ossp-pkg/uuid/uuid.c
/*
** OSSP uuid - Universally Unique Identifier
** Copyright (c) 2004-2008 Ralf S. Engelschall <rse@engelschall.com>
** Copyright (c) 2004-2008 The OSSP Project <http://www.ossp.org/>
**
** This file is part of OSSP uuid, a library for the generation
** of UUIDs which can found at http://www.ossp.org/pkg/lib/uuid/
**
** Permission to use, copy, modify, and distribute this software for
** any purpose with or without fee is hereby granted, provided that
** the above copyright notice and this permission notice appear in all
** copies.
**
** THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESSED OR IMPLIED
** WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
** MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
** IN NO EVENT SHALL THE AUTHORS AND COPYRIGHT HOLDERS AND THEIR
** CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
** SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
** LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
** USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
** ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
** OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
** OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
** SUCH DAMAGE.
**
** uuid.c: library API implementation
*/
/* own headers (part 1/2) */
#include "uuid.h"
#include "uuid_ac.h"
/* system headers */
#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
#include <string.h>
#include <unistd.h>
#include <ctype.h>
#include <fcntl.h>
#include <time.h>
#include <sys/time.h>
#include <sys/types.h>
/* own headers (part 2/2) */
#include "uuid_vers.h"
#include "uuid_md5.h"
#include "uuid_sha1.h"
#include "uuid_prng.h"
#include "uuid_mac.h"
#include "uuid_time.h"
#include "uuid_ui64.h"
#include "uuid_ui128.h"
#include "uuid_str.h"
#include "uuid_bm.h"
#include "uuid_ac.h"
/* maximum number of 100ns ticks of the actual resolution of system clock
(which in our case is 1us (= 1000ns) because we use gettimeofday(2) */
#define UUIDS_PER_TICK 10
/* time offset between UUID and Unix Epoch time according to standards.
(UUID UTC base time is October 15, 1582
Unix UTC base time is January 1, 1970) */
#define UUID_TIMEOFFSET "01B21DD213814000"
/* IEEE 802 MAC address encoding/decoding bit fields */
#define IEEE_MAC_MCBIT BM_OCTET(0,0,0,0,0,0,0,1)
#define IEEE_MAC_LOBIT BM_OCTET(0,0,0,0,0,0,1,0)
/* IEEE 802 MAC address octet length */
#define IEEE_MAC_OCTETS 6
/* UUID binary representation according to UUID standards */
typedef struct {
uuid_uint32_t time_low; /* bits 0-31 of time field */
uuid_uint16_t time_mid; /* bits 32-47 of time field */
uuid_uint16_t time_hi_and_version; /* bits 48-59 of time field plus 4 bit version */
uuid_uint8_t clock_seq_hi_and_reserved; /* bits 8-13 of clock sequence field plus 2 bit variant */
uuid_uint8_t clock_seq_low; /* bits 0-7 of clock sequence field */
uuid_uint8_t node[IEEE_MAC_OCTETS]; /* bits 0-47 of node MAC address */
} uuid_obj_t;
/* abstract data type (ADT) of API */
struct uuid_st {
uuid_obj_t obj; /* inlined UUID object */
prng_t *prng; /* RPNG sub-object */
md5_t *md5; /* MD5 sub-object */
sha1_t *sha1; /* SHA-1 sub-object */
uuid_uint8_t mac[IEEE_MAC_OCTETS]; /* pre-determined MAC address */
struct timeval time_last; /* last retrieved timestamp */
unsigned long time_seq; /* last timestamp sequence counter */
};
/* create UUID object */
uuid_rc_t uuid_create(uuid_t **uuid)
{
uuid_t *obj;
/* argument sanity check */
if (uuid == NULL)
return UUID_RC_ARG;
/* allocate UUID object */
if ((obj = (uuid_t *)malloc(sizeof(uuid_t))) == NULL)
return UUID_RC_MEM;
/* create PRNG, MD5 and SHA1 sub-objects */
if (prng_create(&obj->prng) != PRNG_RC_OK) {
free(obj);
return UUID_RC_INT;
}
if (md5_create(&obj->md5) != MD5_RC_OK) {
(void)prng_destroy(obj->prng);
free(obj);
return UUID_RC_INT;
}
if (sha1_create(&obj->sha1) != SHA1_RC_OK) {
(void)md5_destroy(obj->md5);
(void)prng_destroy(obj->prng);
free(obj);
return UUID_RC_INT;
}
/* set UUID object initially to "Nil UUID" */
if (uuid_load(obj, "nil") != UUID_RC_OK) {
(void)sha1_destroy(obj->sha1);
(void)md5_destroy(obj->md5);
(void)prng_destroy(obj->prng);
free(obj);
return UUID_RC_INT;
}
/* resolve MAC address for insertion into node field of UUIDs */
if (!mac_address((unsigned char *)(obj->mac), sizeof(obj->mac))) {
memset(obj->mac, 0, sizeof(obj->mac));
obj->mac[0] = BM_OCTET(1,0,0,0,0,0,0,0);
}
/* initialize time attributes */
obj->time_last.tv_sec = 0;
obj->time_last.tv_usec = 0;
obj->time_seq = 0;
/* store result object */
*uuid = obj;
return UUID_RC_OK;
}
/* destroy UUID object */
uuid_rc_t uuid_destroy(uuid_t *uuid)
{
/* argument sanity check */
if (uuid == NULL)
return UUID_RC_ARG;
/* destroy PRNG, MD5 and SHA-1 sub-objects */
(void)prng_destroy(uuid->prng);
(void)md5_destroy(uuid->md5);
(void)sha1_destroy(uuid->sha1);
/* free UUID object */
free(uuid);
return UUID_RC_OK;
}
/* clone UUID object */
uuid_rc_t uuid_clone(const uuid_t *uuid, uuid_t **clone)
{
uuid_t *obj;
/* argument sanity check */
if (uuid == NULL || uuid_clone == NULL)
return UUID_RC_ARG;
/* allocate UUID object */
if ((obj = (uuid_t *)malloc(sizeof(uuid_t))) == NULL)
return UUID_RC_MEM;
/* clone entire internal state */
memcpy(obj, uuid, sizeof(uuid_t));
/* re-initialize with new PRNG, MD5 and SHA1 sub-objects */
if (prng_create(&obj->prng) != PRNG_RC_OK) {
free(obj);
return UUID_RC_INT;
}
if (md5_create(&obj->md5) != MD5_RC_OK) {
(void)prng_destroy(obj->prng);
free(obj);
return UUID_RC_INT;
}
if (sha1_create(&obj->sha1) != SHA1_RC_OK) {
(void)md5_destroy(obj->md5);
(void)prng_destroy(obj->prng);
free(obj);
return UUID_RC_INT;
}
/* store result object */
*clone = obj;
return UUID_RC_OK;
}
/* check whether UUID object represents "Nil UUID" */
uuid_rc_t uuid_isnil(const uuid_t *uuid, int *result)
{
const unsigned char *ucp;
int i;
/* sanity check argument(s) */
if (uuid == NULL || result == NULL)
return UUID_RC_ARG;
/* a "Nil UUID" is defined as all octets zero, so check for this case */
*result = UUID_TRUE;
for (i = 0, ucp = (unsigned char *)&(uuid->obj); i < UUID_LEN_BIN; i++) {
if (*ucp++ != (unsigned char)'\0') {
*result = UUID_FALSE;
break;
}
}
return UUID_RC_OK;
}
/* compare UUID objects */
uuid_rc_t uuid_compare(const uuid_t *uuid1, const uuid_t *uuid2, int *result)
{
int r;
/* argument sanity check */
if (result == NULL)
return UUID_RC_ARG;
/* convenience macro for setting result */
#define RESULT(r) \
/*lint -save -e801 -e717*/ \
do { \
*result = (r); \
goto result_exit; \
} while (0) \
/*lint -restore*/
/* special cases: NULL or equal UUIDs */
if (uuid1 == uuid2)
RESULT(0);
if (uuid1 == NULL && uuid2 == NULL)
RESULT(0);
if (uuid1 == NULL)
RESULT((uuid_isnil(uuid2, &r) == UUID_RC_OK ? r : 0) ? 0 : -1);
if (uuid2 == NULL)
RESULT((uuid_isnil(uuid1, &r) == UUID_RC_OK ? r : 0) ? 0 : 1);
/* standard cases: regular different UUIDs */
if (uuid1->obj.time_low != uuid2->obj.time_low)
RESULT((uuid1->obj.time_low < uuid2->obj.time_low) ? -1 : 1);
if ((r = (int)uuid1->obj.time_mid
- (int)uuid2->obj.time_mid) != 0)
RESULT((r < 0) ? -1 : 1);
if ((r = (int)uuid1->obj.time_hi_and_version
- (int)uuid2->obj.time_hi_and_version) != 0)
RESULT((r < 0) ? -1 : 1);
if ((r = (int)uuid1->obj.clock_seq_hi_and_reserved
- (int)uuid2->obj.clock_seq_hi_and_reserved) != 0)
RESULT((r < 0) ? -1 : 1);
if ((r = (int)uuid1->obj.clock_seq_low
- (int)uuid2->obj.clock_seq_low) != 0)
RESULT((r < 0) ? -1 : 1);
if ((r = memcmp(uuid1->obj.node, uuid2->obj.node, sizeof(uuid1->obj.node))) != 0)
RESULT((r < 0) ? -1 : 1);
/* default case: the keys are equal */
*result = 0;
result_exit:
return UUID_RC_OK;
}
/* INTERNAL: unpack UUID binary presentation into UUID object
(allows in-place operation for internal efficiency!) */
static uuid_rc_t uuid_import_bin(uuid_t *uuid, const void *data_ptr, size_t data_len)
{
const uuid_uint8_t *in;
uuid_uint32_t tmp32;
uuid_uint16_t tmp16;
unsigned int i;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL || data_len < UUID_LEN_BIN)
return UUID_RC_ARG;
/* treat input data buffer as octet stream */
in = (const uuid_uint8_t *)data_ptr;
/* unpack "time_low" field */
tmp32 = (uuid_uint32_t)(*in++);
tmp32 = (tmp32 << 8) | (uuid_uint32_t)(*in++);
tmp32 = (tmp32 << 8) | (uuid_uint32_t)(*in++);
tmp32 = (tmp32 << 8) | (uuid_uint32_t)(*in++);
uuid->obj.time_low = tmp32;
/* unpack "time_mid" field */
tmp16 = (uuid_uint16_t)(*in++);
tmp16 = (uuid_uint16_t)(tmp16 << 8) | (uuid_uint16_t)(*in++);
uuid->obj.time_mid = tmp16;
/* unpack "time_hi_and_version" field */
tmp16 = (uuid_uint16_t)*in++;
tmp16 = (uuid_uint16_t)(tmp16 << 8) | (uuid_uint16_t)(*in++);
uuid->obj.time_hi_and_version = tmp16;
/* unpack "clock_seq_hi_and_reserved" field */
uuid->obj.clock_seq_hi_and_reserved = *in++;
/* unpack "clock_seq_low" field */
uuid->obj.clock_seq_low = *in++;
/* unpack "node" field */
for (i = 0; i < (unsigned int)sizeof(uuid->obj.node); i++)
uuid->obj.node[i] = *in++;
return UUID_RC_OK;
}
/* INTERNAL: pack UUID object into binary representation
(allows in-place operation for internal efficiency!) */
static uuid_rc_t uuid_export_bin(const uuid_t *uuid, void *_data_ptr, size_t *data_len)
{
uuid_uint8_t **data_ptr;
uuid_uint8_t *out;
uuid_uint32_t tmp32;
uuid_uint16_t tmp16;
unsigned int i;
/* cast generic data pointer to particular pointer to pointer type */
data_ptr = (uuid_uint8_t **)_data_ptr;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL)
return UUID_RC_ARG;
/* optionally allocate octet data buffer */
if (*data_ptr == NULL) {
if ((*data_ptr = (uuid_uint8_t *)malloc(sizeof(uuid_t))) == NULL)
return UUID_RC_MEM;
if (data_len != NULL)
*data_len = UUID_LEN_BIN;
}
else {
if (data_len == NULL)
return UUID_RC_ARG;
if (*data_len < UUID_LEN_BIN)
return UUID_RC_MEM;
*data_len = UUID_LEN_BIN;
}
/* treat output data buffer as octet stream */
out = *data_ptr;
/* pack "time_low" field */
tmp32 = uuid->obj.time_low;
out[3] = (uuid_uint8_t)(tmp32 & 0xff); tmp32 >>= 8;
out[2] = (uuid_uint8_t)(tmp32 & 0xff); tmp32 >>= 8;
out[1] = (uuid_uint8_t)(tmp32 & 0xff); tmp32 >>= 8;
out[0] = (uuid_uint8_t)(tmp32 & 0xff);
/* pack "time_mid" field */
tmp16 = uuid->obj.time_mid;
out[5] = (uuid_uint8_t)(tmp16 & 0xff); tmp16 >>= 8;
out[4] = (uuid_uint8_t)(tmp16 & 0xff);
/* pack "time_hi_and_version" field */
tmp16 = uuid->obj.time_hi_and_version;
out[7] = (uuid_uint8_t)(tmp16 & 0xff); tmp16 >>= 8;
out[6] = (uuid_uint8_t)(tmp16 & 0xff);
/* pack "clock_seq_hi_and_reserved" field */
out[8] = uuid->obj.clock_seq_hi_and_reserved;
/* pack "clock_seq_low" field */
out[9] = uuid->obj.clock_seq_low;
/* pack "node" field */
for (i = 0; i < (unsigned int)sizeof(uuid->obj.node); i++)
out[10+i] = uuid->obj.node[i];
return UUID_RC_OK;
}
/* INTERNAL: check for valid UUID string representation syntax */
static int uuid_isstr(const char *str, size_t str_len)
{
int i;
const char *cp;
/* example reference:
f81d4fae-7dec-11d0-a765-00a0c91e6bf6
012345678901234567890123456789012345
0 1 2 3 */
if (str == NULL)
return UUID_FALSE;
if (str_len == 0)
str_len = strlen(str);
if (str_len < UUID_LEN_STR)
return UUID_FALSE;
for (i = 0, cp = str; i < UUID_LEN_STR; i++, cp++) {
if ((i == 8) || (i == 13) || (i == 18) || (i == 23)) {
if (*cp == '-')
continue;
else
return UUID_FALSE;
}
if (!isxdigit((int)(*cp)))
return UUID_FALSE;
}
return UUID_TRUE;
}
/* INTERNAL: import UUID object from string representation */
static uuid_rc_t uuid_import_str(uuid_t *uuid, const void *data_ptr, size_t data_len)
{
uuid_uint16_t tmp16;
const char *cp;
char hexbuf[3];
const char *str;
unsigned int i;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL || data_len < UUID_LEN_STR)
return UUID_RC_ARG;
/* check for correct UUID string representation syntax */
str = (const char *)data_ptr;
if (!uuid_isstr(str, 0))
return UUID_RC_ARG;
/* parse hex values of "time" parts */
uuid->obj.time_low = (uuid_uint32_t)strtoul(str, NULL, 16);
uuid->obj.time_mid = (uuid_uint16_t)strtoul(str+9, NULL, 16);
uuid->obj.time_hi_and_version = (uuid_uint16_t)strtoul(str+14, NULL, 16);
/* parse hex values of "clock" parts */
tmp16 = (uuid_uint16_t)strtoul(str+19, NULL, 16);
uuid->obj.clock_seq_low = (uuid_uint8_t)(tmp16 & 0xff); tmp16 >>= 8;
uuid->obj.clock_seq_hi_and_reserved = (uuid_uint8_t)(tmp16 & 0xff);
/* parse hex values of "node" part */
cp = str+24;
hexbuf[2] = '\0';
for (i = 0; i < (unsigned int)sizeof(uuid->obj.node); i++) {
hexbuf[0] = *cp++;
hexbuf[1] = *cp++;
uuid->obj.node[i] = (uuid_uint8_t)strtoul(hexbuf, NULL, 16);
}
return UUID_RC_OK;
}
/* INTERNAL: import UUID object from single integer value representation */
static uuid_rc_t uuid_import_siv(uuid_t *uuid, const void *data_ptr, size_t data_len)
{
const char *str;
uuid_uint8_t tmp_bin[UUID_LEN_BIN];
ui128_t ui, ui2;
uuid_rc_t rc;
int i;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL || data_len < 1)
return UUID_RC_ARG;
/* check for correct UUID single integer value syntax */
str = (const char *)data_ptr;
for (i = 0; i < (int)data_len; i++)
if (!isdigit((int)str[i]))
return UUID_RC_ARG;
/* parse single integer value representation (SIV) */
ui = ui128_s2i(str, NULL, 10);
/* import octets into UUID binary representation */
for (i = 0; i < UUID_LEN_BIN; i++) {
ui = ui128_rol(ui, 8, &ui2);
tmp_bin[i] = (uuid_uint8_t)(ui128_i2n(ui2) & 0xff);
}
/* import into internal UUID representation */
if ((rc = uuid_import(uuid, UUID_FMT_BIN, (void *)&tmp_bin, UUID_LEN_BIN)) != UUID_RC_OK)
return rc;
return UUID_RC_OK;
}
/* INTERNAL: export UUID object to string representation */
static uuid_rc_t uuid_export_str(const uuid_t *uuid, void *_data_ptr, size_t *data_len)
{
char **data_ptr;
char *data_buf;
/* cast generic data pointer to particular pointer to pointer type */
data_ptr = (char **)_data_ptr;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL)
return UUID_RC_ARG;
/* determine output buffer */
if (*data_ptr == NULL) {
if ((data_buf = (char *)malloc(UUID_LEN_STR+1)) == NULL)
return UUID_RC_MEM;
if (data_len != NULL)
*data_len = UUID_LEN_STR+1;
}
else {
data_buf = (char *)(*data_ptr);
if (data_len == NULL)
return UUID_RC_ARG;
if (*data_len < UUID_LEN_STR+1)
return UUID_RC_MEM;
*data_len = UUID_LEN_STR+1;
}
/* format UUID into string representation */
if (str_snprintf(data_buf, UUID_LEN_STR+1,
"%08lx-%04x-%04x-%02x%02x-%02x%02x%02x%02x%02x%02x",
(unsigned long)uuid->obj.time_low,
(unsigned int)uuid->obj.time_mid,
(unsigned int)uuid->obj.time_hi_and_version,
(unsigned int)uuid->obj.clock_seq_hi_and_reserved,
(unsigned int)uuid->obj.clock_seq_low,
(unsigned int)uuid->obj.node[0],
(unsigned int)uuid->obj.node[1],
(unsigned int)uuid->obj.node[2],
(unsigned int)uuid->obj.node[3],
(unsigned int)uuid->obj.node[4],
(unsigned int)uuid->obj.node[5]) != UUID_LEN_STR) {
if (*data_ptr == NULL)
free(data_buf);
return UUID_RC_INT;
}
/* pass back new buffer if locally allocated */
if (*data_ptr == NULL)
*data_ptr = data_buf;
return UUID_RC_OK;
}
/* INTERNAL: export UUID object to single integer value representation */
static uuid_rc_t uuid_export_siv(const uuid_t *uuid, void *_data_ptr, size_t *data_len)
{
char **data_ptr;
char *data_buf;
void *tmp_ptr;
size_t tmp_len;
uuid_uint8_t tmp_bin[UUID_LEN_BIN];
ui128_t ui, ui2;
uuid_rc_t rc;
int i;
/* cast generic data pointer to particular pointer to pointer type */
data_ptr = (char **)_data_ptr;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL)
return UUID_RC_ARG;
/* determine output buffer */
if (*data_ptr == NULL) {
if ((data_buf = (char *)malloc(UUID_LEN_SIV+1)) == NULL)
return UUID_RC_MEM;
if (data_len != NULL)
*data_len = UUID_LEN_SIV+1;
}
else {
data_buf = (char *)(*data_ptr);
if (data_len == NULL)
return UUID_RC_ARG;
if (*data_len < UUID_LEN_SIV+1)
return UUID_RC_MEM;
*data_len = UUID_LEN_SIV+1;
}
/* export into UUID binary representation */
tmp_ptr = (void *)&tmp_bin;
tmp_len = sizeof(tmp_bin);
if ((rc = uuid_export(uuid, UUID_FMT_BIN, &tmp_ptr, &tmp_len)) != UUID_RC_OK) {
if (*data_ptr == NULL)
free(data_buf);
return rc;
}
/* import from UUID binary representation */
ui = ui128_zero();
for (i = 0; i < UUID_LEN_BIN; i++) {
ui2 = ui128_n2i((unsigned long)tmp_bin[i]);
ui = ui128_rol(ui, 8, NULL);
ui = ui128_or(ui, ui2);
}
/* format into single integer value representation */
(void)ui128_i2s(ui, data_buf, UUID_LEN_SIV+1, 10);
/* pass back new buffer if locally allocated */
if (*data_ptr == NULL)
*data_ptr = data_buf;
return UUID_RC_OK;
}
/* decoding tables */
static struct {
uuid_uint8_t num;
const char *desc;
} uuid_dectab_variant[] = {
{ (uuid_uint8_t)BM_OCTET(0,0,0,0,0,0,0,0), "reserved (NCS backward compatible)" },
{ (uuid_uint8_t)BM_OCTET(1,0,0,0,0,0,0,0), "DCE 1.1, ISO/IEC 11578:1996" },
{ (uuid_uint8_t)BM_OCTET(1,1,0,0,0,0,0,0), "reserved (Microsoft GUID)" },
{ (uuid_uint8_t)BM_OCTET(1,1,1,0,0,0,0,0), "reserved (future use)" }
};
static struct {
int num;
const char *desc;
} uuid_dectab_version[] = {
{ 1, "time and node based" },
{ 3, "name based, MD5" },
{ 4, "random data based" },
{ 5, "name based, SHA-1" }
};
/* INTERNAL: dump UUID object as descriptive text */
static uuid_rc_t uuid_export_txt(const uuid_t *uuid, void *_data_ptr, size_t *data_len)
{
char **data_ptr;
uuid_rc_t rc;
char **out;
char *out_ptr;
size_t out_len;
const char *version;
const char *variant;
char *content;
int isnil;
uuid_uint8_t tmp8;
uuid_uint16_t tmp16;
uuid_uint32_t tmp32;
uuid_uint8_t tmp_bin[UUID_LEN_BIN];
char tmp_str[UUID_LEN_STR+1];
char tmp_siv[UUID_LEN_SIV+1];
void *tmp_ptr;
size_t tmp_len;
ui64_t t;
ui64_t t_offset;
int t_nsec;
int t_usec;
time_t t_sec;
char t_buf[19+1]; /* YYYY-MM-DD HH:MM:SS */
struct tm *tm;
int i;
/* cast generic data pointer to particular pointer to pointer type */
data_ptr = (char **)_data_ptr;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL)
return UUID_RC_ARG;
/* initialize output buffer */
out_ptr = NULL;
out = &out_ptr;
/* check for special case of "Nil UUID" */
if ((rc = uuid_isnil(uuid, &isnil)) != UUID_RC_OK)
return rc;
/* decode into various representations */
tmp_ptr = (void *)&tmp_str;
tmp_len = sizeof(tmp_str);
if ((rc = uuid_export(uuid, UUID_FMT_STR, &tmp_ptr, &tmp_len)) != UUID_RC_OK)
return rc;
tmp_ptr = (void *)&tmp_siv;
tmp_len = sizeof(tmp_siv);
if ((rc = uuid_export(uuid, UUID_FMT_SIV, &tmp_ptr, &tmp_len)) != UUID_RC_OK)
return rc;
(void)str_rsprintf(out, "encode: STR: %s\n", tmp_str);
(void)str_rsprintf(out, " SIV: %s\n", tmp_siv);
/* decode UUID variant */
tmp8 = uuid->obj.clock_seq_hi_and_reserved;
if (isnil)
variant = "n.a.";
else {
variant = "unknown";
for (i = 7; i >= 0; i--) {
if ((tmp8 & (uuid_uint8_t)BM_BIT(i,1)) == 0) {
tmp8 &= ~(uuid_uint8_t)BM_MASK(i,0);
break;
}
}
for (i = 0; i < (int)(sizeof(uuid_dectab_variant)/sizeof(uuid_dectab_variant[0])); i++) {
if (uuid_dectab_variant[i].num == tmp8) {
variant = uuid_dectab_variant[i].desc;
break;
}
}
}
(void)str_rsprintf(out, "decode: variant: %s\n", variant);
/* decode UUID version */
tmp16 = (BM_SHR(uuid->obj.time_hi_and_version, 12) & (uuid_uint16_t)BM_MASK(3,0));
if (isnil)
version = "n.a.";
else {
version = "unknown";
for (i = 0; i < (int)(sizeof(uuid_dectab_version)/sizeof(uuid_dectab_version[0])); i++) {
if (uuid_dectab_version[i].num == (int)tmp16) {
version = uuid_dectab_version[i].desc;
break;
}
}
}
str_rsprintf(out, " version: %d (%s)\n", (int)tmp16, version);
/*
* decode UUID content
*/
if (tmp8 == BM_OCTET(1,0,0,0,0,0,0,0) && tmp16 == 1) {
/* decode DCE 1.1 version 1 UUID */
/* decode system time */
t = ui64_rol(ui64_n2i((unsigned long)(uuid->obj.time_hi_and_version & BM_MASK(11,0))), 48, NULL),
t = ui64_or(t, ui64_rol(ui64_n2i((unsigned long)(uuid->obj.time_mid)), 32, NULL));
t = ui64_or(t, ui64_n2i((unsigned long)(uuid->obj.time_low)));
t_offset = ui64_s2i(UUID_TIMEOFFSET, NULL, 16);
t = ui64_sub(t, t_offset, NULL);
t = ui64_divn(t, 10, &t_nsec);
t = ui64_divn(t, 1000000, &t_usec);
t_sec = (time_t)ui64_i2n(t);
tm = gmtime(&t_sec);
(void)strftime(t_buf, sizeof(t_buf), "%Y-%m-%d %H:%M:%S", tm);
(void)str_rsprintf(out, " content: time: %s.%06d.%d UTC\n", t_buf, t_usec, t_nsec);
/* decode clock sequence */
tmp32 = ((uuid->obj.clock_seq_hi_and_reserved & BM_MASK(5,0)) << 8)
+ uuid->obj.clock_seq_low;
(void)str_rsprintf(out, " clock: %ld (usually random)\n", (long)tmp32);
/* decode node MAC address */
(void)str_rsprintf(out, " node: %02x:%02x:%02x:%02x:%02x:%02x (%s %s)\n",
(unsigned int)uuid->obj.node[0],
(unsigned int)uuid->obj.node[1],
(unsigned int)uuid->obj.node[2],
(unsigned int)uuid->obj.node[3],
(unsigned int)uuid->obj.node[4],
(unsigned int)uuid->obj.node[5],
(uuid->obj.node[0] & IEEE_MAC_LOBIT ? "local" : "global"),
(uuid->obj.node[0] & IEEE_MAC_MCBIT ? "multicast" : "unicast"));
}
else {
/* decode anything else as hexadecimal byte-string only */
/* determine annotational hint */
content = "not decipherable: unknown UUID version";
if (isnil)
content = "special case: DCE 1.1 Nil UUID";
else if (tmp16 == 3)
content = "not decipherable: MD5 message digest only";
else if (tmp16 == 4)
content = "no semantics: random data only";
else if (tmp16 == 5)
content = "not decipherable: truncated SHA-1 message digest only";
/* pack UUID into binary representation */
tmp_ptr = (void *)&tmp_bin;
tmp_len = sizeof(tmp_bin);
if ((rc = uuid_export(uuid, UUID_FMT_BIN, &tmp_ptr, &tmp_len)) != UUID_RC_OK)
return rc;
/* mask out version and variant parts */
tmp_bin[6] &= BM_MASK(3,0);
tmp_bin[8] &= BM_MASK(5,0);
/* dump as colon-seperated hexadecimal byte-string */
(void)str_rsprintf(out,
" content: %02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X\n"
" (%s)\n",
(unsigned int)tmp_bin[0], (unsigned int)tmp_bin[1], (unsigned int)tmp_bin[2],
(unsigned int)tmp_bin[3], (unsigned int)tmp_bin[4], (unsigned int)tmp_bin[5],
(unsigned int)tmp_bin[6], (unsigned int)tmp_bin[7], (unsigned int)tmp_bin[8],
(unsigned int)tmp_bin[9], (unsigned int)tmp_bin[10], (unsigned int)tmp_bin[11],
(unsigned int)tmp_bin[12], (unsigned int)tmp_bin[13], (unsigned int)tmp_bin[14],
(unsigned int)tmp_bin[15], content);
}
/* provide result */
out_len = strlen(out_ptr)+1;
if (*data_ptr == NULL) {
*data_ptr = (void *)out_ptr;
if (data_len != NULL)
*data_len = out_len;
}
else {
if (data_len == NULL)
return UUID_RC_ARG;
if (*data_len < out_len)
return UUID_RC_MEM;
memcpy(*data_ptr, out_ptr, out_len);
}
return UUID_RC_OK;
}
/* UUID importing */
uuid_rc_t uuid_import(uuid_t *uuid, uuid_fmt_t fmt, const void *data_ptr, size_t data_len)
{
uuid_rc_t rc;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL)
return UUID_RC_ARG;
/* dispatch into format-specific functions */
switch (fmt) {
case UUID_FMT_BIN: rc = uuid_import_bin(uuid, data_ptr, data_len); break;
case UUID_FMT_STR: rc = uuid_import_str(uuid, data_ptr, data_len); break;
case UUID_FMT_SIV: rc = uuid_import_siv(uuid, data_ptr, data_len); break;
case UUID_FMT_TXT: rc = UUID_RC_IMP; /* not implemented */ break;
default: rc = UUID_RC_ARG;
}
return rc;
}
/* UUID exporting */
uuid_rc_t uuid_export(const uuid_t *uuid, uuid_fmt_t fmt, void *data_ptr, size_t *data_len)
{
uuid_rc_t rc;
/* sanity check argument(s) */
if (uuid == NULL || data_ptr == NULL)
return UUID_RC_ARG;
/* dispatch into format-specific functions */
switch (fmt) {
case UUID_FMT_BIN: rc = uuid_export_bin(uuid, data_ptr, data_len); break;
case UUID_FMT_STR: rc = uuid_export_str(uuid, data_ptr, data_len); break;
case UUID_FMT_SIV: rc = uuid_export_siv(uuid, data_ptr, data_len); break;
case UUID_FMT_TXT: rc = uuid_export_txt(uuid, data_ptr, data_len); break;
default: rc = UUID_RC_ARG;
}
return rc;
}
/* INTERNAL: brand UUID with version and variant */
static void uuid_brand(uuid_t *uuid, unsigned int version)
{
/* set version (as given) */
uuid->obj.time_hi_and_version &= BM_MASK(11,0);
uuid->obj.time_hi_and_version |= (uuid_uint16_t)BM_SHL(version, 12);
/* set variant (always DCE 1.1 only) */
uuid->obj.clock_seq_hi_and_reserved &= BM_MASK(5,0);
uuid->obj.clock_seq_hi_and_reserved |= BM_SHL(0x02, 6);
return;
}
/* INTERNAL: generate UUID version 1: time, clock and node based */
static uuid_rc_t uuid_make_v1(uuid_t *uuid, unsigned int mode, va_list ap)
{
struct timeval time_now;
ui64_t t;
ui64_t offset;
ui64_t ov;
uuid_uint16_t clck;
/*
* GENERATE TIME
*/
/* determine current system time and sequence counter */
for (;;) {
/* determine current system time */
if (time_gettimeofday(&time_now) == -1)
return UUID_RC_SYS;
/* check whether system time changed since last retrieve */
if (!( time_now.tv_sec == uuid->time_last.tv_sec
&& time_now.tv_usec == uuid->time_last.tv_usec)) {
/* reset time sequence counter and continue */
uuid->time_seq = 0;
break;
}
/* until we are out of UUIDs per tick, increment
the time/tick sequence counter and continue */
if (uuid->time_seq < UUIDS_PER_TICK) {
uuid->time_seq++;
break;
}
/* stall the UUID generation until the system clock (which
has a gettimeofday(2) resolution of 1us) catches up */
time_usleep(1);
}
/* convert from timeval (sec,usec) to OSSP ui64 (100*nsec) format */
t = ui64_n2i((unsigned long)time_now.tv_sec);
t = ui64_muln(t, 1000000, NULL);
t = ui64_addn(t, (int)time_now.tv_usec, NULL);
t = ui64_muln(t, 10, NULL);
/* adjust for offset between UUID and Unix Epoch time */
offset = ui64_s2i(UUID_TIMEOFFSET, NULL, 16);
t = ui64_add(t, offset, NULL);
/* compensate for low resolution system clock by adding
the time/tick sequence counter */
if (uuid->time_seq > 0)
t = ui64_addn(t, (int)uuid->time_seq, NULL);
/* store the 60 LSB of the time in the UUID */
t = ui64_rol(t, 16, &ov);
uuid->obj.time_hi_and_version =
(uuid_uint16_t)(ui64_i2n(ov) & 0x00000fff); /* 12 of 16 bit only! */
t = ui64_rol(t, 16, &ov);
uuid->obj.time_mid =
(uuid_uint16_t)(ui64_i2n(ov) & 0x0000ffff); /* all 16 bit */
t = ui64_rol(t, 32, &ov);
uuid->obj.time_low =
(uuid_uint32_t)(ui64_i2n(ov) & 0xffffffff); /* all 32 bit */
/*
* GENERATE CLOCK
*/
/* retrieve current clock sequence */
clck = ((uuid->obj.clock_seq_hi_and_reserved & BM_MASK(5,0)) << 8)
+ uuid->obj.clock_seq_low;
/* generate new random clock sequence (initially or if the
time has stepped backwards) or else just increase it */
if ( clck == 0
|| ( time_now.tv_sec < uuid->time_last.tv_sec
|| ( time_now.tv_sec == uuid->time_last.tv_sec
&& time_now.tv_usec < uuid->time_last.tv_usec))) {
if (prng_data(uuid->prng, (void *)&clck, sizeof(clck)) != PRNG_RC_OK)
return UUID_RC_INT;
}
else
clck++;
clck %= BM_POW2(14);
/* store back new clock sequence */
uuid->obj.clock_seq_hi_and_reserved =
(uuid->obj.clock_seq_hi_and_reserved & BM_MASK(7,6))
| (uuid_uint8_t)((clck >> 8) & 0xff);
uuid->obj.clock_seq_low =
(uuid_uint8_t)(clck & 0xff);
/*
* GENERATE NODE
*/
if ((mode & UUID_MAKE_MC) || (uuid->mac[0] & BM_OCTET(1,0,0,0,0,0,0,0))) {
/* generate random IEEE 802 local multicast MAC address */
if (prng_data(uuid->prng, (void *)&(uuid->obj.node), sizeof(uuid->obj.node)) != PRNG_RC_OK)
return UUID_RC_INT;
uuid->obj.node[0] |= IEEE_MAC_MCBIT;
uuid->obj.node[0] |= IEEE_MAC_LOBIT;
}
else {
/* use real regular MAC address */
memcpy(uuid->obj.node, uuid->mac, sizeof(uuid->mac));
}
/*
* FINISH
*/
/* remember current system time for next iteration */
uuid->time_last.tv_sec = time_now.tv_sec;
uuid->time_last.tv_usec = time_now.tv_usec;
/* brand with version and variant */
uuid_brand(uuid, 1);
return UUID_RC_OK;
}
/* INTERNAL: pre-defined UUID values.
(defined as network byte ordered octet stream) */
#define UUID_MAKE(a1,a2,a3,a4,a5,a6,a7,a8,a9,a10,a11,a12,a13,a14,a15,a16) \
{ (uuid_uint8_t)(a1), (uuid_uint8_t)(a2), (uuid_uint8_t)(a3), (uuid_uint8_t)(a4), \
(uuid_uint8_t)(a5), (uuid_uint8_t)(a6), (uuid_uint8_t)(a7), (uuid_uint8_t)(a8), \
(uuid_uint8_t)(a9), (uuid_uint8_t)(a10), (uuid_uint8_t)(a11), (uuid_uint8_t)(a12), \
(uuid_uint8_t)(a13), (uuid_uint8_t)(a14), (uuid_uint8_t)(a15), (uuid_uint8_t)(a16) }
static struct {
char *name;
uuid_uint8_t uuid[UUID_LEN_BIN];
} uuid_value_table[] = {
{ "nil", /* 00000000-0000-0000-0000-000000000000 ("Nil UUID") */
UUID_MAKE(0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00) },
{ "ns:DNS", /* 6ba7b810-9dad-11d1-80b4-00c04fd430c8 (see RFC 4122) */
UUID_MAKE(0x6b,0xa7,0xb8,0x10,0x9d,0xad,0x11,0xd1,0x80,0xb4,0x00,0xc0,0x4f,0xd4,0x30,0xc8) },
{ "ns:URL", /* 6ba7b811-9dad-11d1-80b4-00c04fd430c8 (see RFC 4122) */
UUID_MAKE(0x6b,0xa7,0xb8,0x11,0x9d,0xad,0x11,0xd1,0x80,0xb4,0x00,0xc0,0x4f,0xd4,0x30,0xc8) },
{ "ns:OID", /* 6ba7b812-9dad-11d1-80b4-00c04fd430c8 (see RFC 4122) */
UUID_MAKE(0x6b,0xa7,0xb8,0x12,0x9d,0xad,0x11,0xd1,0x80,0xb4,0x00,0xc0,0x4f,0xd4,0x30,0xc8) },
{ "ns:X500", /* 6ba7b814-9dad-11d1-80b4-00c04fd430c8 (see RFC 4122) */
UUID_MAKE(0x6b,0xa7,0xb8,0x14,0x9d,0xad,0x11,0xd1,0x80,0xb4,0x00,0xc0,0x4f,0xd4,0x30,0xc8) }
};
/* load UUID object with pre-defined value */
uuid_rc_t uuid_load(uuid_t *uuid, const char *name)
{
uuid_uint8_t *uuid_octets;
uuid_rc_t rc;
unsigned int i;
/* sanity check argument(s) */
if (uuid == NULL || name == NULL)
return UUID_RC_ARG;
/* search for UUID in table */
uuid_octets = NULL;
for (i = 0; i < (unsigned int)sizeof(uuid_value_table)/sizeof(uuid_value_table[0]); i++) {
if (strcmp(uuid_value_table[i].name, name) == 0) {
uuid_octets = uuid_value_table[i].uuid;
break;
}
}
if (uuid_octets == NULL)
return UUID_RC_ARG;
/* import value into UUID object */
if ((rc = uuid_import(uuid, UUID_FMT_BIN, uuid_octets, UUID_LEN_BIN)) != UUID_RC_OK)
return rc;
return UUID_RC_OK;
}
/* INTERNAL: generate UUID version 3: name based with MD5 */
static uuid_rc_t uuid_make_v3(uuid_t *uuid, unsigned int mode, va_list ap)
{
char *str;
uuid_t *uuid_ns;
uuid_uint8_t uuid_buf[UUID_LEN_BIN];
void *uuid_ptr;
size_t uuid_len;
uuid_rc_t rc;
/* determine namespace UUID and name string arguments */
if ((uuid_ns = (uuid_t *)va_arg(ap, void *)) == NULL)
return UUID_RC_ARG;
if ((str = (char *)va_arg(ap, char *)) == NULL)
return UUID_RC_ARG;
/* initialize MD5 context */
if (md5_init(uuid->md5) != MD5_RC_OK)
return UUID_RC_MEM;
/* load the namespace UUID into MD5 context */
uuid_ptr = (void *)&uuid_buf;
uuid_len = sizeof(uuid_buf);
if ((rc = uuid_export(uuid_ns, UUID_FMT_BIN, &uuid_ptr, &uuid_len)) != UUID_RC_OK)
return rc;
if (md5_update(uuid->md5, uuid_buf, uuid_len) != MD5_RC_OK)
return UUID_RC_INT;
/* load the argument name string into MD5 context */
if (md5_update(uuid->md5, str, strlen(str)) != MD5_RC_OK)
return UUID_RC_INT;
/* store MD5 result into UUID
(requires MD5_LEN_BIN space, UUID_LEN_BIN space is available,
and both are equal in size, so we are safe!) */
uuid_ptr = (void *)&(uuid->obj);
if (md5_store(uuid->md5, &uuid_ptr, NULL) != MD5_RC_OK)
return UUID_RC_INT;
/* fulfill requirement of standard and convert UUID data into
local/host byte order (this uses fact that uuid_import_bin() is
able to operate in-place!) */
if ((rc = uuid_import(uuid, UUID_FMT_BIN, (void *)&(uuid->obj), UUID_LEN_BIN)) != UUID_RC_OK)
return rc;
/* brand UUID with version and variant */
uuid_brand(uuid, 3);
return UUID_RC_OK;
}
/* INTERNAL: generate UUID version 4: random number based */
static uuid_rc_t uuid_make_v4(uuid_t *uuid, unsigned int mode, va_list ap)
{
/* fill UUID with random data */
if (prng_data(uuid->prng, (void *)&(uuid->obj), sizeof(uuid->obj)) != PRNG_RC_OK)
return UUID_RC_INT;
/* brand UUID with version and variant */
uuid_brand(uuid, 4);
return UUID_RC_OK;
}
/* INTERNAL: generate UUID version 5: name based with SHA-1 */
static uuid_rc_t uuid_make_v5(uuid_t *uuid, unsigned int mode, va_list ap)
{
char *str;
uuid_t *uuid_ns;
uuid_uint8_t uuid_buf[UUID_LEN_BIN];
void *uuid_ptr;
size_t uuid_len;
uuid_uint8_t sha1_buf[SHA1_LEN_BIN];
void *sha1_ptr;
uuid_rc_t rc;
/* determine namespace UUID and name string arguments */
if ((uuid_ns = (uuid_t *)va_arg(ap, void *)) == NULL)
return UUID_RC_ARG;
if ((str = (char *)va_arg(ap, char *)) == NULL)
return UUID_RC_ARG;
/* initialize SHA-1 context */
if (sha1_init(uuid->sha1) != SHA1_RC_OK)
return UUID_RC_INT;
/* load the namespace UUID into SHA-1 context */
uuid_ptr = (void *)&uuid_buf;
uuid_len = sizeof(uuid_buf);
if ((rc = uuid_export(uuid_ns, UUID_FMT_BIN, &uuid_ptr, &uuid_len)) != UUID_RC_OK)
return rc;
if (sha1_update(uuid->sha1, uuid_buf, uuid_len) != SHA1_RC_OK)
return UUID_RC_INT;
/* load the argument name string into SHA-1 context */
if (sha1_update(uuid->sha1, str, strlen(str)) != SHA1_RC_OK)
return UUID_RC_INT;
/* store SHA-1 result into UUID
(requires SHA1_LEN_BIN space, but UUID_LEN_BIN space is available
only, so use a temporary buffer to store SHA-1 results and then
use lower part only according to standard */
sha1_ptr = (void *)sha1_buf;
if (sha1_store(uuid->sha1, &sha1_ptr, NULL) != SHA1_RC_OK)
return UUID_RC_INT;
uuid_ptr = (void *)&(uuid->obj);
memcpy(uuid_ptr, sha1_ptr, UUID_LEN_BIN);
/* fulfill requirement of standard and convert UUID data into
local/host byte order (this uses fact that uuid_import_bin() is
able to operate in-place!) */
if ((rc = uuid_import(uuid, UUID_FMT_BIN, (void *)&(uuid->obj), UUID_LEN_BIN)) != UUID_RC_OK)
return rc;
/* brand UUID with version and variant */
uuid_brand(uuid, 5);
return UUID_RC_OK;
}
/* generate UUID */
uuid_rc_t uuid_make(uuid_t *uuid, unsigned int mode, ...)
{
va_list ap;
uuid_rc_t rc;
/* sanity check argument(s) */
if (uuid == NULL)
return UUID_RC_ARG;
/* dispatch into version dependent generation functions */
va_start(ap, mode);
if (mode & UUID_MAKE_V1)
rc = uuid_make_v1(uuid, mode, ap);
else if (mode & UUID_MAKE_V3)
rc = uuid_make_v3(uuid, mode, ap);
else if (mode & UUID_MAKE_V4)
rc = uuid_make_v4(uuid, mode, ap);
else if (mode & UUID_MAKE_V5)
rc = uuid_make_v5(uuid, mode, ap);
else
rc = UUID_RC_ARG;
va_end(ap);
return rc;
}
/* translate UUID API error code into corresponding error string */
char *uuid_error(uuid_rc_t rc)
{
char *str;
switch (rc) {
case UUID_RC_OK: str = "everything ok"; break;
case UUID_RC_ARG: str = "invalid argument"; break;
case UUID_RC_MEM: str = "out of memory"; break;
case UUID_RC_SYS: str = "system error"; break;
case UUID_RC_INT: str = "internal error"; break;
case UUID_RC_IMP: str = "not implemented"; break;
default: str = NULL; break;
}
return str;
}
/* OSSP uuid version (link-time information) */
unsigned long uuid_version(void)
{
return (unsigned long)(_UUID_VERSION);
}
