SCANF(3) Linux Programmer's Manual SCANF(3)NAME
scanf, fscanf, sscanf, vscanf, vsscanf, vfscanf - input format conver‐
sion
SYNOPSIS
#include <stdio.h>
int scanf(const char *format, ...);
int fscanf(FILE *stream, const char *format, ...);
int sscanf(const char *str, const char *format, ...);
#include <stdarg.h>
int vscanf(const char *format, va_list ap);
int vsscanf(const char *str, const char *format, va_list ap);
int vfscanf(FILE *stream, const char *format, va_list ap);
Feature Test Macro Requirements for glibc (see feature_test_macros(7)):
vscanf(), vsscanf(), vfscanf():
_XOPEN_SOURCE >= 600 || _ISOC99_SOURCE ||
_POSIX_C_SOURCE >= 200112L;
or cc -std=c99
DESCRIPTION
The scanf() family of functions scans input according to format as
described below. This format may contain conversion specifications;
the results from such conversions, if any, are stored in the locations
pointed to by the pointer arguments that follow format. Each pointer
argument must be of a type that is appropriate for the value returned
by the corresponding conversion specification.
If the number of conversion specifications in format exceeds the number
of pointer arguments, the results are undefined. If the number of
pointer arguments exceeds the number of conversion specifications, then
the excess pointer arguments are evaluated, but are otherwise ignored.
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(3) and vsprintf(3) functions
respectively.
The format string consists of a sequence of directives which describe
how to process the sequence of input characters. If processing of a
directive fails, no further input is read, and scanf() returns. A
"failure" can be either of the following: input failure, meaning that
input characters were unavailable, or matching failure, meaning that
the input was inappropriate (see below).
A directive is one of the following:
· A sequence of white-space characters (space, tab, newline, etc.;
see isspace(3)). This directive matches any amount of white
space, including none, in the input.
· An ordinary character (i.e., one other than white space or '%').
This character must exactly match the next character of input.
· A conversion specification, which commences with a '%' (percent)
character. A sequence of characters from the input is converted
according to this specification, and the result is placed in the
corresponding pointer argument. If the next item of input does
not match the conversion specification, the conversion fails—
this is a matching failure.
Each conversion specification in format begins with either the charac‐
ter '%' or the character sequence "%n$" (see below for the distinction)
followed by:
· An optional '*' assignment-suppression character: scanf() reads
input as directed by the conversion specification, but discards
the input. No corresponding pointer argument is required, and
this specification is not included in the count of successful
assignments returned by scanf().
· An optional 'm' character. This is used with string conversions
(%s, %c, %[), and relieves the caller of the need to allocate a
corresponding buffer to hold the input: instead, scanf() allo‐
cates a buffer of sufficient size, and assigns the address of
this buffer to the corresponding pointer argument, which should
be a pointer to a char * variable (this variable does not need
to be initialized before the call). The caller should subse‐
quently free(3) this buffer when it is no longer required.
· An optional decimal integer which specifies the maximum field
width. Reading of characters stops either when this maximum is
reached or when a nonmatching character is found, whichever hap‐
pens first. Most conversions discard initial white space char‐
acters (the exceptions are noted below), and these discarded
characters don't count toward the maximum field width. String
input conversions store a terminating null byte ('\0') to mark
the end of the input; the maximum field width does not include
this terminator.
· An optional type modifier character. For example, the l type
modifier is used with integer conversions such as %d to specify
that the corresponding pointer argument refers to a long int
rather than a pointer to an int.
· A conversion specifier that specifies the type of input conver‐
sion to be performed.
The conversion specifications in format are of two forms, either begin‐
ning with '%' or beginning with "%n$". The two forms should not be
mixed in the same format string, except that a string containing "%n$"
specifications can include %% and %*. If format contains '%' specifi‐
cations then these correspond in order with successive pointer argu‐
ments. In the "%n$" form (which is specified in POSIX.1-2001, but not
C99), n is a decimal integer that specifies that the converted input
should be placed in the location referred to by the n-th pointer argu‐
ment following format.
Conversions
The following type modifier characters can appear in a conversion spec‐
ification:
h Indicates that the conversion will be one of d, i, o, u, x, X,
or n and the next pointer is a pointer to a short int or
unsigned short int (rather than int).
hh As for h, but the next pointer is a pointer to a signed char or
unsigned char.
j As for h, but the next pointer is a pointer to an intmax_t or a
uintmax_t. This modifier was introduced in C99.
l Indicates either that the conversion will be one of d, i, o, u,
x, X, or n and the next pointer is a pointer to a long int or
unsigned long int (rather than int), or that the conversion will
be one of e, f, or g and the next pointer is a pointer to double
(rather than float). Specifying two l characters is equivalent
to L. If used with %c or %s the corresponding parameter is con‐
sidered as a pointer to a wide character or wide-character
string respectively.
L Indicates that the conversion will be either e, f, or g and the
next pointer is a pointer to long double or the conversion will
be d, i, o, u, or x and the next pointer is a pointer to long
long.
q equivalent to L. This specifier does not exist in ANSI C.
t As for h, but the next pointer is a pointer to a ptrdiff_t.
This modifier was introduced in C99.
z As for h, but the next pointer is a pointer to a size_t. This
modifier was introduced in C99.
The following conversion specifiers are available:
% Matches a literal '%'. That is, %% in the format string matches
a single input '%' character. No conversion is done (but ini‐
tial white space characters are discarded), 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 backward 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.
a (C99) Equivalent to f.
s Matches a sequence of non-white-space characters; the next
pointer must be a pointer to character array that is long enough
to hold the input sequence and the terminating null byte ('\0'),
which is added automatically. The input string stops at white
space or at the maximum field width, whichever occurs first.
c Matches a sequence of characters whose length is specified by
the maximum field width (default 1); the next pointer must be a
pointer to char, and there must be enough room for all the char‐
acters (no terminating null byte 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 null byte. 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 charac‐
ters if the first character after the open bracket is a circum‐
flex (^). 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 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 * assignment-suppression
character. The C standard says: "Execution of a %n directive
does not increment the assignment count returned at the comple‐
tion 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 successfully matched
and assigned, which can be fewer than provided for, or even zero in the
event of an early matching failure.
The value EOF is returned if the end of input is reached before either
the first successful conversion or a matching failure occurs. EOF is
also returned if a read error occurs, in which case the error indicator
for the stream (see ferror(3)) is set, and errno is set indicate the
error.
ERRORS
EAGAIN The file descriptor underlying stream is marked nonblocking, and
the read operation would block.
EBADF The file descriptor underlying stream is invalid, or not open
for reading.
EILSEQ Input byte sequence does not form a valid character.
EINTR The read operation was interrupted by a signal; see signal(7).
EINVAL Not enough arguments; or format is NULL.
ENOMEM Out of memory.
ERANGE The result of an integer conversion would exceed the size that
can be stored in the corresponding integer type.
CONFORMING TO
The functions fscanf(), scanf(), and sscanf() conform to C89 and C99
and POSIX.1-2001. These standards do not specify the ERANGE error.
The q specifier is the 4.4BSD 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 GNU libc (glibc-1.08) for a
more concise description.
NOTES
The GNU C library supported the dynamic allocation conversion specifier
(as a nonstandard extension) via the a character. This feature seems
to be present at least as far back as glibc 2.0.
It is not available if the program is compiled with gcc -std=c99 or gcc
-D_ISOC99_SOURCE (unless _GNU_SOURCE is also specified), in which case
the a is interpreted as a specifier for floating-point numbers (see
above).
Since version 2.7, glibc also provides the m modifier for the same pur‐
pose as the a modifier. The m modifier has the following advantages:
* It may also be applied to %c conversion specifiers (e.g., %3mc).
* It avoids ambiguity with respect to the %a floating-point conversion
specifier (and is unaffected by gcc -std=c99 etc.)
* It is specified in the POSIX.1-2008 standard.
BUGS
All functions are fully C89 conformant, but provide the additional
specifiers q and a as well as an additional behavior of the L and l
specifiers. The latter may be considered to be a bug, as it changes
the behavior of specifiers defined in C89.
Some combinations of the type modifiers and conversion specifiers
defined by ANSI C do not make sense (e.g., %Ld). While they may have a
well-defined behavior on Linux, this need not to be so on other archi‐
tectures. Therefore it usually is better to use modifiers that are not
defined by ANSI C at all, that is, use q instead of L in combination
with d, i, o, u, x, and X conversions or ll.
The usage of q is not the same as on 4.4BSD, as it may be used in float
conversions equivalently to L.
EXAMPLE
To use the dynamic allocation conversion specifier, specify m as a
length modifier (thus %ms or %m[range]). The caller must free(3) the
returned string, as in the following example:
char *p;
int n;
errno = 0;
n = scanf("%m[a-z]", &p);
if (n == 1) {
printf("read: %s\n", p);
free(p);
} else if (errno != 0) {
perror("scanf");
} else {
fprintf(stderr, "No matching characters\n");
}
As shown in the above example, it is necessary to call free(3) only if
the scanf() call successfully read a string.
SEE ALSOgetc(3), printf(3), setlocale(3), strtod(3), strtol(3), strtoul(3)COLOPHON
This page is part of release 3.55 of the Linux man-pages project. A
description of the project, and information about reporting bugs, can
be found at http://www.kernel.org/doc/man-pages/.
GNU 2013-01-30 SCANF(3)