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wireshark/epan/to_str.c

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/* to_str.c
* Routines for utilities to convert various other types to strings.
*
* $Id$
*
* Wireshark - Network traffic analyzer
* By Gerald Combs <gerald@wireshark.org>
* Copyright 1998 Gerald Combs
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include <stdio.h>
#include <string.h>
#include <time.h>
#include <glib.h>
#include "emem.h"
#include "to_str.h"
/*
* If a user _does_ pass in a too-small buffer, this is probably
* going to be too long to fit. However, even a partial string
* starting with "[Buf" should provide enough of a clue to be
* useful.
*/
#define BUF_TOO_SMALL_ERR "[Buffer too small]"
static inline char *
byte_to_hex(char *out, guint32 dword) {
/* At least one version of Apple's C compiler/linker is buggy, causing
a complaint from the linker about the "literal C string section"
not ending with '\0' if we initialize a 16-element "char" array with
a 16-character string, the fact that initializing such an array with
such a string is perfectly legitimate ANSI C nonwithstanding, the 17th
'\0' byte in the string nonwithstanding. */
static const gchar hex_digits[16] =
{ '0', '1', '2', '3', '4', '5', '6', '7',
'8', '9', 'a', 'b', 'c', 'd', 'e', 'f' };
*out++ = hex_digits[(dword >> 4) & 0xF];
*out++ = hex_digits[dword & 0xF];
return out;
}
char *
word_to_hex(char *out, guint16 word) {
out = byte_to_hex(out, word >> 8);
out = byte_to_hex(out, word);
return out;
}
char *
dword_to_hex(char *out, guint32 dword) {
out = byte_to_hex(out, dword >> 24);
out = byte_to_hex(out, dword >> 16);
out = byte_to_hex(out, dword >> 8);
out = byte_to_hex(out, dword);
return out;
}
char *
dword_to_hex_punct(char *out, guint32 dword, char punct) {
out = byte_to_hex(out, dword >> 24);
*out++ = punct;
out = byte_to_hex(out, dword >> 16);
*out++ = punct;
out = byte_to_hex(out, dword >> 8);
*out++ = punct;
out = byte_to_hex(out, dword);
return out;
}
/* buffer need to be at least len * 2 size */
char *
bytes_to_hexstr(char *out, const guint8 *ad, guint32 len) {
guint32 i;
for (i = 0; i < len; i++)
out = byte_to_hex(out, ad[i]);
return out;
}
/* buffer need to be at least len * 3 - 1 size */
char *
bytes_to_hexstr_punct(char *out, const guint8 *ad, guint32 len, char punct) {
guint32 i;
out = byte_to_hex(out, ad[0]);
for (i = 1; i < len; i++) {
*out++ = punct;
out = byte_to_hex(out, ad[i]);
}
return out;
}
/* Routine to convert a sequence of bytes to a hex string, one byte/two hex
* digits at at a time, with a specified punctuation character between
* the bytes.
*
* If punct is '\0', no punctuation is applied (and thus
* the resulting string is (len-1) bytes shorter)
*/
gchar *
bytestring_to_str(const guint8 *ad, guint32 len, char punct) {
gchar *buf;
size_t buflen;
/* XXX, Old code was using int as iterator... Why len is guint32 anyway?! (darkjames) */
if ( ((int) len) < 0)
return "";
if (!len)
return "";
if (punct)
buflen=len*3;
else
buflen=len*2 + 1;
buf=ep_alloc(buflen);
if (punct)
bytes_to_hexstr_punct(buf, ad, len, punct);
else
bytes_to_hexstr(buf, ad, len);
buf[buflen-1] = '\0';
return buf;
}
/* Max string length for displaying byte string. */
#define MAX_BYTE_STR_LEN 48
gchar *
bytes_to_str(const guint8 *bd, int bd_len) {
gchar *cur;
gchar *cur_ptr;
int truncated = 0;
cur=ep_alloc(MAX_BYTE_STR_LEN+3+1);
if (bd_len <= 0) { cur[0] = '\0'; return cur; }
if (bd_len > MAX_BYTE_STR_LEN/2) { /* bd_len > 24 */
truncated = 1;
bd_len = MAX_BYTE_STR_LEN/2;
}
cur_ptr = bytes_to_hexstr(cur, bd, bd_len); /* max MAX_BYTE_STR_LEN bytes */
if (truncated)
cur_ptr = g_stpcpy(cur_ptr, "..."); /* 3 bytes */
*cur_ptr = '\0'; /* 1 byte */
return cur;
}
/* Turn an array of bytes into a string showing the bytes in hex with
* punct as a bytes separator.
*/
gchar *
bytes_to_str_punct(const guint8 *bd, int bd_len, gchar punct) {
gchar *cur;
gchar *cur_ptr;
int truncated = 0;
if (!punct)
return bytes_to_str(bd, bd_len);
cur=ep_alloc(MAX_BYTE_STR_LEN+3+1);
if (bd_len <= 0) { cur[0] = '\0'; return cur; }
if (bd_len > MAX_BYTE_STR_LEN/3) { /* bd_len > 16 */
truncated = 1;
bd_len = MAX_BYTE_STR_LEN/3;
}
cur_ptr = bytes_to_hexstr_punct(cur, bd, bd_len, punct); /* max MAX_BYTE_STR_LEN-1 bytes */
if (truncated) {
*cur_ptr++ = punct; /* 1 byte */
cur_ptr = g_stpcpy(cur_ptr, "..."); /* 3 bytes */
}
*cur_ptr = '\0';
return cur;
}
static int
guint32_to_str_buf_len(guint32 u) {
if (u >= 1000000000)return 10;
if (u >= 100000000) return 9;
if (u >= 10000000) return 8;
if (u >= 1000000) return 7;
if (u >= 100000) return 6;
if (u >= 10000) return 5;
if (u >= 1000) return 4;
if (u >= 100) return 3;
if (u >= 10) return 2;
return 1;
}
static const char * const fast_strings[] = {
"0", "1", "2", "3", "4", "5", "6", "7",
"8", "9", "10", "11", "12", "13", "14", "15",
"16", "17", "18", "19", "20", "21", "22", "23",
"24", "25", "26", "27", "28", "29", "30", "31",
"32", "33", "34", "35", "36", "37", "38", "39",
"40", "41", "42", "43", "44", "45", "46", "47",
"48", "49", "50", "51", "52", "53", "54", "55",
"56", "57", "58", "59", "60", "61", "62", "63",
"64", "65", "66", "67", "68", "69", "70", "71",
"72", "73", "74", "75", "76", "77", "78", "79",
"80", "81", "82", "83", "84", "85", "86", "87",
"88", "89", "90", "91", "92", "93", "94", "95",
"96", "97", "98", "99", "100", "101", "102", "103",
"104", "105", "106", "107", "108", "109", "110", "111",
"112", "113", "114", "115", "116", "117", "118", "119",
"120", "121", "122", "123", "124", "125", "126", "127",
"128", "129", "130", "131", "132", "133", "134", "135",
"136", "137", "138", "139", "140", "141", "142", "143",
"144", "145", "146", "147", "148", "149", "150", "151",
"152", "153", "154", "155", "156", "157", "158", "159",
"160", "161", "162", "163", "164", "165", "166", "167",
"168", "169", "170", "171", "172", "173", "174", "175",
"176", "177", "178", "179", "180", "181", "182", "183",
"184", "185", "186", "187", "188", "189", "190", "191",
"192", "193", "194", "195", "196", "197", "198", "199",
"200", "201", "202", "203", "204", "205", "206", "207",
"208", "209", "210", "211", "212", "213", "214", "215",
"216", "217", "218", "219", "220", "221", "222", "223",
"224", "225", "226", "227", "228", "229", "230", "231",
"232", "233", "234", "235", "236", "237", "238", "239",
"240", "241", "242", "243", "244", "245", "246", "247",
"248", "249", "250", "251", "252", "253", "254", "255"
};
void
guint32_to_str_buf(guint32 u, gchar *buf, int buf_len) {
int str_len = guint32_to_str_buf_len(u)+1;
gchar *bp = &buf[str_len];
gchar const *p;
if (buf_len < str_len) {
g_strlcpy(buf, BUF_TOO_SMALL_ERR, buf_len); /* Let the unexpected value alert user */
return;
}
*--bp = '\0';
while (u >= 10) {
p = fast_strings[100 + (u % 100)];
*--bp = p[2];
*--bp = p[1];
u /= 100;
}
if (bp != buf) /* ugly, fixme! */
*--bp = (u % 10) | '0';
}
gchar *
guint32_to_str(guint32 u) {
int str_len = 16; /* guint32_to_str_buf_len(u)+1; */
gchar *bp = ep_alloc(str_len);
guint32_to_str_buf(u, bp, str_len);
return bp;
}
#define PLURALIZE(n) (((n) > 1) ? "s" : "")
#define COMMA(do_it) ((do_it) ? ", " : "")
/*
* Maximum length of a string showing days/hours/minutes/seconds.
* (Does not include the terminating '\0'.)
* Includes space for a '-' sign for any negative components.
* -12345 days, 12 hours, 12 minutes, 12.123 seconds
*/
#define TIME_SECS_LEN (10+1+4+2+2+5+2+2+7+2+2+7+4)
/*
* Convert a value in seconds and fractions of a second to a string,
* giving time in days, hours, minutes, and seconds, and put the result
* into a buffer.
* "is_nsecs" says that "frac" is microseconds if true and milliseconds
* if false.
* If time is negative, add a '-' to all non-null components.
*/
static void
time_secs_to_str_buf(gint32 time_val, guint32 frac, gboolean is_nsecs,
emem_strbuf_t *buf)
{
int hours, mins, secs;
const gchar *msign = "";
gboolean do_comma = FALSE;
if(time_val == G_MININT32) { /* That Which Shall Not Be Negated */
ep_strbuf_append_printf(buf, "Unable to cope with time value %d", time_val);
return;
}
if(time_val < 0){
time_val = -time_val;
msign = "-";
}
secs = time_val % 60;
time_val /= 60;
mins = time_val % 60;
time_val /= 60;
hours = time_val % 24;
time_val /= 24;
if (time_val != 0) {
ep_strbuf_append_printf(buf, "%s%u day%s", msign, time_val, PLURALIZE(time_val));
do_comma = TRUE;
msign="";
}
if (hours != 0) {
ep_strbuf_append_printf(buf, "%s%s%u hour%s", COMMA(do_comma), msign, hours, PLURALIZE(hours));
do_comma = TRUE;
msign="";
}
if (mins != 0) {
ep_strbuf_append_printf(buf, "%s%s%u minute%s", COMMA(do_comma), msign, mins, PLURALIZE(mins));
do_comma = TRUE;
msign="";
}
if (secs != 0 || frac != 0) {
if (frac != 0) {
if (is_nsecs)
ep_strbuf_append_printf(buf, "%s%s%u.%09u seconds", COMMA(do_comma), msign, secs, frac);
else
ep_strbuf_append_printf(buf, "%s%s%u.%03u seconds", COMMA(do_comma), msign, secs, frac);
} else
ep_strbuf_append_printf(buf, "%s%s%u second%s", COMMA(do_comma), msign, secs, PLURALIZE(secs));
}
}
gchar *
time_secs_to_str(gint32 time_val)
{
emem_strbuf_t *buf;
buf=ep_strbuf_sized_new(TIME_SECS_LEN+1, TIME_SECS_LEN+1);
if (time_val == 0) {
ep_strbuf_append(buf, "0 time");
return buf->str;
}
time_secs_to_str_buf(time_val, 0, FALSE, buf);
return buf->str;
}
static void
time_secs_to_str_buf_unsigned(guint32 time_val, guint32 frac, gboolean is_nsecs,
emem_strbuf_t *buf)
{
int hours, mins, secs;
gboolean do_comma = FALSE;
secs = time_val % 60;
time_val /= 60;
mins = time_val % 60;
time_val /= 60;
hours = time_val % 24;
time_val /= 24;
if (time_val != 0) {
ep_strbuf_append_printf(buf, "%u day%s", time_val, PLURALIZE(time_val));
do_comma = TRUE;
}
if (hours != 0) {
ep_strbuf_append_printf(buf, "%s%u hour%s", COMMA(do_comma), hours, PLURALIZE(hours));
do_comma = TRUE;
}
if (mins != 0) {
ep_strbuf_append_printf(buf, "%s%u minute%s", COMMA(do_comma), mins, PLURALIZE(mins));
do_comma = TRUE;
}
if (secs != 0 || frac != 0) {
if (frac != 0) {
if (is_nsecs)
ep_strbuf_append_printf(buf, "%s%u.%09u seconds", COMMA(do_comma), secs, frac);
else
ep_strbuf_append_printf(buf, "%s%u.%03u seconds", COMMA(do_comma), secs, frac);
} else
ep_strbuf_append_printf(buf, "%s%u second%s", COMMA(do_comma), secs, PLURALIZE(secs));
}
}
gchar *
time_secs_to_str_unsigned(guint32 time_val)
{
emem_strbuf_t *buf;
buf=ep_strbuf_sized_new(TIME_SECS_LEN+1, TIME_SECS_LEN+1);
if (time_val == 0) {
ep_strbuf_append(buf, "0 time");
return buf->str;
}
time_secs_to_str_buf_unsigned(time_val, 0, FALSE, buf);
return buf->str;
}
gchar *
time_msecs_to_str(gint32 time_val)
{
emem_strbuf_t *buf;
int msecs;
buf=ep_strbuf_sized_new(TIME_SECS_LEN+1+3+1, TIME_SECS_LEN+1+3+1);
if (time_val == 0) {
ep_strbuf_append(buf, "0 time");
return buf->str;
}
if(time_val<0){
/* oops we got passed a negative time */
time_val= -time_val;
msecs = time_val % 1000;
time_val /= 1000;
time_val= -time_val;
} else {
msecs = time_val % 1000;
time_val /= 1000;
}
time_secs_to_str_buf(time_val, msecs, FALSE, buf);
return buf->str;
}
static const char *mon_names[12] = {
"Jan",
"Feb",
"Mar",
"Apr",
"May",
"Jun",
"Jul",
"Aug",
"Sep",
"Oct",
"Nov",
"Dec"
};
gchar *
abs_time_to_str(nstime_t *abs_time, absolute_time_display_e fmt)
{
struct tm *tmp = NULL;
const char *zonename = "???";
gchar *buf = NULL;
#ifdef _MSC_VER
/* calling localtime() on MSVC 2005 with huge values causes it to crash */
/* XXX - find the exact value that still does work */
/* XXX - using _USE_32BIT_TIME_T might be another way to circumvent this problem */
if(abs_time->secs > 2000000000) {
tmp = NULL;
} else
#endif
switch (fmt) {
case ABSOLUTE_TIME_UTC:
case ABSOLUTE_TIME_DOY_UTC:
tmp = gmtime(&abs_time->secs);
zonename = "UTC";
break;
case ABSOLUTE_TIME_LOCAL:
tmp = localtime(&abs_time->secs);
if (tmp) {
#if defined(HAVE_TM_ZONE)
zonename = tmp->tm_zone;
#elif defined(HAVE_TZNAME)
zonename = tzname[tmp->tm_isdst];
#elif _WIN32
zonename = _tzname[tmp->tm_isdst];
#else
zonename = tmp->tm_isdst ? "?ST" : "?DT";
#endif
}
break;
}
if (tmp) {
switch (fmt) {
case ABSOLUTE_TIME_DOY_UTC:
buf = ep_strdup_printf("%04d/%03d:%02d:%02d:%02d.%09ld %s",
tmp->tm_year + 1900,
tmp->tm_yday,
tmp->tm_hour,
tmp->tm_min,
tmp->tm_sec,
(long)abs_time->nsecs,
zonename);
break;
case ABSOLUTE_TIME_UTC:
case ABSOLUTE_TIME_LOCAL:
buf = ep_strdup_printf("%s %2d, %d %02d:%02d:%02d.%09ld %s",
mon_names[tmp->tm_mon],
tmp->tm_mday,
tmp->tm_year + 1900,
tmp->tm_hour,
tmp->tm_min,
tmp->tm_sec,
(long)abs_time->nsecs,
zonename);
break;
}
} else
buf = ep_strdup("Not representable");
return buf;
}
gchar *
abs_time_secs_to_str(time_t abs_time, absolute_time_display_e fmt)
{
struct tm *tmp = NULL;
const char *zonename = "???";
gchar *buf = NULL;
#ifdef _MSC_VER
/* calling localtime() on MSVC 2005 with huge values causes it to crash */
/* XXX - find the exact value that still does work */
/* XXX - using _USE_32BIT_TIME_T might be another way to circumvent this problem */
if(abs_time > 2000000000) {
tmp = NULL;
} else
#endif
switch (fmt) {
case ABSOLUTE_TIME_UTC:
case ABSOLUTE_TIME_DOY_UTC:
tmp = gmtime(&abs_time);
zonename = "UTC";
break;
case ABSOLUTE_TIME_LOCAL:
tmp = localtime(&abs_time);
if (tmp) {
#if defined(HAVE_TM_ZONE)
zonename = tmp->tm_zone;
#elif defined(HAVE_TZNAME)
zonename = tzname[tmp->tm_isdst];
#elif _WIN32
zonename = _tzname[tmp->tm_isdst];
#else
zonename = tmp->tm_isdst ? "?ST" : "?DT";
#endif
}
break;
}
if (tmp) {
switch (fmt) {
case ABSOLUTE_TIME_DOY_UTC:
buf = ep_strdup_printf("%04d/%03d:%02d:%02d:%02d %s",
tmp->tm_year + 1900,
tmp->tm_yday,
tmp->tm_hour,
tmp->tm_min,
tmp->tm_sec,
zonename);
break;
case ABSOLUTE_TIME_UTC:
case ABSOLUTE_TIME_LOCAL:
buf = ep_strdup_printf("%s %2d, %d %02d:%02d:%02d %s",
mon_names[tmp->tm_mon],
tmp->tm_mday,
tmp->tm_year + 1900,
tmp->tm_hour,
tmp->tm_min,
tmp->tm_sec,
zonename);
break;
}
} else
buf = ep_strdup("Not representable");
return buf;
}
void
display_signed_time(gchar *buf, int buflen, gint32 sec, gint32 frac,
to_str_time_res_t units)
{
/* If the fractional part of the time stamp is negative,
print its absolute value and, if the seconds part isn't
(the seconds part should be zero in that case), stick
a "-" in front of the entire time stamp. */
if (frac < 0) {
frac = -frac;
if (sec >= 0) {
if (buflen < 1) {
return;
}
buf[0] = '-';
buf++;
buflen--;
}
}
switch (units) {
case TO_STR_TIME_RES_T_SECS:
g_snprintf(buf, buflen, "%d", sec);
break;
case TO_STR_TIME_RES_T_DSECS:
g_snprintf(buf, buflen, "%d.%01d", sec, frac);
break;
case TO_STR_TIME_RES_T_CSECS:
g_snprintf(buf, buflen, "%d.%02d", sec, frac);
break;
case TO_STR_TIME_RES_T_MSECS:
g_snprintf(buf, buflen, "%d.%03d", sec, frac);
break;
case TO_STR_TIME_RES_T_USECS:
g_snprintf(buf, buflen, "%d.%06d", sec, frac);
break;
case TO_STR_TIME_RES_T_NSECS:
g_snprintf(buf, buflen, "%d.%09d", sec, frac);
break;
}
}
void
display_epoch_time(gchar *buf, int buflen, time_t sec, gint32 frac,
to_str_time_res_t units)
{
double elapsed_secs;
elapsed_secs = difftime(sec,(time_t)0);
/* This code copied from display_signed_time; keep it in case anyone
is looking at captures from before 1970 (???).
If the fractional part of the time stamp is negative,
print its absolute value and, if the seconds part isn't
(the seconds part should be zero in that case), stick
a "-" in front of the entire time stamp. */
if (frac < 0) {
frac = -frac;
if (elapsed_secs >= 0) {
if (buflen < 1) {
return;
}
buf[0] = '-';
buf++;
buflen--;
}
}
switch (units) {
case TO_STR_TIME_RES_T_SECS:
g_snprintf(buf, buflen, "%0.0f", elapsed_secs);
break;
case TO_STR_TIME_RES_T_DSECS:
g_snprintf(buf, buflen, "%0.0f.%01d", elapsed_secs, frac);
break;
case TO_STR_TIME_RES_T_CSECS:
g_snprintf(buf, buflen, "%0.0f.%02d", elapsed_secs, frac);
break;
case TO_STR_TIME_RES_T_MSECS:
g_snprintf(buf, buflen, "%0.0f.%03d", elapsed_secs, frac);
break;
case TO_STR_TIME_RES_T_USECS:
g_snprintf(buf, buflen, "%0.0f.%06d", elapsed_secs, frac);
break;
case TO_STR_TIME_RES_T_NSECS:
g_snprintf(buf, buflen, "%0.0f.%09d", elapsed_secs, frac);
break;
}
}
/*
* Display a relative time as days/hours/minutes/seconds.
*/
gchar *
rel_time_to_str(nstime_t *rel_time)
{
emem_strbuf_t *buf;
const char *sign;
gint32 time_val;
gint32 nsec;
buf=ep_strbuf_sized_new(1+TIME_SECS_LEN+1+6+1, 1+TIME_SECS_LEN+1+6+1);
/* If the nanoseconds part of the time stamp is negative,
print its absolute value and, if the seconds part isn't
(the seconds part should be zero in that case), stick
a "-" in front of the entire time stamp. */
sign = "";
time_val = (gint) rel_time->secs;
nsec = rel_time->nsecs;
if (time_val == 0 && nsec == 0) {
ep_strbuf_append(buf, "0.000000000 seconds");
return buf->str;
}
if (nsec < 0) {
nsec = -nsec;
ep_strbuf_append_c(buf, '-');
/*
* We assume here that "rel_time->secs" is negative
* or zero; if it's not, the time stamp is bogus,
* with a positive seconds and negative microseconds.
*/
time_val = (gint) -rel_time->secs;
}
time_secs_to_str_buf(time_val, nsec, TRUE, buf);
return buf->str;
}
#define REL_TIME_SECS_LEN (1+10+1+9+1)
/*
* Display a relative time as seconds.
*/
gchar *
rel_time_to_secs_str(nstime_t *rel_time)
{
gchar *buf;
buf=ep_alloc(REL_TIME_SECS_LEN);
display_signed_time(buf, REL_TIME_SECS_LEN, (gint32) rel_time->secs,
rel_time->nsecs, TO_STR_TIME_RES_T_NSECS);
return buf;
}
/*
* Generates a string representing the bits in a bitfield at "bit_offset" from an 8 bit boundary
* with the length in bits of no_of_bits based on value.
* Ex: ..xx x...
*/
char *
decode_bits_in_field(gint bit_offset, gint no_of_bits, guint64 value)
{
guint64 mask = 0,tmp;
char *str;
int bit;
int i;
mask = 1;
mask = mask << (no_of_bits-1);
/* prepare the string */
str=ep_alloc(256);
str[0]='\0';
for(bit=0;bit<((int)(bit_offset&0x07));bit++){
if(bit&&(!(bit%4))){
strcat(str, " ");
}
strcat(str,".");
}
/* read the bits for the int */
for(i=0;i<no_of_bits;i++){
if(bit&&(!(bit%4))){
strcat(str, " ");
}
if(bit&&(!(bit%8))){
strcat(str, " ");
}
bit++;
tmp = value & mask;
if(tmp != 0){
strcat(str, "1");
} else {
strcat(str, "0");
}
mask = mask>>1;
}
for(;bit%8;bit++){
if(bit&&(!(bit%4))){
strcat(str, " ");
}
strcat(str,".");
}
return str;
}
/* Generate, into "buf", a string showing the bits of a bitfield.
Return a pointer to the character after that string. */
/*XXX this needs a buf_len check */
char *
other_decode_bitfield_value(char *buf, guint32 val, guint32 mask, int width)
{
int i;
guint32 bit;
char *p;
i = 0;
p = buf;
bit = 1 << (width - 1);
for (;;) {
if (mask & bit) {
/* This bit is part of the field. Show its value. */
if (val & bit)
*p++ = '1';
else
*p++ = '0';
} else {
/* This bit is not part of the field. */
*p++ = '.';
}
bit >>= 1;
i++;
if (i >= width)
break;
if (i % 4 == 0)
*p++ = ' ';
}
*p = '\0';
return p;
}
char *
decode_bitfield_value(char *buf, guint32 val, guint32 mask, int width)
{
char *p;
p = other_decode_bitfield_value(buf, val, mask, width);
strcpy(p, " = ");
p += 3;
return p;
}
/* Generate a string describing a Boolean bitfield (a one-bit field that
says something is either true of false). */
const char *
decode_boolean_bitfield(guint32 val, guint32 mask, int width,
const char *truedesc, const char *falsedesc)
{
char *buf;
char *p;
buf=ep_alloc(1025); /* is this a bit overkill? */
p = decode_bitfield_value(buf, val, mask, width);
if (val & mask)
strcpy(p, truedesc);
else
strcpy(p, falsedesc);
return buf;
}
/* Generate a string describing a numeric bitfield (an N-bit field whose
value is just a number). */
const char *
decode_numeric_bitfield(guint32 val, guint32 mask, int width,
const char *fmt)
{
char *buf;
char *p;
int shift = 0;
buf=ep_alloc(1025); /* isnt this a bit overkill? */
/* Compute the number of bits we have to shift the bitfield right
to extract its value. */
while ((mask & (1<<shift)) == 0)
shift++;
p = decode_bitfield_value(buf, val, mask, width);
g_snprintf(p, (gulong) (1025-(p-buf)), fmt, (val & mask) >> shift);
return buf;
}
/*
This function is very fast and this function is called a lot.
XXX update the ep_address_to_str stuff to use this function.
*/
void
ip_to_str_buf(const guint8 *ad, gchar *buf, int buf_len)
{
register gchar const *p;
register gchar *b=buf;
if (buf_len < MAX_IP_STR_LEN) {
g_snprintf ( buf, buf_len, BUF_TOO_SMALL_ERR ); /* Let the unexpected value alert user */
return;
}
p=fast_strings[*ad++];
do {
*b++=*p;
p++;
} while(*p);
*b++='.';
p=fast_strings[*ad++];
do {
*b++=*p;
p++;
} while(*p);
*b++='.';
p=fast_strings[*ad++];
do {
*b++=*p;
p++;
} while(*p);
*b++='.';
p=fast_strings[*ad];
do {
*b++=*p;
p++;
} while(*p);
*b=0;
}
gchar* guid_to_str(const e_guid_t *guid) {
gchar *buf;
buf=ep_alloc(GUID_STR_LEN);
return guid_to_str_buf(guid, buf, GUID_STR_LEN);
}
gchar* guid_to_str_buf(const e_guid_t *guid, gchar *buf, int buf_len) {
char *tempptr = buf;
if (buf_len < GUID_STR_LEN) {
g_strlcpy(buf, BUF_TOO_SMALL_ERR, buf_len);/* Let the unexpected value alert user */
return buf;
}
/* 37 bytes */
tempptr = dword_to_hex(tempptr, guid->data1); /* 8 bytes */
*tempptr++ = '-'; /* 1 byte */
tempptr = word_to_hex(tempptr, guid->data2); /* 4 bytes */
*tempptr++ = '-'; /* 1 byte */
tempptr = word_to_hex(tempptr, guid->data3); /* 4 bytes */
*tempptr++ = '-'; /* 1 byte */
tempptr = bytes_to_hexstr(tempptr, &guid->data4[0], 2); /* 4 bytes */
*tempptr++ = '-'; /* 1 byte */
tempptr = bytes_to_hexstr(tempptr, &guid->data4[2], 6); /* 12 bytes */
*tempptr = '\0';
return buf;
}
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