#include "board.h" #include "mw.h" // Multiwii Serial Protocol 0 #define MSP_VERSION 0 #define CAP_PLATFORM_32BIT ((uint32_t)1 << 31) #define CAP_DYNBALANCE ((uint32_t)1 << 2) #define CAP_FLAPS ((uint32_t)1 << 3) #define MSP_IDENT 100 //out message multitype + multiwii version + protocol version + capability variable #define MSP_STATUS 101 //out message cycletime & errors_count & sensor present & box activation & current setting number #define MSP_RAW_IMU 102 //out message 9 DOF #define MSP_SERVO 103 //out message 8 servos #define MSP_MOTOR 104 //out message 8 motors #define MSP_RC 105 //out message 8 rc chan and more #define MSP_RAW_GPS 106 //out message fix, numsat, lat, lon, alt, speed, ground course #define MSP_COMP_GPS 107 //out message distance home, direction home #define MSP_ATTITUDE 108 //out message 2 angles 1 heading #define MSP_ALTITUDE 109 //out message altitude, variometer #define MSP_ANALOG 110 //out message vbat, powermetersum, rssi if available on RX #define MSP_RC_TUNING 111 //out message rc rate, rc expo, rollpitch rate, yaw rate, dyn throttle PID #define MSP_PID 112 //out message P I D coeff (9 are used currently) #define MSP_BOX 113 //out message BOX setup (number is dependant of your setup) #define MSP_MISC 114 //out message powermeter trig #define MSP_MOTOR_PINS 115 //out message which pins are in use for motors & servos, for GUI #define MSP_BOXNAMES 116 //out message the aux switch names #define MSP_PIDNAMES 117 //out message the PID names #define MSP_WP 118 //out message get a WP, WP# is in the payload, returns (WP#, lat, lon, alt, flags) WP#0-home, WP#16-poshold #define MSP_BOXIDS 119 //out message get the permanent IDs associated to BOXes #define MSP_SERVO_CONF 120 //out message Servo settings #define MSP_SET_RAW_RC 200 //in message 8 rc chan #define MSP_SET_RAW_GPS 201 //in message fix, numsat, lat, lon, alt, speed #define MSP_SET_PID 202 //in message P I D coeff (9 are used currently) #define MSP_SET_BOX 203 //in message BOX setup (number is dependant of your setup) #define MSP_SET_RC_TUNING 204 //in message rc rate, rc expo, rollpitch rate, yaw rate, dyn throttle PID #define MSP_ACC_CALIBRATION 205 //in message no param #define MSP_MAG_CALIBRATION 206 //in message no param #define MSP_SET_MISC 207 //in message powermeter trig + 8 free for future use #define MSP_RESET_CONF 208 //in message no param #define MSP_SET_WP 209 //in message sets a given WP (WP#,lat, lon, alt, flags) #define MSP_SELECT_SETTING 210 //in message Select Setting Number (0-2) #define MSP_SET_HEAD 211 //in message define a new heading hold direction #define MSP_SET_SERVO_CONF 212 //in message Servo settings #define MSP_SET_MOTOR 214 //in message PropBalance function // #define MSP_BIND 240 //in message no param #define MSP_EEPROM_WRITE 250 //in message no param #define MSP_DEBUGMSG 253 //out message debug string buffer #define MSP_DEBUG 254 //out message debug1,debug2,debug3,debug4 // Additional commands that are not compatible with MultiWii #define MSP_UID 160 //out message Unique device ID #define MSP_ACC_TRIM 240 //out message get acc angle trim values #define MSP_SET_ACC_TRIM 239 //in message set acc angle trim values #define MSP_GPSSVINFO 164 //out message get Signal Strength (only U-Blox) #define INBUF_SIZE 64 struct box_t { const uint8_t boxIndex; // this is from boxnames enum const char *boxName; // GUI-readable box name const uint8_t permanentId; // } boxes[] = { { BOXARM, "ARM;", 0 }, { BOXANGLE, "ANGLE;", 1 }, { BOXHORIZON, "HORIZON;", 2 }, { BOXBARO, "BARO;", 3 }, { BOXVARIO, "VARIO;", 4 }, { BOXMAG, "MAG;", 5 }, { BOXHEADFREE, "HEADFREE;", 6 }, { BOXHEADADJ, "HEADADJ;", 7 }, { BOXCAMSTAB, "CAMSTAB;", 8 }, { BOXCAMTRIG, "CAMTRIG;", 9 }, { BOXGPSHOME, "GPS HOME;", 10 }, { BOXGPSHOLD, "GPS HOLD;", 11 }, { BOXPASSTHRU, "PASSTHRU;", 12 }, { BOXBEEPERON, "BEEPER;", 13 }, { BOXLEDMAX, "LEDMAX;", 14 }, { BOXLEDLOW, "LEDLOW;", 15 }, { BOXLLIGHTS, "LLIGHTS;", 16 }, { BOXCALIB, "CALIB;", 17 }, { BOXGOV, "GOVERNOR;", 18 }, { BOXOSD, "OSD SW;", 19 }, { BOXTELEMETRY, "TELEMETRY;", 20 }, { CHECKBOXITEMS, NULL, 0xFF } }; // this is calculated at startup based on enabled features. static uint8_t availableBoxes[CHECKBOXITEMS]; // this is the number of filled indexes in above array static uint8_t numberBoxItems = 0; // from mixer.c extern int16_t motor_disarmed[MAX_MOTORS]; static const char pidnames[] = "ROLL;" "PITCH;" "YAW;" "ALT;" "Pos;" "PosR;" "NavR;" "LEVEL;" "MAG;" "VEL;"; static uint8_t checksum, indRX, inBuf[INBUF_SIZE]; static uint8_t cmdMSP; // signal that we're in cli mode uint8_t cliMode = 0; void serialize32(uint32_t a) { static uint8_t t; t = a; serialWrite(core.mainport, t); checksum ^= t; t = a >> 8; serialWrite(core.mainport, t); checksum ^= t; t = a >> 16; serialWrite(core.mainport, t); checksum ^= t; t = a >> 24; serialWrite(core.mainport, t); checksum ^= t; } void serialize16(int16_t a) { static uint8_t t; t = a; serialWrite(core.mainport, t); checksum ^= t; t = a >> 8 & 0xff; serialWrite(core.mainport, t); checksum ^= t; } void serialize8(uint8_t a) { serialWrite(core.mainport, a); checksum ^= a; } uint8_t read8(void) { return inBuf[indRX++] & 0xff; } uint16_t read16(void) { uint16_t t = read8(); t += (uint16_t) read8() << 8; return t; } uint32_t read32(void) { uint32_t t = read16(); t += (uint32_t) read16() << 16; return t; } void headSerialResponse(uint8_t err, uint8_t s) { serialize8('$'); serialize8('M'); serialize8(err ? '!' : '>'); checksum = 0; // start calculating a new checksum serialize8(s); serialize8(cmdMSP); } void headSerialReply(uint8_t s) { headSerialResponse(0, s); } void headSerialError(uint8_t s) { headSerialResponse(1, s); } void tailSerialReply(void) { serialize8(checksum); } void s_struct(uint8_t *cb, uint8_t siz) { headSerialReply(siz); while (siz--) serialize8(*cb++); } void serializeNames(const char *s) { const char *c; for (c = s; *c; c++) serialize8(*c); } void serializeBoxNamesReply(void) { int i, idx, j, flag = 1, count = 0, len; reset: // in first run of the loop, we grab total size of junk to be sent // then come back and actually send it for (i = 0; i < numberBoxItems; i++) { idx = availableBoxes[i]; len = strlen(boxes[idx].boxName); if (flag) { count += len; } else { for (j = 0; j < len; j++) serialize8(boxes[idx].boxName[j]); } } if (flag) { headSerialReply(count); flag = 0; goto reset; } } void serialInit(uint32_t baudrate) { int idx; core.mainport = uartOpen(USART1, NULL, baudrate, MODE_RXTX); // calculate used boxes based on features and fill availableBoxes[] array memset(availableBoxes, 0xFF, sizeof(availableBoxes)); idx = 0; availableBoxes[idx++] = BOXARM; if (sensors(SENSOR_ACC)) { availableBoxes[idx++] = BOXANGLE; availableBoxes[idx++] = BOXHORIZON; } if (sensors(SENSOR_BARO)) { availableBoxes[idx++] = BOXBARO; if (feature(FEATURE_VARIO)) availableBoxes[idx++] = BOXVARIO; } if (sensors(SENSOR_ACC) || sensors(SENSOR_MAG)) { availableBoxes[idx++] = BOXMAG; availableBoxes[idx++] = BOXHEADFREE; availableBoxes[idx++] = BOXHEADADJ; } if (feature(FEATURE_SERVO_TILT)) availableBoxes[idx++] = BOXCAMSTAB; if (feature(FEATURE_GPS)) { availableBoxes[idx++] = BOXGPSHOME; availableBoxes[idx++] = BOXGPSHOLD; } if (mcfg.mixerConfiguration == MULTITYPE_FLYING_WING || mcfg.mixerConfiguration == MULTITYPE_AIRPLANE) availableBoxes[idx++] = BOXPASSTHRU; availableBoxes[idx++] = BOXBEEPERON; if (feature(FEATURE_INFLIGHT_ACC_CAL)) availableBoxes[idx++] = BOXCALIB; availableBoxes[idx++] = BOXOSD; if (feature(FEATURE_TELEMETRY && mcfg.telemetry_switch)) availableBoxes[idx++] = BOXTELEMETRY; numberBoxItems = idx; } static void evaluateCommand(void) { uint32_t i, tmp, junk; uint8_t wp_no; int32_t lat = 0, lon = 0, alt = 0; switch (cmdMSP) { case MSP_SET_RAW_RC: for (i = 0; i < 8; i++) rcData[i] = read16(); headSerialReply(0); break; case MSP_SET_ACC_TRIM: cfg.angleTrim[PITCH] = read16(); cfg.angleTrim[ROLL] = read16(); headSerialReply(0); break; case MSP_SET_RAW_GPS: f.GPS_FIX = read8(); GPS_numSat = read8(); GPS_coord[LAT] = read32(); GPS_coord[LON] = read32(); GPS_altitude = read16(); GPS_speed = read16(); GPS_update |= 2; // New data signalisation to GPS functions headSerialReply(0); break; case MSP_SET_PID: for (i = 0; i < PIDITEMS; i++) { cfg.P8[i] = read8(); cfg.I8[i] = read8(); cfg.D8[i] = read8(); } headSerialReply(0); break; case MSP_SET_BOX: for (i = 0; i < numberBoxItems; i++) cfg.activate[availableBoxes[i]] = read16(); headSerialReply(0); break; case MSP_SET_RC_TUNING: cfg.rcRate8 = read8(); cfg.rcExpo8 = read8(); cfg.rollPitchRate = read8(); cfg.yawRate = read8(); cfg.dynThrPID = read8(); cfg.thrMid8 = read8(); cfg.thrExpo8 = read8(); headSerialReply(0); break; case MSP_SET_MISC: read16(); // powerfailmeter mcfg.minthrottle = read16(); mcfg.maxthrottle = read16(); mcfg.mincommand = read16(); cfg.failsafe_throttle = read16(); read16(); read32(); cfg.mag_declination = read16() * 10; mcfg.vbatscale = read8(); // actual vbatscale as intended mcfg.vbatmincellvoltage = read8(); // vbatlevel_warn1 in MWC2.3 GUI mcfg.vbatmaxcellvoltage = read8(); // vbatlevel_warn2 in MWC2.3 GUI read8(); // vbatlevel_crit (unused) headSerialReply(0); break; case MSP_SET_MOTOR: for (i = 0; i < 8; i++) motor_disarmed[i] = read16(); break; case MSP_SELECT_SETTING: if (!f.ARMED) { mcfg.current_profile = read8(); if (mcfg.current_profile > 2) mcfg.current_profile = 0; // this writes new profile index and re-reads it writeEEPROM(0, false); } headSerialReply(0); break; case MSP_SET_HEAD: magHold = read16(); headSerialReply(0); break; case MSP_IDENT: headSerialReply(7); serialize8(VERSION); // multiwii version serialize8(mcfg.mixerConfiguration); // type of multicopter serialize8(MSP_VERSION); // MultiWii Serial Protocol Version serialize32(CAP_PLATFORM_32BIT | CAP_DYNBALANCE | (mcfg.flaps_speed ? CAP_FLAPS : 0)); // "capability" break; case MSP_STATUS: headSerialReply(11); serialize16(cycleTime); serialize16(i2cGetErrorCounter()); serialize16(sensors(SENSOR_ACC) | sensors(SENSOR_BARO) << 1 | sensors(SENSOR_MAG) << 2 | sensors(SENSOR_GPS) << 3 | sensors(SENSOR_SONAR) << 4); // OK, so you waste all the fucking time to have BOXNAMES and BOXINDEXES etc, and then you go ahead and serialize enabled shit simply by stuffing all // the bits in order, instead of setting the enabled bits based on BOXINDEX. WHERE IS THE FUCKING LOGIC IN THIS, FUCKWADS. // Serialize the boxes in the order we delivered them, until multiwii retards fix their shit junk = 0; tmp = f.ANGLE_MODE << BOXANGLE | f.HORIZON_MODE << BOXHORIZON | f.BARO_MODE << BOXBARO | f.MAG_MODE << BOXMAG | f.HEADFREE_MODE << BOXHEADFREE | rcOptions[BOXHEADADJ] << BOXHEADADJ | rcOptions[BOXCAMSTAB] << BOXCAMSTAB | rcOptions[BOXCAMTRIG] << BOXCAMTRIG | f.GPS_HOME_MODE << BOXGPSHOME | f.GPS_HOLD_MODE << BOXGPSHOLD | f.PASSTHRU_MODE << BOXPASSTHRU | rcOptions[BOXBEEPERON] << BOXBEEPERON | rcOptions[BOXLEDMAX] << BOXLEDMAX | rcOptions[BOXLLIGHTS] << BOXLLIGHTS | rcOptions[BOXVARIO] << BOXVARIO | rcOptions[BOXCALIB] << BOXCALIB | rcOptions[BOXGOV] << BOXGOV | rcOptions[BOXOSD] << BOXOSD | rcOptions[BOXTELEMETRY] << BOXTELEMETRY | f.ARMED << BOXARM; for (i = 0; i < numberBoxItems; i++) { int flag = (tmp & (1 << availableBoxes[i])); if (flag) junk |= 1 << i; } serialize32(junk); serialize8(mcfg.current_profile); break; case MSP_RAW_IMU: headSerialReply(18); // Retarded hack until multiwiidorks start using real units for sensor data if (acc_1G > 1024) { for (i = 0; i < 3; i++) serialize16(accSmooth[i] / 8); } else { for (i = 0; i < 3; i++) serialize16(accSmooth[i]); } for (i = 0; i < 3; i++) serialize16(gyroData[i]); for (i = 0; i < 3; i++) serialize16(magADC[i]); break; case MSP_SERVO: s_struct((uint8_t *)&servo, 16); break; case MSP_SERVO_CONF: headSerialReply(56); for (i = 0; i < MAX_SERVOS; i++) { serialize16(cfg.servoConf[i].min); serialize16(cfg.servoConf[i].max); serialize16(cfg.servoConf[i].middle); serialize8(cfg.servoConf[i].rate); } break; case MSP_SET_SERVO_CONF: headSerialReply(0); for (i = 0; i < MAX_SERVOS; i++) { cfg.servoConf[i].min = read16(); cfg.servoConf[i].max = read16(); cfg.servoConf[i].middle = read16(); cfg.servoConf[i].rate = read8(); } break; case MSP_MOTOR: s_struct((uint8_t *)motor, 16); break; case MSP_RC: headSerialReply(16); for (i = 0; i < 8; i++) serialize16(rcData[i]); break; case MSP_RAW_GPS: headSerialReply(16); serialize8(f.GPS_FIX); serialize8(GPS_numSat); serialize32(GPS_coord[LAT]); serialize32(GPS_coord[LON]); serialize16(GPS_altitude); serialize16(GPS_speed); serialize16(GPS_ground_course); break; case MSP_COMP_GPS: headSerialReply(5); serialize16(GPS_distanceToHome); serialize16(GPS_directionToHome); serialize8(GPS_update & 1); break; case MSP_ATTITUDE: headSerialReply(8); for (i = 0; i < 2; i++) serialize16(angle[i]); serialize16(heading); serialize16(headFreeModeHold); break; case MSP_ALTITUDE: headSerialReply(6); serialize32(EstAlt); serialize16(vario); break; case MSP_ANALOG: headSerialReply(5); serialize8(vbat); serialize16(0); // power meter trash serialize16(rssi); break; case MSP_RC_TUNING: headSerialReply(7); serialize8(cfg.rcRate8); serialize8(cfg.rcExpo8); serialize8(cfg.rollPitchRate); serialize8(cfg.yawRate); serialize8(cfg.dynThrPID); serialize8(cfg.thrMid8); serialize8(cfg.thrExpo8); break; case MSP_PID: headSerialReply(3 * PIDITEMS); for (i = 0; i < PIDITEMS; i++) { serialize8(cfg.P8[i]); serialize8(cfg.I8[i]); serialize8(cfg.D8[i]); } break; case MSP_PIDNAMES: headSerialReply(sizeof(pidnames) - 1); serializeNames(pidnames); break; case MSP_BOX: headSerialReply(2 * numberBoxItems); for (i = 0; i < numberBoxItems; i++) serialize16(cfg.activate[availableBoxes[i]]); break; case MSP_BOXNAMES: // headSerialReply(sizeof(boxnames) - 1); serializeBoxNamesReply(); break; case MSP_BOXIDS: headSerialReply(numberBoxItems); for (i = 0; i < numberBoxItems; i++) serialize8(availableBoxes[i]); break; case MSP_MISC: headSerialReply(2 * 6 + 4 + 2 + 4); serialize16(0); // intPowerTrigger1 (aka useless trash) serialize16(mcfg.minthrottle); serialize16(mcfg.maxthrottle); serialize16(mcfg.mincommand); serialize16(cfg.failsafe_throttle); serialize16(0); // plog useless shit serialize32(0); // plog useless shit serialize16(cfg.mag_declination / 10); // TODO check this shit serialize8(mcfg.vbatscale); serialize8(mcfg.vbatmincellvoltage); serialize8(mcfg.vbatmaxcellvoltage); serialize8(0); break; case MSP_MOTOR_PINS: headSerialReply(8); for (i = 0; i < 8; i++) serialize8(i + 1); break; case MSP_WP: wp_no = read8(); // get the wp number headSerialReply(18); if (wp_no == 0) { lat = GPS_home[LAT]; lon = GPS_home[LON]; } else if (wp_no == 16) { lat = GPS_hold[LAT]; lon = GPS_hold[LON]; } serialize8(wp_no); serialize32(lat); serialize32(lon); serialize32(AltHold); // altitude (cm) will come here -- temporary implementation to test feature with apps serialize16(0); // heading will come here (deg) serialize16(0); // time to stay (ms) will come here serialize8(0); // nav flag will come here break; case MSP_SET_WP: wp_no = read8(); //get the wp number lat = read32(); lon = read32(); alt = read32(); // to set altitude (cm) read16(); // future: to set heading (deg) read16(); // future: to set time to stay (ms) read8(); // future: to set nav flag if (wp_no == 0) { GPS_home[LAT] = lat; GPS_home[LON] = lon; f.GPS_HOME_MODE = 0; // with this flag, GPS_set_next_wp will be called in the next loop -- OK with SERIAL GPS / OK with I2C GPS f.GPS_FIX_HOME = 1; if (alt != 0) AltHold = alt; // temporary implementation to test feature with apps } else if (wp_no == 16) { // OK with SERIAL GPS -- NOK for I2C GPS / needs more code dev in order to inject GPS coord inside I2C GPS GPS_hold[LAT] = lat; GPS_hold[LON] = lon; if (alt != 0) AltHold = alt; // temporary implementation to test feature with apps nav_mode = NAV_MODE_WP; GPS_set_next_wp(&GPS_hold[LAT], &GPS_hold[LON]); } headSerialReply(0); break; case MSP_RESET_CONF: if (!f.ARMED) checkFirstTime(true); headSerialReply(0); break; case MSP_ACC_CALIBRATION: if (!f.ARMED) calibratingA = CALIBRATING_ACC_CYCLES; headSerialReply(0); break; case MSP_MAG_CALIBRATION: if (!f.ARMED) f.CALIBRATE_MAG = 1; headSerialReply(0); break; case MSP_EEPROM_WRITE: writeEEPROM(0, true); headSerialReply(0); break; case MSP_DEBUG: headSerialReply(8); // make use of this crap, output some useful QA statistics debug[3] = ((hse_value / 1000000) * 1000) + (SystemCoreClock / 1000000); // XX0YY [crystal clock : core clock] for (i = 0; i < 4; i++) serialize16(debug[i]); // 4 variables are here for general monitoring purpose break; // Additional commands that are not compatible with MultiWii case MSP_ACC_TRIM: headSerialReply(4); serialize16(cfg.angleTrim[PITCH]); serialize16(cfg.angleTrim[ROLL]); break; case MSP_UID: headSerialReply(12); serialize32(U_ID_0); serialize32(U_ID_1); serialize32(U_ID_2); break; case MSP_GPSSVINFO: headSerialReply(1 + (GPS_numCh * 4)); serialize8(GPS_numCh); for (i = 0; i < GPS_numCh; i++){ serialize8(GPS_svinfo_chn[i]); serialize8(GPS_svinfo_svid[i]); serialize8(GPS_svinfo_quality[i]); serialize8(GPS_svinfo_cno[i]); } break; default: // we do not know how to handle the (valid) message, indicate error MSP $M! headSerialError(0); break; } tailSerialReply(); } // evaluate all other incoming serial data static void evaluateOtherData(uint8_t sr) { switch (sr) { case '#': cliProcess(); break; case 'R': systemReset(true); // reboot to bootloader break; } } void serialCom(void) { uint8_t c; static uint8_t offset; static uint8_t dataSize; static enum _serial_state { IDLE, HEADER_START, HEADER_M, HEADER_ARROW, HEADER_SIZE, HEADER_CMD, } c_state = IDLE; // in cli mode, all serial stuff goes to here. enter cli mode by sending # if (cliMode) { cliProcess(); return; } while (serialTotalBytesWaiting(core.mainport)) { c = serialRead(core.mainport); if (c_state == IDLE) { c_state = (c == '$') ? HEADER_START : IDLE; if (c_state == IDLE) evaluateOtherData(c); // evaluate all other incoming serial data } else if (c_state == HEADER_START) { c_state = (c == 'M') ? HEADER_M : IDLE; } else if (c_state == HEADER_M) { c_state = (c == '<') ? HEADER_ARROW : IDLE; } else if (c_state == HEADER_ARROW) { if (c > INBUF_SIZE) { // now we are expecting the payload size c_state = IDLE; continue; } dataSize = c; offset = 0; checksum = 0; indRX = 0; checksum ^= c; c_state = HEADER_SIZE; // the command is to follow } else if (c_state == HEADER_SIZE) { cmdMSP = c; checksum ^= c; c_state = HEADER_CMD; } else if (c_state == HEADER_CMD && offset < dataSize) { checksum ^= c; inBuf[offset++] = c; } else if (c_state == HEADER_CMD && offset >= dataSize) { if (checksum == c) { // compare calculated and transferred checksum evaluateCommand(); // we got a valid packet, evaluate it } c_state = IDLE; } } if (!cliMode && feature(FEATURE_TELEMETRY)) { // The first condition should never evaluate to true but I'm putting it here anyway - silpstream sendTelemetry(); } }