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janusdata / raw_data /open5gs_source_code /lib /asn1c /common /INTEGER.c
UmakantKulkarni
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 /*
* Copyright (c) 2003-2019 Lev Walkin <vlm@lionet.info>.
* All rights reserved.
* Redistribution and modifications are permitted subject to BSD license.
*/
#include <asn_internal.h>
#include <INTEGER.h>
#include <errno.h>
#include <inttypes.h>
/*
* INTEGER basic type description.
*/
static const ber_tlv_tag_t asn_DEF_INTEGER_tags[] = {
(ASN_TAG_CLASS_UNIVERSAL | (2 << 2))
};
asn_TYPE_operation_t asn_OP_INTEGER = {
INTEGER_free,
#if !defined(ASN_DISABLE_PRINT_SUPPORT)
INTEGER_print,
#else
0,
#endif /* !defined(ASN_DISABLE_PRINT_SUPPORT) */
INTEGER_compare,
INTEGER_copy,
#if !defined(ASN_DISABLE_BER_SUPPORT)
ber_decode_primitive,
INTEGER_encode_der,
#else
0,
0,
#endif /* !defined(ASN_DISABLE_BER_SUPPORT) */
#if !defined(ASN_DISABLE_XER_SUPPORT)
INTEGER_decode_xer,
INTEGER_encode_xer,
#else
0,
0,
#endif /* !defined(ASN_DISABLE_XER_SUPPORT) */
#if !defined(ASN_DISABLE_JER_SUPPORT)
INTEGER_decode_jer,
INTEGER_encode_jer,
#else
0,
0,
#endif /* !defined(ASN_DISABLE_JER_SUPPORT) */
#if !defined(ASN_DISABLE_OER_SUPPORT)
INTEGER_decode_oer, /* OER decoder */
INTEGER_encode_oer, /* Canonical OER encoder */
#else
0,
0,
#endif /* !defined(ASN_DISABLE_OER_SUPPORT) */
#if !defined(ASN_DISABLE_UPER_SUPPORT)
INTEGER_decode_uper, /* Unaligned PER decoder */
INTEGER_encode_uper, /* Unaligned PER encoder */
#else
0,
0,
#endif /* !defined(ASN_DISABLE_UPER_SUPPORT) */
#if !defined(ASN_DISABLE_APER_SUPPORT)
INTEGER_decode_aper, /* Aligned PER decoder */
INTEGER_encode_aper, /* Aligned PER encoder */
#else
0,
0,
#endif /* !defined(ASN_DISABLE_APER_SUPPORT) */
#if !defined(ASN_DISABLE_RFILL_SUPPORT)
INTEGER_random_fill,
#else
0,
#endif /* !defined(ASN_DISABLE_RFILL_SUPPORT) */
0 /* Use generic outmost tag fetcher */
};
asn_TYPE_descriptor_t asn_DEF_INTEGER = {
"INTEGER",
"INTEGER",
&asn_OP_INTEGER,
asn_DEF_INTEGER_tags,
sizeof(asn_DEF_INTEGER_tags) / sizeof(asn_DEF_INTEGER_tags[0]),
asn_DEF_INTEGER_tags, /* Same as above */
sizeof(asn_DEF_INTEGER_tags) / sizeof(asn_DEF_INTEGER_tags[0]),
{
#if !defined(ASN_DISABLE_OER_SUPPORT)
0,
#endif /* !defined(ASN_DISABLE_OER_SUPPORT) */
#if !defined(ASN_DISABLE_UPER_SUPPORT) || !defined(ASN_DISABLE_APER_SUPPORT)
0,
#endif /* !defined(ASN_DISABLE_UPER_SUPPORT) || !defined(ASN_DISABLE_APER_SUPPORT) */
asn_generic_no_constraint
},
0, 0, /* No members */
0 /* No specifics */
};
/*
* INTEGER specific human-readable output.
*/
ssize_t
INTEGER__dump(const asn_TYPE_descriptor_t *td, const INTEGER_t *st, asn_app_consume_bytes_f *cb, void *app_key, int plainOrXER) {
const asn_INTEGER_specifics_t *specs =
(const asn_INTEGER_specifics_t *)td->specifics;
char scratch[32];
uint8_t *buf = st->buf;
uint8_t *buf_end = st->buf + st->size;
intmax_t value;
ssize_t wrote = 0;
char *p;
int ret;
if(specs && specs->field_unsigned)
ret = asn_INTEGER2umax(st, (uintmax_t *)&value);
else
ret = asn_INTEGER2imax(st, &value);
/* Simple case: the integer size is small */
if(ret == 0) {
const asn_INTEGER_enum_map_t *el;
el = (value >= 0 || !specs || !specs->field_unsigned)
? INTEGER_map_value2enum(specs, value) : 0;
if(el) {
if(plainOrXER == 0)
return asn__format_to_callback(cb, app_key,
"%" ASN_PRIdMAX " (%s)", value, el->enum_name);
else
return asn__format_to_callback(cb, app_key,
"<%s/>", el->enum_name);
} else if(plainOrXER && specs && specs->strict_enumeration) {
ASN_DEBUG("ASN.1 forbids dealing with "
"unknown value of ENUMERATED type");
errno = EPERM;
return -1;
} else {
return asn__format_to_callback(cb, app_key,
(specs && specs->field_unsigned)
? "%" ASN_PRIuMAX
: "%" ASN_PRIdMAX,
value);
}
} else if(plainOrXER && specs && specs->strict_enumeration) {
/*
* Here and earlier, we cannot encode the ENUMERATED values
* if there is no corresponding identifier.
*/
ASN_DEBUG("ASN.1 forbids dealing with "
"unknown value of ENUMERATED type");
errno = EPERM;
return -1;
}
/* Output in the long xx:yy:zz... format */
/* TODO: replace with generic algorithm (Knuth TAOCP Vol 2, 4.3.1) */
for(p = scratch; buf < buf_end; buf++) {
const char * const h2c = "0123456789ABCDEF";
if((p - scratch) >= (ssize_t)(sizeof(scratch) - 4)) {
/* Flush buffer */
if(cb(scratch, p - scratch, app_key) < 0)
return -1;
wrote += p - scratch;
p = scratch;
}
*p++ = h2c[*buf >> 4];
*p++ = h2c[*buf & 0x0F];
*p++ = 0x3a; /* ":" */
}
if(p != scratch)
p--; /* Remove the last ":" */
wrote += p - scratch;
return (cb(scratch, p - scratch, app_key) < 0) ? -1 : wrote;
}
static int
INTEGER__compar_value2enum(const void *kp, const void *am) {
long a = *(const long *)kp;
const asn_INTEGER_enum_map_t *el = (const asn_INTEGER_enum_map_t *)am;
long b = el->nat_value;
if(a < b) return -1;
else if(a == b) return 0;
else return 1;
}
const asn_INTEGER_enum_map_t *
INTEGER_map_value2enum(const asn_INTEGER_specifics_t *specs, long value) {
int count = specs ? specs->map_count : 0;
if(!count) return 0;
return (asn_INTEGER_enum_map_t *)bsearch(&value, specs->value2enum,
count, sizeof(specs->value2enum[0]),
INTEGER__compar_value2enum);
}
static intmax_t
asn__integer_convert(const uint8_t *b, const uint8_t *end) {
uintmax_t value;
/* Perform the sign initialization */
/* Actually value = -(*b >> 7); gains nothing, yet unreadable! */
if((*b >> 7)) {
value = (uintmax_t)(-1);
} else {
value = 0;
}
/* Conversion engine */
for(; b < end; b++) {
value = (value << 8) | *b;
}
return value;
}
int
asn_INTEGER2imax(const INTEGER_t *iptr, intmax_t *lptr) {
uint8_t *b, *end;
size_t size;
/* Sanity checking */
if(!iptr || !iptr->buf || !lptr) {
errno = EINVAL;
return -1;
}
/* Cache the begin/end of the buffer */
b = iptr->buf; /* Start of the INTEGER buffer */
size = iptr->size;
end = b + size; /* Where to stop */
if(size > sizeof(intmax_t)) {
uint8_t *end1 = end - 1;
/*
* Slightly more advanced processing,
* able to process INTEGERs with >sizeof(intmax_t) bytes
* when the actual value is small, e.g. for intmax_t == int32_t
* (0x0000000000abcdef INTEGER would yield a fine 0x00abcdef int32_t)
*/
/* Skip out the insignificant leading bytes */
for(; b < end1; b++) {
switch(*b) {
case 0x00: if((b[1] & 0x80) == 0) continue; break;
case 0xff: if((b[1] & 0x80) != 0) continue; break;
}
break;
}
size = end - b;
if(size > sizeof(intmax_t)) {
/* Still cannot fit the sizeof(intmax_t) */
errno = ERANGE;
return -1;
}
}
/* Shortcut processing of a corner case */
if(end == b) {
*lptr = 0;
return 0;
}
*lptr = asn__integer_convert(b, end);
return 0;
}
/* FIXME: negative INTEGER values are silently interpreted as large unsigned ones. */
int
asn_INTEGER2umax(const INTEGER_t *iptr, uintmax_t *lptr) {
uint8_t *b, *end;
uintmax_t value;
size_t size;
if(!iptr || !iptr->buf || !lptr) {
errno = EINVAL;
return -1;
}
b = iptr->buf;
size = iptr->size;
end = b + size;
/* If all extra leading bytes are zeroes, ignore them */
for(; size > sizeof(value); b++, size--) {
if(*b) {
/* Value won't fit into uintmax_t */
errno = ERANGE;
return -1;
}
}
/* Conversion engine */
for(value = 0; b < end; b++)
value = (value << 8) | *b;
*lptr = value;
return 0;
}
int
asn_umax2INTEGER(INTEGER_t *st, uintmax_t value) {
uint8_t *buf;
uint8_t *end;
uint8_t *b;
int shr;
if(value <= ((~(uintmax_t)0) >> 1)) {
return asn_imax2INTEGER(st, value);
}
buf = (uint8_t *)MALLOC(1 + sizeof(value));
if(!buf) return -1;
end = buf + (sizeof(value) + 1);
buf[0] = 0; /* INTEGERs are signed. 0-byte indicates positive. */
for(b = buf + 1, shr = (sizeof(value) - 1) * 8; b < end; shr -= 8, b++)
*b = (uint8_t)(value >> shr);
if(st->buf) FREEMEM(st->buf);
st->buf = buf;
st->size = 1 + sizeof(value);
return 0;
}
int
asn_imax2INTEGER(INTEGER_t *st, intmax_t value) {
uint8_t *buf, *bp;
uint8_t *p;
uint8_t *pstart;
uint8_t *pend1;
int littleEndian = 1; /* Run-time detection */
int add;
if(!st) {
errno = EINVAL;
return -1;
}
buf = (uint8_t *)(long *)MALLOC(sizeof(value));
if(!buf) return -1;
if(*(char *)&littleEndian) {
pstart = (uint8_t *)&value + sizeof(value) - 1;
pend1 = (uint8_t *)&value;
add = -1;
} else {
pstart = (uint8_t *)&value;
pend1 = pstart + sizeof(value) - 1;
add = 1;
}
/*
* If the contents octet consists of more than one octet,
* then bits of the first octet and bit 8 of the second octet:
* a) shall not all be ones; and
* b) shall not all be zero.
*/
for(p = pstart; p != pend1; p += add) {
switch(*p) {
case 0x00: if((*(p+add) & 0x80) == 0)
continue;
break;
case 0xff: if((*(p+add) & 0x80))
continue;
break;
}
break;
}
/* Copy the integer body */
for(bp = buf, pend1 += add; p != pend1; p += add)
*bp++ = *p;
if(st->buf) FREEMEM(st->buf);
st->buf = buf;
st->size = bp - buf;
return 0;
}
int
asn_INTEGER2long(const INTEGER_t *iptr, long *l) {
intmax_t v;
if(asn_INTEGER2imax(iptr, &v) == 0) {
if(v < LONG_MIN || v > LONG_MAX) {
errno = ERANGE;
return -1;
}
*l = v;
return 0;
} else {
return -1;
}
}
int
asn_INTEGER2ulong(const INTEGER_t *iptr, unsigned long *l) {
uintmax_t v;
if(asn_INTEGER2umax(iptr, &v) == 0) {
if(v > ULONG_MAX) {
errno = ERANGE;
return -1;
}
*l = v;
return 0;
} else {
return -1;
}
}
int
asn_long2INTEGER(INTEGER_t *st, long value) {
return asn_imax2INTEGER(st, value);
}
int
asn_ulong2INTEGER(INTEGER_t *st, unsigned long value) {
return asn_imax2INTEGER(st, value);
}
int asn_INTEGER2int64(const INTEGER_t *st, int64_t *value) {
intmax_t v;
if(asn_INTEGER2imax(st, &v) == 0) {
if(v < INT64_MIN || v > INT64_MAX) {
errno = ERANGE;
return -1;
}
*value = v;
return 0;
} else {
return -1;
}
}
int asn_INTEGER2uint64(const INTEGER_t *st, uint64_t *value) {
uintmax_t v;
if(asn_INTEGER2umax(st, &v) == 0) {
if(v > UINT64_MAX) {
errno = ERANGE;
return -1;
}
*value = v;
return 0;
} else {
return -1;
}
}
int
asn_uint642INTEGER(INTEGER_t *st, uint64_t value) {
uint8_t *buf;
uint8_t *end;
uint8_t *b;
int shr;
if(value <= INT64_MAX)
return asn_int642INTEGER(st, value);
buf = (uint8_t *)MALLOC(1 + sizeof(value));
if(!buf) return -1;
end = buf + (sizeof(value) + 1);
buf[0] = 0;
for(b = buf + 1, shr = (sizeof(value)-1)*8; b < end; shr -= 8, b++)
*b = (uint8_t)(value >> shr);
if(st->buf) FREEMEM(st->buf);
st->buf = buf;
st->size = 1 + sizeof(value);
return 0;
}
int
asn_int642INTEGER(INTEGER_t *st, int64_t value) {
uint8_t *buf, *bp;
uint8_t *p;
uint8_t *pstart;
uint8_t *pend1;
int littleEndian = 1; /* Run-time detection */
int add;
if(!st) {
errno = EINVAL;
return -1;
}
buf = (uint8_t *)MALLOC(sizeof(value));
if(!buf) return -1;
if(*(char *)&littleEndian) {
pstart = (uint8_t *)&value + sizeof(value) - 1;
pend1 = (uint8_t *)&value;
add = -1;
} else {
pstart = (uint8_t *)&value;
pend1 = pstart + sizeof(value) - 1;
add = 1;
}
/*
* If the contents octet consists of more than one octet,
* then bits of the first octet and bit 8 of the second octet:
* a) shall not all be ones; and
* b) shall not all be zero.
*/
for(p = pstart; p != pend1; p += add) {
switch(*p) {
case 0x00: if((*(p+add) & 0x80) == 0)
continue;
break;
case 0xff: if((*(p+add) & 0x80))
continue;
break;
}
break;
}
/* Copy the integer body */
for(pstart = p, bp = buf, pend1 += add; p != pend1; p += add)
*bp++ = *p;
if(st->buf) FREEMEM(st->buf);
st->buf = buf;
st->size = bp - buf;
return 0;
}
/*
* Parse the number in the given string until the given *end position,
* returning the position after the last parsed character back using the
* same (*end) pointer.
* WARNING: This behavior is different from the standard strtol/strtoimax(3).
*/
enum asn_strtox_result_e
asn_strtoimax_lim(const char *str, const char **end, intmax_t *intp) {
int sign = 1;
intmax_t value;
const intmax_t asn1_intmax_max = ((~(uintmax_t)0) >> 1);
const intmax_t upper_boundary = asn1_intmax_max / 10;
intmax_t last_digit_max = asn1_intmax_max % 10;
if(str >= *end) return ASN_STRTOX_ERROR_INVAL;
switch(*str) {
case '-':
last_digit_max++;
sign = -1;
/* FALL THROUGH */
case '+':
str++;
if(str >= *end) {
*end = str;
return ASN_STRTOX_EXPECT_MORE;
}
}
for(value = 0; str < (*end); str++) {
if(*str >= 0x30 && *str <= 0x39) {
int d = *str - '0';
if(value < upper_boundary) {
value = value * 10 + d;
} else if(value == upper_boundary) {
if(d <= last_digit_max) {
if(sign > 0) {
value = value * 10 + d;
} else {
sign = 1;
value = -value * 10 - d;
}
str += 1;
if(str < *end) {
// If digits continue, we're guaranteed out of range.
*end = str;
if(*str >= 0x30 && *str <= 0x39) {
return ASN_STRTOX_ERROR_RANGE;
} else {
*intp = sign * value;
return ASN_STRTOX_EXTRA_DATA;
}
}
break;
} else {
*end = str;
return ASN_STRTOX_ERROR_RANGE;
}
} else {
*end = str;
return ASN_STRTOX_ERROR_RANGE;
}
} else {
*end = str;
*intp = sign * value;
return ASN_STRTOX_EXTRA_DATA;
}
}
*end = str;
*intp = sign * value;
return ASN_STRTOX_OK;
}
/*
* Parse the number in the given string until the given *end position,
* returning the position after the last parsed character back using the
* same (*end) pointer.
* WARNING: This behavior is different from the standard strtoul/strtoumax(3).
*/
enum asn_strtox_result_e
asn_strtoumax_lim(const char *str, const char **end, uintmax_t *uintp) {
uintmax_t value;
const uintmax_t asn1_uintmax_max = ((~(uintmax_t)0));
const uintmax_t upper_boundary = asn1_uintmax_max / 10;
uintmax_t last_digit_max = asn1_uintmax_max % 10;
if(str >= *end) return ASN_STRTOX_ERROR_INVAL;
switch(*str) {
case '-':
return ASN_STRTOX_ERROR_INVAL;
case '+':
str++;
if(str >= *end) {
*end = str;
return ASN_STRTOX_EXPECT_MORE;
}
}
for(value = 0; str < (*end); str++) {
if(*str >= 0x30 && *str <= 0x39) {
unsigned int d = *str - '0';
if(value < upper_boundary) {
value = value * 10 + d;
} else if(value == upper_boundary) {
if(d <= last_digit_max) {
value = value * 10 + d;
str += 1;
if(str < *end) {
// If digits continue, we're guaranteed out of range.
*end = str;
if(*str >= 0x30 && *str <= 0x39) {
return ASN_STRTOX_ERROR_RANGE;
} else {
*uintp = value;
return ASN_STRTOX_EXTRA_DATA;
}
}
break;
} else {
*end = str;
return ASN_STRTOX_ERROR_RANGE;
}
} else {
*end = str;
return ASN_STRTOX_ERROR_RANGE;
}
} else {
*end = str;
*uintp = value;
return ASN_STRTOX_EXTRA_DATA;
}
}
*end = str;
*uintp = value;
return ASN_STRTOX_OK;
}
enum asn_strtox_result_e
asn_strtol_lim(const char *str, const char **end, long *lp) {
intmax_t value;
switch(asn_strtoimax_lim(str, end, &value)) {
case ASN_STRTOX_ERROR_RANGE:
return ASN_STRTOX_ERROR_RANGE;
case ASN_STRTOX_ERROR_INVAL:
return ASN_STRTOX_ERROR_INVAL;
case ASN_STRTOX_EXPECT_MORE:
return ASN_STRTOX_EXPECT_MORE;
case ASN_STRTOX_OK:
if(value >= LONG_MIN && value <= LONG_MAX) {
*lp = value;
return ASN_STRTOX_OK;
} else {
return ASN_STRTOX_ERROR_RANGE;
}
case ASN_STRTOX_EXTRA_DATA:
if(value >= LONG_MIN && value <= LONG_MAX) {
*lp = value;
return ASN_STRTOX_EXTRA_DATA;
} else {
return ASN_STRTOX_ERROR_RANGE;
}
}
assert(!"Unreachable");
return ASN_STRTOX_ERROR_INVAL;
}
enum asn_strtox_result_e
asn_strtoul_lim(const char *str, const char **end, unsigned long *ulp) {
uintmax_t value;
switch(asn_strtoumax_lim(str, end, &value)) {
case ASN_STRTOX_ERROR_RANGE:
return ASN_STRTOX_ERROR_RANGE;
case ASN_STRTOX_ERROR_INVAL:
return ASN_STRTOX_ERROR_INVAL;
case ASN_STRTOX_EXPECT_MORE:
return ASN_STRTOX_EXPECT_MORE;
case ASN_STRTOX_OK:
if(value <= ULONG_MAX) {
*ulp = value;
return ASN_STRTOX_OK;
} else {
return ASN_STRTOX_ERROR_RANGE;
}
case ASN_STRTOX_EXTRA_DATA:
if(value <= ULONG_MAX) {
*ulp = value;
return ASN_STRTOX_EXTRA_DATA;
} else {
return ASN_STRTOX_ERROR_RANGE;
}
}
assert(!"Unreachable");
return ASN_STRTOX_ERROR_INVAL;
}
int
INTEGER_compare(const asn_TYPE_descriptor_t *td, const void *aptr,
const void *bptr) {
const INTEGER_t *a = aptr;
const INTEGER_t *b = bptr;
(void)td;
if(a && b) {
if(a->size && b->size) {
int sign_a = (a->buf[0] & 0x80) ? -1 : 1;
int sign_b = (b->buf[0] & 0x80) ? -1 : 1;
if(sign_a < sign_b) return -1;
if(sign_a > sign_b) return 1;
/* The shortest integer wins, unless comparing negatives */
if(a->size < b->size) {
return -1 * sign_a;
} else if(a->size > b->size) {
return 1 * sign_b;
}
return sign_a * memcmp(a->buf, b->buf, a->size);
} else if(a->size) {
int sign = (a->buf[0] & 0x80) ? -1 : 1;
return (1) * sign;
} else if(b->size) {
int sign = (a->buf[0] & 0x80) ? -1 : 1;
return (-1) * sign;
} else {
return 0;
}
} else if(!a && !b) {
return 0;
} else if(!a) {
return -1;
} else {
return 1;
}
}
int
INTEGER_copy(const asn_TYPE_descriptor_t *td, void **aptr,
const void *bptr) {
(void)td;
INTEGER_t *a = *aptr;
const INTEGER_t *b = bptr;
if(!b) {
if(a) {
FREEMEM(a->buf);
FREEMEM(a);
*aptr = 0;
}
return 0;
}
if(!a) {
a = *aptr = CALLOC(1, sizeof(*a));
if(!a) return -1;
}
if(b->size) {
uint8_t* buf = MALLOC(b->size);
if(!buf) return -1;
memcpy(buf, b->buf, b->size);
FREEMEM(a->buf);
a->buf = buf;
a->size = b->size;
} else {
FREEMEM(a->buf);
a->buf = 0;
a->size = 0;
}
return 0;
}