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add a .clang-format file (#9154)

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Jorropo
2026-01-03 21:19:24 +01:00
committed by GitHub
parent abab6ce815
commit 0d11331d18
771 changed files with 77752 additions and 83184 deletions
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319
src/airtime.cpp
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@@ -9,202 +9,175 @@ AirTime *airTime = NULL;
uint32_t air_period_tx[PERIODS_TO_LOG];
uint32_t air_period_rx[PERIODS_TO_LOG];
void AirTime::logAirtime(reportTypes reportType, uint32_t airtime_ms)
{
void AirTime::logAirtime(reportTypes reportType, uint32_t airtime_ms) {
if (reportType == TX_LOG) {
LOG_DEBUG("Packet TX: %ums", airtime_ms);
this->airtimes.periodTX[0] = this->airtimes.periodTX[0] + airtime_ms;
air_period_tx[0] = air_period_tx[0] + airtime_ms;
if (reportType == TX_LOG) {
LOG_DEBUG("Packet TX: %ums", airtime_ms);
this->airtimes.periodTX[0] = this->airtimes.periodTX[0] + airtime_ms;
air_period_tx[0] = air_period_tx[0] + airtime_ms;
this->utilizationTX[this->getPeriodUtilHour()] = this->utilizationTX[this->getPeriodUtilHour()] + airtime_ms;
} else if (reportType == RX_LOG) {
LOG_DEBUG("Packet RX: %ums", airtime_ms);
this->airtimes.periodRX[0] = this->airtimes.periodRX[0] + airtime_ms;
air_period_rx[0] = air_period_rx[0] + airtime_ms;
} else if (reportType == RX_ALL_LOG) {
LOG_DEBUG("Packet RX (noise?) : %ums", airtime_ms);
this->airtimes.periodRX_ALL[0] = this->airtimes.periodRX_ALL[0] + airtime_ms;
this->utilizationTX[this->getPeriodUtilHour()] = this->utilizationTX[this->getPeriodUtilHour()] + airtime_ms;
} else if (reportType == RX_LOG) {
LOG_DEBUG("Packet RX: %ums", airtime_ms);
this->airtimes.periodRX[0] = this->airtimes.periodRX[0] + airtime_ms;
air_period_rx[0] = air_period_rx[0] + airtime_ms;
} else if (reportType == RX_ALL_LOG) {
LOG_DEBUG("Packet RX (noise?) : %ums", airtime_ms);
this->airtimes.periodRX_ALL[0] = this->airtimes.periodRX_ALL[0] + airtime_ms;
}
// Log all airtime type for channel utilization
this->channelUtilization[this->getPeriodUtilMinute()] = channelUtilization[this->getPeriodUtilMinute()] + airtime_ms;
}
uint8_t AirTime::currentPeriodIndex() { return ((getSecondsSinceBoot() / SECONDS_PER_PERIOD) % PERIODS_TO_LOG); }
uint8_t AirTime::getPeriodUtilMinute() { return (getSecondsSinceBoot() / 10) % CHANNEL_UTILIZATION_PERIODS; }
uint8_t AirTime::getPeriodUtilHour() { return (getSecondsSinceBoot() / 60) % MINUTES_IN_HOUR; }
void AirTime::airtimeRotatePeriod() {
if (this->airtimes.lastPeriodIndex != this->currentPeriodIndex()) {
LOG_DEBUG("Rotate airtimes to a new period = %u", this->currentPeriodIndex());
for (int i = PERIODS_TO_LOG - 2; i >= 0; --i) {
this->airtimes.periodTX[i + 1] = this->airtimes.periodTX[i];
this->airtimes.periodRX[i + 1] = this->airtimes.periodRX[i];
this->airtimes.periodRX_ALL[i + 1] = this->airtimes.periodRX_ALL[i];
air_period_tx[i + 1] = this->airtimes.periodTX[i];
air_period_rx[i + 1] = this->airtimes.periodRX[i];
}
// Log all airtime type for channel utilization
this->channelUtilization[this->getPeriodUtilMinute()] = channelUtilization[this->getPeriodUtilMinute()] + airtime_ms;
this->airtimes.periodTX[0] = 0;
this->airtimes.periodRX[0] = 0;
this->airtimes.periodRX_ALL[0] = 0;
air_period_tx[0] = 0;
air_period_rx[0] = 0;
this->airtimes.lastPeriodIndex = this->currentPeriodIndex();
}
}
uint8_t AirTime::currentPeriodIndex()
{
return ((getSecondsSinceBoot() / SECONDS_PER_PERIOD) % PERIODS_TO_LOG);
uint32_t *AirTime::airtimeReport(reportTypes reportType) {
if (reportType == TX_LOG) {
return this->airtimes.periodTX;
} else if (reportType == RX_LOG) {
return this->airtimes.periodRX;
} else if (reportType == RX_ALL_LOG) {
return this->airtimes.periodRX_ALL;
}
return 0;
}
uint8_t AirTime::getPeriodUtilMinute()
{
return (getSecondsSinceBoot() / 10) % CHANNEL_UTILIZATION_PERIODS;
uint8_t AirTime::getPeriodsToLog() { return PERIODS_TO_LOG; }
uint32_t AirTime::getSecondsPerPeriod() { return SECONDS_PER_PERIOD; }
uint32_t AirTime::getSecondsSinceBoot() { return this->secSinceBoot; }
float AirTime::channelUtilizationPercent() {
uint32_t sum = 0;
for (uint32_t i = 0; i < CHANNEL_UTILIZATION_PERIODS; i++) {
sum += this->channelUtilization[i];
}
return (float(sum) / float(CHANNEL_UTILIZATION_PERIODS * 10 * 1000)) * 100;
}
uint8_t AirTime::getPeriodUtilHour()
{
return (getSecondsSinceBoot() / 60) % MINUTES_IN_HOUR;
float AirTime::utilizationTXPercent() {
uint32_t sum = 0;
for (uint32_t i = 0; i < MINUTES_IN_HOUR; i++) {
sum += this->utilizationTX[i];
}
return (float(sum) / float(MS_IN_HOUR)) * 100;
}
void AirTime::airtimeRotatePeriod()
{
if (this->airtimes.lastPeriodIndex != this->currentPeriodIndex()) {
LOG_DEBUG("Rotate airtimes to a new period = %u", this->currentPeriodIndex());
for (int i = PERIODS_TO_LOG - 2; i >= 0; --i) {
this->airtimes.periodTX[i + 1] = this->airtimes.periodTX[i];
this->airtimes.periodRX[i + 1] = this->airtimes.periodRX[i];
this->airtimes.periodRX_ALL[i + 1] = this->airtimes.periodRX_ALL[i];
air_period_tx[i + 1] = this->airtimes.periodTX[i];
air_period_rx[i + 1] = this->airtimes.periodRX[i];
}
this->airtimes.periodTX[0] = 0;
this->airtimes.periodRX[0] = 0;
this->airtimes.periodRX_ALL[0] = 0;
air_period_tx[0] = 0;
air_period_rx[0] = 0;
this->airtimes.lastPeriodIndex = this->currentPeriodIndex();
}
}
uint32_t *AirTime::airtimeReport(reportTypes reportType)
{
if (reportType == TX_LOG) {
return this->airtimes.periodTX;
} else if (reportType == RX_LOG) {
return this->airtimes.periodRX;
} else if (reportType == RX_ALL_LOG) {
return this->airtimes.periodRX_ALL;
}
return 0;
}
uint8_t AirTime::getPeriodsToLog()
{
return PERIODS_TO_LOG;
}
uint32_t AirTime::getSecondsPerPeriod()
{
return SECONDS_PER_PERIOD;
}
uint32_t AirTime::getSecondsSinceBoot()
{
return this->secSinceBoot;
}
float AirTime::channelUtilizationPercent()
{
uint32_t sum = 0;
for (uint32_t i = 0; i < CHANNEL_UTILIZATION_PERIODS; i++) {
sum += this->channelUtilization[i];
}
return (float(sum) / float(CHANNEL_UTILIZATION_PERIODS * 10 * 1000)) * 100;
}
float AirTime::utilizationTXPercent()
{
uint32_t sum = 0;
for (uint32_t i = 0; i < MINUTES_IN_HOUR; i++) {
sum += this->utilizationTX[i];
}
return (float(sum) / float(MS_IN_HOUR)) * 100;
}
bool AirTime::isTxAllowedChannelUtil(bool polite)
{
uint8_t percentage = (polite ? polite_channel_util_percent : max_channel_util_percent);
if (channelUtilizationPercent() < percentage) {
return true;
} else {
LOG_WARN("Ch. util >%d%%. Skip send", percentage);
return false;
}
}
bool AirTime::isTxAllowedAirUtil()
{
if (!config.lora.override_duty_cycle && myRegion->dutyCycle < 100) {
if (utilizationTXPercent() < myRegion->dutyCycle * polite_duty_cycle_percent / 100) {
return true;
} else {
LOG_WARN("TX air util. >%f%%. Skip send", myRegion->dutyCycle * polite_duty_cycle_percent / 100);
return false;
}
}
bool AirTime::isTxAllowedChannelUtil(bool polite) {
uint8_t percentage = (polite ? polite_channel_util_percent : max_channel_util_percent);
if (channelUtilizationPercent() < percentage) {
return true;
} else {
LOG_WARN("Ch. util >%d%%. Skip send", percentage);
return false;
}
}
bool AirTime::isTxAllowedAirUtil() {
if (!config.lora.override_duty_cycle && myRegion->dutyCycle < 100) {
if (utilizationTXPercent() < myRegion->dutyCycle * polite_duty_cycle_percent / 100) {
return true;
} else {
LOG_WARN("TX air util. >%f%%. Skip send", myRegion->dutyCycle * polite_duty_cycle_percent / 100);
return false;
}
}
return true;
}
// Get the amount of minutes we have to be silent before we can send again
uint8_t AirTime::getSilentMinutes(float txPercent, float dutyCycle)
{
float newTxPercent = txPercent;
for (int8_t i = MINUTES_IN_HOUR - 1; i >= 0; --i) {
newTxPercent -= ((float)this->utilizationTX[i] / (MS_IN_MINUTE * MINUTES_IN_HOUR / 100));
if (newTxPercent < dutyCycle)
return MINUTES_IN_HOUR - 1 - i;
}
uint8_t AirTime::getSilentMinutes(float txPercent, float dutyCycle) {
float newTxPercent = txPercent;
for (int8_t i = MINUTES_IN_HOUR - 1; i >= 0; --i) {
newTxPercent -= ((float)this->utilizationTX[i] / (MS_IN_MINUTE * MINUTES_IN_HOUR / 100));
if (newTxPercent < dutyCycle)
return MINUTES_IN_HOUR - 1 - i;
}
return MINUTES_IN_HOUR;
return MINUTES_IN_HOUR;
}
AirTime::AirTime() : concurrency::OSThread("AirTime"), airtimes({}) {}
int32_t AirTime::runOnce()
{
secSinceBoot++;
int32_t AirTime::runOnce() {
secSinceBoot++;
uint8_t utilPeriod = this->getPeriodUtilMinute();
uint8_t utilPeriodTX = this->getPeriodUtilHour();
uint8_t utilPeriod = this->getPeriodUtilMinute();
uint8_t utilPeriodTX = this->getPeriodUtilHour();
if (firstTime) {
if (firstTime) {
// Init utilizationTX window to all 0
for (uint32_t i = 0; i < MINUTES_IN_HOUR; i++) {
this->utilizationTX[i] = 0;
}
// Init channelUtilization window to all 0
for (uint32_t i = 0; i < CHANNEL_UTILIZATION_PERIODS; i++) {
this->channelUtilization[i] = 0;
}
// Init airtime windows to all 0
for (int i = 0; i < PERIODS_TO_LOG; i++) {
this->airtimes.periodTX[i] = 0;
this->airtimes.periodRX[i] = 0;
this->airtimes.periodRX_ALL[i] = 0;
// air_period_tx[i] = 0;
// air_period_rx[i] = 0;
}
firstTime = false;
lastUtilPeriod = utilPeriod;
} else {
this->airtimeRotatePeriod();
// Reset the channelUtilization window when we roll over
if (lastUtilPeriod != utilPeriod) {
lastUtilPeriod = utilPeriod;
this->channelUtilization[utilPeriod] = 0;
}
if (lastUtilPeriodTX != utilPeriodTX) {
lastUtilPeriodTX = utilPeriodTX;
this->utilizationTX[utilPeriodTX] = 0;
}
// Init utilizationTX window to all 0
for (uint32_t i = 0; i < MINUTES_IN_HOUR; i++) {
this->utilizationTX[i] = 0;
}
return (1000 * 1);
// Init channelUtilization window to all 0
for (uint32_t i = 0; i < CHANNEL_UTILIZATION_PERIODS; i++) {
this->channelUtilization[i] = 0;
}
// Init airtime windows to all 0
for (int i = 0; i < PERIODS_TO_LOG; i++) {
this->airtimes.periodTX[i] = 0;
this->airtimes.periodRX[i] = 0;
this->airtimes.periodRX_ALL[i] = 0;
// air_period_tx[i] = 0;
// air_period_rx[i] = 0;
}
firstTime = false;
lastUtilPeriod = utilPeriod;
} else {
this->airtimeRotatePeriod();
// Reset the channelUtilization window when we roll over
if (lastUtilPeriod != utilPeriod) {
lastUtilPeriod = utilPeriod;
this->channelUtilization[utilPeriod] = 0;
}
if (lastUtilPeriodTX != utilPeriodTX) {
lastUtilPeriodTX = utilPeriodTX;
this->utilizationTX[utilPeriodTX] = 0;
}
}
return (1000 * 1);
}