amiro-os / components / Lidar.cpp @ bc91a128
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#include <amiro/Lidar.h> |
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using namespace chibios_rt; |
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using namespace amiro; |
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uint8_t Lidar::scannedData[NUMBER_OF_CHARACTERS + 1] = {};
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Lidar::Lidar(const uint8_t boardId, Lidar::SETUP setup)
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: BaseStaticThread<256>(),
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boardId(boardId), |
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setup(setup) { |
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} |
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Lidar:: |
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~Lidar() { |
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// Power down the LIDAR
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// TODO Is it correct anyway
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switch (boardId) {
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case(CAN::LIGHT_RING_ID):
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palWritePad(GPIOB, GPIOB_LASER_EN, PAL_LOW); |
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break;
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default:
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break;
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} |
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this->isReady = false; |
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}; |
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void Lidar::flushSD2InputQueue() {
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chSysLock(); |
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chIQResetI(&SD2.iqueue); |
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chSysUnlock(); |
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} |
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msg_t Lidar::main(void) {
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switch (this->boardId) { |
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case(CAN::LIGHT_RING_ID): {
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// Power up the LIDAR
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palWritePad(GPIOB, GPIOB_LASER_EN, PAL_HIGH); |
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BaseThread::sleep(MS2ST(5000));
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// Setup the driver and lidar, if we want to communicate with it
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if (setup != SETUP::POWER_ONLY) {
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// Flush the queue because there is a "0" in it
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flushSD2InputQueue(); |
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// Configure LIDAR serial interface speed
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// chprintf((BaseSequentialStream*) &SD1, "Speed switch to " STR(SD_SPEED) "\n");
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chprintf((BaseSequentialStream*) &SD2, "SS" STR(SD_SPEED_PREFIX) STR(SD_SPEED) LF);
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// Check if the switch went well, otherwise terminate the thread
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if (checkDataString("SS" STR(SD_SPEED_PREFIX) STR(SD_SPEED) "\n00P\n\n")) { |
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chprintf((BaseSequentialStream*) &SD1, "Lidar speed switch OK\n");
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// Configure serial interface of STM32
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sdStop(&SD2); |
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SerialConfig sdLidarconf = { SD_SPEED, 0, 0, 0 }; |
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sdStart(&SD2, &sdLidarconf); |
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} else {
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chprintf((BaseSequentialStream*) &SD1, "Lidar speed switch NOT OK: Terminating Lidar \n");
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palWritePad(GPIOB, GPIOB_LASER_EN, PAL_LOW); |
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return -1; |
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} |
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} |
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break;
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} |
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default:
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break;
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} |
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evtInit(&this->evtimer, UPDATE_LIDAR_PERIOD_MSEC);
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EvtSource *eventTimerEvtSource = reinterpret_cast<EvtSource *>(&this->evtimer.et_es); |
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EvtListener eventTimerEvtListener; |
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// TODO Does PERIODIC_TIMER_ID has something to do with ControllerAreNetwork.h ?
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eventTimerEvtSource->registerOne(&eventTimerEvtListener, CAN::PERIODIC_TIMER_ID); |
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evtStart(&this->evtimer);
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this->setName("Lidar"); |
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while (!this->shouldTerminate()) { |
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eventmask_t eventMask = this->waitOneEvent(ALL_EVENTS);
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switch (eventMask) {
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case EVENT_MASK(CAN::PERIODIC_TIMER_ID):
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// printDetails();
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if (setup != SETUP::POWER_ONLY) {
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updateSensorVal(); |
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} |
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break;
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} |
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} |
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evtStop(&this->evtimer);
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eventTimerEvtSource->unregister(&eventTimerEvtListener); |
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return RDY_OK;
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} |
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bool_t Lidar::getScan(uint16_t (&scannedData)[NUMBER_OF_STEPS]) { |
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if (this->isReady && !this->isFail) { |
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chSysLock(); |
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memcpy(&scannedData, &(Lidar::scannedData[0]), NUMBER_OF_CHARACTERS);
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this->isReady = false; |
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chSysUnlock(); |
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return true; |
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} else {
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return false; |
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} |
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} |
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uint16_t Lidar::getNumberOfValues() { |
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return NUMBER_OF_STEPS;
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} |
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uint16_t Lidar::twoCharacterEncoding(uint8_t &char1, uint8_t &char2) { |
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return uint16_t((((char1 - 0x30) & 0b00111111) << 6) | ((char2 - 0x30) & 0b00111111)); |
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} |
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bool_t Lidar::getData(uint8_t &data, uint32_t timeoutMs) { |
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// data = sdGet(&SD2);
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msg_t dataTmp = chIQGetTimeout(&SD2.iqueue, MS2ST(timeoutMs)); |
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if (dataTmp == Q_TIMEOUT || dataTmp == Q_RESET) {
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return false; |
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} else {
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data = uint8_t(dataTmp); |
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++this->dataCounter;
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return true; |
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} |
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} |
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msg_t Lidar::updateSensorVal() { |
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chSysLock(); |
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// Set this flag so that the everyone knows, that scannedData will be filed right now
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this->isReady = false; |
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// Reset the FAIL flag
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this->isFail = false; |
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chSysUnlock(); |
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while (!this->isReady) { |
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switch(step) {
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case SEND_SCAN_CMD:
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flushSD2InputQueue(); |
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// Read (725-(44-1))=682 values with two-character encoding what makes 1364 datapoints
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// 1456 in total:
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// 16 (Cmd-Echo) + ? (Remaining Scans) + 1 (LF) + ? (String Characters) + 1 (LF) + 2 (Status) + 1 (Sum) + 1 (LF) + ? (Timestamp) + 1 (LF) + 1364 (Data for a certain setup) + 1 (Sum) + 1 (LF) + 1 (LF)
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chprintf((BaseSequentialStream*) &SD2,DATA_ACQ_CODE STR(STARTING_STEP_PREFIX) STR(STARTING_STEP) STR(END_STEP_PREFIX) STR(END_STEP) STR(CLUSTER_COUNT) STR(SCAN_INTERVALL) STR(NUMBER_OF_INTERVALL) LF); |
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step = DATA_VALID_CHECK; |
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this->dataCounter = 0; |
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break;
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case DATA_VALID_CHECK:
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if(getData(this->newInput, 200)) { |
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// TODO check for last data, if scan has a few errors
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// HACK The timeout fix this issue at least, because after a while there
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// wont be any transmitts
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if (this->newInput == validScanTag[this->checkStatusIdx]) { |
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if (++this->checkStatusIdx == 5) { |
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// scan_data is without error: Found the sting "\n99b\n"
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step = DATA_START_CHECK; |
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this->checkStatusIdx = 0; |
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} |
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} else {
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this->checkStatusIdx = 0; |
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} |
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} else {
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step = FAIL; |
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} |
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break;
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case DATA_START_CHECK:
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// Check for the next linefeed to start the record
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if(getData(this->newInput, 200)) { |
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if (this->newInput == 10) { |
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step = DATA_RECORD; |
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this->dataIdx = 0; |
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} |
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} else {
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step = FAIL; |
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} |
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break;
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case DATA_RECORD:
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if(getData(this->newInput, 200)) { |
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if (this->lastInput == 10 && this->newInput == 10) { |
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// end of data
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this->lastInput = 0x0; // Just to delete this->lastInput value |
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step = DATA_DECODE; |
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} else if (this->newInput != 10) { |
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Lidar::scannedData[this->dataIdx++] = this->newInput; |
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this->lastInput = this->newInput; |
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} else { // this->lastInput != 10 && this->newInput == 10 |
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// This is the case, where we know that the last character was the checksum.
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// Therefore, we need to decrement the counter
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--this->dataIdx;
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this->lastInput = this->newInput; |
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} |
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//chprintf((BaseSequentialStream*) &SD1, "%d ", this->newInput);
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} else {
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step = FAIL; |
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} |
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break;
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case DATA_DECODE:
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// Decode the recorded data
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for (uint16_t idx=0; idx < NUMBER_OF_CHARACTERS; idx += 2) { |
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//TODO Check if +1 is right
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*((uint16_t*) &(Lidar::scannedData[idx])) = twoCharacterEncoding(Lidar::scannedData[idx],Lidar::scannedData[idx+1]);
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} |
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// To print out the data in this thread, choose "step = DATA_SHOW"
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step = FINISH; |
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break;
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case DATA_SHOW:
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// Show the decoded data
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chprintf((BaseSequentialStream*) &SD1, "\n%d", this->dataCounter); |
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for (uint32_t idx=0; idx < this->dataIdx; idx+=2) { |
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chprintf((BaseSequentialStream*) &SD1, "\n%d", *((uint16_t*) &(Lidar::scannedData[idx])));
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} |
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step = FINISH; |
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break;
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case FAIL:
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// Set the FAIL flag
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chSysLock(); |
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// Set this flag so that the everyone knows, that scannedData holds wrong information
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this->isFail = true; |
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chSysUnlock(); |
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break;
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case FINISH:
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// Clean up
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this->step = SEND_SCAN_CMD;
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chSysLock(); |
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// Set this flag so that the everyone knows, that scannedData holds the actual data
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this->isReady = true; |
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chSysUnlock(); |
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break;
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default:
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break;
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} |
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} |
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return RDY_OK;
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} |
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void Lidar::printData() {
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uint8_t lastInput = 0xFF, newInput = 0xFF; |
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while (true) { |
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if(getData(newInput, 200)) { |
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if (lastInput == 10 && newInput == 10) { |
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return;
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} else {
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chprintf((BaseSequentialStream*) &SD1, "%c", newInput);
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} |
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lastInput = newInput; |
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} else {
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chprintf((BaseSequentialStream*) &SD1, "TIMEOUT\n", newInput);
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return;
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} |
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} |
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} |
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bool_t Lidar::checkDataString(const char compareString[]) { |
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uint8_t lastInput = 0xFF, newInput = 0xFF, recIdx = 0; |
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bool_t dataOk = true, processFlag = true; |
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while (processFlag) {
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if (getData(newInput, 200)) { |
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// End of data received, quit processing
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if (lastInput == 10 && newInput == 10) { |
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processFlag = false;
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} |
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// Compare data if the characters before have been ok
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// Otherwise do not compare anymore, because of possible
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// segmentation fault
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if (dataOk) {
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if (newInput != compareString[recIdx++]) {
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dataOk = false;
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} |
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} |
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// Save the received character
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lastInput = newInput; |
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} else {
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processFlag = false;
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dataOk = false;
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} |
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} |
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return dataOk;
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} |
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void Lidar::printDetails() {
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chprintf((BaseSequentialStream*) &SD1, "Print sensor details:\n");
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// Tell the sensor to transmit its details
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chprintf((BaseSequentialStream*) &SD2, "VV\n");
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// Print the transmitted data
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printData(); |
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} |
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void Lidar::printSpecification() {
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chprintf((BaseSequentialStream*) &SD1, "Print sensor specification:\n");
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// Tell the sensor to transmit its specifications
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chprintf((BaseSequentialStream*) &SD2, "PP\n");
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// Print the transmitted data
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printData(); |
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} |
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void Lidar::printInformation() {
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chprintf((BaseSequentialStream*) &SD1, "Print sensor information:\n");
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// Tell the sensor to transmit its information
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chprintf((BaseSequentialStream*) &SD2, "II\n");
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// Print the transmitted data
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printData(); |
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} |
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bool_t Lidar::getIsReady() { |
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return this->isReady; |
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} |