// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: -*- nil -*- #include #if CONFIG_HAL_BOARD == HAL_BOARD_LINUX #include "UARTDriver.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../AP_HAL/utility/RingBuffer.h" extern const AP_HAL::HAL& hal; using namespace Linux; LinuxUARTDriver::LinuxUARTDriver(bool default_console) : device_path(NULL), _rd_fd(-1), _wr_fd(-1), _packetise(false), _flow_control(FLOW_CONTROL_DISABLE) { if (default_console) { _rd_fd = 0; _wr_fd = 1; _console = true; } } /* set the tty device to use for this UART */ void LinuxUARTDriver::set_device_path(char *path) { device_path = path; } /* open the tty */ void LinuxUARTDriver::begin(uint32_t b) { begin(b, 0, 0); } void LinuxUARTDriver::begin(uint32_t b, uint16_t rxS, uint16_t txS) { if (device_path == NULL && _console) { _rd_fd = 0; _wr_fd = 1; fcntl(_rd_fd, F_SETFL, fcntl(_rd_fd, F_GETFL, 0) | O_NONBLOCK); fcntl(_wr_fd, F_SETFL, fcntl(_wr_fd, F_GETFL, 0) | O_NONBLOCK); } else if (!_initialised) { if (device_path == NULL) { return; } switch (_parseDevicePath(device_path)){ case DEVICE_TCP: { _connected = false; if (_flag != NULL){ if (!strcmp(_flag, "wait")){ _tcp_start_connection(true); } else { _tcp_start_connection(false); } } else { _tcp_start_connection(false); } if (!_connected) { ::printf("LinuxUARTDriver TCP connection not established\n"); exit(1); } _flow_control = FLOW_CONTROL_ENABLE; break; } case DEVICE_UDP: { _udp_start_connection(); _flow_control = FLOW_CONTROL_ENABLE; break; } case DEVICE_SERIAL: { _rd_fd = open(device_path, O_RDWR); _wr_fd = _rd_fd; if (_rd_fd == -1) { ::fprintf(stdout, "Failed to open UART device %s - %s\n", device_path, strerror(errno)); return; } // always run the file descriptor non-blocking, and deal with // blocking IO in the higher level calls fcntl(_rd_fd, F_SETFL, fcntl(_rd_fd, F_GETFL, 0) | O_NONBLOCK); // TODO: add proper flow control support _flow_control = FLOW_CONTROL_DISABLE; break; } default: { // Notify that the option is not valid and select standart input and output ::printf("LinuxUARTDriver parsing failed, using default\n"); _rd_fd = 0; _wr_fd = 1; fcntl(_rd_fd, F_SETFL, fcntl(_rd_fd, F_GETFL, 0) | O_NONBLOCK); fcntl(_wr_fd, F_SETFL, fcntl(_wr_fd, F_GETFL, 0) | O_NONBLOCK); break; } } } // we have enough memory to have a larger transmit buffer for // all ports. This means we don't get delays while waiting to // write GPS config packets if (rxS < 1024) { rxS = 8192; } if (txS < 8192) { txS = 8192; } _initialised = false; while (_in_timer) hal.scheduler->delay(1); if (b != 0 && _rd_fd == _wr_fd) { // set the baud rate struct termios t; memset(&t, 0, sizeof(t)); tcgetattr(_rd_fd, &t); cfsetspeed(&t, b); // disable LF -> CR/LF t.c_iflag &= ~(BRKINT | ICRNL | IMAXBEL | IXON | IXOFF); t.c_oflag &= ~(OPOST | ONLCR); t.c_lflag &= ~(ISIG | ICANON | IEXTEN | ECHO | ECHOE | ECHOK | ECHOCTL | ECHOKE); t.c_cc[VMIN] = 0; tcsetattr(_rd_fd, TCSANOW, &t); } /* allocate the read buffer */ if (rxS != 0 && rxS != _readbuf_size) { _readbuf_size = rxS; if (_readbuf != NULL) { free(_readbuf); } _readbuf = (uint8_t *)malloc(_readbuf_size); _readbuf_head = 0; _readbuf_tail = 0; } /* allocate the write buffer */ if (txS != 0 && txS != _writebuf_size) { _writebuf_size = txS; if (_writebuf != NULL) { free(_writebuf); } _writebuf = (uint8_t *)malloc(_writebuf_size); _writebuf_head = 0; _writebuf_tail = 0; } if (_writebuf_size != 0 && _readbuf_size != 0) { _initialised = true; } } /* Device path accepts the following syntaxes: - /dev/ttyO1 - tcp:*:1243:wait - udp:192.168.2.15:1243 */ LinuxUARTDriver::device_type LinuxUARTDriver::_parseDevicePath(const char *arg) { struct stat st; _flag = NULL; // init flag char *devstr = strdup(arg); if (devstr == NULL) { return DEVICE_UNKNOWN; } if (stat(devstr, &st) == 0 && S_ISCHR(st.st_mode)) { free(devstr); return DEVICE_SERIAL; } else if (strncmp(devstr, "tcp:", 4) == 0 || strncmp(devstr, "udp:", 4) == 0) { char *saveptr = NULL; // Parse the string char *protocol, *ip, *port, *flag; protocol = strtok_r(devstr, ":", &saveptr); ip = strtok_r(NULL, ":", &saveptr); port = strtok_r(NULL, ":", &saveptr); flag = strtok_r(NULL, ":", &saveptr); _base_port = (uint16_t) atoi(port); if (_ip) free(_ip); _ip = NULL; if (ip) { _ip = strdup(ip); } if (_flag) free(_flag); _flag = NULL; if (flag) { _flag = strdup(flag); } if (strcmp(protocol, "udp") == 0) { free(devstr); return DEVICE_UDP; } free(devstr); return DEVICE_TCP; } free(devstr); return DEVICE_UNKNOWN; } /* start a TCP connection for the serial port. If wait_for_connection is true then block until a client connects */ void LinuxUARTDriver::_tcp_start_connection(bool wait_for_connection) { int one=1; struct sockaddr_in sockaddr; int ret; int listen_fd = -1; // socket we are listening on int net_fd = -1; // network file descriptor, will be linked to wr_fd and rd_fd uint8_t portNumber = 0; // connecto to _base_port + portNumber if (net_fd != -1) { close(net_fd); } if (listen_fd == -1) { memset(&sockaddr,0,sizeof(sockaddr)); #ifdef HAVE_SOCK_SIN_LEN sockaddr.sin_len = sizeof(sockaddr); #endif sockaddr.sin_port = htons(_base_port + portNumber); sockaddr.sin_family = AF_INET; if (strcmp(_ip, "*") == 0) { // Bind to all interfaces sockaddr.sin_addr.s_addr = htonl(INADDR_ANY); } else { sockaddr.sin_addr.s_addr = inet_addr(_ip); } listen_fd = socket(AF_INET, SOCK_STREAM, 0); if (listen_fd == -1) { ::printf("socket failed - %s\n", strerror(errno)); exit(1); } /* we want to be able to re-use ports quickly */ setsockopt(listen_fd, SOL_SOCKET, SO_REUSEADDR, &one, sizeof(one)); if (!wait_for_connection) { ret = connect(listen_fd, (struct sockaddr *)&sockaddr, sizeof(sockaddr)); if (ret < 0) { ::printf("connect failed on port %u - %s\n", (unsigned)ntohs(sockaddr.sin_port), strerror(errno)); exit(1); } fcntl(listen_fd, F_SETFL, fcntl(listen_fd, F_GETFL, 0) | O_NONBLOCK); _rd_fd = listen_fd; _connected = true; ::printf("Serial port %u on TCP port %u\n", portNumber, _base_port + portNumber); fflush(stdout); } else { ret = bind(listen_fd, (struct sockaddr *)&sockaddr, sizeof(sockaddr)); if (ret == -1) { ::printf("bind failed on port %u - %s\n", (unsigned)ntohs(sockaddr.sin_port), strerror(errno)); exit(1); } ret = listen(listen_fd, 5); if (ret == -1) { ::printf("listen failed - %s\n", strerror(errno)); exit(1); } ::printf("Serial port %u on TCP port %u\n", portNumber, _base_port + portNumber); ::fflush(stdout); ::printf("Waiting for connection ....\n"); ::fflush(stdout); net_fd = accept(listen_fd, NULL, NULL); if (net_fd == -1) { ::printf("accept() error - %s", strerror(errno)); exit(1); } setsockopt(net_fd, SOL_SOCKET, SO_REUSEADDR, &one, sizeof(one)); setsockopt(net_fd, IPPROTO_TCP, TCP_NODELAY, &one, sizeof(one)); // always run the file descriptor non-blocking, and deal with | // blocking IO in the higher level calls fcntl(net_fd, F_SETFL, fcntl(net_fd, F_GETFL, 0) | O_NONBLOCK); _connected = true; _rd_fd = net_fd; _wr_fd = net_fd; } } } /* start a UDP connection for the serial port */ void LinuxUARTDriver::_udp_start_connection(void) { struct sockaddr_in sockaddr; int ret; memset(&sockaddr,0,sizeof(sockaddr)); #ifdef HAVE_SOCK_SIN_LEN sockaddr.sin_len = sizeof(sockaddr); #endif sockaddr.sin_port = htons(_base_port); sockaddr.sin_family = AF_INET; sockaddr.sin_addr.s_addr = inet_addr(_ip); _rd_fd = socket(AF_INET, SOCK_DGRAM, 0); if (_rd_fd == -1) { ::printf("socket failed - %s\n", strerror(errno)); exit(1); } ret = connect(_rd_fd, (struct sockaddr *)&sockaddr, sizeof(sockaddr)); if (ret == -1) { ::printf("connect failed to %s:%u - %s\n", _ip, (unsigned)_base_port, strerror(errno)); exit(1); } // always run the file descriptor non-blocking, and deal with | // blocking IO in the higher level calls fcntl(_rd_fd, F_SETFL, fcntl(_rd_fd, F_GETFL, 0) | O_NONBLOCK); _wr_fd = _rd_fd; // try to write on MAVLink packet boundaries if possible _packetise = true; } /* shutdown a UART */ void LinuxUARTDriver::end() { _initialised = false; _connected = false; while (_in_timer) hal.scheduler->delay(1); if (_rd_fd == _wr_fd && _rd_fd != -1) { close(_rd_fd); } _rd_fd = -1; _wr_fd = -1; if (_readbuf) { free(_readbuf); _readbuf = NULL; } if (_writebuf) { free(_writebuf); _writebuf = NULL; } _readbuf_size = _writebuf_size = 0; _writebuf_head = 0; _writebuf_tail = 0; _readbuf_head = 0; _readbuf_tail = 0; } void LinuxUARTDriver::flush() { // we are not doing any buffering, so flush is a no-op } /* return true if the UART is initialised */ bool LinuxUARTDriver::is_initialized() { return _initialised; } /* enable or disable blocking writes */ void LinuxUARTDriver::set_blocking_writes(bool blocking) { _nonblocking_writes = !blocking; } /* do we have any bytes pending transmission? */ bool LinuxUARTDriver::tx_pending() { return !BUF_EMPTY(_writebuf); } /* return the number of bytes available to be read */ int16_t LinuxUARTDriver::available() { if (!_initialised) { return 0; } uint16_t _tail; return BUF_AVAILABLE(_readbuf); } /* how many bytes are available in the output buffer? */ int16_t LinuxUARTDriver::txspace() { if (!_initialised) { return 0; } uint16_t _head; return BUF_SPACE(_writebuf); } int16_t LinuxUARTDriver::read() { uint8_t c; if (!_initialised || _readbuf == NULL) { return -1; } if (BUF_EMPTY(_readbuf)) { return -1; } c = _readbuf[_readbuf_head]; BUF_ADVANCEHEAD(_readbuf, 1); return c; } /* Linux implementations of Print virtual methods */ size_t LinuxUARTDriver::write(uint8_t c) { if (!_initialised) { return 0; } uint16_t _head; while (BUF_SPACE(_writebuf) == 0) { if (_nonblocking_writes) { return 0; } hal.scheduler->delay(1); } _writebuf[_writebuf_tail] = c; BUF_ADVANCETAIL(_writebuf, 1); return 1; } /* write size bytes to the write buffer */ size_t LinuxUARTDriver::write(const uint8_t *buffer, size_t size) { if (!_initialised) { return 0; } if (!_nonblocking_writes) { /* use the per-byte delay loop in write() above for blocking writes */ size_t ret = 0; while (size--) { if (write(*buffer++) != 1) break; ret++; } return ret; } uint16_t _head, space; space = BUF_SPACE(_writebuf); if (space == 0) { return 0; } if (size > space) { size = space; } if (_writebuf_tail < _head) { // perform as single memcpy assert(_writebuf_tail+size <= _writebuf_size); memcpy(&_writebuf[_writebuf_tail], buffer, size); BUF_ADVANCETAIL(_writebuf, size); return size; } // perform as two memcpy calls uint16_t n = _writebuf_size - _writebuf_tail; if (n > size) n = size; assert(_writebuf_tail+n <= _writebuf_size); memcpy(&_writebuf[_writebuf_tail], buffer, n); BUF_ADVANCETAIL(_writebuf, n); buffer += n; n = size - n; if (n > 0) { assert(_writebuf_tail+n <= _writebuf_size); memcpy(&_writebuf[_writebuf_tail], buffer, n); BUF_ADVANCETAIL(_writebuf, n); } return size; } /* try writing n bytes, handling an unresponsive port */ int LinuxUARTDriver::_write_fd(const uint8_t *buf, uint16_t n) { int ret = 0; struct pollfd fds; fds.fd = _wr_fd; fds.events = POLLOUT; fds.revents = 0; if (poll(&fds, 1, 0) == 1) { ret = ::write(_wr_fd, buf, n); } if (ret > 0) { BUF_ADVANCEHEAD(_writebuf, ret); return ret; } return ret; } /* try reading n bytes, handling an unresponsive port */ int LinuxUARTDriver::_read_fd(uint8_t *buf, uint16_t n) { int ret; ret = ::read(_rd_fd, buf, n); if (ret > 0) { BUF_ADVANCETAIL(_readbuf, ret); } else { switch (errno) { case EAGAIN: /* Ignore EAGAIN that resulted from non-blocking read */ break; case EPIPE: /* Ignore EPIPE that resulted from peer shutdown */ break; default: ::fprintf(stdout, "read failed - %s\n", strerror(errno)); break; } } return ret; } /* push any pending bytes to/from the serial port. This is called at 1kHz in the timer thread. Doing it this way reduces the system call overhead in the main task enormously. */ void LinuxUARTDriver::_timer_tick(void) { uint16_t n; if (!_initialised) return; _in_timer = true; // write any pending bytes uint16_t _tail; n = BUF_AVAILABLE(_writebuf); if (_packetise && n > 0 && _writebuf[_writebuf_head] == 254) { // this looks like a MAVLink packet - try to write on // packet boundaries when possible if (n < 8) { n = 0; } else { // the length of the packet is the 2nd byte, and mavlink // packets have a 6 byte header plus 2 byte checksum, // giving len+8 bytes uint16_t ofs = (_writebuf_head + 1) % _writebuf_size; uint8_t len = _writebuf[ofs]; if (n < len+8) { // we don't have a full packet yet n = 0; } else if (n > len+8) { // send just 1 packet at a time (so MAVLink packets // are aligned on UDP boundaries) n = len+8; } } } if (n > 0) { uint16_t n1 = _writebuf_size - _writebuf_head; if (n1 >= n) { // do as a single write _write_fd(&_writebuf[_writebuf_head], n); } else { // split into two writes if (_packetise) { // keep as a single UDP packet uint8_t tmpbuf[n]; memcpy(tmpbuf, &_writebuf[_writebuf_head], n1); if (n > n1) { memcpy(&tmpbuf[n1], &_writebuf[0], n-n1); } _write_fd(tmpbuf, n); } else { int ret = _write_fd(&_writebuf[_writebuf_head], n1); if (ret == n1 && n > n1) { _write_fd(&_writebuf[_writebuf_head], n - n1); } } } } // try to fill the read buffer uint16_t _head; n = BUF_SPACE(_readbuf); if (n > 0) { uint16_t n1 = _readbuf_size - _readbuf_tail; if (n1 >= n) { // one read will do assert(_readbuf_tail+n <= _readbuf_size); _read_fd(&_readbuf[_readbuf_tail], n); } else { assert(_readbuf_tail+n1 <= _readbuf_size); int ret = _read_fd(&_readbuf[_readbuf_tail], n1); if (ret == n1 && n > n1) { assert(_readbuf_tail+(n-n1) <= _readbuf_size); _read_fd(&_readbuf[_readbuf_tail], n - n1); } } } _in_timer = false; } #endif // CONFIG_HAL_BOARD