/* (c) 2017 night_ghost@ykoctpa.ru */ #pragma GCC optimize ("O2") #include #include #include "RCInput.h" #include #include #include #include "sbus.h" #include "GPIO.h" #include "ring_buffer_pulse.h" #include "RC_PPM_parser.h" #include "UARTDriver.h" #include "UART_PPM.h" using namespace F4Light; extern const AP_HAL::HAL& hal; void PPM_parser::init(uint8_t ch){ memset((void *)&_val[0], 0, sizeof(_val)); _last_signal=0; _last_change=0; _channels=0; channel_ctr=0; _ch = ch + 1; last_pulse = {0,0}; _ioc = Scheduler::register_io_completion(FUNCTOR_BIND_MEMBER(&PPM_parser::parse_pulses, void)); // TODO Panic on IOC not allocated // callback is called on each edge so must be as fast as possible Revo_handler h = { .mp = FUNCTOR_BIND_MEMBER(&PPM_parser::start_ioc, void) }; pwm_setHandler(h.h, _ch-1); sbus_state[0].mode=BOARD_RC_SBUS; sbus_state[1].mode=BOARD_RC_SBUS_NI; } void PPM_parser::start_ioc(void){ Scheduler::do_io_completion(_ioc); } void PPM_parser::parse_pulses(void){ if(_ch==0) return; // not initialized Pulse p; #if 0 // [ statistics to tune memory usage uint16_t np = getPPM_count(_ch); if(np>RCInput::max_num_pulses) RCInput::max_num_pulses=np; #endif //] while( getPPM_Pulse(&p, _ch-1)){ rxIntRC(last_pulse.length, p.length, p.state); last_pulse = p; } } void PPM_parser::rxIntRC(uint16_t last_value, uint16_t value, bool state) { if(state) { // was 1 so falling if(_rc_mode==BOARD_RC_NONE){ _process_ppmsum_pulse( (last_value + value) >>1 ); // process PPM only if no protocols detected } if((_rc_mode &~BOARD_RC_SBUS_NI) == 0){ // test for non-inverted SBUS in 2nd memory structures _process_sbus_pulse(last_value>>1, value>>1, sbus_state[1]); // was 1 so now is length of 1, last is a length of 0 } } else { // was 0 so rising if((_rc_mode & ~BOARD_RC_SBUS) == 0){ // try treat as SBUS (inverted) // SBUS protocols detection occures on the beginning of start bit of next frame _process_sbus_pulse(value>>1, last_value>>1, sbus_state[0]); // was 0 so now is length of 0, last is a length of 1 } if((_rc_mode & ~(BOARD_RC_DSM | BOARD_RC_SUMD)) == 0){ // try treat as DSM or SUMD. Detection occures on the end of stop bit _process_dsm_pulse(value>>1, last_value>>1); } } } bool PPM_parser::_process_ppmsum_pulse(uint16_t value) { if (value >= 2700) { // Frame synchronization if( channel_ctr >= F4Light_RC_INPUT_MIN_CHANNELS ) { _channels = channel_ctr; } channel_ctr = 0; _got_ppm=true; return true; } else if(value > 700 && value < 2300) { if (channel_ctr < F4Light_RC_INPUT_NUM_CHANNELS) { _last_signal = systick_uptime(); if(_val[channel_ctr] != value) _last_change = _last_signal; _val[channel_ctr] = value; channel_ctr++; if (channel_ctr >= F4Light_RC_INPUT_NUM_CHANNELS) { _channels = F4Light_RC_INPUT_NUM_CHANNELS; } } return true; } else { // try another protocols return false; } } /* process a SBUS input pulse of the given width pulses are captured on each edges and SBUS parser called on rising edge - beginning of start bit */ void PPM_parser::_process_sbus_pulse(uint16_t width_s0, uint16_t width_s1, F4Light::PPM_parser::SbusState &state) { // convert to bit widths, allowing for up to 4usec error, assuming 100000 bps - inverted uint16_t bits_s0 = (width_s0+4) / 10; uint16_t bits_s1 = (width_s1+4) / 10; uint8_t byte_ofs = state.bit_ofs/12; uint8_t bit_ofs = state.bit_ofs%12; uint16_t nlow; if (bits_s1 == 0 || bits_s0 == 0) { // invalid data goto reset; } if (bits_s1+bit_ofs > 10) { // invalid data as last two bits must be stop bits goto reset; } // pull in the high bits state.bytes[byte_ofs] |= ((1U< 12) { // переехали за границу байта? nlow = 12 - bit_ofs; // остаток этого байта } bits_s0 -= nlow; // непосчитанный остаток нулевых битов state.bit_ofs += nlow; // добить нулями до конца байта if (state.bit_ofs == 25*12 && bits_s0 > 12) { // all frame got and was gap // we have a full frame uint8_t bytes[25]; uint16_t i; for (i=0; i<25; i++) { // get inverted data uint16_t v = ~state.bytes[i]; if ((v & 1) != 0) { // check start bit goto reset; } if ((v & 0xC00) != 0xC00) {// check stop bits goto reset; } // check parity uint8_t parity = 0, j; for (j=1; j<=8; j++) { parity ^= (v & (1U<>9) { goto reset; } bytes[i] = ((v>>1) & 0xFF); } uint16_t values[F4Light_RC_INPUT_NUM_CHANNELS]; uint16_t num_values=0; bool sbus_failsafe=false, sbus_frame_drop=false; if (sbus_decode(bytes, values, &num_values, &sbus_failsafe, &sbus_frame_drop, F4Light_RC_INPUT_NUM_CHANNELS) && num_values >= F4Light_RC_INPUT_MIN_CHANNELS) { for (i=0; i 12) { // Was inter-frame gap but not full frame goto reset; } return; reset: reset_ok: state.bit_ofs=0; memset(&state.bytes, 0, sizeof(state.bytes)); } /* process a DSM satellite input pulse of the given width pulses are captured on each edges and DSM parser called on falling edge - eg. beginning of start bit */ void PPM_parser::_process_dsm_pulse(uint16_t width_s0, uint16_t width_s1) { // convert to bit widths, allowing for up to 1uSec error, assuming 115200 bps uint16_t bits_s0 = ((width_s0+4)*(uint32_t)115200) / 1000000; uint16_t bits_s1 = ((width_s1+4)*(uint32_t)115200) / 1000000; uint8_t bit_ofs, byte_ofs; uint16_t nbits; if (bits_s0 == 0 || bits_s1 == 0) { // invalid data goto reset; } byte_ofs = dsm_state.bit_ofs/10; bit_ofs = dsm_state.bit_ofs%10; if(byte_ofs > 15) { // invalid data goto reset; } // pull in the high bits nbits = bits_s0; if (nbits+bit_ofs > 10) { nbits = 10 - bit_ofs; } dsm_state.bytes[byte_ofs] |= ((1U< 10) { if (dsm_state.bit_ofs == 16*10) { // we have a full frame uint8_t bytes[16]; uint8_t i; for (i=0; i<16; i++) { // get raw data uint16_t v = dsm_state.bytes[i]; // check start bit if ((v & 1) != 0) { goto reset; } // check stop bits if ((v & 0x200) != 0x200) { goto reset; } uint8_t bt= ((v>>1) & 0xFF); bytes[i] = bt; if(_rc_mode != BOARD_RC_DSM) { // try to decode SUMD data on each byte, decoder butters frame itself. uint16_t values[F4Light_RC_INPUT_NUM_CHANNELS]; uint8_t rssi; uint8_t rx_count; uint16_t channel_count; if (sumd_decode(bt, &rssi, &rx_count, &channel_count, values, F4Light_RC_INPUT_NUM_CHANNELS) == 0) { if (channel_count > F4Light_RC_INPUT_NUM_CHANNELS) { continue; } _rc_mode = BOARD_RC_SUMD; for (uint8_t j=0; j= F4Light_RC_INPUT_MIN_CHANNELS) { _rc_mode = BOARD_RC_DSM; // lock input mode, DSM has a checksum so false positive is unreal for (i=0; i_channels) _channels = nc; _val[_channels-1]=bytes[0]; // rssi _got_dsm = true; _last_signal = systick_uptime(); } } } memset(&dsm_state, 0, sizeof(dsm_state)); } byte_ofs = dsm_state.bit_ofs/10; bit_ofs = dsm_state.bit_ofs%10; if (bits_s1+bit_ofs > 10) { // invalid data goto reset; } // pull in the low bits dsm_state.bit_ofs += bits_s1; return; reset: memset(&dsm_state, 0, sizeof(dsm_state)); }