int main(void) {
uint8_t k[32] = {0};
for (int i = 0; i < 32; i++) {
k[i] = 0; // (uint8_t)i;
}
uint8_t nc[32] = {0};
for (int i = 0; i < 24; i++) {
nc[i] = 0; //(uint8_t)(255 - i);
}
printf("k = ");
hexprint(k, 32);
printf("\nn = ");
hexprint(nc, 24);
uint32_t ks[120] = {0};
Rijndael_k32b32_expandkey(ks, k);
uint8_t* E = valloc(1024*32);
if (E == NULL) {
abort();
}
memset(E, 0, 1024*32);
Rijndael_b32_ecb(ks, E, nc);
// Rijndael_k32b32_encrypt_x1(ks, E, nc);
// Rijndael_k32b32_ctr(ks, E, E, nc, 1);
printf("\nE = ");
hexprint(E, 32);//1024*32);
printf("\nnc= ");
hexprint(nc, 32);
free(E);
}
//------------------------------------------------------------------------------
int
compare_buffer(const uint8_t *buffer, const uint32_t length_buffer,
const uint8_t *pattern, const uint32_t length_pattern)
//------------------------------------------------------------------------------
{
int i;
if (length_buffer != length_pattern) {
printf("Length mismatch, expecting %d bytes, got %d bytes\n", length_pattern,
length_buffer);
hexprint(buffer, length_buffer);
return -1;
}
for (i = 0; i < length_buffer; i++) {
if (pattern[i] != buffer[i]) {
printf("Expecting:\n");
hexprint(pattern, length_pattern);
printf("Received:\n");
hexprint(buffer, length_buffer);
printf("Mismatch fount in byte %d\nExpecting 0x%02x, got 0x%02x\n",
i, pattern[i], buffer[i]);
return -1;
}
}
return 0;
}
static
isoprint (struct sockaddr_iso *siso, char *bp)
{
int didone = 0;
if (siso -> siso_plen) {
hexprint (bp, siso -> siso_plen, PSEL (siso), "'", "'H");
bp += strlen (bp);
*bp++ = '/';
didone++;
}
if (siso -> siso_slen || didone) {
hexprint (bp, siso -> siso_slen, SSEL (siso), "'", "'H");
bp += strlen (bp);
*bp++ = '/';
didone++;
}
if (siso -> siso_tlen || didone) {
hexprint (bp, siso -> siso_tlen, TSEL (siso), "'", "'H");
bp += strlen (bp);
*bp++ = '/';
didone++;
}
hexprint (bp, siso -> siso_nlen, siso -> siso_data, "NS+", "");
}
static void print_bitval(FILE *f, const struct msrbits *mb, const struct msr val) {
uint8_t i;
struct msr tmp, mask = MSR1(1);
const struct msrbitvalues *mbv = mb->bitval;
while (mbv->text && !msr_eq(mbv->value, val))
mbv++;
switch (mb->present) {
case PRESENT_BIN:
mask = msr_shl(mask, mb->size - 1);
for (i = 0; i < mb->size; i++) {
memcpy(&tmp, &val, sizeof(val));
msr_and(&tmp, mask);
fprintf(f, "%d", (tmp.hi || tmp.lo) ? 1 : 0);
mask = msr_shr(mask, 1);
}
break;
case PRESENT_DEC:
fprintf(f, "%d", val.lo);
break;
case PRESENT_OCT:
fprintf(f, "0%o", val.lo);
break;
case PRESENT_HEX:
hexprint(f, val, mb->size);
break;
case PRESENT_HEXDEC:
hexprint(f, val, mb->size);
fprintf(f, " %d", val.lo);
break;
}
if (mbv->text)
fprintf(f, ": %s", mbv->text);
fprintf(f, "\n");
}
watchdog_interrupt(void)
{
#ifdef CONTIKI_TARGET_SKY
#if PRINT_STACK_ON_REBOOT
uint8_t dummy;
static uint8_t *ptr;
static int i;
ptr = &dummy;
printstring("Watchdog reset");
printstring("\nStack at $");
hexprint(((int)ptr) >> 8);
hexprint(((int)ptr) & 0xff);
printstring(":\n");
for(i = 0; i < 64; ++i) {
hexprint(ptr[i]);
printchar(' ');
if((i & 0x0f) == 0x0f) {
printchar('\n');
}
}
printchar('\n');
#endif /* PRINT_STACK_ON_REBOOT */
#endif /* CONTIKI_TARGET_SKY */
watchdog_reboot();
}
void
doit (void)
{
char digest[20];
int err;
/* XXX: We need this to fix secure memory. */
gnutls_global_init ();
err =
_gnutls_hmac_fast (GNUTLS_MAC_MD5, "keykeykey", 9, "abcdefgh", 8, digest);
if (err < 0)
fail ("_gnutls_hmac_fast(MD5) failed: %d\n", err);
else
{
if (memcmp (digest, "\x3c\xb0\x9d\x83\x28\x01\xef\xc0"
"\x7b\xb3\xaf\x42\x69\xe5\x93\x9a", 16) == 0)
success ("_gnutls_hmac_fast(MD5) OK\n");
else
{
hexprint (digest, 16);
fail ("_gnutls_hmac_fast(MD5) failure\n");
}
}
err =
_gnutls_hmac_fast (GNUTLS_MAC_SHA1, "keykeykey", 9, "abcdefgh", 8,
digest);
if (err < 0)
fail ("_gnutls_hmac_fast(SHA1) failed: %d\n", err);
else
{
if (memcmp (digest, "\x58\x93\x7a\x58\xfe\xea\x82\xf8"
"\x0e\x64\x62\x01\x40\x2b\x2c\xed\x5d\x54\xc1\xfa",
20) == 0)
success ("_gnutls_hmac_fast(SHA1) OK\n");
else
{
hexprint (digest, 20);
fail ("_gnutls_hmac_fast(SHA1) failure\n");
}
}
err = _gnutls_pbkdf2_sha1 ("password", 8, "salt", 4, 4711, digest, 16);
if (err < 0)
fail ("_gnutls_pkcs5_pbkdf2_sha1() failed: %d\n", err);
else
{
if (memcmp (digest, "\x09\xb7\x85\x57\xdd\xf6\x07\x15"
"\x1c\x52\x34\xde\xba\x5c\xdc\x59", 16) == 0)
success ("_gnutls_pkcs5_pbkdf2_sha1() OK\n");
else
{
hexprint (digest, 16);
fail ("_gnutls_pkcs5_pbkdf2_sha1() failure\n");
}
}
gnutls_global_deinit ();
}
void
doit (void)
{
char *out;
size_t i;
for (i = 0; i < sizeof (nfkc) / sizeof (nfkc[0]); i++)
{
if (debug)
printf ("NFKC entry %ld\n", i);
out = stringprep_utf8_nfkc_normalize (nfkc[i].in,
(ssize_t) strlen (nfkc[i].in));
if (out == NULL)
{
fail ("NFKC entry %ld failed fatally\n", i);
continue;
}
if (debug)
{
uint32_t *t;
size_t len;
printf ("in:\n");
escapeprint (nfkc[i].in, strlen (nfkc[i].in));
hexprint (nfkc[i].in, strlen (nfkc[i].in));
binprint (nfkc[i].in, strlen (nfkc[i].in));
printf ("out:\n");
escapeprint (out, strlen (out));
hexprint (out, strlen (out));
binprint (out, strlen (out));
t = stringprep_utf8_to_ucs4 (out, -1, &len);
if (t)
{
ucs4print (t, len);
free (t);
}
printf ("expected out:\n");
escapeprint (nfkc[i].out, strlen (nfkc[i].out));
hexprint (nfkc[i].out, strlen (nfkc[i].out));
binprint (nfkc[i].out, strlen (nfkc[i].out));
}
if (strlen (nfkc[i].out) != strlen (out) ||
memcmp (nfkc[i].out, out, strlen (out)) != 0)
{
fail ("NFKC entry %ld failed\n", i);
if (debug)
printf ("ERROR\n");
}
else if (debug)
printf ("OK\n");
free (out);
}
}
void disp_label()
{
unsigned char serialbuf[26];
union REGS regs;
struct SREGS sregs;
/* First set the dta to be fcb so information returned is put there. */
regs.x.ax = 0x1a00;
regs.x.dx = (unsigned)fcb; /* needs NEAR POINTER */
intdos(®s, ®s);
/* Now try to find the volume label. */
fcb[fcbDRIVE] = *Drive-'A'+1;
regs.x.ax = 0x1100;
regs.x.dx = (unsigned)fcb; /* needs NEAR POINTER */
intdos(®s, ®s);
if (regs.h.al)
{
myprintf("Volume in drive ",0);
myprintf(Drive,1);
myprintf(" has no label\r\n",0);
} /* end if. */
else
{
NoLabel = 0;
fcb[ENDNAME] = '\0';
myprintf("Volume in drive ",0);
myprintf(Drive,1);
myprintf(" is ",0);
myprintf(&fcb[NAME],0);
myprintf("\r\n",0);
} /* end else. */
/* Now print out the volume serial number, if it exists. */
segread(&sregs);
regs.x.ax = 0x6900;
regs.h.bl = *Drive-'A'+1;
regs.x.dx = (unsigned)serialbuf; /* needs NEAR POINTER */
intdosx(®s, ®s, &sregs);
if (!regs.x.cflag)
{
myprintf("Volume serial number is ",0);
hexprint(serialbuf[5]);
hexprint(serialbuf[4]);
myprintf("-",0);
hexprint(serialbuf[3]);
hexprint(serialbuf[2]);
myprintf("\r\n",0);
} /* end if. */
} /* end disp_label. */
static int sha512_monte_carlo_core (
const char *seed,
const char *checks[100]
) {
struct sha512_ctx_t sha;
sha512_init(&sha);
unsigned char md0[64],md1[64],md2[64];
int ret = hexdecode(md0,seed,64);
if (ret) {
youfail();
printf(" SHA-512 NIST Monte Carlo validation seed hex decode failure.\n");
return -1;
}
int i,j;
memcpy(md1,md0,sizeof(md1));
memcpy(md2,md0,sizeof(md1));
for (j=0; j<100; j++) {
for (i=3; i<1003; i++) {
sha512_update(&sha,md0,sizeof(md0));
sha512_update(&sha,md1,sizeof(md1));
sha512_update(&sha,md2,sizeof(md2));
memcpy(md0,md1,sizeof(md1));
memcpy(md1,md2,sizeof(md1));
sha512_final(&sha,md2);
}
ret = hexdecode(md0,checks[j],64);
if (ret) {
youfail();
printf(" SHA-512 NIST Monte Carlo validation hex decode failure at iteration %d\n", j);
return -1;
} else if (memcmp(md0,md2,sizeof(md2))) {
youfail();
printf(" SHA-512 NIST Monte Carlo validation failure at iteration %d\n", j);
hexprint(" Expected", md0, 64);
hexprint(" But got ", md2, 64);
return j+1;
}
memcpy(md0,md2,sizeof(md1));
memcpy(md1,md2,sizeof(md1));
}
return 0;
}
static void
server_finished_callback (gnutls_session_t session,
const void *finished, size_t len)
{
success ("server finished (length %d)\n", len);
hexprint (finished, len);
}
static ssize_t
client_push (gnutls_transport_ptr_t tr, const void *data, size_t len)
{
size_t newlen = to_server_len + len;
char *tmp;
if (debug)
{
success ("client_push len %d has %d\n", (int) len, (int) to_server_len);
hexprint (data, len);
}
tmp = realloc (to_server, newlen);
if (!tmp)
{
fail ("Memory allocation failure...\n");
exit (1);
}
to_server = tmp;
memcpy (to_server + to_server_len, data, len);
to_server_len = newlen;
return len;
}
static int send_msg(struct nlmsghdr *nlh)
{
struct sockaddr_nl nladdr;
void *buf = (void *)nlh;
int r, len = nlh->nlmsg_len;
memset(&nladdr, 0, sizeof(nladdr));
nladdr.nl_family = AF_NETLINK;
do {
if (hexdump) {
printf("SENT A MESSAGE: %d\n", len);
hexprint((char *)nlh, nlh->nlmsg_len);
}
r = sendto(nl_sd, buf, len, 0, (struct sockaddr *)&nladdr,
sizeof(nladdr));
} while (r < 0 && errno == EINTR);
if (r < 0) {
printf("SEND FAILED: %d\n", r);
return 1;
}
else
return 0;
}
int main(int argc, char **argv)
{
int8_t *p;
uint8_t c;
unsigned int key, len, autoboot = 1, dispmenu = 1;
// Initialize UART
uart_init();
while(1){ /* loop forever until u-boot gets booted or the board is reset */
if(dispmenu){
uart_putstr("\n1: Upload program to RAM\r\n");
// uart_putstr("2: Upload u-boot to Dataflash\r\n");
// uart_putstr("3: Upload Kernel to Dataflash\r\n");
// uart_putstr("4: Start u-boot\r\n");
// uart_putstr("5: Upload Filesystem image\r\n");
// uart_putstr("6: Memory test\r\n");
dispmenu = 0;
}
key = uart_getchar();
autoboot = 0;
if(key == '1'){
len = rxmodem((unsigned char *)0x800);
uart_putstr("Received ");
hexprint(len);
uart_putstr(" bytes\r\n");
// jump(0x1000);
dispmenu = 1;
}
else{
uart_putstr("Invalid input\r\n");
dispmenu = 1;
}
}
}
void
doit (void)
{
MD5_CTX c;
unsigned char md[MD5_DIGEST_LENGTH];
if (global_init () != 0)
fail ("global_init\n");
if (!gnutls_check_version (GNUTLS_VERSION))
success ("gnutls_check_version ERROR\n");
MD5_Init (&c);
MD5_Update (&c, "abc", 3);
MD5_Final (&(md[0]), &c);
if (memcmp (md, "\x90\x01\x50\x98\x3c\xd2\x4f\xb0"
"\xd6\x96\x3f\x7d\x28\xe1\x7f\x72", sizeof (md)) != 0)
{
hexprint (md, sizeof (md));
fail ("MD5 failure\n");
}
else if (debug)
success ("MD5 OK\n");
gnutls_global_deinit ();
}
int write_seriport(struct gwseriport *s,char *buf,int len)
{
if(s){
hexprint("seriport send",buf,len);
return write(s->fd,buf,len);
}
return -1;
}
static int drbg_hmac_reseed(DRBG_CTX *dctx,
const unsigned char *ent, size_t ent_len,
const unsigned char *adin, size_t adin_len)
{
if (!drbg_hmac_update(dctx, ent, ent_len, adin, adin_len, NULL, 0))
return 0;
#ifdef HMAC_DRBG_TRACE
{
DRBG_HMAC_CTX *hmac = &dctx->d.hmac;
fprintf(stderr, "K+V after reseed:\n");
hexprint(stderr, hmac->K, hmac->blocklength);
hexprint(stderr, hmac->V, hmac->blocklength);
}
#endif
return 1;
}
int kmain (void)
{
struct xmitimerval req = {{0, 200000}, {0, 0}};
struct xmtimespec st, et;
int count = 0;
long tm;
long baud = 156000;
int ret;
ret = serial_device_init(my_Console_ttyS, baud);
set_timer(&req, 0);
install_event_handler(0, timer_handler);
unmask_event(0);
enable_events_flag();
//rt_serial_write(string, 30);
while (1) {
suspend_domain (0, 0);
do {
ret = rt_serial_read(string, 1024);
if(ret > 0) {
count ++;
if(count == 1) get_time(&st);
else if(count == 100) {
get_time(&et);
write_scr("\n\n", 2);
tm = et.tv_sec-st.tv_sec;
hexprint(tm);
hexprint(et.tv_nsec);
hexprint(st.tv_nsec);
count = 0;
}
}
} while(ret > 0);
}
return 0;
}
int main(int argc, char *argv[])
{
log_verbose();
get_env();
check(argv);
hexprint(argv[1]);
return 0;
}
static void
client_finished_callback (gnutls_session_t session,
const void *finished, size_t len)
{
if (debug)
{
success ("client finished (length %d)\n", (int) len);
hexprint (finished, len);
}
}
static int drbg_hmac_instantiate(DRBG_CTX *dctx,
const unsigned char *ent, size_t ent_len,
const unsigned char *nonce, size_t nonce_len,
const unsigned char *pstr, size_t pstr_len)
{
DRBG_HMAC_CTX *hmac = &dctx->d.hmac;
memset(hmac->K, 0, dctx->blocklength);
memset(hmac->V, 1, dctx->blocklength);
if (!drbg_hmac_update(dctx,
ent, ent_len, nonce, nonce_len, pstr, pstr_len))
return 0;
#ifdef HMAC_DRBG_TRACE
fprintf(stderr, "K+V after instantiate:\n");
hexprint(stderr, hmac->K, hmac->blocklength);
hexprint(stderr, hmac->V, hmac->blocklength);
#endif
return 1;
}
int main(int argc, char* argv[])
{
if(argc == 1){
fputs("error\n",stderr);
exit(1);
}
hexprint(argv[1]);
return 0;
}
static struct nlmsghdr *get_msg(void)
{
struct nlmsghdr *nlh;
int len;
nlh = (struct nlmsghdr *)malloc(MAX_MSG_SIZE);
if (NULL==nlh)
return NULL;
memset(nlh, 0, MAX_MSG_SIZE);
len = recv(nl_sd, (void *)nlh, MAX_MSG_SIZE, 0);
if (len < 0) {
printf("RECEIVE FAILED with %d", errno);
free(nlh);
return NULL;
}
if (!(NLMSG_OK(nlh, (unsigned int)len))) {
printf("RECEIVE FAILED, message too long\n");
free(nlh);
return NULL;
}
if (nlh->nlmsg_type == NLMSG_ERROR) {
struct nlmsgerr *err = (struct nlmsgerr *) NLMSG_DATA(nlh);
printf("RECEIVE FAILED with msg error %i (pid %d): %s\n",
err->error, nlh->nlmsg_pid, strerror(err->error * -1));
if (hexdump && len > 0)
hexprint((char *)nlh, len);
free(nlh);
return NULL;
}
if (hexdump) {
printf("RECEIVED A MESSAGE: %d\n", len);
hexprint((char *)nlh, nlh->nlmsg_len);
}
return nlh;
}
int main(int argc, char* argv[])
{
unsigned long dwResult = 0;
unsigned char plainText[BUFFERLENGTH];
unsigned char cipher[BUFFERLENGTH];
unsigned char random[17];
unsigned char encryptrandom[33];
// clear text
memset(plainText, 0, BUFFERLENGTH);
memcpy(plainText, "select * from t0a12 where", BUFFERLENGTH);
// test encrypt
printf("Begin encrypt in TDES_ECB mode...\n");
memset(cipher, 0, BUFFERLENGTH);
crypto(0, plainText, cipher);
printf("Success!\nThe cipher:");
hexprint(stdout, cipher, BUFFERLENGTH);
// test decrypt
printf("Begin decrypt in TDES_ECB mode...\n");
memset(plainText, 0, BUFFERLENGTH);
crypto(1, cipher, plainText);
printf("Success!\nThe plainText:");
hexprint(stdout, plainText, BUFFERLENGTH);
printf("%s",plainText);
// test encryptrand
memset(random, 0, 17);
memset(encryptrandom, 0, 33);
memcpy(random, "FCVK3MP6B0d8TezE", 16);
encryptrand(random, encryptrandom);
hexprint(stdout, random, 16);
printf("\n%s\n", encryptrandom);
return dwResult;
}
static int amr_codec_decoder(const struct PluginCodec_Definition * codec,
void * context,
const void * from,
unsigned * fromLen,
void * to,
unsigned * toLen,
unsigned int * flag)
{
// unsigned int mode;
if( *fromLen < 1 )
return 0;
/* // get the AMR mode from the first nibble of the frame
mode = *(char *)from & 0xF;
// check that the input is long enough for the decoder
if( *fromLen != bytes_per_frame[mode] ) {
fprintf(stderr,"AMR codec: packet size %u doesn't match expected %u for mode %u\n", *fromLen,bytes_per_frame[mode], mode );
return 0;
}
*/
Decoder_Interface_Decode( context, (void *)from, (short *)to, 0 );
#if 0
fprintf(stderr,"Decoded AMR frame [");
hexprint(from,*fromLen);
fprintf(stderr,"]\nResult: [");
hexprint(to,40);
fprintf(stderr,"...]\n");
#endif
// return the number of decoded bytes to the caller
*toLen = 160*sizeof(short);
return 1;
}
/* idx == -1 indicates main key
* otherwise the subkey.
*/
static void
print_key_fingerprint (gnutls_buffer_st * str, gnutls_openpgp_crt_t cert)
{
char fpr[128];
size_t fpr_size = sizeof (fpr);
int err;
err = gnutls_openpgp_crt_get_fingerprint (cert, fpr, &fpr_size);
if (err < 0)
addf (str, "error: get_fingerprint: %s\n", gnutls_strerror (err));
else
{
adds (str, _("\tFingerprint (hex): "));
hexprint (str, fpr, fpr_size);
addf (str, "\n");
}
}
char *ft_xitoa(long unsigned int n, char c)
{
char *str;
size_t i;
i = len_str(n);
str = ft_strnew(i);
if (str)
{
if (!n)
str[0] = '0';
while (n)
{
str[--i] = hexprint(n, c);
n = n / 16;
}
}
return (str);
}
static void seriportHandler(aeEventLoop *el,int fd,void *privdata,int mask)
{
struct gwseriport *s = privdata;
int nread = buffer_read_append(s->recvbuf,fd);
if(nread == -1){
if(errno == EAGAIN){
return;
}else{
fprintf(stdout,"Read from seriport: %s\n",strerror(errno));
gwseriport_release(s);
return;
}
}else if(nread == 0){
fprintf(stdout,"Seriport closed\n");
gwseriport_release(s);
return;
}
char buf[512] = {0};
int r;
struct sensor_data *sd;
while((r=buffer_read_slip(s->recvbuf,buf,sizeof(buf))) >= 0){
if(r == 0)
continue;
hexprint("read seriport",buf,r);
sd = slip_to_sensor_data(buf,r);
if(sd != NULL){
sensor_data_debug(sd);
snprintf(s->transfer_media,sizeof(s->transfer_media),"%s",sd->transfer_type);
sdlist_check_push(server.global_sensor_data,sd);
json_server_broadcast(sd);
gw_cloud_broadcast(sd);
sensor_data_release(sd);
}else{
fprintf(stderr,"slip_to_sensor_data return NULL\n");
}
}
}
/* idx == -1 indicates main key
* otherwise the subkey.
*/
static void
print_key_id (gnutls_buffer_st * str, gnutls_openpgp_crt_t cert, int idx)
{
gnutls_openpgp_keyid_t id;
int err;
if (idx < 0)
err = gnutls_openpgp_crt_get_key_id (cert, id);
else
err = gnutls_openpgp_crt_get_subkey_id (cert, idx, id);
if (err < 0)
addf (str, "error: get_key_id: %s\n", gnutls_strerror (err));
else
{
adds (str, _("\tID (hex): "));
hexprint (str, id, sizeof (id));
addf (str, "\n");
}
}
std::ostream& operator << ( std::ostream& stream,
const flowgraph::node* n )
{
stream << tobinary( (void*) n ) << " : ";
if( n -> ins )
stream << * ( n -> ins );
else
stream << " ";
stream << " [ ";
for( std::list< flowgraph::node* > :: const_iterator
p = n -> succ. begin( );
p != n -> succ. end( );
++ p )
{
if( p != ( n -> succ. begin( )))
stream << ", ";
stream << tobinary( (void*) *p );
}
stream << " ]";
#if 0
stream << ", back[ ";
for( std::list< flowgraph::node* > :: const_iterator
p = n -> pred. begin( );
p != n -> pred. end( );
++ p )
{
if( p != ( n -> pred. begin( )))
stream << ", ";
hexprint( stream, (void*) *p );
}
stream << " ]";
#endif
return stream;
}
static void decode(const char *test_name, const gnutls_datum_t *raw, const gnutls_datum_t *id,
const gnutls_datum_t *b, unsigned idx, int res)
{
int ret;
psk_ext_parser_st p;
psk_ext_iter_st iter;
struct psk_st psk;
gnutls_datum_t binder;
unsigned found = 0;
unsigned i, j;
ret = _gnutls13_psk_ext_parser_init(&p, raw->data, raw->size);
if (ret < 0) {
if (res == ret) /* expected */
return;
fail("%s: _gnutls13_psk_ext_parser_init: %d/%s\n", test_name, ret, gnutls_strerror(ret));
exit(1);
}
_gnutls13_psk_ext_iter_init(&iter, &p);
for (i = 0; ; i++) {
ret = _gnutls13_psk_ext_iter_next_identity(&iter, &psk);
if (ret < 0) {
if (ret == GNUTLS_E_REQUESTED_DATA_NOT_AVAILABLE)
break;
if (res == ret) /* expected */
return;
}
if (i == idx) {
if (psk.identity.size == id->size && memcmp(psk.identity.data, id->data, id->size) == 0) {
if (debug)
success("%s: found id\n", test_name);
found = 1;
break;
} else {
fail("%s: did not found identity on index %d\n", test_name, idx);
}
}
}
if (found == 0)
fail("%s: did not found identity!\n", test_name);
_gnutls13_psk_ext_iter_init(&iter, &p);
for (j = 0; j <= i; j++) {
ret = _gnutls13_psk_ext_iter_next_binder(&iter, &binder);
if (ret < 0) {
if (res == ret) /* expected */
return;
fail("%s: could not extract binder: %s\n",
test_name, gnutls_strerror(ret));
}
}
if (debug)
success("%s: found binder\n", test_name);
if (binder.size != b->size || memcmp(binder.data, b->data, b->size) != 0) {
hexprint(binder.data, binder.size);
fail("%s: did not match binder on index %d\n", test_name, idx);
}
return;
}
