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1 .\" Copyright (c) 1990, 1991, 1993
2 .\" The Regents of the University of California. All rights reserved.
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4 .\" This code is derived from software contributed to Berkeley by
5 .\" Chris Torek and the American National Standards Committee X3,
6 .\" on Information Processing Systems.
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31 .\"
32 .\" @(#)printf.3 8.1 (Berkeley) 6/4/93
33 .\" $FreeBSD$
34 .\"
35 .Dd December 2, 2009
36 .Dt PRINTF 3
37 .Os
38 .Sh NAME
39 .Nm printf , fprintf , sprintf , snprintf , asprintf , dprintf ,
40 .Nm vprintf , vfprintf, vsprintf , vsnprintf , vasprintf, vdprintf
41 .Nd formatted output conversion
42 .Sh LIBRARY
43 .Lb libc
44 .Sh SYNOPSIS
45 .In stdio.h
46 .Ft int
47 .Fn printf "const char * restrict format" ...
48 .Ft int
49 .Fn fprintf "FILE * restrict stream" "const char * restrict format" ...
50 .Ft int
51 .Fn sprintf "char * restrict str" "const char * restrict format" ...
52 .Ft int
53 .Fn snprintf "char * restrict str" "size_t size" "const char * restrict format" ...
54 .Ft int
55 .Fn asprintf "char **ret" "const char *format" ...
56 .Ft int
57 .Fn dprintf "int fd" "const char * restrict format" ...
58 .In stdarg.h
59 .Ft int
60 .Fn vprintf "const char * restrict format" "va_list ap"
61 .Ft int
62 .Fn vfprintf "FILE * restrict stream" "const char * restrict format" "va_list ap"
63 .Ft int
64 .Fn vsprintf "char * restrict str" "const char * restrict format" "va_list ap"
65 .Ft int
66 .Fn vsnprintf "char * restrict str" "size_t size" "const char * restrict format" "va_list ap"
67 .Ft int
68 .Fn vasprintf "char **ret" "const char *format" "va_list ap"
69 .Ft int
70 .Fn vdprintf "int fd" "const char * restrict format" "va_list ap"
71 .Sh DESCRIPTION
72 The
73 .Fn printf
74 family of functions produces output according to a
75 .Fa format
76 as described below.
77 The
78 .Fn printf
79 and
80 .Fn vprintf
81 functions
82 write output to
83 .Dv stdout ,
84 the standard output stream;
85 .Fn fprintf
86 and
87 .Fn vfprintf
88 write output to the given output
89 .Fa stream ;
90 .Fn dprintf
91 and
92 .Fn vdprintf
93 write output to the given file descriptor;
94 .Fn sprintf ,
95 .Fn snprintf ,
96 .Fn vsprintf ,
97 and
98 .Fn vsnprintf
99 write to the character string
100 .Fa str ;
101 and
102 .Fn asprintf
103 and
104 .Fn vasprintf
105 dynamically allocate a new string with
106 .Xr malloc 3 .
107 .Pp
108 Extended locale versions of these functions are documented in
109 .Xr printf_l 3 .
110 See
111 .Xr xlocale 3
112 for more information.
113 .Pp
114 These functions write the output under the control of a
115 .Fa format
116 string that specifies how subsequent arguments
117 (or arguments accessed via the variable-length argument facilities of
118 .Xr stdarg 3 )
119 are converted for output.
120 .Pp
121 The
122 .Fn asprintf
123 and
124 .Fn vasprintf
125 functions
126 set
127 .Fa *ret
128 to be a pointer to a buffer sufficiently large to hold the formatted string.
129 This pointer should be passed to
130 .Xr free 3
131 to release the allocated storage when it is no longer needed.
132 If sufficient space cannot be allocated,
133 .Fn asprintf
134 and
135 .Fn vasprintf
136 will return \-1 and set
137 .Fa ret
138 to be a
139 .Dv NULL
140 pointer.
141 .Pp
142 The
143 .Fn snprintf
144 and
145 .Fn vsnprintf
146 functions
147 will write at most
148 .Fa size Ns \-1
149 of the characters printed into the output string
150 (the
151 .Fa size Ns 'th
152 character then gets the terminating
153 .Ql \e0 ) ;
154 if the return value is greater than or equal to the
155 .Fa size
156 argument, the string was too short
157 and some of the printed characters were discarded.
158 The output is always null-terminated, unless
159 .Fa size
160 is 0.
161 .Pp
162 The
163 .Fn sprintf
164 and
165 .Fn vsprintf
166 functions
167 effectively assume a
168 .Fa size
169 of
170 .Dv INT_MAX + 1.
171 .Pp
172 For those routines that write to a user-provided character string,
173 that string and the format strings should not overlap, as the
174 behavior is undefined.
175 .Pp
176 The format string is composed of zero or more directives:
177 ordinary
178 .\" multibyte
179 characters (not
180 .Cm % ) ,
181 which are copied unchanged to the output stream;
182 and conversion specifications, each of which results
183 in fetching zero or more subsequent arguments.
184 Each conversion specification is introduced by
185 the
186 .Cm %
187 character.
188 The arguments must correspond properly (after type promotion)
189 with the conversion specifier.
190 After the
191 .Cm % ,
192 the following appear in sequence:
193 .Bl -bullet
194 .It
195 An optional field, consisting of a decimal digit string followed by a
196 .Cm $ ,
197 specifying the next argument to access.
198 If this field is not provided, the argument following the last
199 argument accessed will be used.
200 Arguments are numbered starting at
201 .Cm 1 .
202 If unaccessed arguments in the format string are interspersed with ones that
203 are accessed the results will be indeterminate.
204 .It
205 Zero or more of the following flags:
206 .Bl -tag -width ".So \ Sc (space)"
207 .It Sq Cm #
208 The value should be converted to an
209 .Dq alternate form .
210 For
211 .Cm c , d , i , n , p , s ,
212 and
213 .Cm u
214 conversions, this option has no effect.
215 For
216 .Cm o
217 conversions, the precision of the number is increased to force the first
218 character of the output string to a zero.
219 For
220 .Cm x
221 and
222 .Cm X
223 conversions, a non-zero result has the string
224 .Ql 0x
225 (or
226 .Ql 0X
227 for
228 .Cm X
229 conversions) prepended to it.
230 For
231 .Cm a , A , e , E , f , F , g ,
232 and
233 .Cm G
234 conversions, the result will always contain a decimal point, even if no
235 digits follow it (normally, a decimal point appears in the results of
236 those conversions only if a digit follows).
237 For
238 .Cm g
239 and
240 .Cm G
241 conversions, trailing zeros are not removed from the result as they
242 would otherwise be.
243 .It So Cm 0 Sc (zero)
244 Zero padding.
245 For all conversions except
246 .Cm n ,
247 the converted value is padded on the left with zeros rather than blanks.
248 If a precision is given with a numeric conversion
249 .Cm ( d , i , o , u , i , x ,
250 and
251 .Cm X ) ,
252 the
253 .Cm 0
254 flag is ignored.
255 .It Sq Cm \-
256 A negative field width flag;
257 the converted value is to be left adjusted on the field boundary.
258 Except for
259 .Cm n
260 conversions, the converted value is padded on the right with blanks,
261 rather than on the left with blanks or zeros.
262 A
263 .Cm \-
264 overrides a
265 .Cm 0
266 if both are given.
267 .It So "\ " Sc (space)
268 A blank should be left before a positive number
269 produced by a signed conversion
270 .Cm ( a , A , d , e , E , f , F , g , G ,
271 or
272 .Cm i ) .
273 .It Sq Cm +
274 A sign must always be placed before a
275 number produced by a signed conversion.
276 A
277 .Cm +
278 overrides a space if both are used.
279 .It So "'" Sc (apostrophe)
280 Decimal conversions
281 .Cm ( d , u ,
282 or
283 .Cm i )
284 or the integral portion of a floating point conversion
285 .Cm ( f
286 or
287 .Cm F )
288 should be grouped and separated by thousands using
289 the non-monetary separator returned by
290 .Xr localeconv 3 .
291 .El
292 .It
293 An optional separator character (
294 .Cm \ , | \; | \ : | _
295 ) used for separating multiple values when printing an AltiVec or SSE vector,
296 or other multi-value unit.
297 .Pp
298 NOTE: This is an extension to the
299 .Fn printf
300 specification.
301 Behaviour of these values for
302 .Fn printf
303 is only defined for operating systems conforming to the
304 AltiVec Technology Programming Interface Manual.
305 (At time of writing this includes only Mac OS X 10.2 and later.)
306 .It
307 An optional decimal digit string specifying a minimum field width.
308 If the converted value has fewer characters than the field width, it will
309 be padded with spaces on the left (or right, if the left-adjustment
310 flag has been given) to fill out
311 the field width.
312 .It
313 An optional precision, in the form of a period
314 .Cm \&.
315 followed by an
316 optional digit string.
317 If the digit string is omitted, the precision is taken as zero.
318 This gives the minimum number of digits to appear for
319 .Cm d , i , o , u , x ,
320 and
321 .Cm X
322 conversions, the number of digits to appear after the decimal-point for
323 .Cm a , A , e , E , f ,
324 and
325 .Cm F
326 conversions, the maximum number of significant digits for
327 .Cm g
328 and
329 .Cm G
330 conversions, or the maximum number of characters to be printed from a
331 string for
332 .Cm s
333 conversions.
334 .It
335 An optional length modifier, that specifies the size of the argument.
336 The following length modifiers are valid for the
337 .Cm d , i , n , o , u , x ,
338 or
339 .Cm X
340 conversion:
341 .Bl -column ".Cm q Em (deprecated)" ".Vt signed char" ".Vt unsigned long long" ".Vt long long *"
342 .It Sy Modifier Ta Cm d , i Ta Cm o , u , x , X Ta Cm n
343 .It Cm hh Ta Vt "signed char" Ta Vt "unsigned char" Ta Vt "signed char *"
344 .It Cm h Ta Vt short Ta Vt "unsigned short" Ta Vt "short *"
345 .It Cm l No (ell) Ta Vt long Ta Vt "unsigned long" Ta Vt "long *"
346 .It Cm ll No (ell ell) Ta Vt "long long" Ta Vt "unsigned long long" Ta Vt "long long *"
347 .It Cm j Ta Vt intmax_t Ta Vt uintmax_t Ta Vt "intmax_t *"
348 .It Cm t Ta Vt ptrdiff_t Ta (see note) Ta Vt "ptrdiff_t *"
349 .It Cm z Ta (see note) Ta Vt size_t Ta (see note)
350 .It Cm q Em (deprecated) Ta Vt quad_t Ta Vt u_quad_t Ta Vt "quad_t *"
351 .El
352 .Pp
353 Note:
354 the
355 .Cm t
356 modifier, when applied to a
357 .Cm o , u , x ,
358 or
359 .Cm X
360 conversion, indicates that the argument is of an unsigned type
361 equivalent in size to a
362 .Vt ptrdiff_t .
363 The
364 .Cm z
365 modifier, when applied to a
366 .Cm d
367 or
368 .Cm i
369 conversion, indicates that the argument is of a signed type equivalent in
370 size to a
371 .Vt size_t .
372 Similarly, when applied to an
373 .Cm n
374 conversion, it indicates that the argument is a pointer to a signed type
375 equivalent in size to a
376 .Vt size_t .
377 .Pp
378 The following length modifier is valid for the
379 .Cm a , A , e , E , f , F , g ,
380 or
381 .Cm G
382 conversion:
383 .Bl -column ".Sy Modifier" ".Cm a , A , e , E , f , F , g , G"
384 .It Sy Modifier Ta Cm a , A , e , E , f , F , g , G
385 .It Cm l No (ell) Ta Vt double
386 (ignored, same behavior as without it)
387 .It Cm L Ta Vt "long double"
388 .El
389 .Pp
390 The following length modifier is valid for the
391 .Cm c
392 or
393 .Cm s
394 conversion:
395 .Bl -column ".Sy Modifier" ".Vt wint_t" ".Vt wchar_t *"
396 .It Sy Modifier Ta Cm c Ta Cm s
397 .It Cm l No (ell) Ta Vt wint_t Ta Vt "wchar_t *"
398 .El
399 .Pp
400 The AltiVec Technology Programming Interface Manual also defines five additional length modifiers
401 which can be used (in place of the conventional length modifiers) for the printing of AltiVec or SSE vectors:
402 .Bl -tag -compact
403 .It Cm v
404 Treat the argument as a vector value, unit length will be determined by the conversion
405 specifier (default = 16 8-bit units for all integer conversions,
406 4 32-bit units for floating point conversions).
407 .It Cm vh, hv
408 Treat the argument as a vector of 8 16-bit units.
409 .It Cm vl, lv
410 Treat the argument as a vector of 4 32-bit units.
411 .El
412 .Pp
413 NOTE: The vector length specifiers are extensions to the
414 .Fn printf
415 specification.
416 Behaviour of these values for
417 .Fn printf
418 is only defined for operating systems conforming to the
419 AltiVec Technology Programming Interface Manual.
420 (At time of writing this includes only Mac OS X 10.2 and later.)
421 .Pp
422 As a further extension, for SSE2 64-bit units:
423 .Bl -tag -compact
424 .It Cm vll, llv
425 Treat the argument as a vector of 2 64-bit units.
426 .El
427 .It
428 A character that specifies the type of conversion to be applied.
429 .El
430 .Pp
431 A field width or precision, or both, may be indicated by
432 an asterisk
433 .Ql *
434 or an asterisk followed by one or more decimal digits and a
435 .Ql $
436 instead of a
437 digit string.
438 In this case, an
439 .Vt int
440 argument supplies the field width or precision.
441 A negative field width is treated as a left adjustment flag followed by a
442 positive field width; a negative precision is treated as though it were
443 missing.
444 If a single format directive mixes positional
445 .Pq Li nn$
446 and non-positional arguments, the results are undefined.
447 .Pp
448 The conversion specifiers and their meanings are:
449 .Bl -tag -width ".Cm diouxX"
450 .It Cm diouxX
451 The
452 .Vt int
453 (or appropriate variant) argument is converted to signed decimal
454 .Cm ( d
455 and
456 .Cm i ) ,
457 unsigned octal
458 .Pq Cm o ,
459 unsigned decimal
460 .Pq Cm u ,
461 or unsigned hexadecimal
462 .Cm ( x
463 and
464 .Cm X )
465 notation.
466 The letters
467 .Dq Li abcdef
468 are used for
469 .Cm x
470 conversions; the letters
471 .Dq Li ABCDEF
472 are used for
473 .Cm X
474 conversions.
475 The precision, if any, gives the minimum number of digits that must
476 appear; if the converted value requires fewer digits, it is padded on
477 the left with zeros.
478 .It Cm DOU
479 The
480 .Vt "long int"
481 argument is converted to signed decimal, unsigned octal, or unsigned
482 decimal, as if the format had been
483 .Cm ld , lo ,
484 or
485 .Cm lu
486 respectively.
487 These conversion characters are deprecated, and will eventually disappear.
488 .It Cm eE
489 The
490 .Vt double
491 argument is rounded and converted in the style
492 .Sm off
493 .Oo \- Oc Ar d Li \&. Ar ddd Li e \(+- Ar dd
494 .Sm on
495 where there is one digit before the
496 decimal-point character
497 and the number of digits after it is equal to the precision;
498 if the precision is missing,
499 it is taken as 6; if the precision is
500 zero, no decimal-point character appears.
501 An
502 .Cm E
503 conversion uses the letter
504 .Ql E
505 (rather than
506 .Ql e )
507 to introduce the exponent.
508 The exponent always contains at least two digits; if the value is zero,
509 the exponent is 00.
510 .Pp
511 For
512 .Cm a , A , e , E , f , F , g ,
513 and
514 .Cm G
515 conversions, positive and negative infinity are represented as
516 .Li inf
517 and
518 .Li -inf
519 respectively when using the lowercase conversion character, and
520 .Li INF
521 and
522 .Li -INF
523 respectively when using the uppercase conversion character.
524 Similarly, NaN is represented as
525 .Li nan
526 when using the lowercase conversion, and
527 .Li NAN
528 when using the uppercase conversion.
529 .It Cm fF
530 The
531 .Vt double
532 argument is rounded and converted to decimal notation in the style
533 .Sm off
534 .Oo \- Oc Ar ddd Li \&. Ar ddd ,
535 .Sm on
536 where the number of digits after the decimal-point character
537 is equal to the precision specification.
538 If the precision is missing, it is taken as 6; if the precision is
539 explicitly zero, no decimal-point character appears.
540 If a decimal point appears, at least one digit appears before it.
541 .It Cm gG
542 The
543 .Vt double
544 argument is converted in style
545 .Cm f
546 or
547 .Cm e
548 (or
549 .Cm F
550 or
551 .Cm E
552 for
553 .Cm G
554 conversions).
555 The precision specifies the number of significant digits.
556 If the precision is missing, 6 digits are given; if the precision is zero,
557 it is treated as 1.
558 Style
559 .Cm e
560 is used if the exponent from its conversion is less than \-4 or greater than
561 or equal to the precision.
562 Trailing zeros are removed from the fractional part of the result; a
563 decimal point appears only if it is followed by at least one digit.
564 .It Cm aA
565 The
566 .Vt double
567 argument is rounded and converted to hexadecimal notation in the style
568 .Sm off
569 .Oo \- Oc Li 0x Ar h Li \&. Ar hhhp Oo \(+- Oc Ar d ,
570 .Sm on
571 where the number of digits after the hexadecimal-point character
572 is equal to the precision specification.
573 If the precision is missing, it is taken as enough to represent
574 the floating-point number exactly, and no rounding occurs.
575 If the precision is zero, no hexadecimal-point character appears.
576 The
577 .Cm p
578 is a literal character
579 .Ql p ,
580 and the exponent consists of a positive or negative sign
581 followed by a decimal number representing an exponent of 2.
582 The
583 .Cm A
584 conversion uses the prefix
585 .Dq Li 0X
586 (rather than
587 .Dq Li 0x ) ,
588 the letters
589 .Dq Li ABCDEF
590 (rather than
591 .Dq Li abcdef )
592 to represent the hex digits, and the letter
593 .Ql P
594 (rather than
595 .Ql p )
596 to separate the mantissa and exponent.
597 .Pp
598 Note that there may be multiple valid ways to represent floating-point
599 numbers in this hexadecimal format.
600 For example,
601 .Li 0x1.92p+1 , 0x3.24p+0 , 0x6.48p-1 ,
602 and
603 .Li 0xc.9p-2
604 are all equivalent.
605 The format chosen depends on the internal representation of the
606 number, but the implementation guarantees that the length of the
607 mantissa will be minimized.
608 Zeroes are always represented with a mantissa of 0 (preceded by a
609 .Ql -
610 if appropriate) and an exponent of
611 .Li +0 .
612 .It Cm C
613 Treated as
614 .Cm c
615 with the
616 .Cm l
617 (ell) modifier.
618 .It Cm c
619 The
620 .Vt int
621 argument is converted to an
622 .Vt "unsigned char" ,
623 and the resulting character is written.
624 .Pp
625 If the
626 .Cm l
627 (ell) modifier is used, the
628 .Vt wint_t
629 argument shall be converted to a
630 .Vt wchar_t ,
631 and the (potentially multi-byte) sequence representing the
632 single wide character is written, including any shift sequences.
633 If a shift sequence is used, the shift state is also restored
634 to the original state after the character.
635 .It Cm S
636 Treated as
637 .Cm s
638 with the
639 .Cm l
640 (ell) modifier.
641 .It Cm s
642 The
643 .Vt "char *"
644 argument is expected to be a pointer to an array of character type (pointer
645 to a string).
646 Characters from the array are written up to (but not including)
647 a terminating
648 .Dv NUL
649 character;
650 if a precision is specified, no more than the number specified are
651 written.
652 If a precision is given, no null character
653 need be present; if the precision is not specified, or is greater than
654 the size of the array, the array must contain a terminating
655 .Dv NUL
656 character.
657 .Pp
658 If the
659 .Cm l
660 (ell) modifier is used, the
661 .Vt "wchar_t *"
662 argument is expected to be a pointer to an array of wide characters
663 (pointer to a wide string).
664 For each wide character in the string, the (potentially multi-byte)
665 sequence representing the
666 wide character is written, including any shift sequences.
667 If any shift sequence is used, the shift state is also restored
668 to the original state after the string.
669 Wide characters from the array are written up to (but not including)
670 a terminating wide
671 .Dv NUL
672 character;
673 if a precision is specified, no more than the number of bytes specified are
674 written (including shift sequences).
675 Partial characters are never written.
676 If a precision is given, no null character
677 need be present; if the precision is not specified, or is greater than
678 the number of bytes required to render the multibyte representation of
679 the string, the array must contain a terminating wide
680 .Dv NUL
681 character.
682 .It Cm p
683 The
684 .Vt "void *"
685 pointer argument is printed in hexadecimal (as if by
686 .Ql %#x
687 or
688 .Ql %#lx ) .
689 .It Cm n
690 The number of characters written so far is stored into the
691 integer indicated by the
692 .Vt "int *"
693 (or variant) pointer argument.
694 No argument is converted.
695 The
696 .Fa format
697 argument must be in write-protected memory if this specifier is used; see
698 .Sx SECURITY CONSIDERATIONS
699 below.
700 .It Cm %
701 A
702 .Ql %
703 is written.
704 No argument is converted.
705 The complete conversion specification
706 is
707 .Ql %% .
708 .El
709 .Pp
710 The decimal point
711 character is defined in the program's locale (category
712 .Dv LC_NUMERIC ) .
713 .Pp
714 In no case does a non-existent or small field width cause truncation of
715 a numeric field; if the result of a conversion is wider than the field
716 width, the
717 field is expanded to contain the conversion result.
718 .Sh RETURN VALUES
719 These functions return the number of characters printed
720 (not including the trailing
721 .Ql \e0
722 used to end output to strings),
723 except for
724 .Fn snprintf
725 and
726 .Fn vsnprintf ,
727 which return the number of characters that would have been printed if the
728 .Fa size
729 were unlimited
730 (again, not including the final
731 .Ql \e0 ) .
732 These functions return a negative value if an error occurs.
733 .Sh EXAMPLES
734 To print a date and time in the form
735 .Dq Li "Sunday, July 3, 10:02" ,
736 where
737 .Fa weekday
738 and
739 .Fa month
740 are pointers to strings:
741 .Bd -literal -offset indent
742 #include <stdio.h>
743 fprintf(stdout, "%s, %s %d, %.2d:%.2d\en",
744 weekday, month, day, hour, min);
745 .Ed
746 .Pp
747 To print \*(Pi
748 to five decimal places:
749 .Bd -literal -offset indent
750 #include <math.h>
751 #include <stdio.h>
752 fprintf(stdout, "pi = %.5f\en", 4 * atan(1.0));
753 .Ed
754 .Pp
755 To allocate a 128 byte string and print into it:
756 .Bd -literal -offset indent
757 #include <stdio.h>
758 #include <stdlib.h>
759 #include <stdarg.h>
760 char *newfmt(const char *fmt, ...)
761 {
762 char *p;
763 va_list ap;
764 if ((p = malloc(128)) == NULL)
765 return (NULL);
766 va_start(ap, fmt);
767 (void) vsnprintf(p, 128, fmt, ap);
768 va_end(ap);
769 return (p);
770 }
771 .Ed
772 .Sh COMPATIBILITY
773 The conversion formats
774 .Cm \&%D , \&%O ,
775 and
776 .Cm \&%U
777 are not standard and
778 are provided only for backward compatibility.
779 The effect of padding the
780 .Cm %p
781 format with zeros (either by the
782 .Cm 0
783 flag or by specifying a precision), and the benign effect (i.e., none)
784 of the
785 .Cm #
786 flag on
787 .Cm %n
788 and
789 .Cm %p
790 conversions, as well as other
791 nonsensical combinations such as
792 .Cm %Ld ,
793 are not standard; such combinations
794 should be avoided.
795 .Sh ERRORS
796 In addition to the errors documented for the
797 .Xr write 2
798 system call, the
799 .Fn printf
800 family of functions may fail if:
801 .Bl -tag -width Er
802 .It Bq Er EILSEQ
803 An invalid wide character code was encountered.
804 .It Bq Er ENOMEM
805 Insufficient storage space is available.
806 .El
807 .Sh SEE ALSO
808 .Xr printf 1 ,
809 .Xr printf_l 3 ,
810 .Xr fmtcheck 3 ,
811 .Xr scanf 3 ,
812 .Xr setlocale 3 ,
813 .Xr stdarg 3 ,
814 .Xr wprintf 3
815 .Sh STANDARDS
816 Subject to the caveats noted in the
817 .Sx BUGS
818 section below, the
819 .Fn fprintf ,
820 .Fn printf ,
821 .Fn sprintf ,
822 .Fn vprintf ,
823 .Fn vfprintf ,
824 and
825 .Fn vsprintf
826 functions
827 conform to
828 .St -ansiC
829 and
830 .St -isoC-99 .
831 With the same reservation, the
832 .Fn snprintf
833 and
834 .Fn vsnprintf
835 functions conform to
836 .St -isoC-99 ,
837 while
838 .Fn dprintf
839 and
840 .Fn vdprintf
841 conform to
842 .St -p1003.1-2008 .
843 .Sh HISTORY
844 The functions
845 .Fn asprintf
846 and
847 .Fn vasprintf
848 first appeared in the
849 .Tn GNU C
850 library.
851 These were implemented by
852 .An Peter Wemm Aq Mt peter@FreeBSD.org
853 in
854 .Fx 2.2 ,
855 but were later replaced with a different implementation
856 from
857 .Ox 2.3
858 by
859 .An Todd C. Miller Aq Mt Todd.Miller@courtesan.com .
860 The
861 .Fn dprintf
862 and
863 .Fn vdprintf
864 functions were added in
865 .Fx 8.0 .
866 .Sh BUGS
867 The
868 .Nm
869 family of functions do not correctly handle multibyte characters in the
870 .Fa format
871 argument.
872 .Sh SECURITY CONSIDERATIONS
873 The
874 .Fn sprintf
875 and
876 .Fn vsprintf
877 functions are easily misused in a manner which enables malicious users
878 to arbitrarily change a running program's functionality through
879 a buffer overflow attack.
880 Because
881 .Fn sprintf
882 and
883 .Fn vsprintf
884 assume an infinitely long string,
885 callers must be careful not to overflow the actual space;
886 this is often hard to assure.
887 For safety, programmers should use the
888 .Fn snprintf
889 interface instead.
890 For example:
891 .Bd -literal
892 void
893 foo(const char *arbitrary_string, const char *and_another)
894 {
895 char onstack[8];
896
897 #ifdef BAD
898 /*
899 * This first sprintf is bad behavior. Do not use sprintf!
900 */
901 sprintf(onstack, "%s, %s", arbitrary_string, and_another);
902 #else
903 /*
904 * The following two lines demonstrate better use of
905 * snprintf().
906 */
907 snprintf(onstack, sizeof(onstack), "%s, %s", arbitrary_string,
908 and_another);
909 #endif
910 }
911 .Ed
912 .Pp
913 The
914 .Fn printf
915 and
916 .Fn sprintf
917 family of functions are also easily misused in a manner
918 allowing malicious users to arbitrarily change a running program's
919 functionality by either causing the program
920 to print potentially sensitive data
921 .Dq "left on the stack" ,
922 or causing it to generate a memory fault or bus error
923 by dereferencing an invalid pointer.
924 .Pp
925 .Cm %n
926 can be used to write arbitrary data to potentially carefully-selected
927 addresses.
928 Programmers are therefore strongly advised to never pass untrusted strings
929 as the
930 .Fa format
931 argument, as an attacker can put format specifiers in the string
932 to mangle your stack,
933 leading to a possible security hole.
934 This holds true even if the string was built using a function like
935 .Fn snprintf ,
936 as the resulting string may still contain user-supplied conversion specifiers
937 for later interpolation by
938 .Fn printf .
939 For this reason, a
940 .Fa format
941 argument containing
942 .Cm %n
943 is assumed to be untrustworthy if located in writable memory (i.e. memory with
944 protection PROT_WRITE; see
945 .Xr mprotect 2 )
946 and any attempt to use such an argument is fatal.
947 Practically, this means that
948 .Cm %n
949 is permitted in literal
950 .Fa format
951 strings but disallowed in
952 .Fa format
953 strings located in normal stack- or heap-allocated memory.
954 .Pp
955 Always use the proper secure idiom:
956 .Pp
957 .Dl "snprintf(buffer, sizeof(buffer), \*q%s\*q, string);"