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/*
* Copyright (C) 2000, 2001 Manuel Novoa III
*
* Function: int __dtostr(FILE * fp, size_t size, double x,
* char flag[], int width, int preci, char mode)
*
* This was written for uClibc to provide floating point support for
* the printf functions. It handles +/- infinity and nan on i386.
*
* Notes:
*
* It should also be fairly portable, as not assumptions are made about the
* bit-layout of doubles.
*
* It should be too difficult to convert this to handle long doubles on i386.
* For information, see the comments below.
*
* TODO:
* long double and/or float version? (note: for float can trim code some).
*
* Decrease the size. This is really much bigger than I'd like.
*/
/*****************************************************************************/
/* Don't change anything that follows unless you know what you're doing. */
/*****************************************************************************/
/*
* Configuration for the scaling power table. Ignoring denormals, you
* should have 2**EXP_TABLE_SIZE >= MAX_DBL_EXP >= 2**(EXP_TABLE_SIZE-1).
* The minimum for standard C is 6. For IEEE 8bit doubles, 9 suffices.
*/
#define EXP_TABLE_SIZE 9
/*
* Set this to the maximum number of digits you want converted.
* Conversion is done in blocks of DIGITS_PER_BLOCK (9 by default) digits.
* 17 digits suffices to uniquely determine a double on i386.
*/
#define MAX_DIGITS 17
/*
* Set this to the smallest integer type capable of storing a pointer.
*/
#define INT_OR_PTR int
/*
* This is really only used to check for infinities. The macro produces
* smaller code for i386 and, since this is tested before any floating point
* calculations, it doesn't appear to suffer from the excess precision problem
* caused by the FPU that strtod had. If it causes problems, call the function
* and compile zoicheck.c with -ffloat-store.
*/
#if 1
#define _zero_or_inf_check(x) ( x == (x/4) )
#else
extern int _zero_or_inf_check(double x);
#endif
/*
* Fairly portable nan check. Bitwise for i386 generated larger code.
* If you have a better version, comment this out.
*/
#define isnan(x) (x != x)
/*****************************************************************************/
/* Don't change anything that follows peroid!!! ;-) */
/*****************************************************************************/
#include <stdio.h>
#include <string.h>
#include <assert.h>
#include <float.h>
#include <limits.h>
extern int fnprintf(FILE * fp, size_t size, const char *fmt, ...);
/* from printf.c -- should really be in an internal header file */
enum {
FLAG_PLUS = 0,
FLAG_MINUS_LJUSTIFY,
FLAG_HASH,
FLAG_0_PAD,
FLAG_SPACE,
};
/*****************************************************************************/
/*
* Set things up for the scaling power table.
*/
#if EXP_TABLE_SIZE < 6
#error EXP_TABLE_SIZE should be at least 6 to comply with standards
#endif
#define EXP_TABLE_MAX (1U<<(EXP_TABLE_SIZE-1))
/*
* Only bother checking if this is too small.
* Throw in some play for denormals ( roughly O(-324) vs O(-307) on i386 ).
*/
#if (3+DBL_DIG-DBL_MIN_10_EXP)/2 > EXP_TABLE_MAX
#error larger EXP_TABLE_SIZE needed
#endif
/*
* With 32 bit ints, we can get 9 digits per block.
*/
#define DIGITS_PER_BLOCK 9
#if (INT_MAX >> 30)
#define DIGIT_BLOCK_TYPE int
#define DB_FMT "%.*d"
#elif (LONG_MAX >> 30)
#define DIGIT_BLOCK_TYPE long
#define DB_FMT "%.*ld"
#else
#error need at least 32 bit longs
#endif
/* Are there actually any machines where this might fail? */
#if 'A' > 'a'
#error ordering assumption violated : 'A' > 'a'
#endif
/* Maximum number of calls to fnprintf to output double. */
#define MAX_CALLS 8
/*****************************************************************************/
#define NUM_DIGIT_BLOCKS ((MAX_DIGITS+DIGITS_PER_BLOCK-1)/DIGITS_PER_BLOCK)
/* extra space for '-', '.', 'e+###', and nul */
#define BUF_SIZE ( 3 + NUM_DIGIT_BLOCKS * DIGITS_PER_BLOCK )
/*****************************************************************************/
static const char *fmts[] = {
"%0*d", "%.*s", ".", "inf", "INF", "nan", "NAN", "%*s"
};
/*****************************************************************************/
int __dtostr(FILE * fp, size_t size, double x,
char flag[], int width, int preci, char mode)
{
double exp_table[EXP_TABLE_SIZE];
double p10;
DIGIT_BLOCK_TYPE digit_block; /* int of at least 32 bits */
int i, j;
int round, o_exp;
int exp, exp_neg;
char *s;
char *e;
char buf[BUF_SIZE];
char buf2[BUF_SIZE];
INT_OR_PTR pc_fwi[2*MAX_CALLS];
INT_OR_PTR *ppc;
char exp_buf[8];
char drvr[8];
char *pdrvr;
int npc;
int cnt;
char sign_str[2];
char o_mode;
/* check that INT_OR_PTR is sufficiently large */
assert( sizeof(INT_OR_PTR) == sizeof(char *) );
*sign_str = flag[FLAG_PLUS];
*(sign_str+1) = 0;
if (isnan(x)) { /* nan check */
pdrvr = drvr + 1;
*pdrvr++ = 5 + (mode < 'a');
pc_fwi[2] = 3;
flag[FLAG_0_PAD] = 0;
goto EXIT_SPECIAL;
}
if (x == 0) { /* handle 0 now to avoid false positive */
exp = -1;
goto GENERATE_DIGITS;
}
if (x < 0) { /* convert negatives to positives */
*sign_str = '-';
x = -x;
}
if (_zero_or_inf_check(x)) { /* must be inf since zero handled above */
pdrvr = drvr + 1;
*pdrvr++ = 3 + + (mode < 'a');
pc_fwi[2] = 3;
flag[FLAG_0_PAD] = 0;
goto EXIT_SPECIAL;
}
/* need to build the scaling table */
for (i = 0, p10 = 10 ; i < EXP_TABLE_SIZE ; i++) {
exp_table[i] = p10;
p10 *= p10;
}
exp_neg = 0;
if (x < 1e8) { /* do we need to scale up or down? */
exp_neg = 1;
}
exp = DIGITS_PER_BLOCK - 1;
i = EXP_TABLE_SIZE;
j = EXP_TABLE_MAX;
while ( i-- ) { /* scale x such that 1e8 <= x < 1e9 */
if (exp_neg) {
if (x * exp_table[i] < 1e9) {
x *= exp_table[i];
exp -= j;
}
} else {
if (x / exp_table[i] >= 1e8) {
x /= exp_table[i];
exp += j;
}
}
j >>= 1;
}
if (x >= 1e9) { /* handle bad rounding case */
x /= 10;
++exp;
}
assert(x < 1e9);
GENERATE_DIGITS:
s = buf2 + 2; /* leave space for '\0' and '0' */
for (i = 0 ; i < NUM_DIGIT_BLOCKS ; ++i ) {
digit_block = (DIGIT_BLOCK_TYPE) x;
x = (x - digit_block) * 1e9;
s += sprintf(s, DB_FMT, DIGITS_PER_BLOCK, digit_block);
}
/*************************************************************************/
*exp_buf = 'e';
if (mode < 'a') {
*exp_buf = 'E';
mode += ('a' - 'A');
}
o_mode = mode;
round = preci;
if ((mode == 'g') && (round > 0)){
--round;
}
if (mode == 'f') {
round += exp;
}
RESTART:
memcpy(buf,buf2,sizeof(buf2)); /* backup in case g need to be f */
s = buf;
*s++ = 0; /* terminator for rounding and 0-triming */
*s = '0'; /* space to round */
i = 0;
e = s + MAX_DIGITS + 1;
if (round < MAX_DIGITS) {
e = s + round + 2;
if (*e >= '5') {
i = 1;
}
}
do { /* handle rounding and trim trailing 0s */
*--e += i; /* add the carry */
} while ((*e == '0') || (*e > '9'));
o_exp = exp;
if (e <= s) { /* we carried into extra digit */
++o_exp;
e = s; /* needed if all 0s */
} else {
++s;
}
*++e = 0; /* ending nul char */
if ((mode == 'g') && ((o_exp >= -4) && (o_exp < round))) {
mode = 'f';
goto RESTART;
}
exp = o_exp;
if (mode != 'f') {
o_exp = 0;
}
if (o_exp < 0) {
*--s = '0'; /* fake the first digit */
}
pdrvr = drvr+1;
ppc = pc_fwi+2;
*pdrvr++ = 0;
*ppc++ = 1;
*ppc++ = (INT_OR_PTR)(*s++ - '0');
i = e - s; /* total digits */
if (o_exp >= 0) {
if (o_exp >= i) { /* all digit(s) left of decimal */
*pdrvr++ = 1;
*ppc++ = i;
*ppc++ = (INT_OR_PTR)(s);
o_exp -= i;
i = 0;
if (o_exp>0) { /* have 0s left of decimal */
*pdrvr++ = 0;
*ppc++ = o_exp;
*ppc++ = 0;
}
} else if (o_exp > 0) { /* decimal between digits */
*pdrvr++ = 1;
*ppc++ = o_exp;
*ppc++ = (INT_OR_PTR)(s);
s += o_exp;
i -= o_exp;
}
o_exp = -1;
}
if (flag[FLAG_HASH] || (i) || ((o_mode != 'g') && (preci > 0))) {
*pdrvr++ = 2; /* need decimal */
*ppc++ = 1; /* needed for width calc */
ppc++;
}
if (++o_exp < 0) { /* have 0s right of decimal */
*pdrvr++ = 0;
*ppc++ = -o_exp;
*ppc++ = 0;
}
if (i) { /* have digit(s) right of decimal */
*pdrvr++ = 1;
*ppc++ = i;
*ppc++ = (INT_OR_PTR)(s);
}
if (o_mode != 'g') {
i -= o_exp;
if (i < preci) { /* have 0s right of digits */
i = preci - i;
*pdrvr++ = 0;
*ppc++ = i;
*ppc++ = 0;
}
}
/* build exponent string */
if (mode != 'f') {
*pdrvr++ = 1;
*ppc++ = sprintf(exp_buf,"%c%+.2d", *exp_buf, exp);
*ppc++ = (INT_OR_PTR) exp_buf;
}
EXIT_SPECIAL:
npc = pdrvr - drvr;
ppc = pc_fwi + 2;
for (i=1 ; i< npc ; i++) {
width -= *(ppc++);
ppc++;
}
i = 0;
if (*sign_str) {
i = 1;
}
width -= i;
if (width <= 0) {
width = 0;
} else {
if (flag[FLAG_MINUS_LJUSTIFY]) { /* padding on right */
++npc;
*pdrvr++ = 7;
*ppc = width;
*++ppc = (INT_OR_PTR)("");
width = 0;
} else if (flag[FLAG_0_PAD] == '0') { /* 0 padding */
pc_fwi[2] += width;
width = 0;
}
}
*drvr = 7;
ppc = pc_fwi;
*ppc++ = width + i;
*ppc = (INT_OR_PTR) sign_str;
pdrvr = drvr;
ppc = pc_fwi;
cnt = 0;
for (i=0 ; i<npc ; i++) {
#if 1
fnprintf(fp, size, fmts[(int)(*pdrvr++)], (INT_OR_PTR)(*(ppc)),
(INT_OR_PTR)(*(ppc+1)));
#else
j = fnprintf(fp, size, fmts[(int)(*pdrvr++)], (INT_OR_PTR)(*(ppc)),
(INT_OR_PTR)(*(ppc+1)));
assert(j == *ppc);
#endif
if (size > *ppc) {
size -= *ppc;
}
cnt += *ppc; /* to avoid problems if j == -1 */
ppc += 2;
}
return cnt;
}
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