Linux Serial Port Programming Mini-Howto
  Antonino Iannella, antonino@usa.net
  Version 1.0, March 9th 1997

  1. Introduction

  This document describes how to program the RS-232 ports for serial
  communications, under PC-Linux. It covers information about
  the serial ports, RS232 connections, modem issues, and the C programming
  logic.

  2. Background
  
  For our final year project, our group had to design a concept World
  Wide Web browser. Our prototype was a hand-held device which plugged
  into a PC's COM2 (25-pin) serial port. The user would issue commands
  to the browser (eg Back, Open, etc) by sending character commands to
  the PC. The browser software would detect it, and perform the required
  operation.
  
  The method provided in the 'Linux I/O port programming mini-HOWTO'
  did not act reliably. Often, an incorrect value would be received.
  The information within provided a 100% reliable, quasi-POSIX-compliant
  approach to communication.
  
  The program provided at the end of this 0 formed the basis of
  the PC's communication program. This document is written from the
  1 needed for the web browser project. It revolves around
  C programming for Linux, for a 9600 baud device attached to COM2.

  3. Acknowledgements
  
  The information here comes mainly from these sources -
    
  Heavily based on the 'Serial Programming Guide for POSIX Compliant 
  Operating Systems', at http://www.easysw.com/~mike/serial/, by
  mike@easysw.com. If you need greater detail or more information, then
  this is the place to visit. Most of the information in this 0
  originated here.
    
  The 'Linux I/O port programming mini-HOWTO', by Riku Saikkonen
  (rjs@spider.compart.fi). This document provides a different approach
  to Linux serial programming.

  'The Linux Serial HOWTO', by Greg Hankins, greg.hankins@cc.gatech.edu
  describes how to set up serial communications devices on a Linux box.
  It describes many aspects of serial devices and 0.
  
  My two wonderful project partners: Gerel Enrile and Joyce Gong.

  4. Copyright
  
  This document is copyright (C) 1997 by Antonino Iannella.
  It is covered under the general Linux HOWTO copyright agreement.
  
  It is intended for the general public. it may be reproduced and
  distributed in whole or in part, using any electronic or physical
  medium. However, this copyright notice must remain on all copies.
  
  Please forward question, suggestions, corrections, and all tidbits
  of information to the author at antonino@usa.net
  (or nettuno@light.iinet.net.au).
  You will be acknowledged in future HOWTO revisions.
  
  5. RS-232 connections
  
  RS-232 is a standard for serial communications. It comes in different
  varieties. The most common is RS-232C which defines a 'mark' bit as a 
  voltage between -3V and -12V, and a 'space' bit as a voltage between 
  +3V and +12V. RS-574 is the standard for 9-pin PC connectors and
  voltages.
  
  RS-232 basically consists of wires for serial communications; sending
  and receiving, timing, status, and handshaking.
  You can use a null modem cable as your connector.
  The following pins are what were used for our project.  We connected
  the device to the DB-25 pin COM2 port. Please note that the Transmit
  line from the PC must connect to the Receive line of the device, and
  vice versa. Also, please note that a parallel port is different to a
  serial port!
  
                          PC's pins   Device's pins
      TxD   Transmit Data         2 - 3       RxD   Receive Data
      RxD   Receive Data          3 - 2       TxD   Transmit Data
      SG    Signal Ground         7 - 7       SG    Signal Ground

  
  Refer to the Linux Serial HOWTO for more specialised connections, and
  detailed RS-232 pins.
  
  6. Serial 0 and RS-232 definitions
  
  The way that data get transmitted in serial communications is, well,
  serially. One data bit is sent at a time. Each bit is either on (or the
  'mark' state), or off (or the 'space' state).
  
  The serial data throughput is usually expressed in bits-per-second (bps)
  or baudot (baud). Throughput is the number of data bits (2 or off) that
  may be sent in a second. Your modem might be able to support 115200 baud.
  The project's web browser device was designed to run at 9600 baud.
  
  RS-232 provides 18 different signals. About 6 are available to UNIX for
  programming.
  
  GND - Logic ground
  
        Very important. Acts as a reference voltage, so the devices know
        the relative voltage of the data transmitted.
        
  TxD - Transmitted data
  
        Carries the data transmitted from your PC.
        A 'mark' voltage is interpreted as 1,
        while a 'space' voltage is interpreted as 0.
        
  RxD - Received data
  
        Carries the data transmitted to your PC from the other device.
        
  DCD - Data carrier detect

        Is sent from the other device to your PC. A 'space' voltage means
        that the device is still connected, or 'on-line'. This signal is
        not always used or available.
        
  DTR - Data terminal ready

        Is sent from your PC to tell the device that you are ready (space)
        or not-ready (mark). DTR is usually enabled automatically whenever
        you access the serial interface.
        
  CTS - Clear to send
  
        Is sent from the other device to your PC. 
        A 'space' voltage means that your PC may send some data.
        It is usually used to regulate the flow of serial data from your
        PC, but it is not currently supported by all UNIX flavours.
        
  RTS - Request to send
  
        Is set to the 'space' voltage by your PC when it requests to send
        more data. It also used to regulate data flow. Many systems leave
        it on 'space' voltage all the time.
        
  7. Communication issues
  
  This section covers other issues of serial communication which might be
  relevant to your particular application.
  Since we are programming for asynchronous communication, we need the 
  PCs/devices to know where each character starts and ends in the serial
  data flow.

  In asynchronous mode, the serial data line stays in the mark state until
  a character is sent. A 'start bit' is sent before each character; it is
  always 0 and tells the PC/device that a character will follow.
  After the start bit, the character's bits are sent, then a 'parity' bit,
  and one or more stop bits.
  
  The parity bit is a checksum of the data bits, indicating the number of
  1 bits it contained -
  
     Even parity  - parity bit is 1 if there is an even number of 1s
     Odd parity   - parity bit is 1 if there is an odd number of 1s
     Space parity - parity bit is always 0
     Mark parity  - parity bit is 1
     No parity    - no parity bit is sent or present.

  'Stop' bits come at the end of every character. There may be 1, 1.5, or 2
  stop bits. They used to be used to give the computer time to process the
  character, but now they are used to synchronise the computer to the
  incoming characters.
  
  Asynchronous data is usually described like '8N1' - 8 data bits, no parity
  bits, 1 stop bit. Another common one is '7N1'.
  
  Flow control is used to regulate the data flow between devices, if there
  is some sort of limitation, such as a slow device. There is 'Software
  Flow Control' using special characters, XON and XOFF, to regulate the flow.
  This method is not useful for transmitting non-textual data.
  'Hardware Flow Control' uses the RTS and CTS signals instead of special
  characters. The receiver sets CTS to space when it is ready to receive,
  and to mark when it's not. The sender uses RTS the same way. This method
  is faster than Software Flow Control, since it uses a separate set of 
  signals instead of extra bits.
  
  Since the receive or transmit signal is at mark voltage until a new character
  is sent. A 'break' condition exists when the line is set to low for 1/4 
  to 1/2 a second. It is used to reset a communications line, or change
  the operation mode of devices like modems.

  8. Basic port programming
  
  Hopefully, all of the above is reasonably clear to you, so you may proceed
  to program with confidence!
  
  In UNIX all system devices are treated as (special) files. All serial ports
  are opened, read from, written to, and closed, just like a binary file.
  In Linux, the PC serial ports are
  
     COM1 - /dev/ttyS0
     COM2 - /dev/ttyS1
     COM3 - /dev/ttyS2
     COM4 - /dev/ttyS3
  
  Firstly, open the serial port as a file. However, UNIX does not allow
  devices to be accessed by normal users. To solve this, either run the
  program as the superuser, or change the permission on the device as root,
  eg
  
     chmod a+rw /dev/ttyS1          (lets everyone access COM2)

  To open the file do the following. Notice the three flags used in the
  open() function. O_RDWR means that we open the port for reading and
  writing. O_NOCTTY specifies that the program won't be the controlling
  entity for the port. Most user programs don't want this feature.
  O_NDELAY means that your program ignores the DCD line. If it didn't,
  the program will be put to sleep until DCD is set to 'space' voltage.
  
  /*
  * 'open_port()' - Open serial port 1 - COM2.
  *
  * Returns the file descriptor on success or -1 on error.
  */

 int open_port(void)
 {
   int fd;                                   /* File descriptor for the port */

   fd = open("/dev/ttyS1", O_RDWR | O_NOCTTY | O_NDELAY);
   if (fd == -1)
   {                                              /* Could not open the port */
     fprintf(stderr, "open_port: Unable to open /dev/ttyS1 - %s\n",
             strerror(errno));
   }

   return (fd);
 }

 If you need to write data to the port, do something like
 
   n = write(fd, "ATZ\r", 4);

   if (n < 0)
      puts("write() of 4 bytes failed!\n");

 Reading from the port is more complicated. If you open the port in 'raw
 data' mode (the norm), each read() returns the number of characters actually
 available in the serial buffers. However, if no characters are available,
 read() will block until it receives characters, an interval timer expires,
 or an error occurs. Use the following to make read return immediately.
 FNDELAY makes read() return 0 if no characters were read.
 
   fcntl(mainfd, F_SETFL, FNDELAY);             /* Configure port reading */
 
 To close the serial port, simply use
 
   close(fd); 
  
 9. Port configuration
 
 This section discusses how to configure the serial port for your device.
 You will need to set the terminal attributes related to the port.
 To do this, include <termios.h> and access the termios structure using the
 POSIX tcgetattr() and tcsetattr() functions.
 
 The termios structure contains
 
   c_cflag - Control options
   c_lflag - Line options
   c_iflag - Input options
   c_oflag - Output options
   c_cc    - Control characters
   
 See section 12 for a list of c_cflag control modes.
 They are used to set the baud rate, parity and stop bits, and flow control.
 Always enable CLOCAL and CREAD, so the program does not own the port, and so
 the serial interface driver will read incoming bytes.
 
 9.1. Accessing the termios structure and the baud rate
 
 Use cfsetospeed() and cfsetispeed() to set the baud rate.
 CRTSCTS might be called CNEW_RTSCTS on other systems.
 The following uses a termios structure called 'options'.
 For our project, the device transmitted at 9600 baud and transmitted nothing
 special.
 
 tcgetattr(mainfd, &options);        /* Get the current options for the port */
 cfsetispeed(&options, B9600);                 /* Set the baud rates to 9600 */
 cfsetospeed(&options, B9600);    
                                   /* Enable the receiver and set local mode */
 options.c_cflag |= (CLOCAL | CREAD);
       
                                        /* Set the new options for the port */
 tcsetattr(mainfd, TCSANOW, &options);

 The tcsetattr() function replaces the port's termios structure with the
 settings you provided. The TCSANOW constant means that the changes should
 occur immediately, without waiting for data transmission to complete.
 Alternative choices are TCSADRAIN and TCSAFLUSH, which wait until buffers
 are cleared. Refer to section 13.
 
 9.2. Character size and parity

 To set the character size, you must use bitwise logic.
 The following code sets the character size to 8 data bits, and no parity.
                         
    options.c_cflag &= ~PARENB;  /* Mask character size to 8 bits, no parity */
    options.c_cflag &= ~CSTOPB;
    options.c_cflag &= ~CSIZE;
    options.c_cflag |=  CS8;                           /* Select 8 data bits */
 
 For other methods, refer to section 11.
 
 9.3. Hardware flow control
 
 To enable hardware flow control, use
 
     options.c_cflag |= CRTSCTS;            /* Enable hardware flow control */  
  
 To disable it,
 
     options.c_cflag &= ~CRTSCTS;          /* Disable hardware flow control */  

 9.4. Canonical and raw input
 
 Canonical input means that all incoming characters are placed in a buffer
 which may be edited by the user, until a carriage return or line feed (CR or
 LF) are received. Typically, you would use
 
  options.c_lflag |= ~(ICANON | ECHO | ECHOE);

 Raw input is unprocessed, so they may be used as they are read.
 Our device sent raw data.

  options.c_lflag &= ~(ICANON | ECHO | ISIG);

 Whether you use canonical or raw input, make sure you never enable input
 echo when connected to a computer/device which is echoing characters to you.
 Refer to section 14 for local mode constants.

 9.5. POSIX input modes
 
 Set the port's input modes for any input processing. 
 Set input parity when you have enabled parity in the c_cflag part.
 Usually you'd use the following to enable parity checking, and strip the
 parity bit off the data, before your program reads it.
  
  options.c_iflag |= (INPCK | ISTRIP);
  
 You might use IGNPAR, which ignores all parity errors. PARMRK marks parity
 errors by inserting a DEL(255) and NUL character before the bad character.
 If IGNPAR is enabled, only a NUL is inserted.
 
 You may set software flow control using
 
  options.c_iflag |= (IXON | IXOFF | IXANY);

 Refer to section 15 for input mode constants.

 9.6. POSIX output modes
 
 To set port output modes, use the c_oflag member.
 To select processed output, use the following. Of all the output modes, you
 will probably only use ONCLR to convert newlines into CR and LFs.
  
  options.c_oflag |= OPOST;
 
 For raw output, use
 
  options.c_oflag &= ~OPOST;

 Refer to section 16 for output mode constants.

 9.7. POSIX control modes
 
 You may set the control characters using the c_cc part.
 Set the software flow control characters in the VSTART and VSTOP
 elements. The standard is DC1(17) and DC3(19) for XON and XOFF.
 VMIN specifies the minimum number of 0 to read. If it is 0, then
 VTIME specifies the time to wait for each character.
 If VMIN is not 0, VTIME is the time to wait to read the first character.
 If the first character is read, then any read() will be blocked until all
 VMIN characters are read.
 VTIME is specified in tenths of seconds. If it is 0, then read()s will
 be permanently blocked unless NDELAY was previously specified with fcntl().

 Refer to section 17 for control mode constants.

 10. Sample program
 
 This program is a skeleton COM2 reader, which was used for our project.
 It did not need all of the information specified above for
 configuring ports. The 20ms delay is used to indicate that data coming into
 the port is buffered, and is available for the next read().
 
 /* Better port reading program
   v1.0
   23-10-96
   
   This test program uses quasi-POSIX compliant UNIX functions to
   open the ABU port and read.
   
   Uses termio functions to initialise the port to 9600 baud, at
   8 data bits, no parity, no hardware flow control,
   and features character buffering.
   The 20ms delay after the port read indicates that characters are
   buffered if a button is pressed many times.
   
   This program was derived from instructions at
    http://www.easysw.com/~mike/serial/
 */

 #include <stdio.h>   /* Standard input/output definitions */
 #include <string.h>  /* String function definitions */
 #include <unistd.h>  /* UNIX standard function definitions */
 #include <fcntl.h>   /* File control definitions */
 #include <errno.h>   /* Error number definitions */
 #include <termios.h> /* POSIX terminal control definitions */

 /*
  * 'open_port()' - Open serial port 1.
  *
  * Returns the file descriptor on success or -1 on error.
  */

 int open_port(void)
 {
   int fd;                                   /* File descriptor for the port */

   fd = open("/dev/ttyS1", O_RDWR | O_NOCTTY | O_NDELAY);

   if (fd == -1)
   {                                              /* Could not open the port */
     fprintf(stderr, "open_port: Unable to open /dev/ttyS1 - %s\n",
             strerror(errno));
   }

   return (fd);
 }

void main()
{
 int mainfd=0;                                            /* File descriptor */
 char chout;
 struct termios options;
   
 mainfd = open_port();

 fcntl(mainfd, F_SETFL, FNDELAY);                  /* Configure port reading */
                                     /* Get the current options for the port */
 tcgetattr(mainfd, &options);
 cfsetispeed(&options, B9600);                 /* Set the baud rates to 9600 */
 cfsetospeed(&options, B9600);
    
                                   /* Enable the receiver and set local mode */
 options.c_cflag |= (CLOCAL | CREAD);
 options.c_cflag &= ~PARENB; /* Mask the character size to 8 bits, no parity */
 options.c_cflag &= ~CSTOPB;
 options.c_cflag &= ~CSIZE;
 options.c_cflag |=  CS8;                              /* Select 8 data bits */
 options.c_cflag &= ~CRTSCTS;               /* Disable hardware flow control */  
 
                                 /* Enable data to be processed as raw input */
 options.c_lflag &= ~(ICANON | ECHO | ISIG);
       
                                        /* Set the new options for the port */
 tcsetattr(mainfd, TCSANOW, &options);
                         
 while (1)
 {
   read(mainfd, &chout, sizeof(chout));          /* Read character from ABU */
   
   if (chout != 0)
      printf("Got %c.\n", chout);

   chout=0;
   usleep(20000);
 }
                                                    /* Close the serial port */
  close(mainfd);
 }

 11. Character and parity settings
 
    No parity (8N1): 

     options.c_cflag &= ~PARENB;
     options.c_cflag &= ~CSTOPB;
     options.c_cflag &= ~CSIZE;
     options.c_cflag |= CS8;

    Even parity (7E1): 

     options.c_cflag |= PARENB;
     options.c_cflag &= ~PARODD;
     options.c_cflag &= ~CSTOPB;
     options.c_cflag &= ~CSIZE;
     options.c_cflag |= CS7;

    Odd parity (7O1): 

     options.c_cflag |= PARENB;
     options.c_cflag |= PARODD;
     options.c_cflag &= ~CSTOPB;
     options.c_cflag &= ~CSIZE;
     options.c_cflag |= CS7;

    Mark parity is simulated by using 2 stop bits (7M1): 

     options.c_cflag &= ~PARENB;
     options.c_cflag |= CSTOPB;
     options.c_cflag &= ~CSIZE;
     options.c_cflag |= CS7;

    Space parity is setup the same as no parity (7S1): 

     options.c_cflag &= ~PARENB;
     options.c_cflag &= ~CSTOPB;
     options.c_cflag &= ~CSIZE;
     options.c_cflag |= CS8;

 12. POSIX control mode flags

 The following table lists the possible control modes for c_cflag.  
   
   Constant     Description
   ________________________
   
   CBAUD        Bit mask for baud rate         
   B0           0 baud (drop DTR)         
   B50          50 baud         
   B75          75 baud         
   B110         110 baud         
   B134         134.5 baud         
   B150         150 baud         
   B200         200 baud         
   B300         300 baud         
   B600         600 baud         
   B1200        1200 baud         
   B1800        1800 baud         
   B2400        2400 baud         
   B4800        4800 baud         
   B9600        9600 baud         
   B19200       19200 baud         
   B38400       38400 baud         
   EXTA         External rate clock         
   EXTB         External rate clock         
   CSIZE        Bit mask for data bits         
   CS5          5 data bits         
   CS6          6 data bits         
   CS7          7 data bits         
   CS8          8 data bits         
   CSTOPB       2 stop bits (1 otherwise)         
   CREAD        Enable receiver         
   PARENB       Enable parity bit         
   PARODD       Use odd parity instead of even         
   HUPCL        Hangup (drop DTR) on last close         
   CLOCAL       Local line - do not change 'owner' of port      
   LOBLK        Block job control output         
   CRTSCTS      Enable hardware flow control (not supported on all platforms)         

 13. POSIX tcsetattr Constants
 
   Constant   Description
   ______________________
   
   TCSANOW    Make changes now without waiting for data to complete
   TCSADRAIN  Wait until everything has been transmitted
   TCSAFLUSH  Flush input and output buffers and make the change

 14. POSIX Local Mode Constants
 
   Constant   Description
   ______________________
   
   ISIG       Enable SIGINTR, SIGSUSP, SIGDSUSP, and SIGQUIT signals
   ICANON     Enable canonical input (else raw)
   XCASE      Map uppercase \lowercase (obselete)
   ECHO       Enable echoing of input characters
   ECHOE      Echo erase character as BS-SP-BS
   ECHOK      Echo NL after kill character
   ECHONL     Echo NL
   NOFLSH     Disable flushing of input buffers after interrupt
              or quit characters
   IEXTEN     Enable extended functions
   ECHOCTL    Echo control characters as ^char and delete as ~?
   ECHOPRT    Echo erased character as character erased
   ECHOKE     BS-SP-BS entire line on line kill
   FLUSHO     Output being flushed
   PENDIN     Retype pending input at next read or input char
   TOSTOP     Send SIGTTOU for background output

 15. POSIX Input Mode Constants

   Constant   Description
   ______________________
   
   INPCK      Enable parity check
   IGNPAR     Ignore parity errors
   PARMRK     Mark parity errors
   ISTRIP     Strip parity bits
   IXON       Enable software flow control (outgoing)
   IXOFF      Enable software flow control (incoming)
   IXANY      Allow any character to start flow again
   IGNBRK     Ignore break condition
   BRKINT     Send a SIGINT when a break condition is detected
   INLCR      Map NL to CR
   IGNCR      Ignore CR
   ICRNL      Map CR to NL
   IUCLC      Map uppercase to lowercase
   IMAXBEL    Echo BEL on input line too long

 16. POSIX Output Mode Constants

   Constant   Description
   ______________________
   
   OPOST      Postprocess output (not set = raw output)
   OLCUC      Map lowercase to uppercase
   ONLCR      Map NL to CR-NL
   OCRNL      Map CR to NL
   NOCR       No CR output at column 0
   ONLRET     NL performs CR function
   OFILL      Use fill characters for delay
   OFDEL      Fill character is DEL
   NLDLY      Mask for delay time needed between lines
   NL0        No delay for NLs
   NL1        Delay further output after newline for 100 milliseconds
   CRDLY      Mask for delay time needed to return carriage to left column
   CR0        No delay for CRs
   CR1        Delay after CRs depending on current column position
   CR2        Delay 100 milliseconds after sending CRs
   CR3        Delay 150 milliseconds after sending CRs
   TABDLY     Mask for delay time needed after TABs
   TAB0       No delay for TABs
   TAB1       Delay after TABs depending on current column position
   TAB2       Delay 100 milliseconds after sending TABs
   TAB3       Expand TAB characters to spaces
   BSDLY      Mask for delay time needed after BSs
   BS0        No delay for BSs
   BS1        Delay 50 milliseconds after sending BSs
   VTDLY      Mask for delay time needed after VTs
   VT0        No delay for VTs
   VT1        Delay 2 seconds after sending VTs
   FFDLY      Mask for delay time needed after FFs
   FF0        No delay for FFs
   FF1        Delay 2 seconds after sending FFs

 17. POSIX Control Character Constants

   Constant   Description          Key
   ______________________________________
   
   VINTR      Interrupt            CTRL-C
   VQUIT      Quit                 CTRL-Z
   VERASE     Erase                Backspace (BS)
   VKILL      Kill-line            CTRL-U
   VEOF       End-of-file          CTRL-D
   VEOL       End-of-line          Carriage return (CR)
   VEOL2      Second end-of-line   Line feed (LF)
   VMIN       Minimum number of characters to read
   VTIME      Time to wait for data (tenths of seconds)

 ----------------- End of Linux Serial Programming Mini-Howto -----------------