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Numerics abs acos acosf acosh acoshf acoshl acosl asin asinf asinh asinhf asinhl asinl atan atan2 atan2f atan2l atanf atanh atanhf atanhl atanl cabs cabsf cabsl cacos cacosf cacosh cacoshf cacoshl cacosl carg cargf cargl casin casinf casinh casinhf casinhl casinl catan catanf catanh catanhf catanhl catanl cbrt cbrtf cbrtl ccos ccosf ccosh ccoshf ccoshl ccosl ceil ceilf ceill cexp cexpf cexpl cimag cimagf cimagl clog clogf clogl CMPLX CMPLXF CMPLXL Common mathematical functions complex Complex number arithmetic conj conjf conjl copysign copysignf copysignl cos cosf cosh coshf coshl cosl cpow cpowf cpowl cproj cprojf cprojl creal crealf creall csin csinf csinh csinhf csinhl csinl csqrt csqrtf csqrtl ctan ctanf ctanh ctanhf ctanhl ctanl div double_t erf erfc erfcf erfcl erff erfl exp exp2 exp2f exp2l expf expl expm1 expm1f expm1l fabs fabsf fabsl fdim feclearexcept fegetenv fegetexceptflag fegetround feholdexcept feraiseexcept fesetenv fesetexceptflag fesetround fetestexcept feupdateenv FE_ALL_EXCEPT FE_DFL_ENV FE_DIVBYZERO FE_DOWNWARD FE_INEXACT FE_INVALID FE_OVERFLOW FE_TONEAREST FE_TOWARDZERO FE_UNDERFLOW FE_UPWARD Floating-point environment float_t floor floorf floorl fma fmaf fmal fmax fmaxf fmaxl fmin fminf fminl fmod fmodf fmodl fpclassify FP_INFINITE FP_NAN FP_NORMAL FP_SUBNORMAL FP_ZERO frexp frexpf frexpl HUGE_VAL HUGE_VALF HUGE_VALL hypot hypotf hypotl I ilogb ilogbf ilogbl imaginary imaxabs imaxdiv INFINITY isfinite isgreater isgreaterequal isinf isless islessequal islessgreater isnan isnormal isunordered labs ldexp ldexpf ldexpl ldiv lgamma lgammaf lgammal llabs lldiv llrint llrintf llrintl llround llroundf llroundl log log10 log10f log10l log1p log1pf log1pl log2 log2f log2l logb logbf logbl logf logl lrint lrintf lrintl lround lroundf lroundl MATH_ERREXCEPT math_errhandling MATH_ERRNO modf modff modfl nan NAN nanf nanl nearbyint nearbyintf nearbyintl nextafter nextafterf nextafterl nexttoward nexttowardf nexttowardl Numerics pow powf powl Pseudo-random number generation rand RAND_MAX remainder remainderf remainderl remquo remquof remquol rint rintf rintl round roundf roundl scalbln scalblnf scalblnl scalbn scalbnf scalbnl signbit sin sinf sinh sinhf sinhl sinl sqrt sqrtf sqrtl srand tan tanf tanh tanhf tanhl tanl tgamma tgammaf tgammal trunc truncf truncl Type-generic math _Complex_I _Imaginary_I Program support abort atexit at_quick_exit exit EXIT_FAILURE EXIT_SUCCESS getenv getenv_s jmp_buf longjmp Program support utilities quick_exit raise setjmp SIGABRT SIGFPE SIGILL SIGINT signal SIGSEGV SIGTERM sig_atomic_t SIG_DFL SIG_ERR SIG_IGN system _Exit Strings atof atoi atol atoll btowc c16rtomb c32rtomb char16_t char32_t isalnum isalpha isblank iscntrl isdigit isgraph islower isprint ispunct isspace isupper iswalnum iswalpha iswblank iswcntrl iswctype iswdigit iswgraph iswlower iswprint iswpunct iswspace iswupper iswxdigit isxdigit mblen mbrlen mbrtoc16 mbrtoc32 mbrtowc mbsinit mbsrtowcs mbsrtowcs_s mbstate_t mbstowcs mbstowcs_s mbtowc memchr memcmp memcpy memcpy_s memmove memmove_s memset memset_s Null-terminated byte strings Null-terminated multibyte strings Null-terminated wide strings strcat strcat_s strchr strcmp strcoll strcpy strcpy_s strcspn strerror strerrorlen_s strerror_s Strings library strlen strncat Thread support call_once cnd_broadcast cnd_destroy cnd_init cnd_signal cnd_timedwait cnd_wait mtx_destroy mtx_init mtx_lock mtx_plain mtx_recursive mtx_timed mtx_timedlock mtx_trylock mtx_unlock once_flag ONCE_FLAG_INIT thrd_busy thrd_create thrd_current thrd_detach thrd_equal thrd_error thrd_exit thrd_join thrd_nomem thrd_sleep thrd_success thrd_timedout thrd_yield Thread support library thread_local tss_create tss_delete TSS_DTOR_ITERATIONS tss_get tss_set Type support Boolean type support library Fixed width integer types FLT_EVAL_METHOD FLT_ROUNDS max_align_t NULL Numeric limits offsetof ptrdiff_t size_t Type support Variadic functions Variadic functions va_arg va_copy va_end va_list va_start
テキスト

在头文件<stdio.h>中定义




(1)


int printf(const char * format,...);

(直到C99)


int printf(const char * restrict format,...);

(自C99以来)



(2)


int fprintf(FILE * stream,const char * format,...);

(直到C99)


int fprintf(FILE * restrict stream,const char * restrict format,...);

(自C99以来)



(3)


int sprintf(char * buffer,const char * format,...);

(直到C99)


int sprintf(char * restrict buffer,const char * restrict format,...);

(自C99以来)


int snprintf(char *限制缓冲区,int bufsz,const char *限制格式,...);

(4)

(自C99以来)

int printf_s(const char * restrict format,...);

(5)

(自C11以来)

int fprintf_s(FILE * restrict stream,const char * restrict format,...);

(6)

(自C11以来)

int sprintf_s(char * restrict buffer,rsize_t bufsz,const char * restrict format,...);

(7)

(自C11以来)

int snprintf_s(char * restrict buffer,rsize_t bufsz,const char * restrict format,...);

(8)

(自C11以来)

从给定的位置加载数据,将它们转换为字符串等价物并将结果写入各种接收器。

1)将结果写入输出流stdout

2)将结果写入输出流stream

3)将结果写入字符串buffer。如果要写入的字符串(加上终止的空字符)超过了指向的数组的大小,则行为未定义buffer

4)将结果写入字符串buffer。最多bufsz- 写入1个字符。结果字符串将以空字符结尾,除非bufsz为零。如果bufsz为零,则不会写入任何内容,并且buffer可能是空指针,但返回值(将写入的字节数)仍然会计算并返回。

5-8)与(1-4)相同,只是在运行时检测到以下错误并调用当前安装的约束处理函数:

  • 转换说明符%n存在于format

  • 任何对应的参数%s都是空指针

  • format或者buffer是空指针

  • bufsz 是零或大于 RSIZE_MAX

  • 编码错误出现在任何字符串和字符转换说明符中

  • sprintf_s仅限于),要存储的字符串buffer(包括结尾空值)将被超出bufsz

由于所有的边界检查功能,printf_sfprintf_ssprintf_s,和snrintf_s仅保证可供如果__STDC_LIB_EXT1__由实现所定义,并且如果用户定义__STDC_WANT_LIB_EXT1__的整数常数1,包括之前<stdio.h>

参数

-

输出文件流写入




































































































































缓冲

-

指向要写入的字符串的指针




































































































































bufsz

-

最多bufsz  - 可能会写入1个字符,再加上空终止符




































































































































格式

-

pointer to a null-terminated multibyte string specifying how to interpret the data. The format string consists of ordinary multibyte characters (except %), which are copied unchanged into the output stream, and conversion specifications. Each conversion specification has the following format:   introductory % character   (optional) one or more flags that modify the behavior of the conversion:    -: the result of the conversion is left-justified within the field (by default it is right-justified)   +: the sign of signed conversions is always prepended to the result of the conversion (by default the result is preceded by minus only when it is negative)   space: if the result of a signed conversion does not start with a sign character, or is empty, space is prepended to the result. It is ignored if + flag is present.   # : alternative form of the conversion is performed. See the table below for exact effects otherwise the behavior is undefined.   0 : for integer and floating point number conversions, leading zeros are used to pad the field instead of space characters. For integer numbers it is ignored if the precision is explicitly specified. For other conversions using this flag results in undefined behavior. It is ignored if - flag is present.    (optional) integer value or * that specifies minimum field width. The result is padded with space characters (by default), if required, on the left when right-justified, or on the right if left-justified. In the case when * is used, the width is specified by an additional argument of type int. If the value of the argument is negative, it results with the - flag specified and positive field width. (Note: This is the minimum width: The value is never truncated.)    (optional) . followed by integer number or *, or neither that specifies precision of the conversion. In the case when * is used, the precision is specified by an additional argument of type int. If the value of this argument is negative, it is ignored. If neither a number nor * is used, the precision is taken as zero. See the table below for exact effects of precision.   (optional) length modifier that specifies the size of the argument   conversion format specifier           The following format specifiers are available:    Conversion specifier   Explanation   Argument type     length modifier   hh (C99).   h   (none)   l   ll (C99).   j (C99).   z (C99).   t (C99).   L     %   writes literal %. The full conversion specification must be %%.   N/A   N/A   N/A   N/A   N/A   N/A   N/A   N/A   N/A     c    writes a single character.  The argument is first converted to unsigned char. If the l modifier is used, the argument is first converted to a character string as if by %ls with a wchar_t2 argument.   N/A   N/A   int   wint_t   N/A   N/A   N/A   N/A   N/A     s    writes a character string  The argument must be a pointer to the initial element of an array of characters. Precision specifies the maximum number of bytes to be written. If Precision is not specified, writes every byte up to and not including the first null terminator. If the l specifier is used, the argument must be a pointer to the initial element of an array of wchar_t, which is converted to char array as if by a call to wcrtomb with zero-initialized conversion state.   N/A   N/A   char*   wchar_t*   N/A   N/A   N/A   N/A   N/A     d i   converts a signed integer into decimal representation -dddd.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters.   signed char   short   int   long   long long   intmax_t   signed size_t    ptrdiff_t   N/A     o   converts a unsigned integer into octal representation oooo.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters. In the alternative implementation precision is increased if necessary, to write one leading zero. In that case if both the converted value and the precision are 0, single 0 is written.   unsigned char   unsigned short   unsigned int   unsigned long   unsigned long long   uintmax_t   size_t   unsigned version of ptrdiff_t    N/A     x X   converts an unsigned integer into hexadecimal representation hhhh.  For the x conversion letters abcdef are used. For the X conversion letters ABCDEF are used. Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters. In the alternative implementation 0x or 0X is prefixed to results if the converted value is nonzero.   N/A     u   converts an unsigned integer into decimal representation dddd.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters.   N/A     f F   converts floating-point number to the decimal notation in the style -ddd.ddd.  Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is 6. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.   N/A   N/A   double    double (C99)    N/A   N/A   N/A   N/A   long double     e  E   converts floating-point number to the decimal exponent notation.  For the e conversion style -d.ddde±dd is used. For the E conversion style -d.dddE±dd is used. The exponent contains at least two digits, more digits are used only if necessary. If the value is 0, the exponent is also 0. Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is 6. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.   N/A   N/A   N/A   N/A   N/A   N/A     a  A (C99).   converts floating-point number to the hexadecimal exponent notation.  For the a conversion style -0xh.hhhp±d is used. For the A conversion style -0Xh.hhhP±d is used. The first hexadecimal digit is 0 if the argument is not a normalized floating point value. If the value is 0, the exponent is also 0. Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is sufficient for exact representation of the value. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.   N/A   N/A   N/A   N/A   N/A   N/A     g  G   converts floating-point number to decimal or decimal exponent notation depending on the value and the precision.  For the g conversion style conversion with style e or f will be performed. For the G conversion style conversion with style E or F will be performed. Let P equal the precision if nonzero, 6 if the precision is not specified, or 1 if the precision is 0. Then, if a conversion with style E would have an exponent of X:   if P > X ≥ −4, the conversion is with style f or F and precision P − 1 − X.   otherwise, the conversion is with style e or E and precision P − 1.   Unless alternative representation is requested the trailing zeros are removed, also the decimal point character is removed if no fractional part is left. For infinity and not-a-number conversion style see notes.   N/A   N/A   N/A   N/A   N/A   N/A     n   returns the number of characters written so far by this call to the function.  The result is written to the value pointed to by the argument. The specification may not contain any flag, field width, or precision.   signed char*   short*   int*   long*   long long*   intmax_t*   signed size_t*    ptrdiff_t*   N/A     p   writes an implementation defined character sequence defining a pointer.   N/A   N/A   void*   N/A   N/A   N/A   N/A   N/A   N/A    The floating point conversion functions convert infinity to inf or infinity. Which one is used is implementation defined. Not-a-number is converted to nan or nan(char_sequence). Which one is used is implementation defined. The conversions F, E, G, A output INF, INFINITY, NAN instead. Even though %c expects int argument, it is safe to pass a char because of the integer promotion that takes place when a variadic function is called. The correct conversion specifications for the fixed-width character types (int8_t, etc) are defined in the header <inttypes.h> (although PRIdMAX, PRIuMAX, etc is synonymous with %jd, %ju, etc). The memory-writing conversion specifier %n is a common target of security exploits where format strings depend on user input and is not supported by the bounds-checked printf_s family of functions. There is a sequence point after the action of each conversion specifier; this permits storing multiple %n results in the same variable or, as an edge case, printing a string modified by an earlier %n within the same call. If a conversion specification is invalid, the behavior is undefined.

Conversion specifier

Explanation

Argument type

length modifier

hh (C99).

h

(none)

l

ll (C99).

j (C99).

z (C99).

t (C99).

L

%

writes literal %. The full conversion specification must be %%.

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

c

writes a single character.  The argument is first converted to unsigned char. If the l modifier is used, the argument is first converted to a character string as if by %ls with a wchar_t2 argument.

N/A

N/A

int

wint_t

N/A

N/A

N/A

N/A

N/A

s

writes a character string  The argument must be a pointer to the initial element of an array of characters. Precision specifies the maximum number of bytes to be written. If Precision is not specified, writes every byte up to and not including the first null terminator. If the l specifier is used, the argument must be a pointer to the initial element of an array of wchar_t, which is converted to char array as if by a call to wcrtomb with zero-initialized conversion state.

N/A

N/A

char*

wchar_t*

N/A

N/A

N/A

N/A

N/A

d i

converts a signed integer into decimal representation -dddd.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters.

signed char

short

int

long

long long

intmax_t

signed size_t

ptrdiff_t

N/A

o

converts a unsigned integer into octal representation oooo.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters. In the alternative implementation precision is increased if necessary, to write one leading zero. In that case if both the converted value and the precision are 0, single 0 is written.

unsigned char

unsigned short

unsigned int

unsigned long

unsigned long long

uintmax_t

size_t

unsigned version of ptrdiff_t

N/A

x X

converts an unsigned integer into hexadecimal representation hhhh.  For the x conversion letters abcdef are used. For the X conversion letters ABCDEF are used. Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters. In the alternative implementation 0x or 0X is prefixed to results if the converted value is nonzero.

N/A

u

converts an unsigned integer into decimal representation dddd.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters.

N/A

f F

converts floating-point number to the decimal notation in the style -ddd.ddd.  Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is 6. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.

N/A

N/A

double

double (C99)

N/A

N/A

N/A

N/A

long double

e  E

converts floating-point number to the decimal exponent notation.  For the e conversion style -d.ddde±dd is used. For the E conversion style -d.dddE±dd is used. The exponent contains at least two digits, more digits are used only if necessary. If the value is 0, the exponent is also 0. Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is 6. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.

N/A

N/A

N/A

N/A

N/A

N/A

a  A (C99).

converts floating-point number to the hexadecimal exponent notation.  For the a conversion style -0xh.hhhp±d is used. For the A conversion style -0Xh.hhhP±d is used. The first hexadecimal digit is 0 if the argument is not a normalized floating point value. If the value is 0, the exponent is also 0. Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is sufficient for exact representation of the value. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.

N/A

N/A

N/A

N/A

N/A

N/A

g  G

converts floating-point number to decimal or decimal exponent notation depending on the value and the precision.  For the g conversion style conversion with style e or f will be performed. For the G conversion style conversion with style E or F will be performed. Let P equal the precision if nonzero, 6 if the precision is not specified, or 1 if the precision is 0. Then, if a conversion with style E would have an exponent of X:   if P > X ≥ −4, the conversion is with style f or F and precision P − 1 − X.   otherwise, the conversion is with style e or E and precision P − 1.   Unless alternative representation is requested the trailing zeros are removed, also the decimal point character is removed if no fractional part is left. For infinity and not-a-number conversion style see notes.

N/A

N/A

N/A

N/A

N/A

N/A

n

returns the number of characters written so far by this call to the function.  The result is written to the value pointed to by the argument. The specification may not contain any flag, field width, or precision.

signed char*

short*

int*

long*

long long*

intmax_t*

signed size_t*

ptrdiff_t*

N/A

p

writes an implementation defined character sequence defining a pointer.

N/A

N/A

void*

N/A

N/A

N/A

N/A

N/A

N/A

Conversion specifier

Explanation

Argument type




































































































































length modifier

hh (C99).

h

(none)

l

ll (C99).

j (C99).

z (C99).

t (C99).

L





























































































































%

writes literal %. The full conversion specification must be %%.

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A




























































































































c

writes a single character.  The argument is first converted to unsigned char. If the l modifier is used, the argument is first converted to a character string as if by %ls with a wchar_t2 argument.

N/A

N/A

int

wint_t

N/A

N/A

N/A

N/A

N/A




























































































































s

writes a character string  The argument must be a pointer to the initial element of an array of characters. Precision specifies the maximum number of bytes to be written. If Precision is not specified, writes every byte up to and not including the first null terminator. If the l specifier is used, the argument must be a pointer to the initial element of an array of wchar_t, which is converted to char array as if by a call to wcrtomb with zero-initialized conversion state.

N/A

N/A

char*

wchar_t*

N/A

N/A

N/A

N/A

N/A




























































































































d i

converts a signed integer into decimal representation -dddd.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters.

signed char

short

int

long

long long

intmax_t

signed size_t

ptrdiff_t

N/A




























































































































o

converts a unsigned integer into octal representation oooo.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters. In the alternative implementation precision is increased if necessary, to write one leading zero. In that case if both the converted value and the precision are 0, single 0 is written.

unsigned char

unsigned short

unsigned int

unsigned long

unsigned long long

uintmax_t

size_t

unsigned version of ptrdiff_t

N/A




























































































































x X

converts an unsigned integer into hexadecimal representation hhhh.  For the x conversion letters abcdef are used. For the X conversion letters ABCDEF are used. Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters. In the alternative implementation 0x or 0X is prefixed to results if the converted value is nonzero.

N/A




































































































































u

converts an unsigned integer into decimal representation dddd.  Precision specifies the minimum number of digits to appear. The default precision is 1. If both the converted value and the precision are 0 the conversion results in no characters.

N/A




































































































































f F

converts floating-point number to the decimal notation in the style -ddd.ddd.  Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is 6. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.

N/A

N/A

double

double (C99)

N/A

N/A

N/A

N/A

long double




























































































































e  E

converts floating-point number to the decimal exponent notation.  For the e conversion style -d.ddde±dd is used. For the E conversion style -d.dddE±dd is used. The exponent contains at least two digits, more digits are used only if necessary. If the value is 0, the exponent is also 0. Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is 6. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.

N/A

N/A

N/A

N/A

N/A

N/A































































































































a  A (C99).

converts floating-point number to the hexadecimal exponent notation.  For the a conversion style -0xh.hhhp±d is used. For the A conversion style -0Xh.hhhP±d is used. The first hexadecimal digit is 0 if the argument is not a normalized floating point value. If the value is 0, the exponent is also 0. Precision specifies the minimum number of digits to appear after the decimal point character. The default precision is sufficient for exact representation of the value. In the alternative implementation decimal point character is written even if no digits follow it. For infinity and not-a-number conversion style see notes.

N/A

N/A

N/A

N/A

N/A

N/A































































































































g  G

converts floating-point number to decimal or decimal exponent notation depending on the value and the precision.  For the g conversion style conversion with style e or f will be performed. For the G conversion style conversion with style E or F will be performed. Let P equal the precision if nonzero, 6 if the precision is not specified, or 1 if the precision is 0. Then, if a conversion with style E would have an exponent of X:   if P > X ≥ −4, the conversion is with style f or F and precision P − 1 − X.   otherwise, the conversion is with style e or E and precision P − 1.   Unless alternative representation is requested the trailing zeros are removed, also the decimal point character is removed if no fractional part is left. For infinity and not-a-number conversion style see notes.

N/A

N/A

N/A

N/A

N/A

N/A































































































































n

将此调用到目前为止写入的字符数返回给该函数。结果写入参数指向的值。规范可能不包含任何标志,字段宽度或精度。

签名字符*

短*

INT *

long*

很长*

*将intmax_t

签名size_t *

ptrdiff_t的*

N / A




























































































































p

写一个实现定义的字符序列来定义一个指针。

N / A

N / A

无效*

N / A

N / A

N / A

N / A

N / A

N / A




























































































































...

-

指定要打印的数据的参数




































































































































  • 介绍%人物

  • (可选)一个或多个修改转换行为的标志:

    • -:转换的结果在字段内左对齐(默认情况下它是右对齐的)

    • +:带符号转换的符号总是预设为转换结果的前缀(默认情况下结果前面为减号,仅当它为负值时)

    • 空格:如果签名转换的结果不是以符号字符开头,或者是空的,则空格会预设为结果。如果+存在标志,则忽略它。

    • #:执行转换的替代形式。请参阅下表以了解确切的效果,否则行为未定义。

    • 0:对于整数和浮点数转换,前导零用于填充字段而不是空格字符。对于整数,如果明确指定了精度,它将被忽略。对于使用此标志的其他转换会导致未定义的行为。如果-存在标志,则忽略它。

  • (可选)整数值或*指定最小字段宽度。如果需要,结果会填充空格字符(默认情况下),右侧对齐时填充空白字符,左侧填充右侧填充。在使用的情况下*,宽度由类型的附加参数指定int。如果参数的值是负数,则结果是-指定的标志和正的字段宽度。(注意:这是最小宽度:该值从不被截断。)

    • (可选).后面跟随整数或者*或者既不指定转换的精度。在使用的情况下*精度由类型的附加参数指定int。如果这个参数的值是负数,它将被忽略。如果既不使用数字也不*使用,则精度取为零。请参阅下表以了解精确度的确切影响。

    • (可选)长度修饰符,用于指定参数的大小

    • 转换格式说明符

以下格式说明符可用:

Conversion

说明符说明参数类型长度修饰符    hh(C99)。

h   (none)   l   ll (C99).

j (C99).

z (C99).

t (C99).

L %   写文字%。完整的转换规范必须是%%。N / AN / AN / AN / AN / AN / AN / AN / AN / A      c    写入单个字符。该论点首先转换为unsigned char。如果使用了l修饰符,则首先将参数转换为字符串,就像通过具有参数的%ls一样wchar_t[2]

N/A   N/A   int

wint_t

N / AN / AN / AN / AN / A      s    写入字符串参数必须是指向字符数组的初始元素的指针。Precision指定要写入的最大字节数。如果未指定Precision,则将每个字节写入并不包括第一个空终止符。如果使用了l说明符,则参数必须是指向数组初始元素的指针wchar_t,它将转换为char数组,就像通过调用wcrtomb具有零初始化转换状态一样。

N/A   N/A   char*

wchar_t*

N/A   N/A   N/A   N/A   N/A     d

i   将有符号的整数转换为十进制表示形式-dddd。  精度指定出现的最小位数。默认的精度是1

如果转换后的值和精度都是0没有字符的转换结果。

signed char

short

int

long

long long

intmax_t

signed size_t

ptrdiff_t

N / A      o   将无符号整数转换为八进制表示oooo。  精度指定出现的最小位数。默认的精度是1。如果转换后的值和精度都是0没有字符的转换结果。在替代实现中,如果需要,可以增加精度以写入一个前导零。在这种情况下,如果转换值和精度都是00写入单个。

unsigned char

unsigned short

unsigned int

unsigned long

unsigned long long

uintmax_t

size_t

未签名的版本 ptrdiff_t

N/A     x

X   将无符号整数转换为十六进制表示hhhh。使用x转换字母abcdef

使用X转换字母ABCDEF

精度指定出现的最小位数。默认的精度是1。如果转换后的值和精度都是0没有字符的转换结果。在替代实现中, 0x或者0X如果转换后的值不为零,则将其作为结果的前缀。

N / A      u   将无符号整数转换为十进制表示形式dddd。  精度指定出现的最小位数。默认的精度是1。如果转换后的值和精度都是0没有字符的转换结果。

N/A     f

F   将浮点数转换为样式-ddd.ddd中的小数表示法。  精度指定小数点后面出现的最小位数。默认的精度是6。在替代实现中,即使没有数字跟随,小数点字符也会被写入。对于无穷大和非数字转换风格,请参阅注释。

N/A   N/A   double

`double` (C99)

N/A   N/A   N/A   N/A   long double

 `e`

E   将浮点数转换为十进制指数符号。对于e转换样式,使用-d.ddd e±dd

对于E转换样式,使用-d.ddd E±dd

指数至少包含两位数字,只有在必要时才使用更多数字。如果值是0,指数也是0精度指定小数点后面出现的最小位数。默认的精度是6。在替代实现中,即使没有数字跟随,小数点字符也会被写入。对于无穷大和非数字转换风格,请参阅注释。

N/A   N/A   N/A   N/A   N/A   N/A     a

A (C99).

浮点数转换为十六进制指数表示法。对于a转换样式- 使用0xh.hhh p±d

对于A转换样式- 使用0Xh.hhh P±d

0如果参数不是标准化的浮点值,则第一个十六进制数字是。如果值是0,指数也是0精度指定小数点后面出现的最小位数。默认精度足以精确表示值。在替代实现中,即使没有数字跟随,小数点字符也会被写入。对于无穷大和非数字转换风格,请参阅注释。

N/A   N/A   N/A   N/A   N/A   N/A     g

G根据值和精度    将浮点数转换为十进制或十进制指数符号。对于风格转换的转换与风格或将被执行。gef

对于G风格转换的转换与风格EF将被执行。

P等于精度如果非零,6如果没有指定精度,或者1如果精度是0。然后,如果具有样式的转换E将具有以下指数X

  • 如果P> X≥-4,转换是用式fF和精度P - 1 - X

  • 否则,转换采用样式eE精度P  -  1

除非请求替代表示,否则尾随零将被删除,如果没有剩余小数部分,小数点字符也会被删除。对于无穷大和非数字转换风格,请参阅注释。

不适用/不适用/不适用/不适用/      n   返回此函数迄今为止写入的字符数。结果写入参数指向的值。规范可能不包含任何标志字段宽度精度

signed char*

short*

int*

long*

long long*

intmax_t*

size_t*

ptrdiff_t*

N / A      p   写入一个实现定义的字符序列来定义一个指针。不适用不适用不适用不适用不适用不适用    void*   浮点转换函数将无穷大转换为infinfinity。使用哪一个是实现定义的。

非数字转换为nan或。使用哪一个是实现定义的。nan(char_sequence)

该转换FEGA输出INFINFINITYNAN来代替。

即使%c需要int参数,通过char调用可变参数函数时发生的整数提升也是安全的。

对于固定宽度的字符类型(正确的转换规格int8_t<inttypes.h>还(虽然,等等)都在头定义PRIdMAXPRIuMAX等是同义词%jd%ju等)。

内存写入转换说明符%n是安全漏洞的常见目标,其中格式字符串取决于用户输入,并且不受边界检查printf_s函数族的支持。

每个转换说明符的操作之后都有一个序列点; 这允许将多个%n结果存储在相同的变量中,或者作为边缘情况,%n在同一个调用中打印由较早修改的字符串。

如果转换规范无效,则行为未定义。

 ...   -   arguments specifying data to print

返回值

1,2)发送到输出流的字符数或负值(如果发生输出错误或编码错误(用于字符串和字符转换说明符))

3)写入的字符数buffer(不包括终止空字符);如果发生编码错误(用于字符串和字符转换说明符),则返回负值

4)buffer如果bufsz被忽略,将被写入的字符数(不包括终止空字符),或者如果编码错误(对于字符串和字符转换说明符)发生,则为负值

5,6)传输到输出流的字符数或负值(如果发生输出错误,运行时间约束违规错误或编码错误)。

7)写入的字符数buffer,不包括空字符(只要buffer不是空指针,bufsz并且不为零且不大于RSIZE_MAX),则不计入空字符,或者在运行时约束违规时为零,编码错误为负值

8)不包括终止空字符的字符数(只要buffer不是空指针并且bufsz不为零且不大于RSIZE_MAX),buffer如果bufsz被忽略,将被写入的字符数或者如果运行时约束违规或编码错误发生

注意

C标准和POSIX指定sprintf当参数与目标缓冲区重叠时,其行为及其变体未定义。例:

sprintf(dst, "%s and %s", dst, t); // <- broken: undefined behavior

POSIX指定该errno设置上的错误。它还指定了额外的转换规范,最显着的是支持参数重新排序(n$紧接在%指示n'th参数之后)。

snprintf使用零bufsz和空指针调用buffer对于确定包含输出所需的缓冲区大小很有用:

const char *fmt = "sqrt(2) = %f";int sz = snprintf(NULL, 0, fmt, sqrt(2));char buf[sz + 1]; // note +1 for terminating null bytesnprintf(buf, sizeof buf, fmt, sqrt(2));

snprintf_s,就像snprintf,但不像sprintf_s,会截断输出以适应bufsz-1

#include <stdio.h>
 int main(void){    printf("Strings:\n");    const char* s = "Hello";    printf("\t.%10s.\n\t.%-10s.\n\t.%*s.\n", s, s, 10, s); 
    printf("Characters:\t%c %%\n", 65); 
    printf("Integers\n");    printf("Decimal:\t%i %d %.6i %i %.0i %+i %u\n", 1, 2, 3, 0, 0, 4, -1);    printf("Hexadecimal:\t%x %x %X %#x\n", 5, 10, 10, 6);    printf("Octal:\t%o %#o %#o\n", 10, 10, 4); 
    printf("Floating point\n");    printf("Rounding:\t%f %.0f %.32f\n", 1.5, 1.5, 1.3);    printf("Padding:\t%05.2f %.2f %5.2f\n", 1.5, 1.5, 1.5);    printf("Scientific:\t%E %e\n", 1.5, 1.5);    printf("Hexadecimal:\t%a %A\n", 1.5, 1.5);}

输出:

Strings:    .     Hello.    .Hello     .    .     Hello.Characters:     A %Integers
Decimal:        1 2 000003 0  +4 4294967295Hexadecimal:    5 a A 0x6Octal:          12 012 04Floating point
Rounding:       1.500000 2 1.30000000000000004440892098500626Padding:        01.50 1.50  1.50Scientific:     1.500000E+00 1.500000e+00Hexadecimal:    0x1.8p+0 0X1.8P+0

参考

  • C11标准(ISO / IEC 9899:2011):

    • 7.21.6.1 fprintf函数(p:309-316)

    • 7.21.6.3 printf函数(p:324)

    • 7.21.6.5 snprintf函数(p:325)

    • 7.21.6.6 sprintf函数(p:325-326)

    • K.3.5.3.1 fprintf_s函数(p:591)

    • K.3.5.3.3 printf_s函数(p:593-594)

    • K.3.5.3.5 snprintf_s函数(p:594-595)

    • K.3.5.3.6 sprintf_s函数(p:595-596)

  • C99标准(ISO / IEC 9899:1999):

    • 7.19.6.1 fprintf函数(p:274-282)

    • 7.19.6.3 printf函数(p:290)

    • 7.19.6.5 snprintf函数(p:290-291)

    • 7.19.6.6 sprintf函数(p:291)

  • C89 / C90标准(ISO / IEC 9899:1990):

    • 4.9.6.1 fprintf函数

    • 4.9.6.3 printf函数

    • 4.9.6.5 sprintf函数

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