/** ****************************************************************************** * @addtogroup OpenPilotSystem OpenPilot System * @{ * @addtogroup OpenPilotLibraries OpenPilot System Libraries * @{ * * @file uavtalk.c * @author The OpenPilot Team, http://www.openpilot.org Copyright (C) 2010. * @brief UAVTalk library, implements to telemetry protocol. See the wiki for more details. * This library should not be called directly by the application, it is only used by the * Telemetry module. * @see The GNU Public License (GPL) Version 3 * *****************************************************************************/ /* * 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, write to the Free Software Foundation, Inc., * 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "openpilot.h" #include "uavtalk_priv.h" // #define UAV_DEBUGLOG 1 #if defined UAV_DEBUGLOG && defined FLASH_FREERTOS #define UAVT_DEBUGLOG_PRINTF(...) PIOS_DEBUGLOG_Printf(__VA_ARGS__) // uncomment and adapt the following lines to filter verbose logging to include specific object(s) only // #include "flighttelemetrystats.h" // #define UAVT_DEBUGLOG_CPRINTF(objId, ...) if (objId == FLIGHTTELEMETRYSTATS_OBJID) { UAVT_DEBUGLOG_PRINTF(__VA_ARGS__); } #endif #ifndef UAVT_DEBUGLOG_PRINTF #define UAVT_DEBUGLOG_PRINTF(...) #endif #ifndef UAVT_DEBUGLOG_CPRINTF #define UAVT_DEBUGLOG_CPRINTF(objId, ...) #endif // Private functions static int32_t objectTransaction(UAVTalkConnectionData *connection, uint8_t type, UAVObjHandle obj, uint16_t instId, int32_t timeout); static int32_t sendObject(UAVTalkConnectionData *connection, uint8_t type, uint32_t objId, uint16_t instId, UAVObjHandle obj); static int32_t sendSingleObject(UAVTalkConnectionData *connection, uint8_t type, uint32_t objId, uint16_t instId, UAVObjHandle obj); static int32_t receiveObject(UAVTalkConnectionData *connection, uint8_t type, uint32_t objId, uint16_t instId, uint8_t *data); static void updateAck(UAVTalkConnectionData *connection, uint8_t type, uint32_t objId, uint16_t instId); /** * Initialize the UAVTalk library * \param[in] connection UAVTalkConnection to be used * \param[in] outputStream Function pointer that is called to send a data buffer * \return 0 Success * \return -1 Failure */ UAVTalkConnection UAVTalkInitialize(UAVTalkOutputStream outputStream) { // allocate object UAVTalkConnectionData *connection = pvPortMalloc(sizeof(UAVTalkConnectionData)); if (!connection) { return 0; } connection->canari = UAVTALK_CANARI; connection->iproc.rxPacketLength = 0; connection->iproc.state = UAVTALK_STATE_SYNC; connection->outStream = outputStream; connection->lock = xSemaphoreCreateRecursiveMutex(); connection->transLock = xSemaphoreCreateRecursiveMutex(); // allocate buffers connection->rxBuffer = pvPortMalloc(UAVTALK_MAX_PACKET_LENGTH); if (!connection->rxBuffer) { return 0; } connection->txBuffer = pvPortMalloc(UAVTALK_MAX_PACKET_LENGTH); if (!connection->txBuffer) { return 0; } vSemaphoreCreateBinary(connection->respSema); xSemaphoreTake(connection->respSema, 0); // reset to zero UAVTalkResetStats((UAVTalkConnection)connection); return (UAVTalkConnection)connection; } /** * Set the communication output stream * \param[in] connection UAVTalkConnection to be used * \param[in] outputStream Function pointer that is called to send a data buffer * \return 0 Success * \return -1 Failure */ int32_t UAVTalkSetOutputStream(UAVTalkConnection connectionHandle, UAVTalkOutputStream outputStream) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return -1); // Lock xSemaphoreTakeRecursive(connection->lock, portMAX_DELAY); // set output stream connection->outStream = outputStream; // Release lock xSemaphoreGiveRecursive(connection->lock); return 0; } /** * Get current output stream * \param[in] connection UAVTalkConnection to be used * @return UAVTarlkOutputStream the output stream used */ UAVTalkOutputStream UAVTalkGetOutputStream(UAVTalkConnection connectionHandle) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return NULL); return connection->outStream; } /** * Get communication statistics counters * \param[in] connection UAVTalkConnection to be used * @param[out] statsOut Statistics counters */ void UAVTalkGetStats(UAVTalkConnection connectionHandle, UAVTalkStats *statsOut, bool reset) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return ); // Lock xSemaphoreTakeRecursive(connection->lock, portMAX_DELAY); // Copy stats memcpy(statsOut, &connection->stats, sizeof(UAVTalkStats)); if (reset) { // Clear stats memset(&connection->stats, 0, sizeof(UAVTalkStats)); } // Release lock xSemaphoreGiveRecursive(connection->lock); } /** * Get communication statistics counters * \param[in] connection UAVTalkConnection to be used * @param[out] statsOut Statistics counters */ void UAVTalkAddStats(UAVTalkConnection connectionHandle, UAVTalkStats *statsOut, bool reset) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return ); // Lock xSemaphoreTakeRecursive(connection->lock, portMAX_DELAY); // Copy stats statsOut->txBytes += connection->stats.txBytes; statsOut->txObjectBytes += connection->stats.txObjectBytes; statsOut->txObjects += connection->stats.txObjects; statsOut->txErrors += connection->stats.txErrors; statsOut->rxBytes += connection->stats.rxBytes; statsOut->rxObjectBytes += connection->stats.rxObjectBytes; statsOut->rxObjects += connection->stats.rxObjects; statsOut->rxErrors += connection->stats.rxErrors; statsOut->rxSyncErrors += connection->stats.rxSyncErrors; statsOut->rxCrcErrors += connection->stats.rxCrcErrors; if (reset) { // Clear stats memset(&connection->stats, 0, sizeof(UAVTalkStats)); } // Release lock xSemaphoreGiveRecursive(connection->lock); } /** * Reset the statistics counters. * \param[in] connection UAVTalkConnection to be used */ void UAVTalkResetStats(UAVTalkConnection connectionHandle) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return ); // Lock xSemaphoreTakeRecursive(connection->lock, portMAX_DELAY); // Clear stats memset(&connection->stats, 0, sizeof(UAVTalkStats)); // Release lock xSemaphoreGiveRecursive(connection->lock); } /** * Accessor method to get the timestamp from the last UAVTalk message */ void UAVTalkGetLastTimestamp(UAVTalkConnection connectionHandle, uint16_t *timestamp) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return ); UAVTalkInputProcessor *iproc = &connection->iproc; *timestamp = iproc->timestamp; } /** * Request an update for the specified object, on success the object data would have been * updated by the GCS. * \param[in] connection UAVTalkConnection to be used * \param[in] obj Object to update * \param[in] instId The instance ID or UAVOBJ_ALL_INSTANCES for all instances. * \param[in] timeout Time to wait for the response, when zero it will return immediately * \return 0 Success * \return -1 Failure */ int32_t UAVTalkSendObjectRequest(UAVTalkConnection connectionHandle, UAVObjHandle obj, uint16_t instId, int32_t timeout) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return -1); return objectTransaction(connection, UAVTALK_TYPE_OBJ_REQ, obj, instId, timeout); } /** * Send the specified object through the telemetry link. * \param[in] connection UAVTalkConnection to be used * \param[in] obj Object to send * \param[in] instId The instance ID or UAVOBJ_ALL_INSTANCES for all instances. * \param[in] acked Selects if an ack is required (1:ack required, 0: ack not required) * \param[in] timeoutMs Time to wait for the ack, when zero it will return immediately * \return 0 Success * \return -1 Failure */ int32_t UAVTalkSendObject(UAVTalkConnection connectionHandle, UAVObjHandle obj, uint16_t instId, uint8_t acked, int32_t timeoutMs) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return -1); // Send object if (acked == 1) { return objectTransaction(connection, UAVTALK_TYPE_OBJ_ACK, obj, instId, timeoutMs); } else { return objectTransaction(connection, UAVTALK_TYPE_OBJ, obj, instId, timeoutMs); } } /** * Send the specified object through the telemetry link with a timestamp. * \param[in] connection UAVTalkConnection to be used * \param[in] obj Object to send * \param[in] instId The instance ID or UAVOBJ_ALL_INSTANCES for all instances. * \param[in] acked Selects if an ack is required (1:ack required, 0: ack not required) * \param[in] timeoutMs Time to wait for the ack, when zero it will return immediately * \return 0 Success * \return -1 Failure */ int32_t UAVTalkSendObjectTimestamped(UAVTalkConnection connectionHandle, UAVObjHandle obj, uint16_t instId, uint8_t acked, int32_t timeoutMs) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return -1); // Send object if (acked == 1) { return objectTransaction(connection, UAVTALK_TYPE_OBJ_ACK_TS, obj, instId, timeoutMs); } else { return objectTransaction(connection, UAVTALK_TYPE_OBJ_TS, obj, instId, timeoutMs); } } /** * Execute the requested transaction on an object. * \param[in] connection UAVTalkConnection to be used * \param[in] type Transaction type * UAVTALK_TYPE_OBJ: send object, * UAVTALK_TYPE_OBJ_REQ: request object update * UAVTALK_TYPE_OBJ_ACK: send object with an ack * \param[in] obj Object * \param[in] instId The instance ID of UAVOBJ_ALL_INSTANCES for all instances. * \param[in] timeoutMs Time to wait for the ack, when zero it will return immediately * \return 0 Success * \return -1 Failure */ static int32_t objectTransaction(UAVTalkConnectionData *connection, uint8_t type, UAVObjHandle obj, uint16_t instId, int32_t timeoutMs) { int32_t respReceived; int32_t ret = -1; // Send object depending on if a response is needed if (type == UAVTALK_TYPE_OBJ_ACK || type == UAVTALK_TYPE_OBJ_ACK_TS || type == UAVTALK_TYPE_OBJ_REQ) { // Get transaction lock (will block if a transaction is pending) xSemaphoreTakeRecursive(connection->transLock, portMAX_DELAY); // Send object xSemaphoreTakeRecursive(connection->lock, portMAX_DELAY); // expected response type connection->respType = (type == UAVTALK_TYPE_OBJ_REQ) ? UAVTALK_TYPE_OBJ : UAVTALK_TYPE_ACK; connection->respObjId = UAVObjGetID(obj); connection->respInstId = instId; ret = sendObject(connection, type, UAVObjGetID(obj), instId, obj); xSemaphoreGiveRecursive(connection->lock); // Wait for response (or timeout) if sending the object succeeded respReceived = pdFALSE; if (ret == 0) { respReceived = xSemaphoreTake(connection->respSema, timeoutMs / portTICK_RATE_MS); } // Check if a response was received if (respReceived == pdTRUE) { // We are done successfully xSemaphoreGiveRecursive(connection->transLock); ret = 0; } else { // Cancel transaction xSemaphoreTakeRecursive(connection->lock, portMAX_DELAY); // non blocking call to make sure the value is reset to zero (binary sema) xSemaphoreTake(connection->respSema, 0); connection->respObjId = 0; xSemaphoreGiveRecursive(connection->lock); xSemaphoreGiveRecursive(connection->transLock); return -1; } } else if (type == UAVTALK_TYPE_OBJ || type == UAVTALK_TYPE_OBJ_TS) { xSemaphoreTakeRecursive(connection->lock, portMAX_DELAY); ret = sendObject(connection, type, UAVObjGetID(obj), instId, obj); xSemaphoreGiveRecursive(connection->lock); } return ret; } /** * Process an byte from the telemetry stream. * \param[in] connectionHandle UAVTalkConnection to be used * \param[in] rxbyte Received byte * \return UAVTalkRxState */ UAVTalkRxState UAVTalkProcessInputStreamQuiet(UAVTalkConnection connectionHandle, uint8_t rxbyte) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return -1); UAVTalkInputProcessor *iproc = &connection->iproc; ++connection->stats.rxBytes; if (iproc->state == UAVTALK_STATE_ERROR || iproc->state == UAVTALK_STATE_COMPLETE) { iproc->state = UAVTALK_STATE_SYNC; } if (iproc->rxPacketLength < 0xffff) { // update packet byte count iproc->rxPacketLength++; } // Receive state machine switch (iproc->state) { case UAVTALK_STATE_SYNC: if (rxbyte != UAVTALK_SYNC_VAL) { connection->stats.rxSyncErrors++; break; } // Initialize and update the CRC iproc->cs = PIOS_CRC_updateByte(0, rxbyte); iproc->rxPacketLength = 1; iproc->rxCount = 0; iproc->type = 0; iproc->state = UAVTALK_STATE_TYPE; break; case UAVTALK_STATE_TYPE: if ((rxbyte & UAVTALK_TYPE_MASK) != UAVTALK_TYPE_VER) { connection->stats.rxErrors++; iproc->state = UAVTALK_STATE_SYNC; break; } // update the CRC iproc->cs = PIOS_CRC_updateByte(iproc->cs, rxbyte); iproc->type = rxbyte; iproc->packet_size = 0; iproc->state = UAVTALK_STATE_SIZE; break; case UAVTALK_STATE_SIZE: // update the CRC iproc->cs = PIOS_CRC_updateByte(iproc->cs, rxbyte); if (iproc->rxCount == 0) { iproc->packet_size += rxbyte; iproc->rxCount++; break; } iproc->packet_size += rxbyte << 8; iproc->rxCount = 0; if (iproc->packet_size < UAVTALK_MIN_HEADER_LENGTH || iproc->packet_size > UAVTALK_MAX_HEADER_LENGTH + UAVTALK_MAX_PAYLOAD_LENGTH) { // incorrect packet size connection->stats.rxErrors++; iproc->state = UAVTALK_STATE_ERROR; break; } iproc->objId = 0; iproc->state = UAVTALK_STATE_OBJID; break; case UAVTALK_STATE_OBJID: // update the CRC iproc->cs = PIOS_CRC_updateByte(iproc->cs, rxbyte); iproc->objId += rxbyte << (8 * (iproc->rxCount++)); if (iproc->rxCount < 4) { break; } iproc->rxCount = 0; iproc->instId = 0; iproc->state = UAVTALK_STATE_INSTID; break; case UAVTALK_STATE_INSTID: // update the CRC iproc->cs = PIOS_CRC_updateByte(iproc->cs, rxbyte); iproc->instId += rxbyte << (8 * (iproc->rxCount++)); if (iproc->rxCount < 2) { break; } iproc->rxCount = 0; UAVObjHandle obj = UAVObjGetByID(iproc->objId); // Determine data length if (iproc->type == UAVTALK_TYPE_OBJ_REQ || iproc->type == UAVTALK_TYPE_ACK || iproc->type == UAVTALK_TYPE_NACK) { iproc->length = 0; iproc->timestampLength = 0; } else { iproc->timestampLength = (iproc->type & UAVTALK_TIMESTAMPED) ? 2 : 0; if (obj) { iproc->length = UAVObjGetNumBytes(obj); } else { iproc->length = iproc->packet_size - iproc->rxPacketLength - iproc->timestampLength; } } // Check length if (iproc->length >= UAVTALK_MAX_PAYLOAD_LENGTH) { // packet error - exceeded payload max length connection->stats.rxErrors++; iproc->state = UAVTALK_STATE_ERROR; break; } // Check the lengths match if ((iproc->rxPacketLength + iproc->timestampLength + iproc->length) != iproc->packet_size) { // packet error - mismatched packet size connection->stats.rxErrors++; iproc->state = UAVTALK_STATE_ERROR; break; } // Determine next state if (iproc->type & UAVTALK_TIMESTAMPED) { // If there is a timestamp get it iproc->timestamp = 0; iproc->state = UAVTALK_STATE_TIMESTAMP; } else { // If there is a payload get it, otherwise receive checksum if (iproc->length > 0) { iproc->state = UAVTALK_STATE_DATA; } else { iproc->state = UAVTALK_STATE_CS; } } break; case UAVTALK_STATE_TIMESTAMP: // update the CRC iproc->cs = PIOS_CRC_updateByte(iproc->cs, rxbyte); iproc->timestamp += rxbyte << (8 * (iproc->rxCount++)); if (iproc->rxCount < 2) { break; } iproc->rxCount = 0; // If there is a payload get it, otherwise receive checksum if (iproc->length > 0) { iproc->state = UAVTALK_STATE_DATA; } else { iproc->state = UAVTALK_STATE_CS; } break; case UAVTALK_STATE_DATA: // update the CRC iproc->cs = PIOS_CRC_updateByte(iproc->cs, rxbyte); connection->rxBuffer[iproc->rxCount++] = rxbyte; if (iproc->rxCount < iproc->length) { break; } iproc->rxCount = 0; iproc->state = UAVTALK_STATE_CS; break; case UAVTALK_STATE_CS: // Check the CRC byte if (rxbyte != iproc->cs) { // packet error - faulty CRC UAVT_DEBUGLOG_PRINTF("BAD CRC"); connection->stats.rxCrcErrors++; connection->stats.rxErrors++; iproc->state = UAVTALK_STATE_ERROR; break; } if (iproc->rxPacketLength != (iproc->packet_size + UAVTALK_CHECKSUM_LENGTH)) { // packet error - mismatched packet size connection->stats.rxErrors++; iproc->state = UAVTALK_STATE_ERROR; break; } connection->stats.rxObjects++; connection->stats.rxObjectBytes += iproc->length; iproc->state = UAVTALK_STATE_COMPLETE; break; default: iproc->state = UAVTALK_STATE_ERROR; break; } // Done return iproc->state; } /** * Process an byte from the telemetry stream. * \param[in] connection UAVTalkConnection to be used * \param[in] rxbyte Received byte * \return UAVTalkRxState */ UAVTalkRxState UAVTalkProcessInputStream(UAVTalkConnection connectionHandle, uint8_t rxbyte) { UAVTalkRxState state = UAVTalkProcessInputStreamQuiet(connectionHandle, rxbyte); if (state == UAVTALK_STATE_COMPLETE) { UAVTalkReceiveObject(connectionHandle); } return state; } /** * Send a parsed packet received on one connection handle out on a different connection handle. * The packet must be in a complete state, meaning it is completed parsing. * The packet is re-assembled from the component parts into a complete message and sent. * This can be used to relay packets from one UAVTalk connection to another. * \param[in] connection UAVTalkConnection to be used * \param[in] rxbyte Received byte * \return 0 Success * \return -1 Failure */ UAVTalkRxState UAVTalkRelayPacket(UAVTalkConnection inConnectionHandle, UAVTalkConnection outConnectionHandle) { UAVTalkConnectionData *inConnection; CHECKCONHANDLE(inConnectionHandle, inConnection, return -1); UAVTalkInputProcessor *inIproc = &inConnection->iproc; // The input packet must be completely parsed. if (inIproc->state != UAVTALK_STATE_COMPLETE) { inConnection->stats.rxErrors++; return -1; } UAVTalkConnectionData *outConnection; CHECKCONHANDLE(outConnectionHandle, outConnection, return -1); if (!outConnection->outStream) { outConnection->stats.txErrors++; return -1; } // Lock xSemaphoreTakeRecursive(outConnection->lock, portMAX_DELAY); outConnection->txBuffer[0] = UAVTALK_SYNC_VAL; // Setup type outConnection->txBuffer[1] = inIproc->type; // next 2 bytes are reserved for data length (inserted here later) // Setup object ID outConnection->txBuffer[4] = (uint8_t)(inIproc->objId & 0xFF); outConnection->txBuffer[5] = (uint8_t)((inIproc->objId >> 8) & 0xFF); outConnection->txBuffer[6] = (uint8_t)((inIproc->objId >> 16) & 0xFF); outConnection->txBuffer[7] = (uint8_t)((inIproc->objId >> 24) & 0xFF); // Setup instance ID outConnection->txBuffer[8] = (uint8_t)(inIproc->instId & 0xFF); outConnection->txBuffer[9] = (uint8_t)((inIproc->instId >> 8) & 0xFF); int32_t headerLength = 10; // Add timestamp when the transaction type is appropriate if (inIproc->type & UAVTALK_TIMESTAMPED) { portTickType time = xTaskGetTickCount(); outConnection->txBuffer[10] = (uint8_t)(time & 0xFF); outConnection->txBuffer[11] = (uint8_t)((time >> 8) & 0xFF); headerLength += 2; } // Copy data (if any) if (inIproc->length > 0) { memcpy(&outConnection->txBuffer[headerLength], inConnection->rxBuffer, inIproc->length); } // Store the packet length outConnection->txBuffer[2] = (uint8_t)((headerLength + inIproc->length) & 0xFF); outConnection->txBuffer[3] = (uint8_t)(((headerLength + inIproc->length) >> 8) & 0xFF); // Copy the checksum outConnection->txBuffer[headerLength + inIproc->length] = inIproc->cs; // Send the buffer. int32_t rc = (*outConnection->outStream)(outConnection->txBuffer, headerLength + inIproc->length + UAVTALK_CHECKSUM_LENGTH); // Update stats outConnection->stats.txBytes += (rc > 0) ? rc : 0; // evaluate return value before releasing the lock UAVTalkRxState rxState = 0; if (rc != (int32_t)(headerLength + inIproc->length + UAVTALK_CHECKSUM_LENGTH)) { outConnection->stats.txErrors++; rxState = -1; } // Release lock xSemaphoreGiveRecursive(outConnection->lock); // Done return rxState; } /** * Complete receiving a UAVTalk packet. This will cause the packet to be unpacked, acked, etc. * \param[in] connectionHandle UAVTalkConnection to be used * \return 0 Success * \return -1 Failure */ int32_t UAVTalkReceiveObject(UAVTalkConnection connectionHandle) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return -1); UAVTalkInputProcessor *iproc = &connection->iproc; if (iproc->state != UAVTALK_STATE_COMPLETE) { return -1; } return receiveObject(connection, iproc->type, iproc->objId, iproc->instId, connection->rxBuffer); } /** * Get the object ID of the current packet. * \param[in] connectionHandle UAVTalkConnection to be used * \return The object ID, or 0 on error. */ uint32_t UAVTalkGetPacketObjId(UAVTalkConnection connectionHandle) { UAVTalkConnectionData *connection; CHECKCONHANDLE(connectionHandle, connection, return 0); return connection->iproc.objId; } /** * Receive an object. This function process objects received through the telemetry stream. * * Parser errors are considered as transmission errors and are not NACKed. * Some senders (GCS) can timeout and retry if the message is not answered by an ack or nack. * * Object handling errors are considered as application errors and are NACked. * In that case we want to nack as there is no point in the sender retrying to send invalid objects. * * \param[in] connection UAVTalkConnection to be used * \param[in] type Type of received message (UAVTALK_TYPE_OBJ, UAVTALK_TYPE_OBJ_REQ, UAVTALK_TYPE_OBJ_ACK, UAVTALK_TYPE_ACK, UAVTALK_TYPE_NACK) * \param[in] objId ID of the object to work on * \param[in] instId The instance ID of UAVOBJ_ALL_INSTANCES for all instances. * \param[in] data Data buffer * \param[in] length Buffer length * \return 0 Success * \return -1 Failure */ static int32_t receiveObject(UAVTalkConnectionData *connection, uint8_t type, uint32_t objId, uint16_t instId, uint8_t *data) { UAVObjHandle obj; int32_t ret = 0; // Lock xSemaphoreTakeRecursive(connection->lock, portMAX_DELAY); // Get the handle to the object. Will be null if object does not exist. // Warning : // Here we ask for instance ID 0 without taking into account the provided instId // The provided instId will be used later when packing, unpacking, etc... // TODO the above should be fixed as it is cumbersome and error prone obj = UAVObjGetByID(objId); // Process message type switch (type) { case UAVTALK_TYPE_OBJ: case UAVTALK_TYPE_OBJ_TS: // All instances not allowed for OBJ messages if (obj && (instId != UAVOBJ_ALL_INSTANCES)) { // Unpack object, if the instance does not exist it will be created! if (UAVObjUnpack(obj, instId, data) == 0) { // Check if this object acks a pending OBJ_REQ message // any OBJ message can ack a pending OBJ_REQ message // even one that was not sent in response to the OBJ_REQ message updateAck(connection, type, objId, instId); } else { ret = -1; } } else { ret = -1; } break; case UAVTALK_TYPE_OBJ_ACK: case UAVTALK_TYPE_OBJ_ACK_TS: UAVT_DEBUGLOG_CPRINTF(objId, "OBJ_ACK %X %d", objId, instId); // All instances not allowed for OBJ_ACK messages if (obj && (instId != UAVOBJ_ALL_INSTANCES)) { // Unpack object, if the instance does not exist it will be created! if (UAVObjUnpack(obj, instId, data) == 0) { UAVT_DEBUGLOG_CPRINTF(objId, "OBJ ACK %X %d", objId, instId); // Object updated or created, transmit ACK sendObject(connection, UAVTALK_TYPE_ACK, objId, instId, NULL); } else { ret = -1; } } else { ret = -1; } if (ret == -1) { // failed to update object, transmit NACK UAVT_DEBUGLOG_PRINTF("OBJ NACK %X %d", objId, instId); sendObject(connection, UAVTALK_TYPE_NACK, objId, instId, NULL); } break; case UAVTALK_TYPE_OBJ_REQ: // Check if requested object exists UAVT_DEBUGLOG_CPRINTF(objId, "REQ %X %d", objId, instId); if (obj) { // Object found, transmit it // The sent object will ack the object request on the receiver side ret = sendObject(connection, UAVTALK_TYPE_OBJ, objId, instId, obj); } else { ret = -1; } if (ret == -1) { // failed to send object, transmit NACK UAVT_DEBUGLOG_PRINTF("REQ NACK %X %d", objId, instId); sendObject(connection, UAVTALK_TYPE_NACK, objId, instId, NULL); } break; case UAVTALK_TYPE_NACK: // Do nothing on flight side, let it time out. // TODO: // The transaction takes the result code of the "semaphore taking operation" into account to determine success. // If we give that semaphore in time, its "success" (ack received) // If we do not give that semaphore before the timeout it will return failure. // What would have to be done here is give the semaphore, but set a flag (for example connection->respFail=true) // that indicates failure and then above where it checks for the result code, have it behave as if it failed // if the explicit failure is set. break; case UAVTALK_TYPE_ACK: // All instances not allowed for ACK messages if (obj && (instId != UAVOBJ_ALL_INSTANCES)) { // Check if an ACK is pending updateAck(connection, type, objId, instId); } else { ret = -1; } break; default: ret = -1; } // Unlock xSemaphoreGiveRecursive(connection->lock); // Done return ret; } /** * Check if an ack is pending on an object and give response semaphore * \param[in] connection UAVTalkConnection to be used * \param[in] obj Object * \param[in] instId The instance ID of UAVOBJ_ALL_INSTANCES for all instances. */ static void updateAck(UAVTalkConnectionData *connection, uint8_t type, uint32_t objId, uint16_t instId) { if ((connection->respObjId == objId) && (connection->respType == type)) { if ((connection->respInstId == UAVOBJ_ALL_INSTANCES) && (instId == 0)) { // last instance received, complete transaction xSemaphoreGive(connection->respSema); connection->respObjId = 0; } else if (connection->respInstId == instId) { xSemaphoreGive(connection->respSema); connection->respObjId = 0; } } } /** * Send an object through the telemetry link. * \param[in] connection UAVTalkConnection to be used * \param[in] type Transaction type * \param[in] objId The object ID * \param[in] instId The instance ID or UAVOBJ_ALL_INSTANCES for all instances * \param[in] obj Object handle to send (null when type is NACK) * \return 0 Success * \return -1 Failure */ static int32_t sendObject(UAVTalkConnectionData *connection, uint8_t type, uint32_t objId, uint16_t instId, UAVObjHandle obj) { uint32_t numInst; uint32_t n; uint32_t ret = -1; // Important note : obj can be null (when type is NACK for example) so protect all obj dereferences. // If all instances are requested and this is a single instance object, force instance ID to zero if ((obj != NULL) && (instId == UAVOBJ_ALL_INSTANCES) && UAVObjIsSingleInstance(obj)) { instId = 0; } // Process message type if (type == UAVTALK_TYPE_OBJ || type == UAVTALK_TYPE_OBJ_TS || type == UAVTALK_TYPE_OBJ_ACK || type == UAVTALK_TYPE_OBJ_ACK_TS) { if (instId == UAVOBJ_ALL_INSTANCES) { // Get number of instances numInst = UAVObjGetNumInstances(obj); // Send all instances in reverse order // This allows the receiver to detect when the last object has been received (i.e. when instance 0 is received) ret = 0; for (n = 0; n < numInst; ++n) { if (sendSingleObject(connection, type, objId, numInst - n - 1, obj) == -1) { ret = -1; break; } } } else { ret = sendSingleObject(connection, type, objId, instId, obj); } } else if (type == UAVTALK_TYPE_OBJ_REQ) { ret = sendSingleObject(connection, type, objId, instId, obj); } else if (type == UAVTALK_TYPE_ACK || type == UAVTALK_TYPE_NACK) { if (instId != UAVOBJ_ALL_INSTANCES) { ret = sendSingleObject(connection, type, objId, instId, obj); } } return ret; } /** * Send an object through the telemetry link. * \param[in] connection UAVTalkConnection to be used * \param[in] type Transaction type * \param[in] objId The object ID * \param[in] instId The instance ID (can NOT be UAVOBJ_ALL_INSTANCES, use () instead) * \param[in] obj Object handle to send (null when type is NACK) * \return 0 Success * \return -1 Failure */ static int32_t sendSingleObject(UAVTalkConnectionData *connection, uint8_t type, uint32_t objId, uint16_t instId, UAVObjHandle obj) { // IMPORTANT : obj can be null (when type is NACK for example) if (!connection->outStream) { connection->stats.txErrors++; return -1; } // Setup sync byte connection->txBuffer[0] = UAVTALK_SYNC_VAL; // Setup type connection->txBuffer[1] = type; // next 2 bytes are reserved for data length (inserted here later) // Setup object ID connection->txBuffer[4] = (uint8_t)(objId & 0xFF); connection->txBuffer[5] = (uint8_t)((objId >> 8) & 0xFF); connection->txBuffer[6] = (uint8_t)((objId >> 16) & 0xFF); connection->txBuffer[7] = (uint8_t)((objId >> 24) & 0xFF); // Setup instance ID connection->txBuffer[8] = (uint8_t)(instId & 0xFF); connection->txBuffer[9] = (uint8_t)((instId >> 8) & 0xFF); int32_t headerLength = 10; // Add timestamp when the transaction type is appropriate if (type & UAVTALK_TIMESTAMPED) { portTickType time = xTaskGetTickCount(); connection->txBuffer[10] = (uint8_t)(time & 0xFF); connection->txBuffer[11] = (uint8_t)((time >> 8) & 0xFF); headerLength += 2; } // Determine data length int32_t length; if (type == UAVTALK_TYPE_OBJ_REQ || type == UAVTALK_TYPE_ACK || type == UAVTALK_TYPE_NACK) { length = 0; } else { length = UAVObjGetNumBytes(obj); } // Check length if (length > UAVOBJECTS_LARGEST) { connection->stats.txErrors++; return -1; } // Copy data (if any) if (length > 0) { if (UAVObjPack(obj, instId, &connection->txBuffer[headerLength]) == -1) { connection->stats.txErrors++; return -1; } } // Store the packet length connection->txBuffer[2] = (uint8_t)((headerLength + length) & 0xFF); connection->txBuffer[3] = (uint8_t)(((headerLength + length) >> 8) & 0xFF); // Calculate and store checksum connection->txBuffer[headerLength + length] = PIOS_CRC_updateCRC(0, connection->txBuffer, headerLength + length); // Send object uint16_t tx_msg_len = headerLength + length + UAVTALK_CHECKSUM_LENGTH; int32_t rc = (*connection->outStream)(connection->txBuffer, tx_msg_len); // Update stats if (rc == tx_msg_len) { ++connection->stats.txObjects; connection->stats.txObjectBytes += length; connection->stats.txBytes += tx_msg_len; } else { connection->stats.txErrors++; // TDOD rc == -1 connection not open, -2 buffer full should retry connection->stats.txBytes += (rc > 0) ? rc : 0; return -1; } // Done return 0; } /** * @} * @} */