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Remove merge artifact

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This commit is contained in:
jflyper 2017-05-08 10:54:45 +09:00
parent 4b80bceb1f
commit f33a661fa7
1 changed files with 0 additions and 865 deletions
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865
src/main/fc/config.c.orig
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@ -1,865 +0,0 @@
/*
* This file is part of Cleanflight.
*
* Cleanflight is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Cleanflight is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Cleanflight. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdbool.h>
#include <stdint.h>
#include <string.h>
#include <math.h>
#include "platform.h"
#include "build/build_config.h"
#include "build/debug.h"
#include "blackbox/blackbox_io.h"
#include "cms/cms.h"
#include "common/axis.h"
#include "common/color.h"
#include "common/filter.h"
#include "common/maths.h"
#include "config/config_eeprom.h"
#include "config/feature.h"
#include "config/parameter_group.h"
#include "config/parameter_group_ids.h"
#include "drivers/accgyro/accgyro.h"
#include "drivers/compass/compass.h"
#include "drivers/inverter.h"
#include "drivers/io.h"
#include "drivers/light_led.h"
#include "drivers/light_ws2811strip.h"
#include "drivers/max7456.h"
#include "drivers/pwm_esc_detect.h"
#include "drivers/pwm_output.h"
#include "drivers/rx_pwm.h"
#include "drivers/rx_spi.h"
#include "drivers/sdcard.h"
#include "drivers/sensor.h"
#include "drivers/serial.h"
#include "drivers/sonar_hcsr04.h"
#include "drivers/sound_beeper.h"
#include "drivers/system.h"
#include "drivers/timer.h"
#include "drivers/vcd.h"
#include "fc/config.h"
#include "fc/controlrate_profile.h"
#include "fc/fc_core.h"
#include "fc/fc_rc.h"
#include "fc/rc_adjustments.h"
#include "fc/rc_controls.h"
#include "fc/runtime_config.h"
#include "flight/altitude.h"
#include "flight/failsafe.h"
#include "flight/imu.h"
#include "flight/mixer.h"
#include "flight/navigation.h"
#include "flight/pid.h"
#include "flight/servos.h"
#include "io/beeper.h"
#include "io/gimbal.h"
#include "io/gps.h"
#include "io/ledstrip.h"
#include "io/motors.h"
#include "io/osd.h"
#include "io/serial.h"
#include "io/servos.h"
#include "io/vtx_control.h"
#include "rx/rx.h"
#include "rx/rx_spi.h"
#include "sensors/acceleration.h"
#include "sensors/barometer.h"
#include "sensors/battery.h"
#include "sensors/boardalignment.h"
#include "sensors/compass.h"
#include "sensors/gyro.h"
#include "sensors/sensors.h"
#include "telemetry/telemetry.h"
#ifndef USE_OSD_SLAVE
pidProfile_t *currentPidProfile;
#endif
#ifndef DEFAULT_FEATURES
#define DEFAULT_FEATURES 0
#endif
#ifndef DEFAULT_RX_FEATURE
#define DEFAULT_RX_FEATURE FEATURE_RX_PARALLEL_PWM
#endif
#ifndef RX_SPI_DEFAULT_PROTOCOL
#define RX_SPI_DEFAULT_PROTOCOL 0
#endif
PG_REGISTER_WITH_RESET_TEMPLATE(featureConfig_t, featureConfig, PG_FEATURE_CONFIG, 0);
PG_RESET_TEMPLATE(featureConfig_t, featureConfig,
.enabledFeatures = DEFAULT_FEATURES | DEFAULT_RX_FEATURE | FEATURE_FAILSAFE
);
PG_REGISTER_WITH_RESET_TEMPLATE(systemConfig_t, systemConfig, PG_SYSTEM_CONFIG, 0);
#ifndef USE_OSD_SLAVE
PG_RESET_TEMPLATE(systemConfig_t, systemConfig,
.pidProfileIndex = 0,
.activeRateProfile = 0,
.debug_mode = DEBUG_MODE,
.task_statistics = true,
.name = { 0 } // FIXME misplaced, see PG_PILOT_CONFIG in CF v1.x
);
#endif
#ifdef USE_OSD_SLAVE
PG_RESET_TEMPLATE(systemConfig_t, systemConfig,
.debug_mode = DEBUG_MODE,
.task_statistics = true
);
#endif
#ifdef BEEPER
PG_REGISTER(beeperConfig_t, beeperConfig, PG_BEEPER_CONFIG, 0);
#endif
#ifdef USE_ADC
PG_REGISTER_WITH_RESET_FN(adcConfig_t, adcConfig, PG_ADC_CONFIG, 0);
#endif
#ifdef USE_PWM
PG_REGISTER_WITH_RESET_FN(pwmConfig_t, pwmConfig, PG_PWM_CONFIG, 0);
#endif
#ifdef USE_PPM
PG_REGISTER_WITH_RESET_FN(ppmConfig_t, ppmConfig, PG_PPM_CONFIG, 0);
#endif
PG_REGISTER_WITH_RESET_FN(statusLedConfig_t, statusLedConfig, PG_STATUS_LED_CONFIG, 0);
PG_REGISTER_WITH_RESET_FN(serialPinConfig_t, serialPinConfig, PG_SERIAL_PIN_CONFIG, 0);
#ifdef USE_FLASHFS
PG_REGISTER_WITH_RESET_TEMPLATE(flashConfig_t, flashConfig, PG_FLASH_CONFIG, 0);
#ifdef M25P16_CS_PIN
#define FLASH_CONFIG_CSTAG IO_TAG(M25P16_CS_PIN)
#else
#define FLASH_CONFIG_CSTAG IO_TAG_NONE
#endif
PG_RESET_TEMPLATE(flashConfig_t, flashConfig,
.csTag = FLASH_CONFIG_CSTAG
);
#endif // USE_FLASH_FS
#ifdef USE_SDCARD
PG_REGISTER_WITH_RESET_TEMPLATE(sdcardConfig_t, sdcardConfig, PG_SDCARD_CONFIG, 0);
#if defined(SDCARD_DMA_CHANNEL_TX)
#define SDCARD_CONFIG_USE_DMA true
#else
#define SDCARD_CONFIG_USE_DMA false
#endif
PG_RESET_TEMPLATE(sdcardConfig_t, sdcardConfig,
.useDma = SDCARD_CONFIG_USE_DMA
);
#endif
// no template required since defaults are zero
PG_REGISTER(vcdProfile_t, vcdProfile, PG_VCD_CONFIG, 0);
#ifdef SONAR
void resetSonarConfig(sonarConfig_t *sonarConfig)
{
#if defined(SONAR_TRIGGER_PIN) && defined(SONAR_ECHO_PIN)
sonarConfig->triggerTag = IO_TAG(SONAR_TRIGGER_PIN);
sonarConfig->echoTag = IO_TAG(SONAR_ECHO_PIN);
#else
#error Sonar not defined for target
#endif
}
#endif
#ifdef USE_ADC
void pgResetFn_adcConfig(adcConfig_t *adcConfig)
{
#ifdef VBAT_ADC_PIN
adcConfig->vbat.enabled = true;
adcConfig->vbat.ioTag = IO_TAG(VBAT_ADC_PIN);
#endif
#ifdef EXTERNAL1_ADC_PIN
adcConfig->external1.enabled = true;
adcConfig->external1.ioTag = IO_TAG(EXTERNAL1_ADC_PIN);
#endif
#ifdef CURRENT_METER_ADC_PIN
adcConfig->current.enabled = true;
adcConfig->current.ioTag = IO_TAG(CURRENT_METER_ADC_PIN);
#endif
#ifdef RSSI_ADC_PIN
adcConfig->rssi.enabled = true;
adcConfig->rssi.ioTag = IO_TAG(RSSI_ADC_PIN);
#endif
}
#endif // USE_ADC
#if defined(USE_PWM) || defined(USE_PPM)
void pgResetFn_ppmConfig(ppmConfig_t *ppmConfig)
{
#ifdef PPM_PIN
ppmConfig->ioTag = IO_TAG(PPM_PIN);
#else
for (int i = 0; i < USABLE_TIMER_CHANNEL_COUNT; i++) {
if (timerHardware[i].usageFlags & TIM_USE_PPM) {
ppmConfig->ioTag = timerHardware[i].tag;
return;
}
}
ppmConfig->ioTag = IO_TAG_NONE;
#endif
}
void pgResetFn_pwmConfig(pwmConfig_t *pwmConfig)
{
pwmConfig->inputFilteringMode = INPUT_FILTERING_DISABLED;
int inputIndex = 0;
for (int i = 0; i < USABLE_TIMER_CHANNEL_COUNT && inputIndex < PWM_INPUT_PORT_COUNT; i++) {
if (timerHardware[i].usageFlags & TIM_USE_PWM) {
pwmConfig->ioTags[inputIndex] = timerHardware[i].tag;
inputIndex++;
}
}
}
#endif
// Default pin (NONE).
// XXX Does this mess belong here???
#ifdef USE_UART1
# if !defined(UART1_RX_PIN)
# define UART1_RX_PIN NONE
# endif
# if !defined(UART1_TX_PIN)
# define UART1_TX_PIN NONE
# endif
#endif
#ifdef USE_UART2
# if !defined(UART2_RX_PIN)
# define UART2_RX_PIN NONE
# endif
# if !defined(UART2_TX_PIN)
# define UART2_TX_PIN NONE
# endif
#endif
#ifdef USE_UART3
# if !defined(UART3_RX_PIN)
# define UART3_RX_PIN NONE
# endif
# if !defined(UART3_TX_PIN)
# define UART3_TX_PIN NONE
# endif
#endif
#ifdef USE_UART4
# if !defined(UART4_RX_PIN)
# define UART4_RX_PIN NONE
# endif
# if !defined(UART4_TX_PIN)
# define UART4_TX_PIN NONE
# endif
#endif
#ifdef USE_UART5
# if !defined(UART5_RX_PIN)
# define UART5_RX_PIN NONE
# endif
# if !defined(UART5_TX_PIN)
# define UART5_TX_PIN NONE
# endif
#endif
#ifdef USE_UART6
# if !defined(UART6_RX_PIN)
# define UART6_RX_PIN NONE
# endif
# if !defined(UART6_TX_PIN)
# define UART6_TX_PIN NONE
# endif
#endif
#ifdef USE_UART7
# if !defined(UART7_RX_PIN)
# define UART7_RX_PIN NONE
# endif
# if !defined(UART7_TX_PIN)
# define UART7_TX_PIN NONE
# endif
#endif
#ifdef USE_UART8
# if !defined(UART8_RX_PIN)
# define UART8_RX_PIN NONE
# endif
# if !defined(UART8_TX_PIN)
# define UART8_TX_PIN NONE
# endif
#endif
#ifdef USE_SOFTSERIAL1
# if !defined(SOFTSERIAL1_RX_PIN)
# define SOFTSERIAL1_RX_PIN NONE
# endif
# if !defined(SOFTSERIAL1_TX_PIN)
# define SOFTSERIAL1_TX_PIN NONE
# endif
#endif
#ifdef USE_SOFTSERIAL2
# if !defined(SOFTSERIAL2_RX_PIN)
# define SOFTSERIAL2_RX_PIN NONE
# endif
# if !defined(SOFTSERIAL2_TX_PIN)
# define SOFTSERIAL2_TX_PIN NONE
# endif
#endif
void pgResetFn_serialPinConfig(serialPinConfig_t *serialPinConfig)
{
for (int port = 0 ; port < SERIAL_PORT_MAX_INDEX ; port++) {
serialPinConfig->ioTagRx[port] = IO_TAG(NONE);
serialPinConfig->ioTagTx[port] = IO_TAG(NONE);
}
for (int index = 0 ; index < SERIAL_PORT_COUNT ; index++) {
switch (serialPortIdentifiers[index]) {
case SERIAL_PORT_USART1:
#ifdef USE_UART1
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART1)] = IO_TAG(UART1_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART1)] = IO_TAG(UART1_TX_PIN);
<<<<<<< HEAD
#ifdef INVERTER_PIN_UART1
serialPinConfig->ioTagInverter[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART1)] = IO_TAG(INVERTER_PIN_UART1);
#endif
=======
>>>>>>> betaflight/master
#endif
break;
case SERIAL_PORT_USART2:
#ifdef USE_UART2
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART2)] = IO_TAG(UART2_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART2)] = IO_TAG(UART2_TX_PIN);
<<<<<<< HEAD
#ifdef INVERTER_PIN_UART2
serialPinConfig->ioTagInverter[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART2)] = IO_TAG(INVERTER_PIN_UART2);
#endif
=======
>>>>>>> betaflight/master
#endif
break;
case SERIAL_PORT_USART3:
#ifdef USE_UART3
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART3)] = IO_TAG(UART3_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART3)] = IO_TAG(UART3_TX_PIN);
<<<<<<< HEAD
#ifdef INVERTER_PIN_UART3
serialPinConfig->ioTagInverter[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART3)] = IO_TAG(INVERTER_PIN_UART3);
#endif
=======
>>>>>>> betaflight/master
#endif
break;
case SERIAL_PORT_UART4:
#ifdef USE_UART4
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_UART4)] = IO_TAG(UART4_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_UART4)] = IO_TAG(UART4_TX_PIN);
<<<<<<< HEAD
#ifdef INVERTER_PIN_UART4
serialPinConfig->ioTagInverter[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART4)] = IO_TAG(INVERTER_PIN_UART4);
#endif
=======
>>>>>>> betaflight/master
#endif
break;
case SERIAL_PORT_UART5:
#ifdef USE_UART5
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_UART5)] = IO_TAG(UART5_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_UART5)] = IO_TAG(UART5_TX_PIN);
<<<<<<< HEAD
#ifdef INVERTER_PIN_UART5
serialPinConfig->ioTagInverter[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART5)] = IO_TAG(INVERTER_PIN_UART5);
#endif
=======
>>>>>>> betaflight/master
#endif
break;
case SERIAL_PORT_USART6:
#ifdef USE_UART6
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART6)] = IO_TAG(UART6_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART6)] = IO_TAG(UART6_TX_PIN);
<<<<<<< HEAD
#ifdef INVERTER_PIN_UART6
serialPinConfig->ioTagInverter[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART6)] = IO_TAG(INVERTER_PIN_UART6);
#endif
=======
>>>>>>> betaflight/master
#endif
break;
case SERIAL_PORT_USART7:
#ifdef USE_UART7
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART7)] = IO_TAG(UART7_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART7)] = IO_TAG(UART7_TX_PIN);
#endif
break;
case SERIAL_PORT_USART8:
#ifdef USE_UART8
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART8)] = IO_TAG(UART8_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_USART8)] = IO_TAG(UART8_TX_PIN);
#endif
break;
case SERIAL_PORT_SOFTSERIAL1:
#ifdef USE_SOFTSERIAL1
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_SOFTSERIAL1)] = IO_TAG(SOFTSERIAL1_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_SOFTSERIAL1)] = IO_TAG(SOFTSERIAL1_TX_PIN);
#endif
break;
case SERIAL_PORT_SOFTSERIAL2:
#ifdef USE_SOFTSERIAL2
serialPinConfig->ioTagRx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_SOFTSERIAL2)] = IO_TAG(SOFTSERIAL2_RX_PIN);
serialPinConfig->ioTagTx[SERIAL_PORT_IDENTIFIER_TO_INDEX(SERIAL_PORT_SOFTSERIAL2)] = IO_TAG(SOFTSERIAL2_TX_PIN);
#endif
break;
case SERIAL_PORT_USB_VCP:
break;
case SERIAL_PORT_NONE:
break;
}
}
}
#ifdef SWAP_SERIAL_PORT_0_AND_1_DEFAULTS
#define FIRST_PORT_INDEX 1
#define SECOND_PORT_INDEX 0
#else
#define FIRST_PORT_INDEX 0
#define SECOND_PORT_INDEX 1
#endif
void pgResetFn_statusLedConfig(statusLedConfig_t *statusLedConfig)
{
for (int i = 0; i < LED_NUMBER; i++) {
statusLedConfig->ledTags[i] = IO_TAG_NONE;
}
#ifdef LED0
statusLedConfig->ledTags[0] = IO_TAG(LED0);
#endif
#ifdef LED1
statusLedConfig->ledTags[1] = IO_TAG(LED1);
#endif
#ifdef LED2
statusLedConfig->ledTags[2] = IO_TAG(LED2);
#endif
statusLedConfig->polarity = 0
#ifdef LED0_INVERTED
| BIT(0)
#endif
#ifdef LED1_INVERTED
| BIT(1)
#endif
#ifdef LED2_INVERTED
| BIT(2)
#endif
;
}
#ifndef USE_OSD_SLAVE
uint8_t getCurrentPidProfileIndex(void)
{
return systemConfig()->pidProfileIndex;
}
static void setPidProfile(uint8_t pidProfileIndex)
{
if (pidProfileIndex < MAX_PROFILE_COUNT) {
systemConfigMutable()->pidProfileIndex = pidProfileIndex;
currentPidProfile = pidProfilesMutable(pidProfileIndex);
pidInit(currentPidProfile); // re-initialise pid controller to re-initialise filters and config
}
}
uint8_t getCurrentControlRateProfileIndex(void)
{
return systemConfigMutable()->activeRateProfile;
}
uint16_t getCurrentMinthrottle(void)
{
return motorConfig()->minthrottle;
}
#endif
void resetConfigs(void)
{
pgResetAll(MAX_PROFILE_COUNT);
#if defined(TARGET_CONFIG)
targetConfiguration();
#endif
pgActivateProfile(0);
#ifndef USE_OSD_SLAVE
setPidProfile(0);
setControlRateProfile(0);
#endif
#ifdef LED_STRIP
reevaluateLedConfig();
#endif
}
void activateConfig(void)
{
#ifndef USE_OSD_SLAVE
generateThrottleCurve();
resetAdjustmentStates();
useRcControlsConfig(modeActivationConditions(0), currentPidProfile);
useAdjustmentConfig(currentPidProfile);
#ifdef GPS
gpsUsePIDs(currentPidProfile);
#endif
failsafeReset();
setAccelerationTrims(&accelerometerConfigMutable()->accZero);
setAccelerationFilter(accelerometerConfig()->acc_lpf_hz);
imuConfigure(throttleCorrectionConfig()->throttle_correction_angle);
#endif
}
void validateAndFixConfig(void)
{
#ifndef USE_OSD_SLAVE
if((motorConfig()->dev.motorPwmProtocol == PWM_TYPE_BRUSHED) && (motorConfig()->mincommand < 1000)){
motorConfigMutable()->mincommand = 1000;
}
if ((motorConfig()->dev.motorPwmProtocol == PWM_TYPE_STANDARD) && (motorConfig()->dev.motorPwmRate > BRUSHLESS_MOTORS_PWM_RATE)) {
motorConfigMutable()->dev.motorPwmRate = BRUSHLESS_MOTORS_PWM_RATE;
}
if (!(featureConfigured(FEATURE_RX_PARALLEL_PWM) || featureConfigured(FEATURE_RX_PPM) || featureConfigured(FEATURE_RX_SERIAL) || featureConfigured(FEATURE_RX_MSP) || featureConfigured(FEATURE_RX_SPI))) {
featureSet(DEFAULT_RX_FEATURE);
}
if (featureConfigured(FEATURE_RX_PPM)) {
featureClear(FEATURE_RX_SERIAL | FEATURE_RX_PARALLEL_PWM | FEATURE_RX_MSP | FEATURE_RX_SPI);
}
if (featureConfigured(FEATURE_RX_MSP)) {
featureClear(FEATURE_RX_SERIAL | FEATURE_RX_PARALLEL_PWM | FEATURE_RX_PPM | FEATURE_RX_SPI);
}
if (featureConfigured(FEATURE_RX_SERIAL)) {
featureClear(FEATURE_RX_PARALLEL_PWM | FEATURE_RX_MSP | FEATURE_RX_PPM | FEATURE_RX_SPI);
}
if (featureConfigured(FEATURE_RX_SPI)) {
featureClear(FEATURE_RX_SERIAL | FEATURE_RX_PARALLEL_PWM | FEATURE_RX_PPM | FEATURE_RX_MSP);
}
if (featureConfigured(FEATURE_RX_PARALLEL_PWM)) {
featureClear(FEATURE_RX_SERIAL | FEATURE_RX_MSP | FEATURE_RX_PPM | FEATURE_RX_SPI);
#if defined(STM32F10X)
// rssi adc needs the same ports
featureClear(FEATURE_RSSI_ADC);
// current meter needs the same ports
if (batteryConfig()->currentMeterSource == CURRENT_METER_ADC) {
batteryConfigMutable()->currentMeterSource = CURRENT_METER_NONE;
}
#endif
// software serial needs free PWM ports
featureClear(FEATURE_SOFTSERIAL);
}
#ifdef USE_SOFTSPI
if (featureConfigured(FEATURE_SOFTSPI)) {
featureClear(FEATURE_RX_PPM | FEATURE_RX_PARALLEL_PWM | FEATURE_SOFTSERIAL);
batteryConfigMutable()->voltageMeterSource = VOLTAGE_METER_NONE;
#if defined(STM32F10X)
featureClear(FEATURE_LED_STRIP);
// rssi adc needs the same ports
featureClear(FEATURE_RSSI_ADC);
// current meter needs the same ports
if (batteryConfig()->currentMeterSource == CURRENT_METER_ADC) {
batteryConfigMutable()->currentMeterSource = CURRENT_METER_NONE;
}
#endif
}
#endif
// Prevent invalid notch cutoff
if (currentPidProfile->dterm_notch_cutoff >= currentPidProfile->dterm_notch_hz) {
currentPidProfile->dterm_notch_hz = 0;
}
validateAndFixGyroConfig();
#endif
if (!isSerialConfigValid(serialConfig())) {
pgResetFn_serialConfig(serialConfigMutable());
}
#if defined(TARGET_VALIDATECONFIG)
targetValidateConfiguration();
#endif
}
#ifndef USE_OSD_SLAVE
void validateAndFixGyroConfig(void)
{
// Prevent invalid notch cutoff
if (gyroConfig()->gyro_soft_notch_cutoff_1 >= gyroConfig()->gyro_soft_notch_hz_1) {
gyroConfigMutable()->gyro_soft_notch_hz_1 = 0;
}
if (gyroConfig()->gyro_soft_notch_cutoff_2 >= gyroConfig()->gyro_soft_notch_hz_2) {
gyroConfigMutable()->gyro_soft_notch_hz_2 = 0;
}
float samplingTime = 0.000125f;
if (gyroConfig()->gyro_lpf != GYRO_LPF_256HZ && gyroConfig()->gyro_lpf != GYRO_LPF_NONE) {
pidConfigMutable()->pid_process_denom = 1; // When gyro set to 1khz always set pid speed 1:1 to sampling speed
gyroConfigMutable()->gyro_sync_denom = 1;
gyroConfigMutable()->gyro_use_32khz = false;
samplingTime = 0.001f;
}
if (gyroConfig()->gyro_use_32khz) {
samplingTime = 0.00003125;
// F1 and F3 can't handle high sample speed.
#if defined(STM32F1)
gyroConfigMutable()->gyro_sync_denom = MAX(gyroConfig()->gyro_sync_denom, 16);
#elif defined(STM32F3)
gyroConfigMutable()->gyro_sync_denom = MAX(gyroConfig()->gyro_sync_denom, 4);
#endif
} else {
#if defined(STM32F1)
gyroConfigMutable()->gyro_sync_denom = MAX(gyroConfig()->gyro_sync_denom, 3);
#endif
}
#if !defined(GYRO_USES_SPI) || !defined(USE_MPU_DATA_READY_SIGNAL)
gyroConfigMutable()->gyro_isr_update = false;
#endif
// check for looptime restrictions based on motor protocol. Motor times have safety margin
const float pidLooptime = samplingTime * gyroConfig()->gyro_sync_denom * pidConfig()->pid_process_denom;
float motorUpdateRestriction;
switch(motorConfig()->dev.motorPwmProtocol) {
case (PWM_TYPE_STANDARD):
motorUpdateRestriction = 1.0f/BRUSHLESS_MOTORS_PWM_RATE;
break;
case (PWM_TYPE_ONESHOT125):
motorUpdateRestriction = 0.0005f;
break;
case (PWM_TYPE_ONESHOT42):
motorUpdateRestriction = 0.0001f;
break;
#ifdef USE_DSHOT
case (PWM_TYPE_DSHOT150):
motorUpdateRestriction = 0.000250f;
break;
case (PWM_TYPE_DSHOT300):
motorUpdateRestriction = 0.0001f;
break;
#endif
default:
motorUpdateRestriction = 0.00003125f;
}
if (pidLooptime < motorUpdateRestriction) {
const uint8_t maxPidProcessDenom = constrain(motorUpdateRestriction / (samplingTime * gyroConfig()->gyro_sync_denom), 1, MAX_PID_PROCESS_DENOM);
pidConfigMutable()->pid_process_denom = MIN(pidConfigMutable()->pid_process_denom, maxPidProcessDenom);
}
// Prevent overriding the max rate of motors
if (motorConfig()->dev.useUnsyncedPwm && (motorConfig()->dev.motorPwmProtocol <= PWM_TYPE_BRUSHED) && motorConfig()->dev.motorPwmProtocol != PWM_TYPE_STANDARD) {
uint32_t maxEscRate = lrintf(1.0f / motorUpdateRestriction);
if(motorConfig()->dev.motorPwmRate > maxEscRate)
motorConfigMutable()->dev.motorPwmRate = maxEscRate;
}
}
#endif
void readEEPROM(void)
{
#ifndef USE_OSD_SLAVE
suspendRxSignal();
#endif
// Sanity check, read flash
if (!loadEEPROM()) {
failureMode(FAILURE_INVALID_EEPROM_CONTENTS);
}
#ifndef USE_OSD_SLAVE
if (systemConfig()->activeRateProfile >= CONTROL_RATE_PROFILE_COUNT) {// sanity check
systemConfigMutable()->activeRateProfile = 0;
}
setControlRateProfile(systemConfig()->activeRateProfile);
if (systemConfig()->pidProfileIndex >= MAX_PROFILE_COUNT) {// sanity check
systemConfigMutable()->pidProfileIndex = 0;
}
setPidProfile(systemConfig()->pidProfileIndex);
#endif
validateAndFixConfig();
activateConfig();
#ifndef USE_OSD_SLAVE
resumeRxSignal();
#endif
}
void writeEEPROM(void)
{
#ifndef USE_OSD_SLAVE
suspendRxSignal();
#endif
writeConfigToEEPROM();
#ifndef USE_OSD_SLAVE
resumeRxSignal();
#endif
}
void resetEEPROM(void)
{
resetConfigs();
writeEEPROM();
}
void ensureEEPROMContainsValidData(void)
{
if (isEEPROMContentValid()) {
return;
}
resetEEPROM();
}
void saveConfigAndNotify(void)
{
writeEEPROM();
readEEPROM();
beeperConfirmationBeeps(1);
}
#ifndef USE_OSD_SLAVE
void changePidProfile(uint8_t pidProfileIndex)
{
if (pidProfileIndex >= MAX_PROFILE_COUNT) {
pidProfileIndex = MAX_PROFILE_COUNT - 1;
}
systemConfigMutable()->pidProfileIndex = pidProfileIndex;
currentPidProfile = pidProfilesMutable(pidProfileIndex);
beeperConfirmationBeeps(pidProfileIndex + 1);
}
#endif
void beeperOffSet(uint32_t mask)
{
#ifdef BEEPER
beeperConfigMutable()->beeper_off_flags |= mask;
#else
UNUSED(mask);
#endif
}
void beeperOffSetAll(uint8_t beeperCount)
{
#ifdef BEEPER
beeperConfigMutable()->beeper_off_flags = (1 << beeperCount) -1;
#else
UNUSED(beeperCount);
#endif
}
void beeperOffClear(uint32_t mask)
{
#ifdef BEEPER
beeperConfigMutable()->beeper_off_flags &= ~(mask);
#else
UNUSED(mask);
#endif
}
void beeperOffClearAll(void)
{
#ifdef BEEPER
beeperConfigMutable()->beeper_off_flags = 0;
#endif
}
uint32_t getBeeperOffMask(void)
{
#ifdef BEEPER
return beeperConfig()->beeper_off_flags;
#else
return 0;
#endif
}
void setBeeperOffMask(uint32_t mask)
{
#ifdef BEEPER
beeperConfigMutable()->beeper_off_flags = mask;
#else
UNUSED(mask);
#endif
}
uint32_t getPreferredBeeperOffMask(void)
{
#ifdef BEEPER
return beeperConfig()->preferred_beeper_off_flags;
#else
return 0;
#endif
}
void setPreferredBeeperOffMask(uint32_t mask)
{
#ifdef BEEPER
beeperConfigMutable()->preferred_beeper_off_flags = mask;
#else
UNUSED(mask);
#endif
}