The
scanf
family of functions scans input according to a
format
as described below. This format may contain
conversion specifiers;
the results from such conversions, if any, are stored through the
pointer
arguments. The
scanf
function reads input from the standard input stream
stdin,
fscanf
reads input from the stream pointer
stream,
and
sscanf
reads its input from the character string pointed to by
str.
The
vfscanf
function is analogous to
vfprintf(3)
and reads input from the stream pointer
stream
using a variable argument list of pointers (see
stdarg(3).
The
vscanf
function scans a variable argument list from the standard input and the
vsscanf
function scans it from a string; these are analogous to the
vprintf
and
vsprintf
functions respectively.
Each successive
pointer
argument must correspond properly with each successive conversion specifier
(but see `suppression' below). All conversions are introduced by the
%
(percent sign) character. The
format
string may also contain other characters. White space (such as blanks,
tabs, or newlines) in the
format
string match any amount of white space, including none, in the input.
Everything else matches only itself. Scanning stops when an input
character does not match such a format character. Scanning also stops when
an input conversion cannot be made (see below).
CONVERSIONS
Following the
%
character introducing a conversion there may be a number of
flag
characters, as follows:
*
Suppresses assignment. The conversion that follows occurs as usual, but no
pointer is used; the result of the conversion is simply discarded.
a
Indicates that the conversion will be
s,
the needed memory space for the string will be malloc'ed and
the pointer to it will be assigned to the
char
pointer variable, which does not have to be initialised before.
This flag does not exist in
ANSI C.
h
Indicates that the conversion will be one of
dioux
or
n
and the next pointer is a pointer to a
short int
(rather than
int).
l
Indicates either that the conversion will be one of
dioux
or
n
and the next pointer is a pointer to a
long int
(rather than
int),
or that the conversion will be one of
efg
and the next pointer is a pointer to
double
(rather than
float).
Specifying two
l
flags is equivalent to the
L
flag.
L
Indicates that the conversion will be either
efg
and the next pointer is a pointer to
long double
or the conversion will be
dioux
and the next pointer is a pointer to
long long.
(Note that long long is not an
ANSI C
type. Any program using this will not be portable to all
architectures).
q
equivalent to L.
This flag does not exist in
ANSI C.
In addition to these flags, there may be an optional maximum field width,
expressed as a decimal integer, between the
%
and the conversion. If no width is given, a default of `infinity' is used
(with one exception, below); otherwise at most this many characters are
scanned in processing the conversion. Before conversion begins, most
conversions skip white space; this white space is not counted against the
field width.
The following conversions are available:
%
Matches a literal `%'. That is, `%%' in the format string matches a
single input `%' character. No conversion is done, and assignment does not
occur.
d
Matches an optionally signed decimal integer;
the next pointer must be a pointer to
int.
D
Equivalent to
ld;
this exists only for backwards compatibility.
(Note: thus only in libc4. In libc5 and glibc the %D is
silently ignored, causing old programs to fail mysteriously.)
i
Matches an optionally signed integer; the next pointer must be a pointer to
int.
The integer is read in base 16 if it begins with `0x' or `0X', in base 8 if
it begins with `0', and in base 10 otherwise. Only characters that
correspond to the base are used.
o
Matches an unsigned octal integer; the next pointer must be a pointer to
unsigned int.
u
Matches an unsigned decimal integer; the next pointer must be a
pointer to
unsigned int.
x
Matches an unsigned hexadecimal integer; the next pointer must
be a pointer to
unsigned int.
X
Equivalent to
x
f
Matches an optionally signed floating-point number; the next pointer must
be a pointer to
float.
e
Equivalent to
f.
g
Equivalent to
f.
E
Equivalent to
f
s
Matches a sequence of non-white-space characters; the next pointer must be
a pointer to
char,
and the array must be large enough to accept all the sequence and the
terminating
NUL
character. The input string stops at white space or at the maximum field
width, whichever occurs first.
c
Matches a sequence of
width
count characters (default 1); the next pointer must be a pointer to
char,
and there must be enough room for all the characters (no terminating
NUL
is added). The usual skip of leading white space is suppressed. To skip
white space first, use an explicit space in the format.
[
Matches a nonempty sequence of characters from the specified set of
accepted characters; the next pointer must be a pointer to
char,
and there must be enough room for all the characters in the string, plus a
terminating
NUL
character. The usual skip of leading white space is suppressed. The
string is to be made up of characters in (or not in) a particular set; the
set is defined by the characters between the open bracket
[
character and a close bracket
]
character. The set
excludes
those characters if the first character after the open bracket is a
circumflex
^.
To include a close bracket in the set, make it the first character after
the open bracket or the circumflex; any other position will end the set.
The hyphen character
-
is also special; when placed between two other characters, it adds all
intervening characters to the set. To include a hyphen, make it the last
character before the final close bracket. For instance, `[^]0-9-]' means
the set `everything except close bracket, zero through nine, and hyphen'.
The string ends with the appearance of a character not in the (or, with a
circumflex, in) set or when the field width runs out.
p
Matches a pointer value (as printed by `%p' in
printf(3);
the next pointer must be a pointer to
void.
n
Nothing is expected; instead, the number of characters consumed thus far
from the input is stored through the next pointer, which must be a pointer
to
int.
This is
not
a conversion, although it can be suppressed with the
*
flag.
The C standard says: `Execution of a %n directive does not increment
the assignment count returned at the completion of execution'
but the Corrigendum seems to contradict this. Probably it is wise
not to make any assumptions on the effect of %n conversions on
the return value.
RETURN VALUE
These functions return the number of input items assigned, which can be
fewer than provided for, or even zero, in the event of a matching failure.
Zero indicates that, while there was input available, no conversions were
assigned; typically this is due to an invalid input character, such as an
alphabetic character for a `%d' conversion. The value
EOF
is returned if an input failure occurs before any conversion such as an
end-of-file occurs. If an error or end-of-file occurs after conversion has
begun, the number of conversions which were successfully completed is
returned.
The functions
fscanf,
scanf,
and
sscanf
conform to ANSI X3.159-1989 (``ANSI C'').
The
q
flag is the
BSD 4.4
notation for
long long,
while
ll
or the usage of
L
in integer conversions is the GNU notation.
The Linux version of these functions is based on the
GNU libio
library. Take a look at the
info
documentation of
GNUlibc (glibc-1.08)
for a more concise description.
BUGS
All functions are fully ANSI X3.159-1989 conformant, but provide the
additional flags
q
and
a
as well as an additional behaviour of the
L
and
l
flags. The latter may be considered to be a bug, as it changes the
behaviour of flags defined in ANSI X3.159-1989.
Some combinations of flags defined by
ANSI C
are not making sense in
ANSI C
(e.g.
%Ld).
While they may have a well-defined behaviour on Linux, this need not
to be so on other architectures. Therefore it usually is better to use
flags that are not defined by
ANSI C
at all, i.e. use
q
instead of
L
in combination with
diouxX
conversions or
ll.
The usage of
q
is not the same as on
BSD 4.4,
as it may be used in float conversions equivalently to
L.