#ifndef _MAVLINK_HELPERS_H_ #define _MAVLINK_HELPERS_H_ #include "string.h" #include "checksum.h" #include "mavlink_types.h" #ifndef MAVLINK_HELPER #define MAVLINK_HELPER #endif /* internal function to give access to the channel status for each channel */ MAVLINK_HELPER mavlink_status_t* mavlink_get_channel_status(uint8_t chan) { static mavlink_status_t m_mavlink_status[MAVLINK_COMM_NUM_BUFFERS]; return &m_mavlink_status[chan]; } /** * @brief Finalize a MAVLink message with channel assignment * * This function calculates the checksum and sets length and aircraft id correctly. * It assumes that the message id and the payload are already correctly set. This function * can also be used if the message header has already been written before (as in mavlink_msg_xxx_pack * instead of mavlink_msg_xxx_pack_headerless), it just introduces little extra overhead. * * @param msg Message to finalize * @param system_id Id of the sending (this) system, 1-127 * @param length Message length */ #if MAVLINK_CRC_EXTRA MAVLINK_HELPER uint16_t mavlink_finalize_message_chan(mavlink_message_t* msg, uint8_t system_id, uint8_t component_id, uint8_t chan, uint8_t length, uint8_t crc_extra) #else MAVLINK_HELPER uint16_t mavlink_finalize_message_chan(mavlink_message_t* msg, uint8_t system_id, uint8_t component_id, uint8_t chan, uint8_t length) #endif { // This code part is the same for all messages; uint16_t checksum; msg->magic = MAVLINK_STX; msg->len = length; msg->sysid = system_id; msg->compid = component_id; // One sequence number per component msg->seq = mavlink_get_channel_status(chan)->current_tx_seq; mavlink_get_channel_status(chan)->current_tx_seq = mavlink_get_channel_status(chan)->current_tx_seq+1; checksum = crc_calculate((uint8_t*)&msg->len, length + MAVLINK_CORE_HEADER_LEN); #if MAVLINK_CRC_EXTRA crc_accumulate(crc_extra, &checksum); #endif mavlink_ck_a(msg) = (uint8_t)(checksum & 0xFF); mavlink_ck_b(msg) = (uint8_t)(checksum >> 8); return length + MAVLINK_NUM_NON_PAYLOAD_BYTES; } /** * @brief Finalize a MAVLink message with MAVLINK_COMM_0 as default channel */ #if MAVLINK_CRC_EXTRA MAVLINK_HELPER uint16_t mavlink_finalize_message(mavlink_message_t* msg, uint8_t system_id, uint8_t component_id, uint8_t length, uint8_t crc_extra) { return mavlink_finalize_message_chan(msg, system_id, component_id, MAVLINK_COMM_0, length, crc_extra); } #else MAVLINK_HELPER uint16_t mavlink_finalize_message(mavlink_message_t* msg, uint8_t system_id, uint8_t component_id, uint8_t length) { return mavlink_finalize_message_chan(msg, system_id, component_id, MAVLINK_COMM_0, length); } #endif #ifdef MAVLINK_USE_CONVENIENCE_FUNCTIONS MAVLINK_HELPER void _mavlink_send_uart(mavlink_channel_t chan, const char *buf, uint16_t len); /** * @brief Finalize a MAVLink message with channel assignment and send */ #if MAVLINK_CRC_EXTRA MAVLINK_HELPER void _mav_finalize_message_chan_send(mavlink_channel_t chan, uint8_t msgid, const char *packet, uint8_t length, uint8_t crc_extra) #else MAVLINK_HELPER void _mav_finalize_message_chan_send(mavlink_channel_t chan, uint8_t msgid, const char *packet, uint8_t length) #endif { uint16_t checksum; uint8_t buf[MAVLINK_NUM_HEADER_BYTES]; uint8_t ck[2]; mavlink_status_t *status = mavlink_get_channel_status(chan); buf[0] = MAVLINK_STX; buf[1] = length; buf[2] = status->current_tx_seq; buf[3] = mavlink_system.sysid; buf[4] = mavlink_system.compid; buf[5] = msgid; status->current_tx_seq++; checksum = crc_calculate((uint8_t*)&buf[1], MAVLINK_CORE_HEADER_LEN); crc_accumulate_buffer(&checksum, packet, length); #if MAVLINK_CRC_EXTRA crc_accumulate(crc_extra, &checksum); #endif ck[0] = (uint8_t)(checksum & 0xFF); ck[1] = (uint8_t)(checksum >> 8); MAVLINK_START_UART_SEND(chan, MAVLINK_NUM_NON_PAYLOAD_BYTES + (uint16_t)length); _mavlink_send_uart(chan, (const char *)buf, MAVLINK_NUM_HEADER_BYTES); _mavlink_send_uart(chan, packet, length); _mavlink_send_uart(chan, (const char *)ck, 2); MAVLINK_END_UART_SEND(chan, MAVLINK_NUM_NON_PAYLOAD_BYTES + (uint16_t)length); } #endif // MAVLINK_USE_CONVENIENCE_FUNCTIONS /** * @brief Pack a message to send it over a serial byte stream */ MAVLINK_HELPER uint16_t mavlink_msg_to_send_buffer(uint8_t *buffer, const mavlink_message_t *msg) { memcpy(buffer, (uint8_t *)&msg->magic, MAVLINK_NUM_NON_PAYLOAD_BYTES + (uint16_t)msg->len); return MAVLINK_NUM_NON_PAYLOAD_BYTES + (uint16_t)msg->len; } union __mavlink_bitfield { uint8_t uint8; int8_t int8; uint16_t uint16; int16_t int16; uint32_t uint32; int32_t int32; }; MAVLINK_HELPER void mavlink_start_checksum(mavlink_message_t* msg) { crc_init(&msg->checksum); } MAVLINK_HELPER void mavlink_update_checksum(mavlink_message_t* msg, uint8_t c) { crc_accumulate(c, &msg->checksum); } /** * This is a convenience function which handles the complete MAVLink parsing. * the function will parse one byte at a time and return the complete packet once * it could be successfully decoded. Checksum and other failures will be silently * ignored. * * @param chan ID of the current channel. This allows to parse different channels with this function. * a channel is not a physical message channel like a serial port, but a logic partition of * the communication streams in this case. COMM_NB is the limit for the number of channels * on MCU (e.g. ARM7), while COMM_NB_HIGH is the limit for the number of channels in Linux/Windows * @param c The char to barse * * @param returnMsg NULL if no message could be decoded, the message data else * @return 0 if no message could be decoded, 1 else * * A typical use scenario of this function call is: * * @code * #include // For fixed-width uint8_t type * * mavlink_message_t msg; * int chan = 0; * * * while(serial.bytesAvailable > 0) * { * uint8_t byte = serial.getNextByte(); * if (mavlink_parse_char(chan, byte, &msg)) * { * printf("Received message with ID %d, sequence: %d from component %d of system %d", msg.msgid, msg.seq, msg.compid, msg.sysid); * } * } * * * @endcode */ MAVLINK_HELPER uint8_t mavlink_parse_char(uint8_t chan, uint8_t c, mavlink_message_t* r_message, mavlink_status_t* r_mavlink_status) { static mavlink_message_t m_mavlink_message[MAVLINK_COMM_NUM_BUFFERS]; /* default message crc function. You can override this per-system to put this data in a different memory segment */ #if MAVLINK_CRC_EXTRA #ifndef MAVLINK_MESSAGE_CRC static const uint8_t mavlink_message_crcs[256] = MAVLINK_MESSAGE_CRCS; #define MAVLINK_MESSAGE_CRC(msgid) mavlink_message_crcs[msgid] #endif #endif mavlink_message_t* rxmsg = &m_mavlink_message[chan]; ///< The currently decoded message mavlink_status_t* status = mavlink_get_channel_status(chan); ///< The current decode status int bufferIndex = 0; status->msg_received = 0; switch (status->parse_state) { case MAVLINK_PARSE_STATE_UNINIT: case MAVLINK_PARSE_STATE_IDLE: if (c == MAVLINK_STX) { status->parse_state = MAVLINK_PARSE_STATE_GOT_STX; rxmsg->len = 0; mavlink_start_checksum(rxmsg); } break; case MAVLINK_PARSE_STATE_GOT_STX: if (status->msg_received || c > MAVLINK_MAX_PAYLOAD_LEN) { status->buffer_overrun++; status->parse_error++; status->msg_received = 0; status->parse_state = MAVLINK_PARSE_STATE_IDLE; } else { // NOT counting STX, LENGTH, SEQ, SYSID, COMPID, MSGID, CRC1 and CRC2 rxmsg->len = c; status->packet_idx = 0; mavlink_update_checksum(rxmsg, c); status->parse_state = MAVLINK_PARSE_STATE_GOT_LENGTH; } break; case MAVLINK_PARSE_STATE_GOT_LENGTH: rxmsg->seq = c; mavlink_update_checksum(rxmsg, c); status->parse_state = MAVLINK_PARSE_STATE_GOT_SEQ; break; case MAVLINK_PARSE_STATE_GOT_SEQ: rxmsg->sysid = c; mavlink_update_checksum(rxmsg, c); status->parse_state = MAVLINK_PARSE_STATE_GOT_SYSID; break; case MAVLINK_PARSE_STATE_GOT_SYSID: rxmsg->compid = c; mavlink_update_checksum(rxmsg, c); status->parse_state = MAVLINK_PARSE_STATE_GOT_COMPID; break; case MAVLINK_PARSE_STATE_GOT_COMPID: rxmsg->msgid = c; mavlink_update_checksum(rxmsg, c); if (rxmsg->len == 0) { status->parse_state = MAVLINK_PARSE_STATE_GOT_PAYLOAD; } else { status->parse_state = MAVLINK_PARSE_STATE_GOT_MSGID; } break; case MAVLINK_PARSE_STATE_GOT_MSGID: _MAV_PAYLOAD(rxmsg)[status->packet_idx++] = (char)c; mavlink_update_checksum(rxmsg, c); if (status->packet_idx == rxmsg->len) { status->parse_state = MAVLINK_PARSE_STATE_GOT_PAYLOAD; } break; case MAVLINK_PARSE_STATE_GOT_PAYLOAD: #if MAVLINK_CRC_EXTRA mavlink_update_checksum(rxmsg, MAVLINK_MESSAGE_CRC(rxmsg->msgid)); #endif if (c != (rxmsg->checksum & 0xFF)) { // Check first checksum byte status->parse_error++; status->msg_received = 0; status->parse_state = MAVLINK_PARSE_STATE_IDLE; if (c == MAVLINK_STX) { status->parse_state = MAVLINK_PARSE_STATE_GOT_STX; rxmsg->len = 0; mavlink_start_checksum(rxmsg); } } else { status->parse_state = MAVLINK_PARSE_STATE_GOT_CRC1; } break; case MAVLINK_PARSE_STATE_GOT_CRC1: if (c != (rxmsg->checksum >> 8)) { // Check second checksum byte status->parse_error++; status->msg_received = 0; status->parse_state = MAVLINK_PARSE_STATE_IDLE; if (c == MAVLINK_STX) { status->parse_state = MAVLINK_PARSE_STATE_GOT_STX; rxmsg->len = 0; mavlink_start_checksum(rxmsg); } } else { // Successfully got message status->msg_received = 1; status->parse_state = MAVLINK_PARSE_STATE_IDLE; memcpy(r_message, rxmsg, sizeof(mavlink_message_t)); } break; } bufferIndex++; // If a message has been sucessfully decoded, check index if (status->msg_received == 1) { //while(status->current_seq != rxmsg->seq) //{ // status->packet_rx_drop_count++; // status->current_seq++; //} status->current_rx_seq = rxmsg->seq; // Initial condition: If no packet has been received so far, drop count is undefined if (status->packet_rx_success_count == 0) status->packet_rx_drop_count = 0; // Count this packet as received status->packet_rx_success_count++; } r_mavlink_status->current_rx_seq = status->current_rx_seq+1; r_mavlink_status->packet_rx_success_count = status->packet_rx_success_count; r_mavlink_status->packet_rx_drop_count = status->parse_error; status->parse_error = 0; return status->msg_received; } /** * @brief Put a bitfield of length 1-32 bit into the buffer * * @param b the value to add, will be encoded in the bitfield * @param bits number of bits to use to encode b, e.g. 1 for boolean, 2, 3, etc. * @param packet_index the position in the packet (the index of the first byte to use) * @param bit_index the position in the byte (the index of the first bit to use) * @param buffer packet buffer to write into * @return new position of the last used byte in the buffer */ MAVLINK_HELPER uint8_t put_bitfield_n_by_index(int32_t b, uint8_t bits, uint8_t packet_index, uint8_t bit_index, uint8_t* r_bit_index, uint8_t* buffer) { uint16_t bits_remain = bits; // Transform number into network order int32_t v; uint8_t i_bit_index, i_byte_index, curr_bits_n; #if MAVLINK_NEED_BYTE_SWAP union { int32_t i; uint8_t b[4]; } bin, bout; bin.i = b; bout.b[0] = bin.b[3]; bout.b[1] = bin.b[2]; bout.b[2] = bin.b[1]; bout.b[3] = bin.b[0]; v = bout.i; #else v = b; #endif // buffer in // 01100000 01000000 00000000 11110001 // buffer out // 11110001 00000000 01000000 01100000 // Existing partly filled byte (four free slots) // 0111xxxx // Mask n free bits // 00001111 = 2^0 + 2^1 + 2^2 + 2^3 = 2^n - 1 // = ((uint32_t)(1 << n)) - 1; // = 2^n - 1 // Shift n bits into the right position // out = in >> n; // Mask and shift bytes i_bit_index = bit_index; i_byte_index = packet_index; if (bit_index > 0) { // If bits were available at start, they were available // in the byte before the current index i_byte_index--; } // While bits have not been packed yet while (bits_remain > 0) { // Bits still have to be packed // there can be more than 8 bits, so // we might have to pack them into more than one byte // First pack everything we can into the current 'open' byte //curr_bits_n = bits_remain << 3; // Equals bits_remain mod 8 //FIXME if (bits_remain <= (uint8_t)(8 - i_bit_index)) { // Enough space curr_bits_n = (uint8_t)bits_remain; } else { curr_bits_n = (8 - i_bit_index); } // Pack these n bits into the current byte // Mask out whatever was at that position with ones (xxx11111) buffer[i_byte_index] &= (0xFF >> (8 - curr_bits_n)); // Put content to this position, by masking out the non-used part buffer[i_byte_index] |= ((0x00 << curr_bits_n) & v); // Increment the bit index i_bit_index += curr_bits_n; // Now proceed to the next byte, if necessary bits_remain -= curr_bits_n; if (bits_remain > 0) { // Offer another 8 bits / one byte i_byte_index++; i_bit_index = 0; } } *r_bit_index = i_bit_index; // If a partly filled byte is present, mark this as consumed if (i_bit_index != 7) i_byte_index++; return i_byte_index - packet_index; } #ifdef MAVLINK_USE_CONVENIENCE_FUNCTIONS // To make MAVLink work on your MCU, define comm_send_ch() if you wish // to send 1 byte at a time, or MAVLINK_SEND_UART_BYTES() to send a // whole packet at a time /* #include "mavlink_types.h" void comm_send_ch(mavlink_channel_t chan, uint8_t ch) { if (chan == MAVLINK_COMM_0) { uart0_transmit(ch); } if (chan == MAVLINK_COMM_1) { uart1_transmit(ch); } } */ MAVLINK_HELPER void _mavlink_send_uart(mavlink_channel_t chan, const char *buf, uint16_t len) { #ifdef MAVLINK_SEND_UART_BYTES /* this is the more efficient approach, if the platform defines it */ MAVLINK_SEND_UART_BYTES(chan, (uint8_t *)buf, len); #else /* fallback to one byte at a time */ uint16_t i; for (i = 0; i < len; i++) { comm_send_ch(chan, (uint8_t)buf[i]); } #endif } #endif // MAVLINK_USE_CONVENIENCE_FUNCTIONS #endif /* _MAVLINK_HELPERS_H_ */