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Formatted Output


Print Formats · Print Functions · Print Conversion Specifiers


Several library functions help you convert data values from encoded internal representations to text sequences that are generally readable by people. You provide a format string as the value of the format argument to each of these functions, hence the term formatted output. The functions fall into two categories.

The byte print functions (declared in <stdio.h>) convert internal representations to sequences of type char, and help you compose such sequences for display: fprintf, printf, sprintf, vfprintf, vprintf, and vsprintf. For these function, a format string is a multibyte string that begins and ends in the initial shift state.

The wide print functions (declared in <wchar.h> and hence added with Amendment 1) convert internal representations to sequences of type wchar_t, and help you compose such sequences for display: fwprintf, swprintf, wprintf, vfwprintf, vswprintf, and vwprintf. For these functions, a format string is a wide-character string. In the descriptions that follow, a wide character wc from a format string or a stream is compared to a specific (byte) character c as if by evaluating the expression wctob(wc) == c.

Print Formats

A format string has the same syntax for both the print functions and the scan functions, as shown in the diagram.

A format string consists of zero or more conversion specifications interspersed with literal text and white space. White space is a sequence of one or more characters c for which the call isspace(c) returns nonzero. (The characters defined as white space can change when you change the LC_CTYPE locale category.) For the print functions, a conversion specification is one of the print conversion specifications described below.

A print function scans the format string once from beginning to end to determine what conversions to perform. Every print function accepts a varying number of arguments, either directly or under control of an argument of type va_list. Some print conversion specifications in the format string use the next argument in the list. A print function uses each successive argument no more than once. Trailing arguments can be left unused.

In the description that follows:

Print Functions

For the print functions, literal text or white space in a format string generates characters that match the characters in the format string. A print conversion specification typically generates characters by converting the next argument value to a corresponding text sequence. A print conversion specification has the format:

Boldface indicates a feature added with C99.

Following the percent character (%) in the format string, you can write zero or more format flags:

Following any format flags, you can write a field width that specifies the minimum number of characters to generate for the conversion. Unless altered by a format flag, the default behavior is to pad a short conversion on the left with space characters. If you write an asterisk (*) instead of a decimal number for a field width, then a print function takes the value of the next argument (which must be of type int) as the field width. If the argument value is negative, it supplies a - format flag and its magnitude is the field width.

Following any field width, you can write a dot (.) followed by a precision that specifies one of the following: the minimum number of digits to generate on an integer conversion; the number of fraction digits to generate on an e, E, or f conversion; the maximum number of significant digits to generate on a g or G conversion; or the maximum number of characters to generate from a C string on an s conversion.

If you write an * instead of a decimal number for a precision, a print function takes the value of the next argument (which must be of type int) as the precision. If the argument value is negative, the default precision applies. If you do not write either an * or a decimal number following the dot, the precision is zero.

Print Conversion Specifiers

Following any precision, you must write a one-character print conversion specifier, possibly preceded by a one- or two-character qualifier. Each combination determines the type required of the next argument (if any) and how the library functions alter the argument value before converting it to a text sequence. The integer and floating-point conversions also determine what base to use for the text representation. If a conversion specifier requires a precision p and you do not provide one in the format, then the conversion specifier chooses a default value for the precision. The following table lists all defined combinations and their properties.

Conversion  Argument        Converted          Default  Pre-
 Specifier    Type            Value              Base  cision

   %c       int x          (unsigned char)x
  %lc       wint_t x       wchar_t a[2] = {x}

   %d       int x          (int)x                 10     1
  %hd       int x          (short)x               10     1
  %ld       long x         (long)x                10     1

   %e       double x       (double)x              10     6
  %Le       long double x  (long double)x         10     6
   %E       double x       (double)x              10     6
  %LE       long double x  (long double)x         10     6

   %f       double x       (double)x              10     6
  %Lf       long double x  (long double)x         10     6

   %g       double x       (double)x              10     6
  %Lg       long double x  (long double)x         10     6
   %G       double x       (double)x              10     6
  %LG       long double x  (long double)x         10     6

   %i       int x          (int)x                 10     1
  %hi       int x          (short)x               10     1
  %li       long x         (long)x                10     1

   %n       int *x
  %hn       short *x
  %ln       long *x

   %o       int x          (unsigned int)x         8     1
  %ho       int x          (unsigned short)x       8     1
  %lo       long x         (unsigned long)x        8     1

   %p       void *x        (void *)x

   %s       char x[]       x[0]...                     large
  %ls       wchar_t x[]    x[0]...                     large

   %u       int x          (unsigned int)x        10     1
  %hu       int x          (unsigned short)x      10     1
  %lu       long x         (unsigned long)x       10     1

   %x       int x          (unsigned int)x        16     1
  %hx       int x          (unsigned short)x      16     1
  %lx       long x         (unsigned long)x       16     1

   %X       int x          (unsigned int)x        16     1
  %hX       int x          (unsigned short)x      16     1
  %lX       long x         (unsigned long)x       16     1

   %%       none           '%'

The print conversion specifier determines any behavior not summarized in this table. For all floating-point conversions:

The upper-case version prints only for an upper-case conversion specifier, such as %E but not %Lg.

In the following descriptions, p is the precision. Examples follow each of the print conversion specifiers. A single conversion can generate up to 509 characters.

You write %c to generate a single character from the converted value.

    printf("%c", 'a')               generates a
    printf("<%3c|%-3c>", 'a', 'b')  generates <  a|b  >

For a wide stream, conversion of the character x occurs as if by calling btowc(x).

    wprintf(L"%c", 'a')             generates btowc(a)

You write %lc to generate a single character from the converted value. Conversion of the character x occurs as if it is followed by a null character in an array of two elements of type wchar_t converted by the conversion specification ls.

    printf("%lc", L'a')             generates a
    wprintf(L"lc", L'a')            generates L'a'

You write %d, %i, %o, %u, %x, or %X to generate a possibly signed integer representation. %d or %i specifies signed decimal representation, %o unsigned octal, %u unsigned decimal, %x unsigned hexadecimal using the digits 0-9 and a-f, and %X unsigned hexadecimal using the digits 0-9 and A-F. The conversion generates at least p digits to represent the converted value. If p is zero, a converted value of zero generates no digits.

    printf("%d %o %x", 31, 31, 31)  generates 31 37 1f
    printf("%hu", 0xffff)           generates 65535
    printf("%#X %+d", 31, 31)       generates 0X1F +31

You write %e or %E to generate a signed decimal fractional representation with a decimal power-of-ten exponent. The generated text takes the form ±d.dddE±dd, where ± is either a plus or minus sign, d is a decimal digit, the decimal point (.) is the decimal point for the current locale, and E is either e (for %e conversion) or E (for %E conversion). The generated text has one integer digit, a decimal point if p is nonzero or if you specify the # format flag, p fraction digits, and at least two exponent digits. The result is rounded. The value zero has a zero exponent.

    printf("%e", 31.4)              generates 3.140000e+01
    printf("%.2E", 31.4)            generates 3.14E+01

You write %f to generate a signed decimal fractional representation with no exponent. The generated text takes the form ±d.ddd, where ± is either a plus or minus sign, d is a decimal digit, and the decimal point (.) is the decimal point for the current locale. The generated text has at least one integer digit, a decimal point if p is nonzero or if you specify the # format flag, and p fraction digits. The result is rounded.

    printf("%f", 31.4)              generates 31.400000
    printf("%.0f %#.0f", 31.0, 31.0)generates 31 31.

You write %g or %G to generate a signed decimal fractional representation with or without a decimal power-of-ten exponent, as appropriate. For %g conversion, the generated text takes the same form as either %e or %f conversion. For %G conversion, it takes the same form as either %E or %f conversion. The precision p specifies the number of significant digits generated. (If p is zero, it is changed to 1.) If %e conversion would yield an exponent in the range [-4, p), then %f conversion occurs instead. The generated text has no trailing zeros in any fraction and has a decimal point only if there are nonzero fraction digits, unless you specify the # format flag.

    printf("%.6g", 31.4)            generates 31.4
    printf("%.1g", 31.4)            generates 3.14e+01

You write %n to store the number of characters generated (up to this point in the format) in an integer object whose address is the value of the next successive argument.

    printf("abc%n", &x)                   stores 3

You write %p to generate an external representation of a pointer to void. The conversion is implementation defined.

    printf("%p", (void *)&x)        generates, e.g. F4C0

You write %s to generate a sequence of characters from the values stored in the argument C string.

    printf("%s", "hello")           generates hello
    printf("%.2s", "hello")         generates he

For a wide stream, conversion occurs as if by repeatedly calling mbrtowc, beginning in the initial conversion state. The conversion generates no more than p characters, up to but not including the terminating null character.

    wprintf(L"%s", "hello")         generates hello

You write %ls to generate a sequence of characters from the values stored in the argument wide-character string. For a byte stream, conversion occurs as if by repeatedly calling wcrtomb, beginning in the initial conversion state, so long as complete multibyte characters can be generated. The conversion generates no more than p characters, up to but not including the terminating null character.

    printf("%ls", L"hello")         generates hello
    wprintf(L"%.2s", L"hello")      generates he

You write %% to generate the percent character (%).

    printf("%%")                    generates %

See also the Table of Contents and the Index.

Copyright © 1989-2002 by P.J. Plauger and Jim Brodie. All rights reserved.

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