This chapter describes functions that are specific to terminal devices. You can use these functions to do things like turn off input echoing; set serial line characteristics such as line speed and flow control; and change which characters are used for end-of-file, command-line editing, sending signals, and similar control functions.
Most of the functions in this chapter operate on file descriptors. See section 8 Low-Level Input/Output, for more information about what a file descriptor is and how to open a file descriptor for a terminal device.
The functions described in this chapter only work on files that
correspond to terminal devices. You can find out whether a file
descriptor is associated with a terminal by using the isatty
function.
Prototypes for both isatty
and ttyname
are declared in
the header file `unistd.h'.
1
if filedes is a file descriptor
associated with an open terminal device, and 0
otherwise.
If a file descriptor is associated with a terminal, you can get its
associated file name using the ttyname
function. See also the
ctermid
function, described in section 24.7.1 Identifying the Controlling Terminal.
ttyname
function returns a pointer to a
statically-allocated, null-terminated string containing the file name of
the terminal file. The value is a null pointer if the file descriptor
isn't associated with a terminal, or the file name cannot be determined.
Many of the remaining functions in this section refer to the input and output queues of a terminal device. These queues implement a form of buffering within the kernel independent of the buffering implemented by I/O streams (see section 7 Input/Output on Streams).
The terminal input queue is also sometimes referred to as its typeahead buffer. It holds the characters that have been received from the terminal but not yet read by any process.
The size of the terminal's input queue is described by the
MAX_INPUT
and _POSIX_MAX_INPUT
parameters; see section 28.6 Limits on File System Capacity. You are guaranteed a queue size of at least
MAX_INPUT
, but the queue might be larger, and might even
dynamically change size. If input flow control is enabled by setting
the IXOFF
input mode bit (see section 12.4.4 Input Modes), the terminal
driver transmits STOP and START characters to the terminal when
necessary to prevent the queue from overflowing. Otherwise, input may
be lost if it comes in too fast from the terminal. In canonical mode,
all input stays in the queue until a newline character is received, so
the terminal input queue can fill up when you type a very long line.
See section 12.3 Two Styles of Input: Canonical or Not.
The terminal output queue is like the input queue, but for output;
it contains characters that have been written by processes, but not yet
transmitted to the terminal. If output flow control is enabled by
setting the IXON
input mode bit (see section 12.4.4 Input Modes), the
terminal driver obeys STOP and STOP characters sent by the terminal to
stop and restart transmission of output.
Clearing the terminal input queue means discarding any characters that have been received but not yet read. Similarly, clearing the terminal output queue means discarding any characters that have been written but not yet transmitted.
POSIX systems support two basic modes of input: canonical and noncanonical.
In canonical input processing mode, terminal input is processed in
lines terminated by newline ('\n'
), EOF, or EOL characters. No
input can be read until an entire line has been typed by the user, and
the read
function (see section 8.2 Input and Output Primitives) returns at most a
single line of input, no matter how many bytes are requested.
In canonical input mode, the operating system provides input editing facilities: some characters are interpreted specially to perform editing operations within the current line of text, such as ERASE and KILL. See section 12.4.9.1 Characters for Input Editing.
The constants _POSIX_MAX_CANON
and MAX_CANON
parameterize
the maximum number of bytes which may appear in a single line of
canonical input. See section 28.6 Limits on File System Capacity. You are guaranteed a maximum
line length of at least MAX_CANON
bytes, but the maximum might be
larger, and might even dynamically change size.
In noncanonical input processing mode, characters are not grouped into lines, and ERASE and KILL processing is not performed. The granularity with which bytes are read in noncanonical input mode is controlled by the MIN and TIME settings. See section 12.4.10 Noncanonical Input.
Most programs use canonical input mode, because this gives the user a way to edit input line by line. The usual reason to use noncanonical mode is when the program accepts single-character commands or provides its own editing facilities.
The choice of canonical or noncanonical input is controlled by the
ICANON
flag in the c_lflag
member of struct termios
.
See section 12.4.7 Local Modes.
This section describes the various terminal attributes that control how input and output are done. The functions, data structures, and symbolic constants are all declared in the header file `termios.h'.
struct termios
and
related types.
The entire collection of attributes of a terminal is stored in a
structure of type struct termios
. This structure is used
with the functions tcgetattr
and tcsetattr
to read
and set the attributes.
tcflag_t c_iflag
tcflag_t c_oflag
tcflag_t c_cflag
tcflag_t c_lflag
cc_t c_cc[NCCS]
The struct termios
structure also contains members which
encode input and output transmission speeds, but the representation is
not specified. See section 12.4.8 Line Speed, for how to examine and store the
speed values.
The following sections describe the details of the members of the
struct termios
structure.
c_cc
array.
If successful, tcgetattr
returns 0
. A return value of -1
indicates an error. The following errno
error conditions are
defined for this function:
EBADF
ENOTTY
The when argument specifies how to deal with input and output already queued. It can be one of the following values:
TCSANOW
TCSADRAIN
TCSAFLUSH
TCSADRAIN
, but also discards any queued input.
TCSASOFT
TCSASOFT
is exactly the same as setting the CIGNORE
bit in the c_cflag
member of the structure termios-p points
to. See section 12.4.6 Control Modes, for a description of CIGNORE
.
If this function is called from a background process on its controlling
terminal, normally all processes in the process group are sent a
SIGTTOU
signal, in the same way as if the process were trying to
write to the terminal. The exception is if the calling process itself
is ignoring or blocking SIGTTOU
signals, in which case the
operation is performed and no signal is sent. See section 24 Job Control.
If successful, tcsetattr
returns 0
. A return value of
-1
indicates an error. The following errno
error
conditions are defined for this function:
EBADF
ENOTTY
EINVAL
when
argument is not valid, or there is
something wrong with the data in the termios-p argument.
Although tcgetattr
and tcsetattr
specify the terminal
device with a file descriptor, the attributes are those of the terminal
device itself and not of the file descriptor. This means that the
effects of changing terminal attributes are persistent; if another
process opens the terminal file later on, it will see the changed
attributes even though it doesn't have anything to do with the open file
descriptor you originally specified in changing the attributes.
Similarly, if a single process has multiple or duplicated file descriptors for the same terminal device, changing the terminal attributes affects input and output to all of these file descriptors. This means, for example, that you can't open one file descriptor or stream to read from a terminal in the normal line-buffered, echoed mode; and simultaneously have another file descriptor for the same terminal that you use to read from it in single-character, non-echoed mode. Instead, you have to explicitly switch the terminal back and forth between the two modes.
When you set terminal modes, you should call tcgetattr
first to
get the current modes of the particular terminal device, modify only
those modes that you are really interested in, and store the result with
tcsetattr
.
It's a bad idea to simply initialize a struct termios
structure
to a chosen set of attributes and pass it directly to tcsetattr
.
Your program may be run years from now, on systems that support members
not documented in this manual. The way to avoid setting these members
to unreasonable values is to avoid changing them.
What's more, different terminal devices may require different mode settings in order to function properly. So you should avoid blindly copying attributes from one terminal device to another.
When a member contains a collection of independent flags, as the
c_iflag
, c_oflag
and c_cflag
members do, even
setting the entire member is a bad idea, because particular operating
systems have their own flags. Instead, you should start with the
current value of the member and alter only the flags whose values matter
in your program, leaving any other flags unchanged.
Here is an example of how to set one flag (ISTRIP
) in the
struct termios
structure while properly preserving all the other
data in the structure:
int set_istrip (int desc, int value) { struct termios settings; int result; result = tcgetattr (desc, &settings); if (result < 0) { perror ("error in tcgetattr"); return 0; } settings.c_iflag &= ~ISTRIP; if (value) settings.c_iflag |= ISTRIP; result = tcsetattr (desc, TCSANOW, &settings); if (result < 0) { perror ("error in tcgetattr"); return; } return 1; }
This section describes the terminal attribute flags that control fairly low-level aspects of input processing: handling of parity errors, break signals, flow control, and RET and LFD characters.
All of these flags are bits in the c_iflag
member of the
struct termios
structure. The member is an integer, and you
change flags using the operators &
, |
and ^
. Don't
try to specify the entire value for c_iflag
---instead, change
only specific flags and leave the rest untouched (see section 12.4.3 Setting Terminal Modes Properly).
Parity checking on input processing is independent of whether parity
detection and generation on the underlying terminal hardware is enabled;
see section 12.4.6 Control Modes. For example, you could clear the INPCK
input mode flag and set the PARENB
control mode flag to ignore
parity errors on input, but still generate parity on output.
If this bit is set, what happens when a parity error is detected depends
on whether the IGNPAR
or PARMRK
bits are set. If neither
of these bits are set, a byte with a parity error is passed to the
application as a '\0'
character.
INPCK
is also set.
INPCK
is set and IGNPAR
is not set.
The way erroneous bytes are marked is with two preceding bytes,
377
and 0
. Thus, the program actually reads three bytes
for one erroneous byte received from the terminal.
If a valid byte has the value 0377
, and ISTRIP
(see below)
is not set, the program might confuse it with the prefix that marks a
parity error. So a valid byte 0377
is passed to the program as
two bytes, 0377
0377
, in this case.
A break condition is defined in the context of asynchronous serial data transmission as a series of zero-value bits longer than a single byte.
IGNBRK
is not set, a break condition
clears the terminal input and output queues and raises a SIGINT
signal for the foreground process group associated with the terminal.
If neither BRKINT
nor IGNBRK
are set, a break condition is
passed to the application as a single '\0'
character if
PARMRK
is not set, or otherwise as a three-character sequence
'\377'
, '\0'
, '\0'
.
'\r'
) are
discarded on input. Discarding carriage return may be useful on
terminals that send both carriage return and linefeed when you type the
RET key.
IGNCR
is not set, carriage return characters
('\r'
) received as input are passed to the application as newline
characters ('\n'
).
'\n'
) received as input
are passed to the application as carriage return characters ('\r'
).
This is a BSD extension; it exists only on BSD systems and the GNU system.
007
) to the terminal to ring the bell.
This is a BSD extension.
This section describes the terminal flags and fields that control how
output characters are translated and padded for display. All of these
are contained in the c_oflag
member of the struct termios
structure.
The c_oflag
member itself is an integer, and you change the flags
and fields using the operators &
, |
, and ^
. Don't
try to specify the entire value for c_oflag
---instead, change
only specific flags and leave the rest untouched (see section 12.4.3 Setting Terminal Modes Properly).
'\n'
) onto
carriage return and linefeed pairs.
If this bit isn't set, the characters are transmitted as-is.
The following three bits are BSD features, and they exist only BSD
systems and the GNU system. They are effective only if OPOST
is
set.
004
) on
output. These characters cause many dial-up terminals to disconnect.
This section describes the terminal flags and fields that control
parameters usually associated with asynchronous serial data
transmission. These flags may not make sense for other kinds of
terminal ports (such as a network connection pseudo-terminal). All of
these are contained in the c_cflag
member of the struct
termios
structure.
The c_cflag
member itself is an integer, and you change the flags
and fields using the operators &
, |
, and ^
. Don't
try to specify the entire value for c_cflag
---instead, change
only specific flags and leave the rest untouched (see section 12.4.3 Setting Terminal Modes Properly).
On many systems if this bit is not set and you call open
without
the O_NONBLOCK
flag set, open
blocks until a modem
connection is established.
If this bit is not set and a modem disconnect is detected, a
SIGHUP
signal is sent to the controlling process group for the
terminal (if it has one). Normally, this causes the process to exit;
see section 21 Signal Handling. Reading from the terminal after a disconnect
causes an end-of-file condition, and writing causes an EIO
error
to be returned. The terminal device must be closed and reopened to
clear the condition.
If this bit is not set, no parity bit is added to output characters, and input characters are not checked for correct parity.
PARENB
is set. If PARODD
is set,
odd parity is used, otherwise even parity is used.
The control mode flags also includes a field for the number of bits per
character. You can use the CSIZE
macro as a mask to extract the
value, like this: settings.c_cflag & CSIZE
.
The following four bits are BSD extensions; this exist only on BSD systems and the GNU system.
tcsetattr
.
The c_cflag
member and the line speed values returned by
cfgetispeed
and cfgetospeed
will be unaffected by the
call. CIGNORE
is useful if you want to set all the software
modes in the other members, but leave the hardware details in
c_cflag
unchanged. (This is how the TCSASOFT
flag to
tcsettattr
works.)
This bit is never set in the structure filled in by tcgetattr
.
This section describes the flags for the c_lflag
member of the
struct termios
structure. These flags generally control
higher-level aspects of input processing than the input modes flags
described in section 12.4.4 Input Modes, such as echoing, signals, and the choice
of canonical or noncanonical input.
The c_lflag
member itself is an integer, and you change the flags
and fields using the operators &
, |
, and ^
. Don't
try to specify the entire value for c_lflag
---instead, change
only specific flags and leave the rest untouched (see section 12.4.3 Setting Terminal Modes Properly).
This bit only controls the display behavior; the ICANON
bit by
itself controls actual recognition of the ERASE character and erasure of
input, without which ECHOE
is simply irrelevant.
ECHOE
, enables display of the ERASE character in
a way that is geared to a hardcopy terminal. When you type the ERASE
character, a `\' character is printed followed by the first
character erased. Typing the ERASE character again just prints the next
character erased. Then, the next time you type a normal character, a
`/' character is printed before the character echoes.
This is a BSD extension, and exists only in BSD systems and the GNU system.
ECHOKE
(below) is nicer to look at.
If this bit is not set, the KILL character echoes just as it would if it were not the KILL character. Then it is up to the user to remember that the KILL character has erased the preceding input; there is no indication of this on the screen.
This bit only controls the display behavior; the ICANON
bit by
itself controls actual recognition of the KILL character and erasure of
input, without which ECHOK
is simply irrelevant.
ECHOK
. It enables special display of the
KILL character by erasing on the screen the entire line that has been
killed. This is a BSD extension, and exists only in BSD systems and the
GNU system.
ICANON
bit is also set, then the
newline ('\n'
) character is echoed even if the ECHO
bit
is not set.
ECHO
bit is also set, echo control
characters with `^' followed by the corresponding text character.
Thus, control-A echoes as `^A'. This is usually the preferred mode
for interactive input, because echoing a control character back to the
terminal could have some undesired effect on the terminal.
This is a BSD extension, and exists only in BSD systems and the GNU system.
You should use caution when disabling recognition of these characters. Programs that cannot be interrupted interactively are very user-unfriendly. If you clear this bit, your program should provide some alternate interface that allows the user to interactively send the signals associated with these characters, or to escape from the program.
See section 12.4.9.2 Characters that Cause Signals.
IEXTEN
implementation-defined meaning,
so you cannot rely on this interpretation on all systems.
On BSD systems and the GNU system, it enables the LNEXT and DISCARD characters. See section 12.4.9.4 Other Special Characters.
SIGTTOU
signals are generated by background processes that
attempt to write to the terminal. See section 24.4 Access to the Controlling Terminal.
The following bits are BSD extensions; they exist only in BSD systems and the GNU system.
If this bit is clear, then the beginning of a word is a nonwhitespace character following a whitespace character. If the bit is set, then the beginning of a word is an alphanumeric character or underscore following a character which is none of those.
See section 12.4.9.1 Characters for Input Editing, for more information about the WERASE character.
The terminal line speed tells the computer how fast to read and write data on the terminal.
If the terminal is connected to a real serial line, the terminal speed you specify actually controls the line--if it doesn't match the terminal's own idea of the speed, communication does not work. Real serial ports accept only certain standard speeds. Also, particular hardware may not support even all the standard speeds. Specifying a speed of zero hangs up a dialup connection and turns off modem control signals.
If the terminal is not a real serial line (for example, if it is a network connection), then the line speed won't really affect data transmission speed, but some programs will use it to determine the amount of padding needed. It's best to specify a line speed value that matches the actual speed of the actual terminal, but you can safely experiment with different values to vary the amount of padding.
There are actually two line speeds for each terminal, one for input and one for output. You can set them independently, but most often terminals use the same speed for both directions.
The speed values are stored in the struct termios
structure, but
don't try to access them in the struct termios
structure
directly. Instead, you should use the following functions to read and
store them:
*termios-p
.
*termios-p
.
*termios-p
as the output
speed. The normal return value is 0
; a value of -1
indicates an error. If speed is not a speed, cfsetospeed
returns -1
.
*termios-p
as the input
speed. The normal return value is 0
; a value of -1
indicates an error. If speed is not a speed, cfsetospeed
returns -1
.
*termios-p
as both the
input and output speeds. The normal return value is 0
; a value
of -1
indicates an error. If speed is not a speed,
cfsetspeed
returns -1
. This function is an extension in
4.4 BSD.
speed_t
type is an unsigned integer data type used to
represent line speeds.
The functions cfsetospeed
and cfsetispeed
report errors
only for speed values that the system simply cannot handle. If you
specify a speed value that is basically acceptable, then those functions
will succeed. But they do not check that a particular hardware device
can actually support the specified speeds--in fact, they don't know
which device you plan to set the speed for. If you use tcsetattr
to set the speed of a particular device to a value that it cannot
handle, tcsetattr
returns -1
.
Portability note: In the GNU library, the functions above
accept speeds measured in bits per second as input, and return speed
values measured in bits per second. Other libraries require speeds to
be indicated by special codes. For POSIX.1 portability, you must use
one of the following symbols to represent the speed; their precise
numeric values are system-dependent, but each name has a fixed meaning:
B110
stands for 110 bps, B300
for 300 bps, and so on.
There is no portable way to represent any speed but these, but these are
the only speeds that typical serial lines can support.
B0 B50 B75 B110 B134 B150 B200 B300 B600 B1200 B1800 B2400 B4800 B9600 B19200 B38400
BSD defines two additional speed symbols as aliases: EXTA
is an
alias for B19200
and EXTB
is an alias for B38400
.
These aliases are obsolete.
In canonical input, the terminal driver recognizes a number of special
characters which perform various control functions. These include the
ERASE character (usually DEL) for editing input, and other editing
characters. The INTR character (normally C-c) for sending a
SIGINT
signal, and other signal-raising characters, may be
available in either canonical or noncanonical input mode. All these
characters are described in this section.
The particular characters used are specified in the c_cc
member
of the struct termios
structure. This member is an array; each
element specifies the character for a particular role. Each element has
a symbolic constant that stands for the index of that element--for
example, INTR
is the index of the element that specifies the INTR
character, so storing '='
in termios.c_cc[INTR]
specifies `=' as the INTR character.
On some systems, you can disable a particular special character function
by specifying the value _POSIX_VDISABLE
for that role. This
value is unequal to any possible character code. See section 28.7 Optional Features in File Support, for more information about how to tell whether the operating
system you are using supports _POSIX_VDISABLE
.
These special characters are active only in canonical input mode. See section 12.3 Two Styles of Input: Canonical or Not.
termios.c_cc[VEOF]
holds the character
itself.
The EOF character is recognized only in canonical input mode. It acts
as a line terminator in the same way as a newline character, but if the
EOF character is typed at the beginning of a line it causes read
to return a byte count of zero, indicating end-of-file. The EOF
character itself is discarded.
Usually, the EOF character is C-d.
termios.c_cc[VEOL]
holds the character
itself.
The EOL character is recognized only in canonical input mode. It acts as a line terminator, just like a newline character. The EOL character is not discarded; it is read as the last character in the input line.
You don't need to use the EOL character to make RET end a line. Just set the ICRNL flag. In fact, this is the default state of affairs.
termios.c_cc[VEOL2]
holds the character
itself.
The EOL2 character works just like the EOL character (see above), but it can be a different character. Thus, you can specify two characters to terminate an input line, by setting EOL to one of them and EOL2 to the other.
The EOL2 character is a BSD extension; it exists only on BSD systems and the GNU system.
termios.c_cc[VERASE]
holds the
character itself.
The ERASE character is recognized only in canonical input mode. When the user types the erase character, the previous character typed is discarded. (If the terminal generates multibyte character sequences, this may cause more than one byte of input to be discarded.) This cannot be used to erase past the beginning of the current line of text. The ERASE character itself is discarded.
Usually, the ERASE character is DEL.
termios.c_cc[VWERASE]
holds the character
itself.
The WERASE character is recognized only in canonical mode. It erases an entire word of prior input, and any whitespace after it; whitespace characters before the word are not erased.
The definition of a "word" depends on the setting of the
ALTWERASE
mode; see section 12.4.7 Local Modes.
If the ALTWERASE
mode is not set, a word is defined as a sequence
of any characters except space or tab.
If the ALTWERASE
mode is set, a word is defined as a sequence of
characters containing only letters, numbers, and underscores, optionally
followed by one character that is not a letter, number, or underscore.
The WERASE character is usually C-w.
This is a BSD extension.
termios.c_cc[VKILL]
holds the character
itself.
The KILL character is recognized only in canonical input mode. When the user types the kill character, the entire contents of the current line of input are discarded. The kill character itself is discarded too.
The KILL character is usually C-u.
termios.c_cc[VREPRINT]
holds the character
itself.
The REPRINT character is recognized only in canonical mode. It reprints the current input line. If some asynchronous output has come while you are typing, this lets you see the line you are typing clearly again.
The REPRINT character is usually C-r.
This is a BSD extension.
These special characters may be active in either canonical or noncanonical
input mode, but only when the ISIG
flag is set (see section 12.4.7 Local Modes).
termios.c_cc[VINTR]
holds the character
itself.
The INTR (interrupt) character raises a SIGINT
signal for all
processes in the foreground job associated with the terminal. The INTR
character itself is then discarded. See section 21 Signal Handling, for more
information about signals.
Typically, the INTR character is C-c.
termios.c_cc[VQUIT]
holds the character
itself.
The QUIT character raises a SIGQUIT
signal for all processes in
the foreground job associated with the terminal. The QUIT character
itself is then discarded. See section 21 Signal Handling, for more information
about signals.
Typically, the QUIT character is C-\.
termios.c_cc[VSUSP]
holds the character
itself.
The SUSP (suspend) character is recognized only if the implementation
supports job control (see section 24 Job Control). It causes a SIGTSTP
signal to be sent to all processes in the foreground job associated with
the terminal. The SUSP character itself is then discarded.
See section 21 Signal Handling, for more information about signals.
Typically, the SUSP character is C-z.
Few applications disable the normal interpretation of the SUSP
character. If your program does this, it should provide some other
mechanism for the user to stop the job. When the user invokes this
mechanism, the program should send a SIGTSTP
signal to the
process group of the process, not just to the process itself.
See section 21.6.2 Signaling Another Process.
termios.c_cc[VDSUSP]
holds the character
itself.
The DSUSP (suspend) character is recognized only if the implementation
supports job control (see section 24 Job Control). It sends a SIGTSTP
signal, like the SUSP character, but not right away--only when the
program tries to read it as input. Not all systems with job control
support DSUSP; only BSD-compatible systems (including the GNU system).
See section 21 Signal Handling, for more information about signals.
Typically, the DSUSP character is C-y.
These special characters may be active in either canonical or noncanonical
input mode, but their use is controlled by the flags IXON
and
IXOFF
(see section 12.4.4 Input Modes).
termios.c_cc[VSTART]
holds the
character itself.
The START character is used to support the IXON
and IXOFF
input modes. If IXON
is set, receiving a START character resumes
suspended output; the START character itself is discarded. If
IXANY
is set, receiving any character at all resumes suspended
output; the resuming character is not discarded unless it is the START
character. IXOFF
is set, the system may also transmit START
characters to the terminal.
The usual value for the START character is C-q. You may not be able to change this value--the hardware may insist on using C-q regardless of what you specify.
termios.c_cc[VSTOP]
holds the character
itself.
The STOP character is used to support the IXON
and IXOFF
input modes. If IXON
is set, receiving a STOP character causes
output to be suspended; the STOP character itself is discarded. If
IXOFF
is set, the system may also transmit STOP characters to the
terminal, to prevent the input queue from overflowing.
The usual value for the STOP character is C-s. You may not be able to change this value--the hardware may insist on using C-s regardless of what you specify.
These special characters exist only in BSD systems and the GNU system.
termios.c_cc[VLNEXT]
holds the character
itself.
The LNEXT character is recognized only when IEXTEN
is set, but in
both canonical and noncanonical mode. It disables any special
significance of the next character the user types. Even if the
character would normally perform some editing function or generate a
signal, it is read as a plain character. This is the analogue of the
C-q command in Emacs. "LNEXT" stands for "literal next."
The LNEXT character is usually C-v.
termios.c_cc[VDISCARD]
holds the character
itself.
The DISCARD character is recognized only when IEXTEN
is set, but
in both canonical and noncanonical mode. Its effect is to toggle the
discard-output flag. When this flag is set, all program output is
discarded. Setting the flag also discards all output currently in the
output buffer. Typing any other character resets the flag.
termios.c_cc[VSTATUS]
holds the character
itself.
The STATUS character's effect is to print out a status message about how the current process is running.
The STATUS character is recognized only in canonical mode, and only if
NOKERNINFO
is not set.
In noncanonical input mode, the special editing characters such as ERASE and KILL are ignored. The system facilities for the user to edit input are disabled in noncanonical mode, so that all input characters (unless they are special for signal or flow-control purposes) are passed to the application program exactly as typed. It is up to the application program to give the user ways to edit the input, if appropriate.
Noncanonical mode offers special parameters called MIN and TIME for controlling whether and how long to wait for input to be available. You can even use them to avoid ever waiting--to return immediately with whatever input is available, or with no input.
The MIN and TIME are stored in elements of the c_cc
array, which
is a member of the struct termios
structure. Each element of
this array has a particular role, and each element has a symbolic
constant that stands for the index of that element. VMIN
and
VMAX
are the names for the indices in the array of the MIN and
TIME slots.
c_cc
array. Thus,
termios.c_cc[VMIN]
is the value itself.
The MIN slot is only meaningful in noncanonical input mode; it
specifies the minimum number of bytes that must be available in the
input queue in order for read
to return.
c_cc
array. Thus,
termios.c_cc[VTIME]
is the value itself.
The TIME slot is only meaningful in noncanonical input mode; it specifies how long to wait for input before returning, in units of 0.1 seconds.
The MIN and TIME values interact to determine the criterion for when
read
should return; their precise meanings depend on which of
them are nonzero. There are four possible cases:
read
keeps waiting until either MIN bytes have arrived in all, or
TIME elapses with no further input.
read
always blocks until the first character arrives, even if
TIME elapses first. read
can return more than MIN characters if
more than MIN happen to be in the queue.
read
always returns immediately with as many
characters as are available in the queue, up to the number requested.
If no input is immediately available, read
returns a value of
zero.
read
waits for time TIME for input to become
available; the availability of a single byte is enough to satisfy the
read request and cause read
to return. When it returns, it
returns as many characters as are available, up to the number requested.
If no input is available before the timer expires, read
returns a
value of zero.
read
waits until at least MIN bytes are available
in the queue. At that time, read
returns as many characters as
are available, up to the number requested. read
can return more
than MIN characters if more than MIN happen to be in the queue.
What happens if MIN is 50 and you ask to read just 10 bytes?
Normally, read
waits until there are 50 bytes in the buffer (or,
more generally, the wait condition described above is satisfied), and
then reads 10 of them, leaving the other 40 buffered in the operating
system for a subsequent call to read
.
Portability note: On some systems, the MIN and TIME slots are actually the same as the EOF and EOL slots. This causes no serious problem because the MIN and TIME slots are used only in noncanonical input and the EOF and EOL slots are used only in canonical input, but it isn't very clean. The GNU library allocates separate slots for these uses.
*termios-p
for
what has traditionally been called "raw mode" in BSD. This uses
noncanonical input, and turns off most processing to give an unmodified
channel to the terminal.
It does exactly this:
termios-p->c_iflag &= ~(IGNBRK|BRKINT|PARMRK|ISTRIP |INLCR|IGNCR|ICRNL|IXON); termios-p->c_oflag &= ~OPOST; termios-p->c_lflag &= ~(ECHO|ECHONL|ICANON|ISIG|IEXTEN); termios-p->c_cflag &= ~(CSIZE|PARENB); termios-p->c_cflag |= CS8;
These functions perform miscellaneous control actions on terminal
devices. As regards terminal access, they are treated like doing
output: if any of these functions is used by a background process on its
controlling terminal, normally all processes in the process group are
sent a SIGTTOU
signal. The exception is if the calling process
itself is ignoring or blocking SIGTTOU
signals, in which case the
operation is performed and no signal is sent. See section 24 Job Control.
This function does nothing if the terminal is not an asynchronous serial data port.
The return value is normally zero. In the event of an error, a value
of -1
is returned. The following errno
error conditions
are defined for this function:
EBADF
ENOTTY
tcdrain
function waits until all queued
output to the terminal filedes has been transmitted.
The return value is normally zero. In the event of an error, a value
of -1
is returned. The following errno
error conditions
are defined for this function:
EBADF
ENOTTY
EINTR
tcflush
function is used to clear the input and/or output
queues associated with the terminal file filedes. The queue
argument specifies which queue(s) to clear, and can be one of the
following values:
TCIFLUSH
TCOFLUSH
TCIOFLUSH
The return value is normally zero. In the event of an error, a value
of -1
is returned. The following errno
error conditions
are defined for this function:
EBADF
ENOTTY
EINVAL
It is unfortunate that this function is named tcflush
, because
the term "flush" is normally used for quite another operation--waiting
until all output is transmitted--and using it for discarding input or
output would be confusing. Unfortunately, the name tcflush
comes
from POSIX and we cannot change it.
tcflow
function is used to perform operations relating to
XON/XOFF flow control on the terminal file specified by filedes.
The action argument specifies what operation to perform, and can be one of the following values:
TCOOFF
TCOON
TCIOFF
TCION
For more information about the STOP and START characters, see section 12.4.9 Special Characters.
The return value is normally zero. In the event of an error, a value
of -1
is returned. The following errno
error conditions
are defined for this function:
EBADF
ENOTTY
EINVAL
Here is an example program that shows how you can set up a terminal device to read single characters in noncanonical input mode, without echo.
#include <unistd.h> #include <stdio.h> #include <stdlib.h> #include <termios.h> /* Use this variable to remember original terminal attributes. */ struct termios saved_attributes; void reset_input_mode (void) { tcsetattr (STDIN_FILENO, TCSANOW, &saved_attributes); } void set_input_mode (void) { struct termios tattr; char *name; /* Make sure stdin is a terminal. */ if (!isatty (STDIN_FILENO)) { fprintf (stderr, "Not a terminal.\n"); exit (EXIT_FAILURE); } /* Save the terminal attributes so we can restore them later. */ tcgetattr (STDIN_FILENO, &saved_attributes); atexit (reset_input_mode); /* Set the funny terminal modes. */ tcgetattr (STDIN_FILENO, &tattr); tattr.c_lflag &= ~(ICANON|ECHO); /* Clear ICANON and ECHO. */ tattr.c_cc[VMIN] = 1; tattr.c_cc[VTIME] = 0; tcsetattr (STDIN_FILENO, TCSAFLUSH, &tattr); } int main (void) { char c; set_input_mode (); while (1) { read (STDIN_FILENO, &c, 1); if (c == '\004') /* C-d */ break; else putchar (c); } return EXIT_SUCCESS; }
This program is careful to restore the original terminal modes before
exiting or terminating with a signal. It uses the atexit
function (see section 22.3.3 Cleanups on Exit) to make sure this is done
by exit
.
The shell is supposed to take care of resetting the terminal modes when a process is stopped or continued; see section 24 Job Control. But some existing shells do not actually do this, so you may wish to establish handlers for job control signals that reset terminal modes. The above example does so.
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