/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- /* This program 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. This program 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 this program. If not, see . */ /* Flymaple port by Mike McCauley */ #include #if CONFIG_HAL_BOARD == HAL_BOARD_FLYMAPLE #include "FlymapleWirish.h" #include "AnalogIn.h" using namespace AP_HAL_FLYMAPLE_NS; extern const AP_HAL::HAL& hal; FLYMAPLEAnalogSource::FLYMAPLEAnalogSource(uint8_t pin) : _sum_count(0), _sum(0), _last_average(0), _pin(ANALOG_INPUT_NONE), _stop_pin(ANALOG_INPUT_NONE), _settle_time_ms(0) { set_pin(pin); } float FLYMAPLEAnalogSource::read_average() { return _read_average(); } float FLYMAPLEAnalogSource::read_latest() { noInterrupts(); uint16_t latest = _latest; interrupts(); return latest; } /* return voltage from 0.0 to 3.3V, scaled to Vcc */ float FLYMAPLEAnalogSource::voltage_average(void) { return voltage_average_ratiometric(); } float FLYMAPLEAnalogSource::voltage_latest(void) { float v = read_latest(); return v * (3.3f / 4095.0f); } /* return voltage from 0.0 to 3.3V, assuming a ratiometric sensor. This means the result is really a pseudo-voltage, that assumes the supply voltage is exactly 3.3V. */ float FLYMAPLEAnalogSource::voltage_average_ratiometric(void) { float v = read_average(); return v * (3.3f / 4095.0f); } void FLYMAPLEAnalogSource::set_pin(uint8_t pin) { if (pin != _pin) { // ensure the pin is marked as an INPUT pin if (pin != ANALOG_INPUT_NONE && pin != ANALOG_INPUT_BOARD_VCC) { int8_t dpin = hal.gpio->analogPinToDigitalPin(pin); if (dpin != -1) { pinMode(dpin, INPUT_ANALOG); } } noInterrupts(); _sum = 0; _sum_count = 0; _last_average = 0; _latest = 0; _pin = pin; interrupts(); } } void FLYMAPLEAnalogSource::set_stop_pin(uint8_t pin) { _stop_pin = pin; } void FLYMAPLEAnalogSource::set_settle_time(uint16_t settle_time_ms) { _settle_time_ms = settle_time_ms; } /* read_average is called from the normal thread (not an interrupt). */ float FLYMAPLEAnalogSource::_read_average() { uint16_t sum; uint8_t sum_count; if (_sum_count == 0) { // avoid blocking waiting for new samples return _last_average; } /* Read and clear in a critical section */ noInterrupts(); sum = _sum; sum_count = _sum_count; _sum = 0; _sum_count = 0; interrupts(); float avg = sum / (float) sum_count; _last_average = avg; return avg; } void FLYMAPLEAnalogSource::setup_read() { if (_stop_pin != ANALOG_INPUT_NONE) { uint8_t digital_pin = hal.gpio->analogPinToDigitalPin(_stop_pin); hal.gpio->pinMode(digital_pin, HAL_GPIO_OUTPUT); hal.gpio->write(digital_pin, 1); } if (_settle_time_ms != 0) { _read_start_time_ms = AP_HAL::millis(); } adc_reg_map *regs = ADC1->regs; adc_set_reg_seqlen(ADC1, 1); uint8 channel = 0; if (_pin == ANALOG_INPUT_BOARD_VCC) channel = PIN_MAP[FLYMAPLE_VCC_ANALOG_IN_PIN].adc_channel; else if (_pin == ANALOG_INPUT_NONE) ; // NOOP else channel = PIN_MAP[_pin].adc_channel; regs->SQR3 = channel; } void FLYMAPLEAnalogSource::stop_read() { if (_stop_pin != ANALOG_INPUT_NONE) { uint8_t digital_pin = hal.gpio->analogPinToDigitalPin(_stop_pin); hal.gpio->pinMode(digital_pin, HAL_GPIO_OUTPUT); hal.gpio->write(digital_pin, 0); } } bool FLYMAPLEAnalogSource::reading_settled() { if (_settle_time_ms != 0 && (AP_HAL::millis() - _read_start_time_ms) < _settle_time_ms) { return false; } return true; } /* new_sample is called from an interrupt. It always has access to * _sum and _sum_count. Lock out the interrupts briefly with * noInterrupts()/interrupts() to read these variables from outside an interrupt. */ void FLYMAPLEAnalogSource::new_sample(uint16_t sample) { _sum += sample; _latest = sample; if (_sum_count >= 15) { // Flymaple has a 12 bit ADC, so can only sum 16 in a uint16_t _sum >>= 1; _sum_count = 8; } else { _sum_count++; } } #endif