16);
std::vector<uint8_t> data_session_key_vector(data_session_key, data_session_key + 16);
if (current_network_address != network_address_vector) {
logInfo("changing network address from \"%s\" to \"%s\"",
mts::Text::bin2hexString(current_network_address).c_str(),
mts::Text::bin2hexString(network_address_vector).c_str());
if (this->setNetworkAddress(network_address_vector) != this->MDOT_OK) {
logError("failed to set network address to \"%s\"",
mts::Text::bin2hexString(network_address_vector).c_str());
}
}
if (current_network_session_key != network_session_key_vector) {
logInfo("changing network session key from \"%s\" to \"%s\"",
mts::Text::bin2hexString(current_network_session_key).c_str(),
mts::Text::bin2hexString(network_session_key_vector).c_str());
if (this->setNetworkSessionKey(network_session_key_vector) != this->MDOT_OK) {
logError("failed to set network session key to \"%s\"",
mts::Text::bin2hexString(network_session_key_vector).c_str());
}
}
if (current_data_session_key != data_session_key_vector) {
logInfo("changing data session key from \"%s\" to \"%s\"",
mts::Text::bin2hexString(current_data_session_key).c_str(),
mts::Text::bin2hexString(data_session_key_vector).c_str());
if (this->setDataSessionKey(data_session_key_vector) != this->MDOT_OK) {
logError("failed to set data session key to \"%s\"",
mts::Text::bin2hexString(data_session_key_vector).c_str());
}
}
if (current_frequency_sub_band != frequency_sub_band) {
logInfo("changing frequency sub band from %u to %u", current_frequency_sub_band, frequency_sub_band);
if (this->setFrequencySubBand(frequency_sub_band) != this->MDOT_OK) {
logError("failed to set frequency sub band to %u", frequency_sub_band);
}
}
if (current_public_network != public_network) {
logInfo("changing public network from %s to %s", current_public_network ? "on" : "off",
public_network ? "on" : "off");
if (this->setPublicNetwork(public_network) != this->MDOT_OK) {
logError("failed to set public network to %s", public_network ? "on" : "off");
}
}
if (current_ack != ack) {
logInfo("changing acks from %u to %u", current_ack, ack);
if (this->setAck(ack) != this->MDOT_OK) {
logError("failed to set acks to %u", ack);
}
}
}
void MultitechDot::update_peer_to_peer_config(uint8_t *network_address, uint8_t *network_session_key,
uint8_t *data_session_key, uint32_t tx_frequency, uint8_t tx_datarate,
uint8_t tx_power) {
std::vector<uint8_t> current_network_address = this->getNetworkAddress();
std::vector<uint8_t> current_network_session_key = this->getNetworkSessionKey();
std::vector<uint8_t> current_data_session_key = this->getDataSessionKey();
uint32_t current_tx_frequency = this->getTxFrequency();
uint8_t current_tx_datarate = this->getTxDataRate();
uint8_t current_tx_power = this->getTxPower();
std::vector<uint8_t> network_address_vector(network_address, network_address + 4);
std::vector<uint8_t> network_session_key_vector(network_session_key, network_session_key + 16);
std::vector<uint8_t> data_session_key_vector(data_session_key, data_session_key + 16);
if (current_network_address != network_address_vector) {
logInfo("changing network address from \"%s\" to \"%s\"",
mts::Text::bin2hexString(current_network_address).c_str(),
mts::Text::bin2hexString(network_address_vector).c_str());
if (this->setNetworkAddress(network_address_vector) != this->MDOT_OK) {
logError("failed to set network address to \"%s\"",
mts::Text::bin2hexString(network_address_vector).c_str());
}
}
if (current_network_session_key != network_session_key_vector) {
logInfo("changing network session key from \"%s\" to \"%s\"",
mts::Text::bin2hexString(current_network_session_key).c_str(),
mts::Text::bin2hexString(network_session_key_vector).c_str());
if (this->setNetworkSessionKey(network_session_key_vector) != this->MDOT_OK) {
logError("failed to set network session key to \"%s\"",
mts::Text::bin2hexString(network_session_key_vector).c_str());
}
}
if (current_data_session_key != data_session_key_vector) {
logInfo("changing data session key from \"%s\" to \"%s\"",
mts::Text::bin2hexString(current_data_session_key).c_str(),
mts::Text::bin2hexString(data_session_key_vector).c_str());
if (this->setDataSessionKey(data_session_key_vector) != this->MDOT_OK) {
logError("failed to set data session key to \"%s\"",
mts::Text::bin2hexString(data_session_key_vector).c_str());
}
}
if (current_tx_frequency != tx_frequency) {
logInfo("changing TX frequency from %lu to %lu", current_tx_frequency, tx_frequency);
if (this->setTxFrequency(tx_frequency) != this->MDOT_OK) {
logError("failed to set TX frequency to %lu", tx_frequency);
}
}
if (current_tx_datarate != tx_datarate) {
logInfo("changing TX datarate from %u to %u", current_tx_datarate, tx_datarate);
if (this->setTxDataRate(tx_datarate) != this->MDOT_OK) {
logError("failed to set TX datarate to %u", tx_datarate);
}
}
if (current_tx_power != tx_power) {
logInfo("changing TX power from %u to %u", current_tx_power, tx_power);
if (this->setTxPower(tx_power) != this->MDOT_OK) {
logError("failed to set TX power to %u", tx_power);
}
}
}
void MultitechDot::update_network_link_check_config(uint8_t link_check_count, uint8_t link_check_threshold) {
uint8_t current_link_check_count = this->getLinkCheckCount();
uint8_t current_link_check_threshold = this->getLinkCheckThreshold();
if (current_link_check_count != link_check_count) {
logInfo("changing link check count from %u to %u", current_link_check_count, link_check_count);
if (this->setLinkCheckCount(link_check_count) != this->MDOT_OK) {
logError("failed to set link check count to %u", link_check_count);
}
}
if (current_link_check_threshold != link_check_threshold) {
logInfo("changing link check threshold from %u to %u", current_link_check_threshold, link_check_threshold);
if (this->setLinkCheckThreshold(link_check_threshold) != this->MDOT_OK) {
logError("failed to set link check threshold to %u", link_check_threshold);
}
}
}
void MultitechDot::join_network() {
int32_t j_attempts = 0;
int32_t ret = this->MDOT_ERROR;
// attempt to join the network
while (ret != this->MDOT_OK) {
logInfo("attempt %d to join network", ++j_attempts);
ret = this->joinNetwork();
if (ret != this->MDOT_OK) {
logError("failed to join network %d:%s", ret, this->getReturnCodeString(ret).c_str());
// in some frequency bands we need to wait until another channel is available before transmitting again
uint32_t delay_s = (this->getNextTxMs() / 1000) + 1;
if (delay_s < 2) {
logInfo("waiting %lu s until next free channel", delay_s);
wait(delay_s);
} else {
logInfo("sleeping %lu s until next free channel", delay_s);
this->sleep(delay_s, this->RTC_ALARM, false);
}
}
}
}
void MultitechDot::deep_sleep(uint32_t min_delay_s) {
uint32_t delay_s = this->getNextTxMs() / 1000;
// save the session so we don't need to join again after waking up
// not necessary if going into sleep mode since RAM is retained
logInfo("saving network session to NVM");
this->saveNetworkSession();
if (delay_s < min_delay_s) {
delay_s = min_delay_s;
}
logInfo("deepsleeping %lus", delay_s);
logInfo("application will execute from beginning after waking up");
// go to deepsleep for delay_s seconds and wake using the RTC alarm
this->sleep(delay_s, this->RTC_ALARM, true);
}
void MultitechDot::sleep_wake_rtc_only(bool deepsleep) {
// in some frequency bands we need to wait until another channel is available before transmitting again
// wait at least 10s between transmissions
uint32_t delay_s = this->getNextTxMs() / 1000;
if (delay_s < 10) {
delay_s = 10;
}
logInfo("%ssleeping %lus", deepsleep ? "deep" : "", delay_s);
logInfo("application will %s after waking up", deepsleep ? "execute from beginning" : "resume");
// lowest current consumption in sleep mode can only be achieved by configuring IOs as analog inputs with no pull resistors
// the library handles all internal IOs automatically, but the external IOs are the application's responsibility
// certain IOs may require internal pullup or pulldown resistors because leaving them floating would cause extra current consumption
// for xDot: UART_*, I2C_*, SPI_*, GPIO*, WAKE
// for mDot: XBEE_*, USBTX, USBRX, PB_0, PB_1
// steps are:
// * save IO configuration
// * configure IOs to reduce current consumption
// * sleep
// * restore IO configuration
if (!deepsleep) {
// save the GPIO state.
sleep_save_io();
// configure GPIOs for lowest current
sleep_configure_io();
}
// go to sleep/deepsleep for delay_s seconds and wake using the RTC alarm
this->sleep(delay_s, this->RTC_ALARM, deepsleep);
if (!deepsleep) {
// restore the GPIO state.
sleep_restore_io();
}
}
void MultitechDot::sleep_wake_interrupt_only(bool deepsleep) {
if (deepsleep) {
// for xDot, WAKE pin (connected to S2 on xDot-DK) is the only pin that can wake the processor from deepsleep
// it is automatically configured when INTERRUPT or RTC_ALARM_OR_INTERRUPT is the wakeup source and deepsleep is true in the mDot::sleep call
} else {
// configure WAKE pin (connected to S2 on xDot-DK) as the pin that will wake the xDot from low power modes
// other pins can be confgured instead: GPIO0-3 or UART_RX
this->setWakePin(WAKE);
}
logInfo("%ssleeping until interrupt on %s pin", deepsleep ? "deep" : "",
deepsleep ? "WAKE" : this->pinName2Str(this->getWakePin()).c_str());
logInfo("application will %s after waking up", deepsleep ? "execute from beginning" : "resume");
// lowest current consumption in sleep mode can only be achieved by configuring IOs as analog inputs with no pull resistors
// the library handles all internal IOs automatically, but the external IOs are the application's responsibility
// certain IOs may require internal pullup or pulldown resistors because leaving them floating would cause extra current consumption
// for xDot: UART_*, I2C_*, SPI_*, GPIO*, WAKE
// for mDot: XBEE_*, USBTX, USBRX, PB_0, PB_1
// steps are:
// * save IO configuration
// * configure IOs to reduce current consumption
// * sleep
// * restore IO configuration
if (!deepsleep) {
// save the GPIO state.
this->sleep_save_io();
// configure GPIOs for lowest current
this->sleep_configure_io();
}
// go to sleep/deepsleep and wake on rising edge of configured wake pin (only the WAKE pin in deepsleep)
// since we're not waking on the RTC alarm, the interval is ignored
this->sleep(0, this->INTERRUPT, deepsleep);
if (!deepsleep) {
// restore the GPIO state.
this->sleep_restore_io();
}
}
void MultitechDot::sleep_wake_rtc_or_interrupt(uint32_t delay_s, bool deepsleep) {
if (deepsleep) {
// for xDot, WAKE pin (connected to S2 on xDot-DK) is the only pin that can wake the processor from deepsleep
// it is automatically configured when INTERRUPT or RTC_ALARM_OR_INTERRUPT is the wakeup source and deepsleep is true in the this->sleep call
} else {
// configure WAKE pin (connected to S2 on xDot-DK) as the pin that will wake the xDot from low power modes
// other pins can be confgured instead: GPIO0-3 or UART_RX
this->setWakePin(WAKE);
}
logInfo("%ssleeping %lus or until interrupt on %s pin", deepsleep ? "deep" : "", delay_s,
deepsleep ? "WAKE" : this->pinName2Str(this->getWakePin()).c_str());
logInfo("application will %s after waking up", deepsleep ? "execute from beginning" : "resume");
// lowest current consumption in sleep mode can only be achieved by configuring IOs as analog inputs with no pull resistors
// the library handles all internal IOs automatically, but the external IOs are the application's responsibility
// certain IOs may require internal pullup or pulldown resistors because leaving them floating would cause extra current consumption
// for xDot: UART_*, I2C_*, SPI_*, GPIO*, WAKE
// for mDot: XBEE_*, USBTX, USBRX, PB_0, PB_1
// steps are:
// * save IO configuration
// * configure IOs to reduce current consumption
// * sleep
// * restore IO configuration
if (!deepsleep) {
// save the GPIO state.
this->sleep_save_io();
// configure GPIOs for lowest current
this->sleep_configure_io();
}
// go to sleep/deepsleep and wake using the RTC alarm after delay_s seconds or rising edge of configured wake pin (only the WAKE pin in deepsleep)
// whichever comes first will wake the xDot
this->sleep(delay_s, this->RTC_ALARM_OR_INTERRUPT, deepsleep);
if (!deepsleep) {
// restore the GPIO state.
this->sleep_restore_io();
}
}
void MultitechDot::sleep_save_io() {
xdot_save_gpio_state();
}
void MultitechDot::sleep_configure_io() {
// GPIO Ports Clock Enable
__GPIOA_CLK_ENABLE();
__GPIOB_CLK_ENABLE();
__GPIOC_CLK_ENABLE();
__GPIOH_CLK_ENABLE();
GPIO_InitTypeDef GPIO_InitStruct;
// UART1_TX, UART1_RTS & UART1_CTS to analog nopull - RX could be a wakeup source
GPIO_InitStruct.Pin = GPIO_PIN_9 | GPIO_PIN_11 | GPIO_PIN_12;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOA, &GPIO_InitStruct);
// I2C_SDA & I2C_SCL to analog nopull
GPIO_InitStruct.Pin = GPIO_PIN_8 | GPIO_PIN_9;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOB, &GPIO_InitStruct);
// SPI_MOSI, SPI_MISO, SPI_SCK, & SPI_NSS to analog nopull
GPIO_InitStruct.Pin = GPIO_PIN_12 | GPIO_PIN_13 | GPIO_PIN_14 | GPIO_PIN_15;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOB, &GPIO_InitStruct);
// iterate through potential wake pins - leave the configured wake pin alone if one is needed
if (this->getWakePin() != WAKE || this->getWakeMode() == this->RTC_ALARM) {
GPIO_InitStruct.Pin = GPIO_PIN_0;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOA, &GPIO_InitStruct);
}
if (this->getWakePin() != GPIO0 || this->getWakeMode() == this->RTC_ALARM) {
GPIO_InitStruct.Pin = GPIO_PIN_4;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOA, &GPIO_InitStruct);
}
if (this->getWakePin() != GPIO1 || this->getWakeMode() == this->RTC_ALARM) {
GPIO_InitStruct.Pin = GPIO_PIN_5;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOA, &GPIO_InitStruct);
}
if (this->getWakePin() != GPIO2 || this->getWakeMode() == this->RTC_ALARM) {
GPIO_InitStruct.Pin = GPIO_PIN_0;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOB, &GPIO_InitStruct);
}
if (this->getWakePin() != GPIO3 || this->getWakeMode() == this->RTC_ALARM) {
GPIO_InitStruct.Pin = GPIO_PIN_2;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOB, &GPIO_InitStruct);
}
if (this->getWakePin() != UART1_RX || this->getWakeMode() == this->RTC_ALARM) {
GPIO_InitStruct.Pin = GPIO_PIN_10;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(GPIOA, &GPIO_InitStruct);
}
}
void MultitechDot::sleep_restore_io() {
xdot_restore_gpio_state();
}
void MultitechDot::send_data(std::vector<uint8_t> data) {
uint32_t ret;
ret = this->send(data);
if (ret != this->MDOT_OK) {
logError("failed to send data to %s [%d][%s]", this->getJoinMode() == this->PEER_TO_PEER ? "peer" : "gateway",
ret, this->getReturnCodeString(ret).c_str());
} else {
logInfo("successfully sent data to %s", this->getJoinMode() == this->PEER_TO_PEER ? "peer" : "gateway");
}
}