ns-o-ran-scp-ric-app-kpimon/e2ap/lib/OCTET_STRING.c

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/*-
* Copyright (c) 2003-2017 Lev Walkin <vlm@lionet.info>.
* All rights reserved.
* Redistribution and modifications are permitted subject to BSD license.
*/
#include <asn_internal.h>
#include <OCTET_STRING.h>
#include <BIT_STRING.h> /* for .bits_unused member */
#include <errno.h>
/*
* OCTET STRING basic type description.
*/
static const ber_tlv_tag_t asn_DEF_OCTET_STRING_tags[] = {
(ASN_TAG_CLASS_UNIVERSAL | (4 << 2))
};
asn_OCTET_STRING_specifics_t asn_SPC_OCTET_STRING_specs = {
sizeof(OCTET_STRING_t),
offsetof(OCTET_STRING_t, _asn_ctx),
ASN_OSUBV_STR
};
asn_TYPE_operation_t asn_OP_OCTET_STRING = {
OCTET_STRING_free,
OCTET_STRING_print, /* OCTET STRING generally means a non-ascii sequence */
OCTET_STRING_compare,
OCTET_STRING_decode_ber,
OCTET_STRING_encode_der,
OCTET_STRING_decode_xer_hex,
OCTET_STRING_encode_xer,
#ifdef ASN_DISABLE_OER_SUPPORT
0,
0,
#else
OCTET_STRING_decode_oer,
OCTET_STRING_encode_oer,
#endif /* ASN_DISABLE_OER_SUPPORT */
#ifdef ASN_DISABLE_PER_SUPPORT
0,
0,
0,
0,
#else
OCTET_STRING_decode_uper, /* Unaligned PER decoder */
OCTET_STRING_encode_uper, /* Unaligned PER encoder */
OCTET_STRING_decode_aper, /* Aligned PER decoder */
OCTET_STRING_encode_aper, /* Aligned PER encoder */
#endif /* ASN_DISABLE_PER_SUPPORT */
OCTET_STRING_random_fill,
0 /* Use generic outmost tag fetcher */
};
asn_TYPE_descriptor_t asn_DEF_OCTET_STRING = {
"OCTET STRING", /* Canonical name */
"OCTET_STRING", /* XML tag name */
&asn_OP_OCTET_STRING,
asn_DEF_OCTET_STRING_tags,
sizeof(asn_DEF_OCTET_STRING_tags)
/ sizeof(asn_DEF_OCTET_STRING_tags[0]),
asn_DEF_OCTET_STRING_tags, /* Same as above */
sizeof(asn_DEF_OCTET_STRING_tags)
/ sizeof(asn_DEF_OCTET_STRING_tags[0]),
{ 0, 0, asn_generic_no_constraint },
0, 0, /* No members */
&asn_SPC_OCTET_STRING_specs
};
#undef _CH_PHASE
#undef NEXT_PHASE
#undef PREV_PHASE
#define _CH_PHASE(ctx, inc) do { \
if(ctx->phase == 0) \
ctx->context = 0; \
ctx->phase += inc; \
} while(0)
#define NEXT_PHASE(ctx) _CH_PHASE(ctx, +1)
#define PREV_PHASE(ctx) _CH_PHASE(ctx, -1)
#undef ADVANCE
#define ADVANCE(num_bytes) do { \
size_t num = (num_bytes); \
buf_ptr = ((const char *)buf_ptr) + num; \
size -= num; \
consumed_myself += num; \
} while(0)
#undef RETURN
#define RETURN(_code) do { \
asn_dec_rval_t tmprval; \
tmprval.code = _code; \
tmprval.consumed = consumed_myself; \
return tmprval; \
} while(0)
#undef APPEND
#define APPEND(bufptr, bufsize) do { \
size_t _bs = (bufsize); /* Append size */ \
size_t _ns = ctx->context; /* Allocated now */ \
size_t _es = st->size + _bs; /* Expected size */ \
/* int is really a typeof(st->size): */ \
if((int)_es < 0) RETURN(RC_FAIL); \
if(_ns <= _es) { \
void *ptr; \
/* Be nice and round to the memory allocator */ \
do { _ns = _ns ? _ns << 1 : 16; } \
while(_ns <= _es); \
/* int is really a typeof(st->size): */ \
if((int)_ns < 0) RETURN(RC_FAIL); \
ptr = REALLOC(st->buf, _ns); \
if(ptr) { \
st->buf = (uint8_t *)ptr; \
ctx->context = _ns; \
} else { \
RETURN(RC_FAIL); \
} \
ASN_DEBUG("Reallocating into %ld", (long)_ns); \
} \
memcpy(st->buf + st->size, bufptr, _bs); \
/* Convenient nul-termination */ \
st->buf[_es] = '\0'; \
st->size = _es; \
} while(0)
/*
* The main reason why ASN.1 is still alive is that too much time and effort
* is necessary for learning it more or less adequately, thus creating a gut
* necessity to demonstrate that aquired skill everywhere afterwards.
* No, I am not going to explain what the following stuff is.
*/
struct _stack_el {
ber_tlv_len_t left; /* What's left to read (or -1) */
ber_tlv_len_t got; /* What was actually processed */
unsigned cont_level; /* Depth of subcontainment */
int want_nulls; /* Want null "end of content" octets? */
int bits_chopped; /* Flag in BIT STRING mode */
ber_tlv_tag_t tag; /* For debugging purposes */
struct _stack_el *prev;
struct _stack_el *next;
};
struct _stack {
struct _stack_el *tail;
struct _stack_el *cur_ptr;
};
static struct _stack_el *
OS__add_stack_el(struct _stack *st) {
struct _stack_el *nel;
/*
* Reuse the old stack frame or allocate a new one.
*/
if(st->cur_ptr && st->cur_ptr->next) {
nel = st->cur_ptr->next;
nel->bits_chopped = 0;
nel->got = 0;
/* Retain the nel->cont_level, it's correct. */
} else {
nel = (struct _stack_el *)CALLOC(1, sizeof(struct _stack_el));
if(nel == NULL)
return NULL;
if(st->tail) {
/* Increase a subcontainment depth */
nel->cont_level = st->tail->cont_level + 1;
st->tail->next = nel;
}
nel->prev = st->tail;
st->tail = nel;
}
st->cur_ptr = nel;
return nel;
}
static struct _stack *
_new_stack(void) {
return (struct _stack *)CALLOC(1, sizeof(struct _stack));
}
/*
* Decode OCTET STRING type.
*/
asn_dec_rval_t
OCTET_STRING_decode_ber(const asn_codec_ctx_t *opt_codec_ctx,
const asn_TYPE_descriptor_t *td, void **sptr,
const void *buf_ptr, size_t size, int tag_mode) {
const asn_OCTET_STRING_specifics_t *specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
BIT_STRING_t *st = (BIT_STRING_t *)*sptr;
asn_dec_rval_t rval;
asn_struct_ctx_t *ctx;
ssize_t consumed_myself = 0;
struct _stack *stck; /* Expectations stack structure */
struct _stack_el *sel = 0; /* Stack element */
int tlv_constr;
enum asn_OS_Subvariant type_variant = specs->subvariant;
ASN_DEBUG("Decoding %s as %s (frame %ld)",
td->name,
(type_variant == ASN_OSUBV_STR) ?
"OCTET STRING" : "OS-SpecialCase",
(long)size);
/*
* Create the string if does not exist.
*/
if(st == NULL) {
st = (BIT_STRING_t *)(*sptr = CALLOC(1, specs->struct_size));
if(st == NULL) RETURN(RC_FAIL);
}
/* Restore parsing context */
ctx = (asn_struct_ctx_t *)((char *)st + specs->ctx_offset);
switch(ctx->phase) {
case 0:
/*
* Check tags.
*/
rval = ber_check_tags(opt_codec_ctx, td, ctx,
buf_ptr, size, tag_mode, -1,
&ctx->left, &tlv_constr);
if(rval.code != RC_OK)
return rval;
if(tlv_constr) {
/*
* Complex operation, requires stack of expectations.
*/
ctx->ptr = _new_stack();
if(!ctx->ptr) {
RETURN(RC_FAIL);
}
} else {
/*
* Jump into stackless primitive decoding.
*/
_CH_PHASE(ctx, 3);
if(type_variant == ASN_OSUBV_ANY && tag_mode != 1)
APPEND(buf_ptr, rval.consumed);
ADVANCE(rval.consumed);
goto phase3;
}
NEXT_PHASE(ctx);
/* Fall through */
case 1:
phase1:
/*
* Fill the stack with expectations.
*/
stck = (struct _stack *)ctx->ptr;
sel = stck->cur_ptr;
do {
ber_tlv_tag_t tlv_tag;
ber_tlv_len_t tlv_len;
ber_tlv_tag_t expected_tag;
ssize_t tl, ll, tlvl;
/* This one works even if (sel->left == -1) */
size_t Left = ((!sel||(size_t)sel->left >= size)
?size:(size_t)sel->left);
ASN_DEBUG("%p, s->l=%ld, s->wn=%ld, s->g=%ld\n", (void *)sel,
(long)(sel?sel->left:0),
(long)(sel?sel->want_nulls:0),
(long)(sel?sel->got:0)
);
if(sel && sel->left <= 0 && sel->want_nulls == 0) {
if(sel->prev) {
struct _stack_el *prev = sel->prev;
if(prev->left != -1) {
if(prev->left < sel->got)
RETURN(RC_FAIL);
prev->left -= sel->got;
}
prev->got += sel->got;
sel = stck->cur_ptr = prev;
if(!sel) break;
tlv_constr = 1;
continue;
} else {
sel = stck->cur_ptr = 0;
break; /* Nothing to wait */
}
}
tl = ber_fetch_tag(buf_ptr, Left, &tlv_tag);
ASN_DEBUG("fetch tag(size=%ld,L=%ld), %sstack, left=%ld, wn=%ld, tl=%ld",
(long)size, (long)Left, sel?"":"!",
(long)(sel?sel->left:0),
(long)(sel?sel->want_nulls:0),
(long)tl);
switch(tl) {
case -1: RETURN(RC_FAIL);
case 0: RETURN(RC_WMORE);
}
tlv_constr = BER_TLV_CONSTRUCTED(buf_ptr);
ll = ber_fetch_length(tlv_constr,
(const char *)buf_ptr + tl,Left - tl,&tlv_len);
ASN_DEBUG("Got tag=%s, tc=%d, left=%ld, tl=%ld, len=%ld, ll=%ld",
ber_tlv_tag_string(tlv_tag), tlv_constr,
(long)Left, (long)tl, (long)tlv_len, (long)ll);
switch(ll) {
case -1: RETURN(RC_FAIL);
case 0: RETURN(RC_WMORE);
}
if(sel && sel->want_nulls
&& ((const uint8_t *)buf_ptr)[0] == 0
&& ((const uint8_t *)buf_ptr)[1] == 0)
{
ASN_DEBUG("Eat EOC; wn=%d--", sel->want_nulls);
if(type_variant == ASN_OSUBV_ANY
&& (tag_mode != 1 || sel->cont_level))
APPEND("\0\0", 2);
ADVANCE(2);
sel->got += 2;
if(sel->left != -1) {
sel->left -= 2; /* assert(sel->left >= 2) */
}
sel->want_nulls--;
if(sel->want_nulls == 0) {
/* Move to the next expectation */
sel->left = 0;
tlv_constr = 1;
}
continue;
}
/*
* Set up expected tags,
* depending on ASN.1 type being decoded.
*/
switch(type_variant) {
case ASN_OSUBV_BIT:
/* X.690: 8.6.4.1, NOTE 2 */
/* Fall through */
case ASN_OSUBV_STR:
default:
if(sel) {
unsigned level = sel->cont_level;
if(level < td->all_tags_count) {
expected_tag = td->all_tags[level];
break;
} else if(td->all_tags_count) {
expected_tag = td->all_tags
[td->all_tags_count - 1];
break;
}
/* else, Fall through */
}
/* Fall through */
case ASN_OSUBV_ANY:
expected_tag = tlv_tag;
break;
}
if(tlv_tag != expected_tag) {
char buf[2][32];
ber_tlv_tag_snprint(tlv_tag,
buf[0], sizeof(buf[0]));
ber_tlv_tag_snprint(td->tags[td->tags_count-1],
buf[1], sizeof(buf[1]));
ASN_DEBUG("Tag does not match expectation: %s != %s",
buf[0], buf[1]);
RETURN(RC_FAIL);
}
tlvl = tl + ll; /* Combined length of T and L encoding */
if((tlv_len + tlvl) < 0) {
/* tlv_len value is too big */
ASN_DEBUG("TLV encoding + length (%ld) is too big",
(long)tlv_len);
RETURN(RC_FAIL);
}
/*
* Append a new expectation.
*/
sel = OS__add_stack_el(stck);
if(!sel) RETURN(RC_FAIL);
sel->tag = tlv_tag;
sel->want_nulls = (tlv_len==-1);
if(sel->prev && sel->prev->left != -1) {
/* Check that the parent frame is big enough */
if(sel->prev->left < tlvl + (tlv_len==-1?0:tlv_len))
RETURN(RC_FAIL);
if(tlv_len == -1)
sel->left = sel->prev->left - tlvl;
else
sel->left = tlv_len;
} else {
sel->left = tlv_len;
}
if(type_variant == ASN_OSUBV_ANY
&& (tag_mode != 1 || sel->cont_level))
APPEND(buf_ptr, tlvl);
sel->got += tlvl;
ADVANCE(tlvl);
ASN_DEBUG("+EXPECT2 got=%ld left=%ld, wn=%d, clvl=%u",
(long)sel->got, (long)sel->left,
sel->want_nulls, sel->cont_level);
} while(tlv_constr);
if(sel == NULL) {
/* Finished operation, "phase out" */
ASN_DEBUG("Phase out");
_CH_PHASE(ctx, +3);
break;
}
NEXT_PHASE(ctx);
/* Fall through */
case 2:
stck = (struct _stack *)ctx->ptr;
sel = stck->cur_ptr;
ASN_DEBUG("Phase 2: Need %ld bytes, size=%ld, alrg=%ld, wn=%d",
(long)sel->left, (long)size, (long)sel->got,
sel->want_nulls);
{
ber_tlv_len_t len;
assert(sel->left >= 0);
len = ((ber_tlv_len_t)size < sel->left)
? (ber_tlv_len_t)size : sel->left;
if(len > 0) {
if(type_variant == ASN_OSUBV_BIT
&& sel->bits_chopped == 0) {
/* Put the unused-bits-octet away */
st->bits_unused = *(const uint8_t *)buf_ptr;
APPEND(((const char *)buf_ptr+1), (len - 1));
sel->bits_chopped = 1;
} else {
APPEND(buf_ptr, len);
}
ADVANCE(len);
sel->left -= len;
sel->got += len;
}
if(sel->left) {
ASN_DEBUG("OS left %ld, size = %ld, wn=%d\n",
(long)sel->left, (long)size, sel->want_nulls);
RETURN(RC_WMORE);
}
PREV_PHASE(ctx);
goto phase1;
}
break;
case 3:
phase3:
/*
* Primitive form, no stack required.
*/
assert(ctx->left >= 0);
if(size < (size_t)ctx->left) {
if(!size) RETURN(RC_WMORE);
if(type_variant == ASN_OSUBV_BIT && !ctx->context) {
st->bits_unused = *(const uint8_t *)buf_ptr;
ctx->left--;
ADVANCE(1);
}
APPEND(buf_ptr, size);
assert(ctx->context > 0);
ctx->left -= size;
ADVANCE(size);
RETURN(RC_WMORE);
} else {
if(type_variant == ASN_OSUBV_BIT
&& !ctx->context && ctx->left) {
st->bits_unused = *(const uint8_t *)buf_ptr;
ctx->left--;
ADVANCE(1);
}
APPEND(buf_ptr, ctx->left);
ADVANCE(ctx->left);
ctx->left = 0;
NEXT_PHASE(ctx);
}
break;
}
if(sel) {
ASN_DEBUG("3sel p=%p, wn=%d, l=%ld, g=%ld, size=%ld",
(void *)sel->prev, sel->want_nulls,
(long)sel->left, (long)sel->got, (long)size);
if(sel->prev || sel->want_nulls > 1 || sel->left > 0) {
RETURN(RC_WMORE);
}
}
/*
* BIT STRING-specific processing.
*/
if(type_variant == ASN_OSUBV_BIT) {
if(st->size) {
if(st->bits_unused < 0 || st->bits_unused > 7) {
RETURN(RC_FAIL);
}
/* Finalize BIT STRING: zero out unused bits. */
st->buf[st->size-1] &= 0xff << st->bits_unused;
} else {
if(st->bits_unused) {
RETURN(RC_FAIL);
}
}
}
ASN_DEBUG("Took %ld bytes to encode %s: [%s]:%ld",
(long)consumed_myself, td->name,
(type_variant == ASN_OSUBV_STR) ? (char *)st->buf : "<data>",
(long)st->size);
RETURN(RC_OK);
}
/*
* Encode OCTET STRING type using DER.
*/
asn_enc_rval_t
OCTET_STRING_encode_der(const asn_TYPE_descriptor_t *td, const void *sptr,
int tag_mode, ber_tlv_tag_t tag,
asn_app_consume_bytes_f *cb, void *app_key) {
asn_enc_rval_t er = { 0, 0, 0 };
const asn_OCTET_STRING_specifics_t *specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
const BIT_STRING_t *st = (const BIT_STRING_t *)sptr;
enum asn_OS_Subvariant type_variant = specs->subvariant;
int fix_last_byte = 0;
ASN_DEBUG("%s %s as OCTET STRING",
cb?"Estimating":"Encoding", td->name);
/*
* Write tags.
*/
if(type_variant != ASN_OSUBV_ANY || tag_mode == 1) {
er.encoded = der_write_tags(td,
(type_variant == ASN_OSUBV_BIT) + st->size,
tag_mode, type_variant == ASN_OSUBV_ANY, tag,
cb, app_key);
if(er.encoded == -1) {
er.failed_type = td;
er.structure_ptr = sptr;
return er;
}
} else {
/* Disallow: [<tag>] IMPLICIT ANY */
assert(type_variant != ASN_OSUBV_ANY || tag_mode != -1);
er.encoded = 0;
}
if(!cb) {
er.encoded += (type_variant == ASN_OSUBV_BIT) + st->size;
ASN__ENCODED_OK(er);
}
/*
* Prepare to deal with the last octet of BIT STRING.
*/
if(type_variant == ASN_OSUBV_BIT) {
uint8_t b = st->bits_unused & 0x07;
if(b && st->size) fix_last_byte = 1;
ASN__CALLBACK(&b, 1);
}
/* Invoke callback for the main part of the buffer */
ASN__CALLBACK(st->buf, st->size - fix_last_byte);
/* The last octet should be stripped off the unused bits */
if(fix_last_byte) {
uint8_t b = st->buf[st->size-1] & (0xff << st->bits_unused);
ASN__CALLBACK(&b, 1);
}
ASN__ENCODED_OK(er);
cb_failed:
ASN__ENCODE_FAILED;
}
asn_enc_rval_t
OCTET_STRING_encode_xer(const asn_TYPE_descriptor_t *td, const void *sptr,
int ilevel, enum xer_encoder_flags_e flags,
asn_app_consume_bytes_f *cb, void *app_key) {
const char * const h2c = "0123456789ABCDEF";
const OCTET_STRING_t *st = (const OCTET_STRING_t *)sptr;
asn_enc_rval_t er = { 0, 0, 0 };
char scratch[16 * 3 + 4];
char *p = scratch;
uint8_t *buf;
uint8_t *end;
size_t i;
if(!st || (!st->buf && st->size))
ASN__ENCODE_FAILED;
er.encoded = 0;
/*
* Dump the contents of the buffer in hexadecimal.
*/
buf = st->buf;
end = buf + st->size;
if(flags & XER_F_CANONICAL) {
char *scend = scratch + (sizeof(scratch) - 2);
for(; buf < end; buf++) {
if(p >= scend) {
ASN__CALLBACK(scratch, p - scratch);
p = scratch;
}
*p++ = h2c[(*buf >> 4) & 0x0F];
*p++ = h2c[*buf & 0x0F];
}
ASN__CALLBACK(scratch, p-scratch); /* Dump the rest */
} else {
for(i = 0; buf < end; buf++, i++) {
if(!(i % 16) && (i || st->size > 16)) {
ASN__CALLBACK(scratch, p-scratch);
p = scratch;
ASN__TEXT_INDENT(1, ilevel);
}
*p++ = h2c[(*buf >> 4) & 0x0F];
*p++ = h2c[*buf & 0x0F];
*p++ = 0x20;
}
if(p - scratch) {
p--; /* Remove the tail space */
ASN__CALLBACK(scratch, p-scratch); /* Dump the rest */
if(st->size > 16)
ASN__TEXT_INDENT(1, ilevel-1);
}
}
ASN__ENCODED_OK(er);
cb_failed:
ASN__ENCODE_FAILED;
}
static const struct OCTET_STRING__xer_escape_table_s {
const char *string;
int size;
} OCTET_STRING__xer_escape_table[] = {
#define OSXET(s) { s, sizeof(s) - 1 }
OSXET("\074\156\165\154\057\076"), /* <nul/> */
OSXET("\074\163\157\150\057\076"), /* <soh/> */
OSXET("\074\163\164\170\057\076"), /* <stx/> */
OSXET("\074\145\164\170\057\076"), /* <etx/> */
OSXET("\074\145\157\164\057\076"), /* <eot/> */
OSXET("\074\145\156\161\057\076"), /* <enq/> */
OSXET("\074\141\143\153\057\076"), /* <ack/> */
OSXET("\074\142\145\154\057\076"), /* <bel/> */
OSXET("\074\142\163\057\076"), /* <bs/> */
OSXET("\011"), /* \t */
OSXET("\012"), /* \n */
OSXET("\074\166\164\057\076"), /* <vt/> */
OSXET("\074\146\146\057\076"), /* <ff/> */
OSXET("\015"), /* \r */
OSXET("\074\163\157\057\076"), /* <so/> */
OSXET("\074\163\151\057\076"), /* <si/> */
OSXET("\074\144\154\145\057\076"), /* <dle/> */
OSXET("\074\144\143\061\057\076"), /* <de1/> */
OSXET("\074\144\143\062\057\076"), /* <de2/> */
OSXET("\074\144\143\063\057\076"), /* <de3/> */
OSXET("\074\144\143\064\057\076"), /* <de4/> */
OSXET("\074\156\141\153\057\076"), /* <nak/> */
OSXET("\074\163\171\156\057\076"), /* <syn/> */
OSXET("\074\145\164\142\057\076"), /* <etb/> */
OSXET("\074\143\141\156\057\076"), /* <can/> */
OSXET("\074\145\155\057\076"), /* <em/> */
OSXET("\074\163\165\142\057\076"), /* <sub/> */
OSXET("\074\145\163\143\057\076"), /* <esc/> */
OSXET("\074\151\163\064\057\076"), /* <is4/> */
OSXET("\074\151\163\063\057\076"), /* <is3/> */
OSXET("\074\151\163\062\057\076"), /* <is2/> */
OSXET("\074\151\163\061\057\076"), /* <is1/> */
{ 0, 0 }, /* " " */
{ 0, 0 }, /* ! */
{ 0, 0 }, /* \" */
{ 0, 0 }, /* # */
{ 0, 0 }, /* $ */
{ 0, 0 }, /* % */
OSXET("\046\141\155\160\073"), /* &amp; */
{ 0, 0 }, /* ' */
{0,0},{0,0},{0,0},{0,0},{0,0},{0,0},{0,0},{0,0}, /* ()*+,-./ */
{0,0},{0,0},{0,0},{0,0},{0,0},{0,0},{0,0},{0,0}, /* 01234567 */
{0,0},{0,0},{0,0},{0,0}, /* 89:; */
OSXET("\046\154\164\073"), /* &lt; */
{ 0, 0 }, /* = */
OSXET("\046\147\164\073"), /* &gt; */
};
static int
OS__check_escaped_control_char(const void *buf, int size) {
size_t i;
/*
* Inefficient algorithm which translates the escape sequences
* defined above into characters. Returns -1 if not found.
* TODO: replace by a faster algorithm (bsearch(), hash or
* nested table lookups).
*/
for(i = 0; i < 32 /* Don't spend time on the bottom half */; i++) {
const struct OCTET_STRING__xer_escape_table_s *el;
el = &OCTET_STRING__xer_escape_table[i];
if(el->size == size && memcmp(buf, el->string, size) == 0)
return i;
}
return -1;
}
static int
OCTET_STRING__handle_control_chars(void *struct_ptr, const void *chunk_buf, size_t chunk_size) {
/*
* This might be one of the escape sequences
* for control characters. Check it out.
* #11.15.5
*/
int control_char = OS__check_escaped_control_char(chunk_buf,chunk_size);
if(control_char >= 0) {
OCTET_STRING_t *st = (OCTET_STRING_t *)struct_ptr;
void *p = REALLOC(st->buf, st->size + 2);
if(p) {
st->buf = (uint8_t *)p;
st->buf[st->size++] = control_char;
st->buf[st->size] = '\0'; /* nul-termination */
return 0;
}
}
return -1; /* No, it's not */
}
asn_enc_rval_t
OCTET_STRING_encode_xer_utf8(const asn_TYPE_descriptor_t *td, const void *sptr,
int ilevel, enum xer_encoder_flags_e flags,
asn_app_consume_bytes_f *cb, void *app_key) {
const OCTET_STRING_t *st = (const OCTET_STRING_t *)sptr;
asn_enc_rval_t er = { 0, 0, 0 };
uint8_t *buf, *end;
uint8_t *ss; /* Sequence start */
ssize_t encoded_len = 0;
(void)ilevel; /* Unused argument */
(void)flags; /* Unused argument */
if(!st || (!st->buf && st->size))
ASN__ENCODE_FAILED;
buf = st->buf;
end = buf + st->size;
for(ss = buf; buf < end; buf++) {
unsigned int ch = *buf;
int s_len; /* Special encoding sequence length */
/*
* Escape certain characters: X.680/11.15
*/
if(ch < sizeof(OCTET_STRING__xer_escape_table)
/sizeof(OCTET_STRING__xer_escape_table[0])
&& (s_len = OCTET_STRING__xer_escape_table[ch].size)) {
if(((buf - ss) && cb(ss, buf - ss, app_key) < 0)
|| cb(OCTET_STRING__xer_escape_table[ch].string, s_len,
app_key) < 0)
ASN__ENCODE_FAILED;
encoded_len += (buf - ss) + s_len;
ss = buf + 1;
}
}
encoded_len += (buf - ss);
if((buf - ss) && cb(ss, buf - ss, app_key) < 0)
ASN__ENCODE_FAILED;
er.encoded = encoded_len;
ASN__ENCODED_OK(er);
}
/*
* Convert from hexadecimal format (cstring): "AB CD EF"
*/
static ssize_t OCTET_STRING__convert_hexadecimal(void *sptr, const void *chunk_buf, size_t chunk_size, int have_more) {
OCTET_STRING_t *st = (OCTET_STRING_t *)sptr;
const char *chunk_stop = (const char *)chunk_buf;
const char *p = chunk_stop;
const char *pend = p + chunk_size;
unsigned int clv = 0;
int half = 0; /* Half bit */
uint8_t *buf;
/* Reallocate buffer according to high cap estimation */
size_t new_size = st->size + (chunk_size + 1) / 2;
void *nptr = REALLOC(st->buf, new_size + 1);
if(!nptr) return -1;
st->buf = (uint8_t *)nptr;
buf = st->buf + st->size;
/*
* If something like " a b c " appears here, the " a b":3 will be
* converted, and the rest skipped. That is, unless buf_size is greater
* than chunk_size, then it'll be equivalent to "ABC0".
*/
for(; p < pend; p++) {
int ch = *(const unsigned char *)p;
switch(ch) {
case 0x09: case 0x0a: case 0x0c: case 0x0d:
case 0x20:
/* Ignore whitespace */
continue;
case 0x30: case 0x31: case 0x32: case 0x33: case 0x34: /*01234*/
case 0x35: case 0x36: case 0x37: case 0x38: case 0x39: /*56789*/
clv = (clv << 4) + (ch - 0x30);
break;
case 0x41: case 0x42: case 0x43: /* ABC */
case 0x44: case 0x45: case 0x46: /* DEF */
clv = (clv << 4) + (ch - 0x41 + 10);
break;
case 0x61: case 0x62: case 0x63: /* abc */
case 0x64: case 0x65: case 0x66: /* def */
clv = (clv << 4) + (ch - 0x61 + 10);
break;
default:
*buf = 0; /* JIC */
return -1;
}
if(half++) {
half = 0;
*buf++ = clv;
chunk_stop = p + 1;
}
}
/*
* Check partial decoding.
*/
if(half) {
if(have_more) {
/*
* Partial specification is fine,
* because no more more PXER_TEXT data is available.
*/
*buf++ = clv << 4;
chunk_stop = p;
}
} else {
chunk_stop = p;
}
st->size = buf - st->buf; /* Adjust the buffer size */
assert(st->size <= new_size);
st->buf[st->size] = 0; /* Courtesy termination */
return (chunk_stop - (const char *)chunk_buf); /* Converted size */
}
/*
* Convert from binary format: "00101011101"
*/
static ssize_t OCTET_STRING__convert_binary(void *sptr, const void *chunk_buf, size_t chunk_size, int have_more) {
BIT_STRING_t *st = (BIT_STRING_t *)sptr;
const char *p = (const char *)chunk_buf;
const char *pend = p + chunk_size;
int bits_unused = st->bits_unused & 0x7;
uint8_t *buf;
/* Reallocate buffer according to high cap estimation */
size_t new_size = st->size + (chunk_size + 7) / 8;
void *nptr = REALLOC(st->buf, new_size + 1);
if(!nptr) return -1;
st->buf = (uint8_t *)nptr;
buf = st->buf + st->size;
(void)have_more;
if(bits_unused == 0)
bits_unused = 8;
else if(st->size)
buf--;
/*
* Convert series of 0 and 1 into the octet string.
*/
for(; p < pend; p++) {
int ch = *(const unsigned char *)p;
switch(ch) {
case 0x09: case 0x0a: case 0x0c: case 0x0d:
case 0x20:
/* Ignore whitespace */
break;
case 0x30:
case 0x31:
if(bits_unused-- <= 0) {
*++buf = 0; /* Clean the cell */
bits_unused = 7;
}
*buf |= (ch&1) << bits_unused;
break;
default:
st->bits_unused = bits_unused;
return -1;
}
}
if(bits_unused == 8) {
st->size = buf - st->buf;
st->bits_unused = 0;
} else {
st->size = buf - st->buf + 1;
st->bits_unused = bits_unused;
}
assert(st->size <= new_size);
st->buf[st->size] = 0; /* Courtesy termination */
return chunk_size; /* Converted in full */
}
/*
* Something like strtod(), but with stricter rules.
*/
static int
OS__strtoent(int base, const char *buf, const char *end, int32_t *ret_value) {
const int32_t last_unicode_codepoint = 0x10ffff;
int32_t val = 0;
const char *p;
for(p = buf; p < end; p++) {
int ch = *p;
switch(ch) {
case 0x30: case 0x31: case 0x32: case 0x33: case 0x34: /*01234*/
case 0x35: case 0x36: case 0x37: case 0x38: case 0x39: /*56789*/
val = val * base + (ch - 0x30);
break;
case 0x41: case 0x42: case 0x43: /* ABC */
case 0x44: case 0x45: case 0x46: /* DEF */
val = val * base + (ch - 0x41 + 10);
break;
case 0x61: case 0x62: case 0x63: /* abc */
case 0x64: case 0x65: case 0x66: /* def */
val = val * base + (ch - 0x61 + 10);
break;
case 0x3b: /* ';' */
*ret_value = val;
return (p - buf) + 1;
default:
return -1; /* Character set error */
}
/* Value exceeds the Unicode range. */
if(val > last_unicode_codepoint) {
return -1;
}
}
*ret_value = -1;
return (p - buf);
}
/*
* Convert from the plain UTF-8 format, expanding entity references: "2 &lt; 3"
*/
static ssize_t
OCTET_STRING__convert_entrefs(void *sptr, const void *chunk_buf,
size_t chunk_size, int have_more) {
OCTET_STRING_t *st = (OCTET_STRING_t *)sptr;
const char *p = (const char *)chunk_buf;
const char *pend = p + chunk_size;
uint8_t *buf;
/* Reallocate buffer */
size_t new_size = st->size + chunk_size;
void *nptr = REALLOC(st->buf, new_size + 1);
if(!nptr) return -1;
st->buf = (uint8_t *)nptr;
buf = st->buf + st->size;
/*
* Convert series of 0 and 1 into the octet string.
*/
for(; p < pend; p++) {
int ch = *(const unsigned char *)p;
int len; /* Length of the rest of the chunk */
if(ch != 0x26 /* '&' */) {
*buf++ = ch;
continue; /* That was easy... */
}
/*
* Process entity reference.
*/
len = chunk_size - (p - (const char *)chunk_buf);
if(len == 1 /* "&" */) goto want_more;
if(p[1] == 0x23 /* '#' */) {
const char *pval; /* Pointer to start of digits */
int32_t val = 0; /* Entity reference value */
int base;
if(len == 2 /* "&#" */) goto want_more;
if(p[2] == 0x78 /* 'x' */)
pval = p + 3, base = 16;
else
pval = p + 2, base = 10;
len = OS__strtoent(base, pval, p + len, &val);
if(len == -1) {
/* Invalid charset. Just copy verbatim. */
*buf++ = ch;
continue;
}
if(!len || pval[len-1] != 0x3b) goto want_more;
assert(val > 0);
p += (pval - p) + len - 1; /* Advance past entref */
if(val < 0x80) {
*buf++ = (char)val;
} else if(val < 0x800) {
*buf++ = 0xc0 | ((val >> 6));
*buf++ = 0x80 | ((val & 0x3f));
} else if(val < 0x10000) {
*buf++ = 0xe0 | ((val >> 12));
*buf++ = 0x80 | ((val >> 6) & 0x3f);
*buf++ = 0x80 | ((val & 0x3f));
} else if(val < 0x200000) {
*buf++ = 0xf0 | ((val >> 18));
*buf++ = 0x80 | ((val >> 12) & 0x3f);
*buf++ = 0x80 | ((val >> 6) & 0x3f);
*buf++ = 0x80 | ((val & 0x3f));
} else if(val < 0x4000000) {
*buf++ = 0xf8 | ((val >> 24));
*buf++ = 0x80 | ((val >> 18) & 0x3f);
*buf++ = 0x80 | ((val >> 12) & 0x3f);
*buf++ = 0x80 | ((val >> 6) & 0x3f);
*buf++ = 0x80 | ((val & 0x3f));
} else {
*buf++ = 0xfc | ((val >> 30) & 0x1);
*buf++ = 0x80 | ((val >> 24) & 0x3f);
*buf++ = 0x80 | ((val >> 18) & 0x3f);
*buf++ = 0x80 | ((val >> 12) & 0x3f);
*buf++ = 0x80 | ((val >> 6) & 0x3f);
*buf++ = 0x80 | ((val & 0x3f));
}
} else {
/*
* Ugly, limited parsing of &amp; &gt; &lt;
*/
char *sc = (char *)memchr(p, 0x3b, len > 5 ? 5 : len);
if(!sc) goto want_more;
if((sc - p) == 4
&& p[1] == 0x61 /* 'a' */
&& p[2] == 0x6d /* 'm' */
&& p[3] == 0x70 /* 'p' */) {
*buf++ = 0x26;
p = sc;
continue;
}
if((sc - p) == 3) {
if(p[1] == 0x6c) {
*buf = 0x3c; /* '<' */
} else if(p[1] == 0x67) {
*buf = 0x3e; /* '>' */
} else {
/* Unsupported entity reference */
*buf++ = ch;
continue;
}
if(p[2] != 0x74) {
/* Unsupported entity reference */
*buf++ = ch;
continue;
}
buf++;
p = sc;
continue;
}
/* Unsupported entity reference */
*buf++ = ch;
}
continue;
want_more:
if(have_more) {
/*
* We know that no more data (of the same type)
* is coming. Copy the rest verbatim.
*/
*buf++ = ch;
continue;
}
chunk_size = (p - (const char *)chunk_buf);
/* Processing stalled: need more data */
break;
}
st->size = buf - st->buf;
assert(st->size <= new_size);
st->buf[st->size] = 0; /* Courtesy termination */
return chunk_size; /* Converted in full */
}
/*
* Decode OCTET STRING from the XML element's body.
*/
static asn_dec_rval_t
OCTET_STRING__decode_xer(
const asn_codec_ctx_t *opt_codec_ctx, const asn_TYPE_descriptor_t *td,
void **sptr, const char *opt_mname, const void *buf_ptr, size_t size,
int (*opt_unexpected_tag_decoder)(void *struct_ptr, const void *chunk_buf,
size_t chunk_size),
ssize_t (*body_receiver)(void *struct_ptr, const void *chunk_buf,
size_t chunk_size, int have_more)) {
OCTET_STRING_t *st = (OCTET_STRING_t *)*sptr;
const asn_OCTET_STRING_specifics_t *specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
const char *xml_tag = opt_mname ? opt_mname : td->xml_tag;
asn_struct_ctx_t *ctx; /* Per-structure parser context */
asn_dec_rval_t rval; /* Return value from the decoder */
int st_allocated;
/*
* Create the string if does not exist.
*/
if(!st) {
st = (OCTET_STRING_t *)CALLOC(1, specs->struct_size);
*sptr = (void *)st;
if(!st) goto sta_failed;
st_allocated = 1;
} else {
st_allocated = 0;
}
if(!st->buf) {
/* This is separate from above section */
st->buf = (uint8_t *)CALLOC(1, 1);
if(!st->buf) {
if(st_allocated) {
*sptr = 0;
goto stb_failed;
} else {
goto sta_failed;
}
}
}
/* Restore parsing context */
ctx = (asn_struct_ctx_t *)(((char *)*sptr) + specs->ctx_offset);
return xer_decode_general(opt_codec_ctx, ctx, *sptr, xml_tag,
buf_ptr, size, opt_unexpected_tag_decoder, body_receiver);
stb_failed:
FREEMEM(st);
sta_failed:
rval.code = RC_FAIL;
rval.consumed = 0;
return rval;
}
/*
* Decode OCTET STRING from the hexadecimal data.
*/
asn_dec_rval_t
OCTET_STRING_decode_xer_hex(const asn_codec_ctx_t *opt_codec_ctx,
const asn_TYPE_descriptor_t *td, void **sptr,
const char *opt_mname, const void *buf_ptr,
size_t size) {
return OCTET_STRING__decode_xer(opt_codec_ctx, td, sptr, opt_mname,
buf_ptr, size, 0, OCTET_STRING__convert_hexadecimal);
}
/*
* Decode OCTET STRING from the binary (0/1) data.
*/
asn_dec_rval_t
OCTET_STRING_decode_xer_binary(const asn_codec_ctx_t *opt_codec_ctx,
const asn_TYPE_descriptor_t *td, void **sptr,
const char *opt_mname, const void *buf_ptr,
size_t size) {
return OCTET_STRING__decode_xer(opt_codec_ctx, td, sptr, opt_mname,
buf_ptr, size, 0, OCTET_STRING__convert_binary);
}
/*
* Decode OCTET STRING from the string (ASCII/UTF-8) data.
*/
asn_dec_rval_t
OCTET_STRING_decode_xer_utf8(const asn_codec_ctx_t *opt_codec_ctx,
const asn_TYPE_descriptor_t *td, void **sptr,
const char *opt_mname, const void *buf_ptr,
size_t size) {
return OCTET_STRING__decode_xer(opt_codec_ctx, td, sptr, opt_mname,
buf_ptr, size,
OCTET_STRING__handle_control_chars,
OCTET_STRING__convert_entrefs);
}
#ifndef ASN_DISABLE_PER_SUPPORT
static int
OCTET_STRING_per_get_characters(asn_per_data_t *po, uint8_t *buf,
size_t units, unsigned int bpc, unsigned int unit_bits,
long lb, long ub, const asn_per_constraints_t *pc) {
uint8_t *end = buf + units * bpc;
ASN_DEBUG("Expanding %d characters into (%ld..%ld):%d",
(int)units, lb, ub, unit_bits);
/* X.691: 27.5.4 */
if((unsigned long)ub <= ((unsigned long)2 << (unit_bits - 1))) {
/* Decode without translation */
lb = 0;
} else if(pc && pc->code2value) {
if(unit_bits > 16)
return 1; /* FATAL: can't have constrained
* UniversalString with more than
* 16 million code points */
for(; buf < end; buf += bpc) {
int value;
int code = per_get_few_bits(po, unit_bits);
if(code < 0) return -1; /* WMORE */
value = pc->code2value(code);
if(value < 0) {
ASN_DEBUG("Code %d (0x%02x) is"
" not in map (%ld..%ld)",
code, code, lb, ub);
return 1; /* FATAL */
}
switch(bpc) {
case 1: *buf = value; break;
case 2: buf[0] = value >> 8; buf[1] = value; break;
case 4: buf[0] = value >> 24; buf[1] = value >> 16;
buf[2] = value >> 8; buf[3] = value; break;
}
}
return 0;
}
/* Shortcut the no-op copying to the aligned structure */
if(lb == 0 && (unit_bits == 8 * bpc)) {
return per_get_many_bits(po, buf, 0, unit_bits * units);
}
for(; buf < end; buf += bpc) {
int32_t code = per_get_few_bits(po, unit_bits);
int32_t ch = code + lb;
if(code < 0) return -1; /* WMORE */
if(ch > ub) {
ASN_DEBUG("Code %d is out of range (%ld..%ld)",
ch, lb, ub);
return 1; /* FATAL */
}
switch(bpc) {
case 1: *buf = ch; break;
case 2: buf[0] = ch >> 8; buf[1] = ch; break;
case 4: buf[0] = ch >> 24; buf[1] = ch >> 16;
buf[2] = ch >> 8; buf[3] = ch; break;
}
}
return 0;
}
static int
OCTET_STRING_per_put_characters(asn_per_outp_t *po, const uint8_t *buf,
size_t units, unsigned int bpc, unsigned int unit_bits,
long lb, long ub, const asn_per_constraints_t *pc) {
const uint8_t *end = buf + units * bpc;
ASN_DEBUG("Squeezing %d characters into (%ld..%ld):%d (%d bpc)",
(int)units, lb, ub, unit_bits, bpc);
/* X.691: 27.5.4 */
if((unsigned long)ub <= ((unsigned long)2 << (unit_bits - 1))) {
/* Encode as is */
lb = 0;
} else if(pc && pc->value2code) {
for(; buf < end; buf += bpc) {
int code;
uint32_t value;
switch(bpc) {
case 1: value = *(const uint8_t *)buf; break;
case 2: value = (buf[0] << 8) | buf[1]; break;
case 4: value = (buf[0] << 24) | (buf[1] << 16)
| (buf[2] << 8) | buf[3]; break;
default: return -1;
}
code = pc->value2code(value);
if(code < 0) {
ASN_DEBUG("Character %d (0x%02x) is"
" not in map (%ld..%ld)",
*buf, *buf, lb, ub);
return -1;
}
if(per_put_few_bits(po, code, unit_bits))
return -1;
}
}
/* Shortcut the no-op copying to the aligned structure */
if(lb == 0 && (unit_bits == 8 * bpc)) {
return per_put_many_bits(po, buf, unit_bits * units);
}
for(ub -= lb; buf < end; buf += bpc) {
int ch;
uint32_t value;
switch(bpc) {
case 1:
value = *(const uint8_t *)buf;
break;
case 2:
value = (buf[0] << 8) | buf[1];
break;
case 4:
value = (buf[0] << 24) | (buf[1] << 16) | (buf[2] << 8) | buf[3];
break;
default:
return -1;
}
ch = value - lb;
if(ch < 0 || ch > ub) {
ASN_DEBUG("Character %d (0x%02x) is out of range (%ld..%ld)", *buf,
value, lb, ub + lb);
return -1;
}
if(per_put_few_bits(po, ch, unit_bits)) return -1;
}
return 0;
}
static asn_per_constraints_t asn_DEF_OCTET_STRING_constraints = {
{ APC_CONSTRAINED, 8, 8, 0, 255 },
{ APC_SEMI_CONSTRAINED, -1, -1, 0, 0 },
0, 0
};
asn_dec_rval_t
OCTET_STRING_decode_uper(const asn_codec_ctx_t *opt_codec_ctx,
const asn_TYPE_descriptor_t *td,
const asn_per_constraints_t *constraints, void **sptr,
asn_per_data_t *pd) {
const asn_OCTET_STRING_specifics_t *specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
const asn_per_constraints_t *pc =
constraints ? constraints : td->encoding_constraints.per_constraints;
const asn_per_constraint_t *cval;
const asn_per_constraint_t *csiz;
asn_dec_rval_t rval = { RC_OK, 0 };
OCTET_STRING_t *st = (OCTET_STRING_t *)*sptr;
ssize_t consumed_myself = 0;
int repeat;
enum {
OS__BPC_CHAR = 1,
OS__BPC_U16 = 2,
OS__BPC_U32 = 4
} bpc; /* Bytes per character */
unsigned int unit_bits;
unsigned int canonical_unit_bits;
(void)opt_codec_ctx;
if(pc) {
cval = &pc->value;
csiz = &pc->size;
} else {
cval = &asn_DEF_OCTET_STRING_constraints.value;
csiz = &asn_DEF_OCTET_STRING_constraints.size;
}
switch(specs->subvariant) {
default:
case ASN_OSUBV_ANY:
case ASN_OSUBV_BIT:
ASN_DEBUG("Unrecognized subvariant %d", specs->subvariant);
RETURN(RC_FAIL);
break;
case ASN_OSUBV_STR:
canonical_unit_bits = unit_bits = 8;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_CHAR;
break;
case ASN_OSUBV_U16:
canonical_unit_bits = unit_bits = 16;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_U16;
break;
case ASN_OSUBV_U32:
canonical_unit_bits = unit_bits = 32;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_U32;
break;
}
/*
* Allocate the string.
*/
if(!st) {
st = (OCTET_STRING_t *)(*sptr = CALLOC(1, specs->struct_size));
if(!st) RETURN(RC_FAIL);
}
ASN_DEBUG("PER Decoding %s size %ld .. %ld bits %d",
csiz->flags & APC_EXTENSIBLE ? "extensible" : "non-extensible",
csiz->lower_bound, csiz->upper_bound, csiz->effective_bits);
if(csiz->flags & APC_EXTENSIBLE) {
int inext = per_get_few_bits(pd, 1);
if(inext < 0) RETURN(RC_WMORE);
if(inext) {
csiz = &asn_DEF_OCTET_STRING_constraints.size;
unit_bits = canonical_unit_bits;
}
}
if(csiz->effective_bits >= 0) {
FREEMEM(st->buf);
if(bpc) {
st->size = csiz->upper_bound * bpc;
} else {
st->size = (csiz->upper_bound + 7) >> 3;
}
st->buf = (uint8_t *)MALLOC(st->size + 1);
if(!st->buf) { st->size = 0; RETURN(RC_FAIL); }
}
/* X.691, #16.5: zero-length encoding */
/* X.691, #16.6: short fixed length encoding (up to 2 octets) */
/* X.691, #16.7: long fixed length encoding (up to 64K octets) */
if(csiz->effective_bits == 0) {
int ret;
if(bpc) {
ASN_DEBUG("Encoding OCTET STRING size %ld",
csiz->upper_bound);
ret = OCTET_STRING_per_get_characters(pd, st->buf,
csiz->upper_bound, bpc, unit_bits,
cval->lower_bound, cval->upper_bound, pc);
if(ret > 0) RETURN(RC_FAIL);
} else {
ASN_DEBUG("Encoding BIT STRING size %ld",
csiz->upper_bound);
ret = per_get_many_bits(pd, st->buf, 0,
unit_bits * csiz->upper_bound);
}
if(ret < 0) RETURN(RC_WMORE);
consumed_myself += unit_bits * csiz->upper_bound;
st->buf[st->size] = 0;
RETURN(RC_OK);
}
st->size = 0;
do {
ssize_t raw_len;
ssize_t len_bytes;
void *p;
int ret;
/* Get the PER length */
raw_len = uper_get_length(pd, csiz->effective_bits, csiz->lower_bound,
&repeat);
if(raw_len < 0) RETURN(RC_WMORE);
if(raw_len == 0 && st->buf) break;
ASN_DEBUG("Got PER length eb %ld, len %ld, %s (%s)",
(long)csiz->effective_bits, (long)raw_len,
repeat ? "repeat" : "once", td->name);
len_bytes = raw_len * bpc;
p = REALLOC(st->buf, st->size + len_bytes + 1);
if(!p) RETURN(RC_FAIL);
st->buf = (uint8_t *)p;
ret = OCTET_STRING_per_get_characters(pd, &st->buf[st->size], raw_len,
bpc, unit_bits, cval->lower_bound,
cval->upper_bound, pc);
if(ret > 0) RETURN(RC_FAIL);
if(ret < 0) RETURN(RC_WMORE);
st->size += len_bytes;
} while(repeat);
st->buf[st->size] = 0; /* nul-terminate */
return rval;
}
asn_enc_rval_t
OCTET_STRING_encode_uper(const asn_TYPE_descriptor_t *td,
const asn_per_constraints_t *constraints,
const void *sptr, asn_per_outp_t *po) {
const asn_OCTET_STRING_specifics_t *specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
const asn_per_constraints_t *pc = constraints ? constraints
: td->encoding_constraints.per_constraints;
const asn_per_constraint_t *cval;
const asn_per_constraint_t *csiz;
const OCTET_STRING_t *st = (const OCTET_STRING_t *)sptr;
asn_enc_rval_t er = { 0, 0, 0 };
int inext = 0; /* Lies not within extension root */
unsigned int unit_bits;
unsigned int canonical_unit_bits;
size_t size_in_units;
const uint8_t *buf;
int ret;
enum {
OS__BPC_CHAR = 1,
OS__BPC_U16 = 2,
OS__BPC_U32 = 4
} bpc; /* Bytes per character */
int ct_extensible;
if(!st || (!st->buf && st->size))
ASN__ENCODE_FAILED;
if(pc) {
cval = &pc->value;
csiz = &pc->size;
} else {
cval = &asn_DEF_OCTET_STRING_constraints.value;
csiz = &asn_DEF_OCTET_STRING_constraints.size;
}
ct_extensible = csiz->flags & APC_EXTENSIBLE;
switch(specs->subvariant) {
default:
case ASN_OSUBV_ANY:
case ASN_OSUBV_BIT:
ASN__ENCODE_FAILED;
case ASN_OSUBV_STR:
canonical_unit_bits = unit_bits = 8;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_CHAR;
size_in_units = st->size;
break;
case ASN_OSUBV_U16:
canonical_unit_bits = unit_bits = 16;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_U16;
size_in_units = st->size >> 1;
if(st->size & 1) {
ASN_DEBUG("%s string size is not modulo 2", td->name);
ASN__ENCODE_FAILED;
}
break;
case ASN_OSUBV_U32:
canonical_unit_bits = unit_bits = 32;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_U32;
size_in_units = st->size >> 2;
if(st->size & 3) {
ASN_DEBUG("%s string size is not modulo 4", td->name);
ASN__ENCODE_FAILED;
}
break;
}
ASN_DEBUG("Encoding %s into %" ASN_PRI_SIZE " units of %d bits"
" (%ld..%ld, effective %d)%s",
td->name, size_in_units, unit_bits,
csiz->lower_bound, csiz->upper_bound,
csiz->effective_bits, ct_extensible ? " EXT" : "");
/* Figure out whether size lies within PER visible constraint */
if(csiz->effective_bits >= 0) {
if((ssize_t)size_in_units < csiz->lower_bound
|| (ssize_t)size_in_units > csiz->upper_bound) {
if(ct_extensible) {
csiz = &asn_DEF_OCTET_STRING_constraints.size;
unit_bits = canonical_unit_bits;
inext = 1;
} else {
ASN__ENCODE_FAILED;
}
}
} else {
inext = 0;
}
if(ct_extensible) {
/* Declare whether length is [not] within extension root */
if(per_put_few_bits(po, inext, 1))
ASN__ENCODE_FAILED;
}
if(csiz->effective_bits >= 0 && !inext) {
ASN_DEBUG("Encoding %" ASN_PRI_SIZE " bytes (%ld), length in %d bits", st->size,
size_in_units - csiz->lower_bound, csiz->effective_bits);
ret = per_put_few_bits(po, size_in_units - csiz->lower_bound,
csiz->effective_bits);
if(ret) ASN__ENCODE_FAILED;
ret = OCTET_STRING_per_put_characters(po, st->buf, size_in_units, bpc,
unit_bits, cval->lower_bound,
cval->upper_bound, pc);
if(ret) ASN__ENCODE_FAILED;
ASN__ENCODED_OK(er);
}
ASN_DEBUG("Encoding %" ASN_PRI_SIZE " bytes", st->size);
buf = st->buf;
ASN_DEBUG("Encoding %" ASN_PRI_SIZE " in units", size_in_units);
do {
int need_eom = 0;
ssize_t may_save = uper_put_length(po, size_in_units, &need_eom);
if(may_save < 0) ASN__ENCODE_FAILED;
ASN_DEBUG("Encoding %" ASN_PRI_SSIZE " of %" ASN_PRI_SIZE "%s", may_save, size_in_units,
need_eom ? ",+EOM" : "");
ret = OCTET_STRING_per_put_characters(po, buf, may_save, bpc, unit_bits,
cval->lower_bound,
cval->upper_bound, pc);
if(ret) ASN__ENCODE_FAILED;
buf += may_save * bpc;
size_in_units -= may_save;
assert(!(may_save & 0x07) || !size_in_units);
if(need_eom && uper_put_length(po, 0, 0))
ASN__ENCODE_FAILED; /* End of Message length */
} while(size_in_units);
ASN__ENCODED_OK(er);
}
asn_dec_rval_t
OCTET_STRING_decode_aper(const asn_codec_ctx_t *opt_codec_ctx,
const asn_TYPE_descriptor_t *td,
const asn_per_constraints_t *constraints,
void **sptr, asn_per_data_t *pd) {
const asn_OCTET_STRING_specifics_t *specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
const asn_per_constraints_t *pc = constraints ? constraints
: td->encoding_constraints.per_constraints;
const asn_per_constraint_t *cval;
const asn_per_constraint_t *csiz;
asn_dec_rval_t rval = { RC_OK, 0 };
BIT_STRING_t *st = (BIT_STRING_t *)*sptr;
ssize_t consumed_myself = 0;
int repeat;
enum {
OS__BPC_BIT = 0,
OS__BPC_CHAR = 1,
OS__BPC_U16 = 2,
OS__BPC_U32 = 4
} bpc; /* Bytes per character */
unsigned int unit_bits;
unsigned int canonical_unit_bits;
(void)opt_codec_ctx;
if(pc) {
cval = &pc->value;
csiz = &pc->size;
} else {
cval = &asn_DEF_OCTET_STRING_constraints.value;
csiz = &asn_DEF_OCTET_STRING_constraints.size;
}
switch(specs->subvariant) {
default:
/* case ASN_OSUBV_ANY:
ASN_DEBUG("Unrecognized subvariant %d", specs->subvariant);
RETURN(RC_FAIL);
*/
case ASN_OSUBV_BIT:
canonical_unit_bits = unit_bits = 1;
bpc = OS__BPC_BIT;
break;
case ASN_OSUBV_ANY:
case ASN_OSUBV_STR:
canonical_unit_bits = unit_bits = 8;
/* if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
*/
bpc = OS__BPC_CHAR;
break;
case ASN_OSUBV_U16:
canonical_unit_bits = unit_bits = 16;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_U16;
break;
case ASN_OSUBV_U32:
canonical_unit_bits = unit_bits = 32;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_U32;
break;
}
/*
* Allocate the string.
*/
if(!st) {
st = (BIT_STRING_t *)(*sptr = CALLOC(1, specs->struct_size));
if(!st) RETURN(RC_FAIL);
}
ASN_DEBUG("PER Decoding %s size %ld .. %ld bits %d",
csiz->flags & APC_EXTENSIBLE ? "extensible" : "non-extensible",
csiz->lower_bound, csiz->upper_bound, csiz->effective_bits);
if(csiz->flags & APC_EXTENSIBLE) {
int inext = per_get_few_bits(pd, 1);
if(inext < 0) RETURN(RC_WMORE);
if(inext) {
csiz = &asn_DEF_OCTET_STRING_constraints.size;
cval = &asn_DEF_OCTET_STRING_constraints.value;
unit_bits = canonical_unit_bits;
}
}
if(csiz->effective_bits >= 0) {
FREEMEM(st->buf);
if(bpc) {
st->size = csiz->upper_bound * bpc;
} else {
st->size = (csiz->upper_bound + 7) >> 3;
}
st->buf = (uint8_t *)MALLOC(st->size + 1);
if(!st->buf) { st->size = 0; RETURN(RC_FAIL); }
}
/* X.691, #16.5: zero-length encoding */
/* X.691, #16.6: short fixed length encoding (up to 2 octets) */
/* X.691, #16.7: long fixed length encoding (up to 64K octets) */
if(csiz->effective_bits == 0) {
int ret;
if (st->size > 2) { /* X.691 #16 NOTE 1 */
if (aper_get_align(pd) < 0)
RETURN(RC_FAIL);
}
if(bpc) {
ASN_DEBUG("Decoding OCTET STRING size %ld",
csiz->upper_bound);
ret = OCTET_STRING_per_get_characters(pd, st->buf,
csiz->upper_bound, bpc, unit_bits,
cval->lower_bound, cval->upper_bound, pc);
if(ret > 0) RETURN(RC_FAIL);
} else {
ASN_DEBUG("Decoding BIT STRING size %ld",
csiz->upper_bound);
ret = per_get_many_bits(pd, st->buf, 0,
unit_bits * csiz->upper_bound);
}
if(ret < 0) RETURN(RC_WMORE);
consumed_myself += unit_bits * csiz->upper_bound;
st->buf[st->size] = 0;
if(bpc == 0) {
int ubs = (csiz->upper_bound & 0x7);
st->bits_unused = ubs ? 8 - ubs : 0;
}
RETURN(RC_OK);
}
st->size = 0;
do {
ssize_t raw_len;
ssize_t len_bytes;
ssize_t len_bits;
void *p;
int ret;
/* Get the PER length */
if (csiz->upper_bound - csiz->lower_bound == 0)
/* Indefinite length case */
raw_len = aper_get_length(pd, -1, csiz->effective_bits, &repeat);
else
raw_len = aper_get_length(pd, csiz->upper_bound - csiz->lower_bound + 1, csiz->effective_bits, &repeat);
repeat = 0;
if(raw_len < 0) RETURN(RC_WMORE);
raw_len += csiz->lower_bound;
ASN_DEBUG("Got PER length eb %ld, len %ld, %s (%s)",
(long)csiz->effective_bits, (long)raw_len,
repeat ? "repeat" : "once", td->name);
if (raw_len > 2) { /* X.691 #16 NOTE 1 */
if (aper_get_align(pd) < 0)
RETURN(RC_FAIL);
}
if(bpc) {
len_bytes = raw_len * bpc;
len_bits = len_bytes * unit_bits;
} else {
len_bits = raw_len;
len_bytes = (len_bits + 7) >> 3;
if(len_bits & 0x7)
st->bits_unused = 8 - (len_bits & 0x7);
/* len_bits be multiple of 16K if repeat is set */
}
p = REALLOC(st->buf, st->size + len_bytes + 1);
if(!p) RETURN(RC_FAIL);
st->buf = (uint8_t *)p;
if(bpc) {
ret = OCTET_STRING_per_get_characters(pd,
&st->buf[st->size], raw_len, bpc, unit_bits,
cval->lower_bound, cval->upper_bound, pc);
if(ret > 0) RETURN(RC_FAIL);
} else {
ret = per_get_many_bits(pd, &st->buf[st->size],
0, len_bits);
}
if(ret < 0) RETURN(RC_WMORE);
st->size += len_bytes;
} while(repeat);
st->buf[st->size] = 0; /* nul-terminate */
return rval;
}
asn_enc_rval_t
OCTET_STRING_encode_aper(const asn_TYPE_descriptor_t *td,
const asn_per_constraints_t *constraints,
const void *sptr, asn_per_outp_t *po) {
const asn_OCTET_STRING_specifics_t *specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
const asn_per_constraints_t *pc = constraints ? constraints
: td->encoding_constraints.per_constraints;
const asn_per_constraint_t *cval;
const asn_per_constraint_t *csiz;
const BIT_STRING_t *st = (const BIT_STRING_t *)sptr;
asn_enc_rval_t er = { 0, 0, 0 };
int inext = 0; /* Lies not within extension root */
unsigned int unit_bits;
unsigned int canonical_unit_bits;
unsigned int sizeinunits;
const uint8_t *buf;
int ret;
enum {
OS__BPC_BIT = 0,
OS__BPC_CHAR = 1,
OS__BPC_U16 = 2,
OS__BPC_U32 = 4
} bpc; /* Bytes per character */
int ct_extensible;
if(!st || (!st->buf && st->size))
ASN__ENCODE_FAILED;
if(pc) {
cval = &pc->value;
csiz = &pc->size;
} else {
cval = &asn_DEF_OCTET_STRING_constraints.value;
csiz = &asn_DEF_OCTET_STRING_constraints.size;
}
ct_extensible = csiz->flags & APC_EXTENSIBLE;
switch(specs->subvariant) {
default:
/* case ASN_OSUBV_ANY:
ASN__ENCODE_FAILED;
*/
case ASN_OSUBV_BIT:
canonical_unit_bits = unit_bits = 1;
bpc = OS__BPC_BIT;
sizeinunits = st->size * 8 - (st->bits_unused & 0x07);
ASN_DEBUG("BIT STRING of %d bytes",
sizeinunits);
break;
case ASN_OSUBV_ANY:
case ASN_OSUBV_STR:
canonical_unit_bits = unit_bits = 8;
/* if(cval->flags & APC_CONSTRAINED)
unit_bits = 8;
*/
bpc = OS__BPC_CHAR;
sizeinunits = st->size;
break;
case ASN_OSUBV_U16:
canonical_unit_bits = unit_bits = 16;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_U16;
sizeinunits = st->size / 2;
break;
case ASN_OSUBV_U32:
canonical_unit_bits = unit_bits = 32;
if(cval->flags & APC_CONSTRAINED)
unit_bits = cval->range_bits;
bpc = OS__BPC_U32;
sizeinunits = st->size / 4;
break;
}
ASN_DEBUG("Encoding %s into %d units of %d bits"
" (%ld..%ld, effective %d)%s",
td->name, sizeinunits, unit_bits,
csiz->lower_bound, csiz->upper_bound,
csiz->effective_bits, ct_extensible ? " EXT" : "");
/* Figure out wheter size lies within PER visible constraint */
if(csiz->effective_bits >= 0) {
if((int)sizeinunits < csiz->lower_bound
|| (int)sizeinunits > csiz->upper_bound) {
if(ct_extensible) {
cval = &asn_DEF_OCTET_STRING_constraints.value;
csiz = &asn_DEF_OCTET_STRING_constraints.size;
unit_bits = canonical_unit_bits;
inext = 1;
} else
ASN__ENCODE_FAILED;
}
} else {
inext = 0;
}
if(ct_extensible) {
/* Declare whether length is [not] within extension root */
if(per_put_few_bits(po, inext, 1))
ASN__ENCODE_FAILED;
}
/* X.691, #16.5: zero-length encoding */
/* X.691, #16.6: short fixed length encoding (up to 2 octets) */
/* X.691, #16.7: long fixed length encoding (up to 64K octets) */
if(csiz->effective_bits >= 0) {
ASN_DEBUG("Encoding %lu bytes (%ld), length in %d bits",
st->size, sizeinunits - csiz->lower_bound,
csiz->effective_bits);
if (csiz->effective_bits > 0) {
ret = aper_put_length(po, csiz->upper_bound - csiz->lower_bound + 1, sizeinunits - csiz->lower_bound);
if(ret) ASN__ENCODE_FAILED;
}
/* EB MOD
AFAIU if lb != ub it is aligned whatever the number of bits */
if ((st->size > 2) || (csiz->lower_bound != csiz->upper_bound)) { /* X.691 #16.11 */
if (aper_put_align(po) < 0)
ASN__ENCODE_FAILED;
}
if(bpc) {
ret = OCTET_STRING_per_put_characters(po, st->buf,
sizeinunits, bpc, unit_bits,
cval->lower_bound, cval->upper_bound, pc);
} else {
ret = per_put_many_bits(po, st->buf,
sizeinunits * unit_bits);
}
if(ret) ASN__ENCODE_FAILED;
ASN__ENCODED_OK(er);
}
ASN_DEBUG("Encoding %lu bytes", st->size);
if(sizeinunits == 0) {
if(aper_put_length(po, -1, 0))
ASN__ENCODE_FAILED;
ASN__ENCODED_OK(er);
}
buf = st->buf;
while(sizeinunits) {
ssize_t maySave = aper_put_length(po, -1, sizeinunits);
if(maySave < 0) ASN__ENCODE_FAILED;
ASN_DEBUG("Encoding %ld of %ld",
(long)maySave, (long)sizeinunits);
if(bpc) {
ret = OCTET_STRING_per_put_characters(po, buf,
maySave, bpc, unit_bits,
cval->lower_bound, cval->upper_bound, pc);
} else {
ret = per_put_many_bits(po, buf, maySave * unit_bits);
}
if(ret) ASN__ENCODE_FAILED;
if(bpc)
buf += maySave * bpc;
else
buf += maySave >> 3;
sizeinunits -= maySave;
assert(!(maySave & 0x07) || !sizeinunits);
}
ASN__ENCODED_OK(er);
}
#endif /* ASN_DISABLE_PER_SUPPORT */
int
OCTET_STRING_print(const asn_TYPE_descriptor_t *td, const void *sptr,
int ilevel, asn_app_consume_bytes_f *cb, void *app_key) {
const char * const h2c = "0123456789ABCDEF";
const OCTET_STRING_t *st = (const OCTET_STRING_t *)sptr;
char scratch[16 * 3 + 4];
char *p = scratch;
uint8_t *buf;
uint8_t *end;
size_t i;
(void)td; /* Unused argument */
if(!st || (!st->buf && st->size))
return (cb("<absent>", 8, app_key) < 0) ? -1 : 0;
/*
* Dump the contents of the buffer in hexadecimal.
*/
buf = st->buf;
end = buf + st->size;
for(i = 0; buf < end; buf++, i++) {
if(!(i % 16) && (i || st->size > 16)) {
if(cb(scratch, p - scratch, app_key) < 0)
return -1;
_i_INDENT(1);
p = scratch;
}
*p++ = h2c[(*buf >> 4) & 0x0F];
*p++ = h2c[*buf & 0x0F];
*p++ = 0x20;
}
if(p > scratch) {
p--; /* Remove the tail space */
if(cb(scratch, p - scratch, app_key) < 0)
return -1;
}
return 0;
}
int
OCTET_STRING_print_utf8(const asn_TYPE_descriptor_t *td, const void *sptr,
int ilevel, asn_app_consume_bytes_f *cb,
void *app_key) {
const OCTET_STRING_t *st = (const OCTET_STRING_t *)sptr;
(void)td; /* Unused argument */
(void)ilevel; /* Unused argument */
if(st && (st->buf || !st->size)) {
return (cb(st->buf, st->size, app_key) < 0) ? -1 : 0;
} else {
return (cb("<absent>", 8, app_key) < 0) ? -1 : 0;
}
}
void
OCTET_STRING_free(const asn_TYPE_descriptor_t *td, void *sptr,
enum asn_struct_free_method method) {
OCTET_STRING_t *st = (OCTET_STRING_t *)sptr;
const asn_OCTET_STRING_specifics_t *specs;
asn_struct_ctx_t *ctx;
struct _stack *stck;
if(!td || !st)
return;
specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
ctx = (asn_struct_ctx_t *)((char *)st + specs->ctx_offset);
ASN_DEBUG("Freeing %s as OCTET STRING", td->name);
if(st->buf) {
FREEMEM(st->buf);
st->buf = 0;
}
/*
* Remove decode-time stack.
*/
stck = (struct _stack *)ctx->ptr;
if(stck) {
while(stck->tail) {
struct _stack_el *sel = stck->tail;
stck->tail = sel->prev;
FREEMEM(sel);
}
FREEMEM(stck);
}
switch(method) {
case ASFM_FREE_EVERYTHING:
FREEMEM(sptr);
break;
case ASFM_FREE_UNDERLYING:
break;
case ASFM_FREE_UNDERLYING_AND_RESET:
memset(sptr, 0,
td->specifics
? ((const asn_OCTET_STRING_specifics_t *)(td->specifics))
->struct_size
: sizeof(OCTET_STRING_t));
break;
}
}
/*
* Conversion routines.
*/
int
OCTET_STRING_fromBuf(OCTET_STRING_t *st, const char *str, int len) {
void *buf;
if(st == 0 || (str == 0 && len)) {
errno = EINVAL;
return -1;
}
/*
* Clear the OCTET STRING.
*/
if(str == NULL) {
FREEMEM(st->buf);
st->buf = 0;
st->size = 0;
return 0;
}
/* Determine the original string size, if not explicitly given */
if(len < 0)
len = strlen(str);
/* Allocate and fill the memory */
buf = MALLOC(len + 1);
if(buf == NULL)
return -1;
memcpy(buf, str, len);
((uint8_t *)buf)[len] = '\0'; /* Couldn't use memcpy(len+1)! */
FREEMEM(st->buf);
st->buf = (uint8_t *)buf;
st->size = len;
return 0;
}
OCTET_STRING_t *
OCTET_STRING_new_fromBuf(const asn_TYPE_descriptor_t *td, const char *str,
int len) {
const asn_OCTET_STRING_specifics_t *specs =
td->specifics ? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
OCTET_STRING_t *st;
st = (OCTET_STRING_t *)CALLOC(1, specs->struct_size);
if(st && str && OCTET_STRING_fromBuf(st, str, len)) {
FREEMEM(st);
st = NULL;
}
return st;
}
/*
* Lexicographically compare the common prefix of both strings,
* and if it is the same return -1 for the smallest string.
*/
int
OCTET_STRING_compare(const asn_TYPE_descriptor_t *td, const void *aptr,
const void *bptr) {
const asn_OCTET_STRING_specifics_t *specs = td->specifics;
const OCTET_STRING_t *a = aptr;
const OCTET_STRING_t *b = bptr;
assert(!specs || specs->subvariant != ASN_OSUBV_BIT);
if(a && b) {
size_t common_prefix_size = a->size <= b->size ? a->size : b->size;
int ret = memcmp(a->buf, b->buf, common_prefix_size);
if(ret == 0) {
/* Figure out which string with equal prefixes is longer. */
if(a->size < b->size) {
return -1;
} else if(a->size > b->size) {
return 1;
} else {
return 0;
}
} else {
return ret < 0 ? -1 : 1;
}
} else if(!a && !b) {
return 0;
} else if(!a) {
return -1;
} else {
return 1;
}
}
/*
* Biased function for randomizing character values around their limits.
*/
static uint32_t
OCTET_STRING__random_char(unsigned long lb, unsigned long ub) {
assert(lb <= ub);
switch(asn_random_between(0, 16)) {
case 0:
if(lb < ub) return lb + 1;
/* Fall through */
case 1:
return lb;
case 2:
if(lb < ub) return ub - 1;
/* Fall through */
case 3:
return ub;
default:
return asn_random_between(lb, ub);
}
}
size_t
OCTET_STRING_random_length_constrained(
const asn_TYPE_descriptor_t *td,
const asn_encoding_constraints_t *constraints, size_t max_length) {
const unsigned lengths[] = {0, 1, 2, 3, 4, 8,
126, 127, 128, 16383, 16384, 16385,
65534, 65535, 65536, 65537};
size_t rnd_len;
/* Figure out how far we should go */
rnd_len = lengths[asn_random_between(
0, sizeof(lengths) / sizeof(lengths[0]) - 1)];
if(!constraints || !constraints->per_constraints)
constraints = &td->encoding_constraints;
if(constraints->per_constraints) {
const asn_per_constraint_t *pc = &constraints->per_constraints->size;
if(pc->flags & APC_CONSTRAINED) {
long suggested_upper_bound = pc->upper_bound < (ssize_t)max_length
? pc->upper_bound
: (ssize_t)max_length;
if(max_length <= (size_t)pc->lower_bound) {
return pc->lower_bound;
}
if(pc->flags & APC_EXTENSIBLE) {
switch(asn_random_between(0, 5)) {
case 0:
if(pc->lower_bound > 0) {
rnd_len = pc->lower_bound - 1;
break;
}
/* Fall through */
case 1:
rnd_len = pc->upper_bound + 1;
break;
case 2:
/* Keep rnd_len from the table */
if(rnd_len <= max_length) {
break;
}
/* Fall through */
default:
rnd_len = asn_random_between(pc->lower_bound,
suggested_upper_bound);
}
} else {
rnd_len =
asn_random_between(pc->lower_bound, suggested_upper_bound);
}
} else {
rnd_len = asn_random_between(0, max_length);
}
} else if(rnd_len > max_length) {
rnd_len = asn_random_between(0, max_length);
}
return rnd_len;
}
asn_random_fill_result_t
OCTET_STRING_random_fill(const asn_TYPE_descriptor_t *td, void **sptr,
const asn_encoding_constraints_t *constraints,
size_t max_length) {
const asn_OCTET_STRING_specifics_t *specs = td->specifics
? (const asn_OCTET_STRING_specifics_t *)td->specifics
: &asn_SPC_OCTET_STRING_specs;
asn_random_fill_result_t result_ok = {ARFILL_OK, 1};
asn_random_fill_result_t result_failed = {ARFILL_FAILED, 0};
asn_random_fill_result_t result_skipped = {ARFILL_SKIPPED, 0};
unsigned int unit_bytes = 1;
unsigned long clb = 0; /* Lower bound on char */
unsigned long cub = 255; /* Higher bound on char value */
uint8_t *buf;
uint8_t *bend;
uint8_t *b;
size_t rnd_len;
OCTET_STRING_t *st;
if(max_length == 0 && !*sptr) return result_skipped;
switch(specs->subvariant) {
default:
case ASN_OSUBV_ANY:
return result_failed;
case ASN_OSUBV_BIT:
/* Handled by BIT_STRING itself. */
return result_failed;
case ASN_OSUBV_STR:
unit_bytes = 1;
clb = 0;
cub = 255;
break;
case ASN_OSUBV_U16:
unit_bytes = 2;
clb = 0;
cub = 65535;
break;
case ASN_OSUBV_U32:
unit_bytes = 4;
clb = 0;
cub = 0x10FFFF;
break;
}
if(!constraints || !constraints->per_constraints)
constraints = &td->encoding_constraints;
if(constraints->per_constraints) {
const asn_per_constraint_t *pc = &constraints->per_constraints->value;
if(pc->flags & APC_SEMI_CONSTRAINED) {
clb = pc->lower_bound;
} else if(pc->flags & APC_CONSTRAINED) {
clb = pc->lower_bound;
cub = pc->upper_bound;
}
}
rnd_len =
OCTET_STRING_random_length_constrained(td, constraints, max_length);
buf = CALLOC(unit_bytes, rnd_len + 1);
if(!buf) return result_failed;
bend = &buf[unit_bytes * rnd_len];
switch(unit_bytes) {
case 1:
for(b = buf; b < bend; b += unit_bytes) {
*(uint8_t *)b = OCTET_STRING__random_char(clb, cub);
}
*(uint8_t *)b = 0;
break;
case 2:
for(b = buf; b < bend; b += unit_bytes) {
uint32_t code = OCTET_STRING__random_char(clb, cub);
b[0] = code >> 8;
b[1] = code;
}
*(uint16_t *)b = 0;
break;
case 4:
for(b = buf; b < bend; b += unit_bytes) {
uint32_t code = OCTET_STRING__random_char(clb, cub);
b[0] = code >> 24;
b[1] = code >> 16;
b[2] = code >> 8;
b[3] = code;
}
*(uint32_t *)b = 0;
break;
}
if(*sptr) {
st = *sptr;
FREEMEM(st->buf);
} else {
st = (OCTET_STRING_t *)(*sptr = CALLOC(1, specs->struct_size));
if(!st) {
FREEMEM(buf);
return result_failed;
}
}
st->buf = buf;
st->size = unit_bytes * rnd_len;
result_ok.length = st->size;
return result_ok;
}