31ece5769d
ntp 4.2.8p5 Reviewed by: cy, roberto Relnotes: yes Differential Revision: https://reviews.freebsd.org/D4828
175 lines
3.1 KiB
C
175 lines
3.1 KiB
C
/*
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* dolfptoa - do the grunge work of converting an l_fp number to decimal
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*/
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#include <config.h>
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#include <stdio.h>
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#include "ntp_fp.h"
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#include "lib_strbuf.h"
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#include "ntp_string.h"
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#include "ntp_stdlib.h"
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char *
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dolfptoa(
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u_int32 fpi,
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u_int32 fpv,
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int neg,
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short ndec,
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int msec
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)
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{
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u_char *cp, *cpend, *cpdec;
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int dec;
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u_char cbuf[24];
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char *buf, *bp;
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/*
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* Get a string buffer before starting
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*/
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LIB_GETBUF(buf);
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/*
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* Zero the character buffer
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*/
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ZERO(cbuf);
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/*
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* Work on the integral part. This should work reasonable on
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* all machines with 32 bit arithmetic. Please note that 32 bits
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* can *always* be represented with at most 10 decimal digits,
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* including a possible rounding from the fractional part.
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*/
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cp = cpend = cpdec = &cbuf[10];
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for (dec = (int)(cp - cbuf); dec > 0 && fpi != 0; dec--) {
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/* can add another digit */
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u_int32 digit;
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digit = fpi;
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fpi /= 10U;
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digit -= (fpi << 3) + (fpi << 1); /* i*10 */
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*--cp = (u_char)digit;
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}
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/*
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* Done that, now deal with the problem of the fraction. First
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* determine the number of decimal places.
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*/
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dec = ndec;
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if (dec < 0)
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dec = 0;
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if (msec) {
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dec += 3;
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cpdec += 3;
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}
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if ((size_t)dec > sizeof(cbuf) - (cpend - cbuf))
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dec = (int)(sizeof(cbuf) - (cpend - cbuf));
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/*
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* If there's a fraction to deal with, do so.
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*/
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for (/*NOP*/; dec > 0 && fpv != 0; dec--) {
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u_int32 digit, tmph, tmpl;
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/*
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* The scheme here is to multiply the fraction
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* (0.1234...) by ten. This moves a junk of BCD into
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* the units part. record that and iterate.
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* multiply by shift/add in two dwords.
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*/
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digit = 0;
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M_LSHIFT(digit, fpv);
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tmph = digit;
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tmpl = fpv;
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M_LSHIFT(digit, fpv);
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M_LSHIFT(digit, fpv);
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M_ADD(digit, fpv, tmph, tmpl);
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*cpend++ = (u_char)digit;
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}
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/* decide whether to round or simply extend by zeros */
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if (dec > 0) {
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/* only '0' digits left -- just reposition end */
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cpend += dec;
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} else {
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/* some bits remain in 'fpv'; do round */
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u_char *tp = cpend;
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int carry = ((fpv & 0x80000000) != 0);
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for (dec = (int)(tp - cbuf); carry && dec > 0; dec--) {
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*--tp += 1;
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if (*tp == 10)
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*tp = 0;
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else
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carry = FALSE;
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}
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if (tp < cp) /* rounding from 999 to 1000 or similiar? */
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cp = tp;
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}
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/*
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* We've now got the fraction in cbuf[], with cp pointing at
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* the first character, cpend pointing past the last, and
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* cpdec pointing at the first character past the decimal.
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* Remove leading zeros, then format the number into the
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* buffer.
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*/
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while (cp < cpdec && *cp == 0)
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cp++;
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if (cp >= cpdec)
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cp = cpdec - 1;
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bp = buf;
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if (neg)
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*bp++ = '-';
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while (cp < cpend) {
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if (cp == cpdec)
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*bp++ = '.';
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*bp++ = (char)(*cp++) + '0';
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}
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*bp = '\0';
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/*
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* Done!
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*/
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return buf;
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}
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char *
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mfptoa(
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u_int32 fpi,
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u_int32 fpf,
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short ndec
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)
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{
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int isneg;
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isneg = M_ISNEG(fpi);
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if (isneg) {
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M_NEG(fpi, fpf);
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}
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return dolfptoa(fpi, fpf, isneg, ndec, FALSE);
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}
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char *
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mfptoms(
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u_int32 fpi,
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u_int32 fpf,
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short ndec
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)
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{
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int isneg;
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isneg = M_ISNEG(fpi);
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if (isneg) {
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M_NEG(fpi, fpf);
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}
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return dolfptoa(fpi, fpf, isneg, ndec, TRUE);
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}
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