/****************
* This filter is used to en/de-cipher data with a conventional algorithm
*/
int
cipher_filter( void *opaque, int control,
IOBUF a, byte *buf, size_t *ret_len)
{
size_t size = *ret_len;
cipher_filter_context_t *cfx = opaque;
int rc=0;
if( control == IOBUFCTRL_UNDERFLOW ) { /* decrypt */
rc = -1; /* not yet used */
}
else if( control == IOBUFCTRL_FLUSH ) { /* encrypt */
assert(a);
if( !cfx->header ) {
write_header( cfx, a );
}
if (cfx->mdc_hash)
gcry_md_write (cfx->mdc_hash, buf, size);
gcry_cipher_encrypt (cfx->cipher_hd, buf, size, NULL, 0);
rc = iobuf_write( a, buf, size );
}
else if( control == IOBUFCTRL_FREE ) {
if( cfx->mdc_hash ) {
byte *hash;
int hashlen = gcry_md_get_algo_dlen (gcry_md_get_algo
(cfx->mdc_hash));
byte temp[22];
assert( hashlen == 20 );
/* We must hash the prefix of the MDC packet here. */
temp[0] = 0xd3;
temp[1] = 0x14;
gcry_md_putc (cfx->mdc_hash, temp[0]);
gcry_md_putc (cfx->mdc_hash, temp[1]);
gcry_md_final (cfx->mdc_hash);
hash = gcry_md_read (cfx->mdc_hash, 0);
memcpy(temp+2, hash, 20);
gcry_cipher_encrypt (cfx->cipher_hd, temp, 22, NULL, 0);
gcry_md_close (cfx->mdc_hash); cfx->mdc_hash = NULL;
if( iobuf_write( a, temp, 22 ) )
log_error("writing MDC packet failed\n" );
}
gcry_cipher_close (cfx->cipher_hd);
}
else if( control == IOBUFCTRL_DESC ) {
*(char**)buf = "cipher_filter";
}
return rc;
}
/* final part of the hash */
static uint8_t *hash_finish( gcry_md_hd_t hd, signature_packet_t *p_sig )
{
if( p_sig->version == 3 )
{
gcry_md_putc( hd, p_sig->type );
gcry_md_write( hd, &p_sig->specific.v3.timestamp, 4 );
}
else if( p_sig->version == 4 )
{
gcry_md_putc( hd, p_sig->version );
gcry_md_putc( hd, p_sig->type );
gcry_md_putc( hd, p_sig->public_key_algo );
gcry_md_putc( hd, p_sig->digest_algo );
gcry_md_write( hd, p_sig->specific.v4.hashed_data_len, 2 );
size_t i_len = scalar_number( p_sig->specific.v4.hashed_data_len, 2 );
gcry_md_write( hd, p_sig->specific.v4.hashed_data, i_len );
gcry_md_putc( hd, 0x04 );
gcry_md_putc( hd, 0xFF );
i_len += 6; /* hashed data + 6 bytes header */
gcry_md_putc( hd, (i_len >> 24) & 0xff );
gcry_md_putc( hd, (i_len >> 16) & 0xff );
gcry_md_putc( hd, (i_len >> 8) & 0xff );
gcry_md_putc( hd, (i_len) & 0xff );
}
int _hash_my_key(QSP_ARG_DECL void **vpp,const char *key,int key_len)
{
unsigned char *digest;
unsigned char *storage;
int i;
int need_size;
// get required digest size
need_size = gcry_md_get_algo_dlen(the_hash_algo);
storage = getbuf(need_size);
for(i=0;i<key_len;i++){
gcry_md_putc(my_hash_hdl,key[i]);
}
gcry_md_final(my_hash_hdl);
digest = gcry_md_read(my_hash_hdl,0);
memcpy(storage,digest,need_size);
*vpp = storage;
gcry_md_reset(my_hash_hdl); // to compute a second hash
// or we could close?
// return the length of the hash
// For SHA256, this is 32
return the_hash_len;
}
/*
* This filter is used to en/de-cipher data with a symmetric algorithm
*/
int
cipher_filter_cfb (void *opaque, int control,
iobuf_t a, byte *buf, size_t *ret_len)
{
cipher_filter_context_t *cfx = opaque;
size_t size = *ret_len;
int rc = 0;
if (control == IOBUFCTRL_UNDERFLOW) /* decrypt */
{
rc = -1; /* not yet used */
}
else if (control == IOBUFCTRL_FLUSH) /* encrypt */
{
log_assert (a);
if (!cfx->wrote_header)
write_header (cfx, a);
if (cfx->mdc_hash)
gcry_md_write (cfx->mdc_hash, buf, size);
gcry_cipher_encrypt (cfx->cipher_hd, buf, size, NULL, 0);
if (cfx->short_blklen_warn)
{
cfx->short_blklen_count += size;
if (cfx->short_blklen_count > (150 * 1024 * 1024))
{
log_info ("WARNING: encrypting more than %d MiB with algorithm "
"%s should be avoided\n", 150,
openpgp_cipher_algo_name (cfx->dek->algo));
cfx->short_blklen_warn = 0; /* Don't show again. */
}
}
rc = iobuf_write (a, buf, size);
}
else if (control == IOBUFCTRL_FREE)
{
if (cfx->mdc_hash)
{
byte *hash;
int hashlen = gcry_md_get_algo_dlen (gcry_md_get_algo(cfx->mdc_hash));
byte temp[22];
log_assert (hashlen == 20);
/* We must hash the prefix of the MDC packet here. */
temp[0] = 0xd3;
temp[1] = 0x14;
gcry_md_putc (cfx->mdc_hash, temp[0]);
gcry_md_putc (cfx->mdc_hash, temp[1]);
gcry_md_final (cfx->mdc_hash);
hash = gcry_md_read (cfx->mdc_hash, 0);
memcpy(temp+2, hash, 20);
gcry_cipher_encrypt (cfx->cipher_hd, temp, 22, NULL, 0);
gcry_md_close (cfx->mdc_hash); cfx->mdc_hash = NULL;
if (iobuf_write( a, temp, 22))
log_error ("writing MDC packet failed\n");
}
gcry_cipher_close (cfx->cipher_hd);
}
else if (control == IOBUFCTRL_DESC)
{
mem2str (buf, "cipher_filter_cfb", *ret_len);
}
return rc;
}
static int
iscsi_login_add_chap_response(struct iscsi_context *iscsi, struct iscsi_pdu *pdu)
{
char str[MAX_STRING_SIZE+1];
char * strp;
unsigned char c, cc[2];
unsigned char digest[16];
gcry_md_hd_t ctx;
int i;
if (iscsi->current_phase != ISCSI_PDU_LOGIN_CSG_SECNEG
|| iscsi->secneg_phase != ISCSI_LOGIN_SECNEG_PHASE_SEND_RESPONSE) {
return 0;
}
gcry_md_open(&ctx, GCRY_MD_MD5, 0);
if (!ctx) {
iscsi_set_error(iscsi, "Cannot create MD5 algorithm");
return -1;
}
if (!iscsi->chap_c[0]) {
iscsi_set_error(iscsi, "No CHAP challenge found");
return -1;
}
gcry_md_putc(ctx, iscsi->chap_i);
gcry_md_write(ctx, (unsigned char *)iscsi->passwd, strlen(iscsi->passwd));
strp = iscsi->chap_c;
while (*strp != 0) {
c = (h2i(strp[0]) << 4) | h2i(strp[1]);
strp += 2;
gcry_md_putc(ctx, c);
}
memcpy(digest, gcry_md_read(ctx, 0), sizeof(digest));
gcry_md_close(ctx);
strncpy(str,"CHAP_R=0x",MAX_STRING_SIZE);
if (iscsi_pdu_add_data(iscsi, pdu, (unsigned char *)str, strlen(str))
!= 0) {
iscsi_set_error(iscsi, "Out-of-memory: pdu add data failed.");
return -1;
}
for (i=0; i<16; i++) {
c = digest[i];
cc[0] = i2h((c >> 4)&0x0f);
cc[1] = i2h((c )&0x0f);
if (iscsi_pdu_add_data(iscsi, pdu, &cc[0], 2) != 0) {
iscsi_set_error(iscsi, "Out-of-memory: pdu add data "
"failed.");
return -1;
}
}
c = 0;
if (iscsi_pdu_add_data(iscsi, pdu, &c, 1) != 0) {
iscsi_set_error(iscsi, "Out-of-memory: pdu add data "
"failed.");
return -1;
}
return 0;
}
/* Hash a passphrase using the supplied s2k.
Always needs: dek->algo, s2k->mode, s2k->hash_algo. */
static void
hash_passphrase ( DEK *dek, char *pw, STRING2KEY *s2k)
{
gcry_md_hd_t md;
int pass, i;
int used = 0;
int pwlen = strlen(pw);
assert ( s2k->hash_algo );
dek->keylen = openpgp_cipher_get_algo_keylen (dek->algo);
if ( !(dek->keylen > 0 && dek->keylen <= DIM(dek->key)) )
BUG();
if (gcry_md_open (&md, s2k->hash_algo, 1))
BUG ();
for (pass=0; used < dek->keylen ; pass++ )
{
if ( pass )
{
gcry_md_reset (md);
for (i=0; i < pass; i++ ) /* Preset the hash context. */
gcry_md_putc (md, 0 );
}
if ( s2k->mode == 1 || s2k->mode == 3 )
{
int len2 = pwlen + 8;
ulong count = len2;
if ( s2k->mode == 3 )
{
count = S2K_DECODE_COUNT(s2k->count);
if ( count < len2 )
count = len2;
}
/* Fixme: To avoid DoS attacks by sending an sym-encrypted
packet with a very high S2K count, we should either cap
the iteration count or CPU seconds based timeout. */
/* A little bit complicated because we need a ulong for count. */
while ( count > len2 ) /* maybe iterated+salted */
{
gcry_md_write ( md, s2k->salt, 8 );
gcry_md_write ( md, pw, pwlen );
count -= len2;
}
if ( count < 8 )
gcry_md_write ( md, s2k->salt, count );
else
{
gcry_md_write ( md, s2k->salt, 8 );
count -= 8;
gcry_md_write ( md, pw, count );
}
}
else
gcry_md_write ( md, pw, pwlen );
gcry_md_final( md );
i = gcry_md_get_algo_dlen ( s2k->hash_algo );
if ( i > dek->keylen - used )
i = dek->keylen - used;
memcpy (dek->key+used, gcry_md_read (md, s2k->hash_algo), i);
used += i;
}
gcry_md_close(md);
}
static void
md_bench ( const char *algoname )
{
int algo;
gcry_md_hd_t hd;
int i, j, repcount;
char buf_base[1000+15];
size_t bufsize = 1000;
char *buf;
char *largebuf_base;
char *largebuf;
char digest[512/8];
gcry_error_t err = GPG_ERR_NO_ERROR;
if (!algoname)
{
for (i=1; i < 400; i++)
if (in_fips_mode && i == GCRY_MD_MD5)
; /* Don't use MD5 in fips mode. */
else if ( !gcry_md_test_algo (i) )
md_bench (gcry_md_algo_name (i));
return;
}
buf = buf_base + ((16 - ((size_t)buf_base & 0x0f)) % buffer_alignment);
algo = gcry_md_map_name (algoname);
if (!algo)
{
fprintf (stderr, PGM ": invalid hash algorithm `%s'\n", algoname);
exit (1);
}
err = gcry_md_open (&hd, algo, 0);
if (err)
{
fprintf (stderr, PGM ": error opening hash algorithm `%s'\n", algoname);
exit (1);
}
for (i=0; i < bufsize; i++)
buf[i] = i;
printf ("%-12s", gcry_md_algo_name (algo));
start_timer ();
for (repcount=0; repcount < hash_repetitions; repcount++)
for (i=0; i < 1000; i++)
gcry_md_write (hd, buf, bufsize);
gcry_md_final (hd);
stop_timer ();
printf (" %s", elapsed_time ());
fflush (stdout);
gcry_md_reset (hd);
start_timer ();
for (repcount=0; repcount < hash_repetitions; repcount++)
for (i=0; i < 10000; i++)
gcry_md_write (hd, buf, bufsize/10);
gcry_md_final (hd);
stop_timer ();
printf (" %s", elapsed_time ());
fflush (stdout);
gcry_md_reset (hd);
start_timer ();
for (repcount=0; repcount < hash_repetitions; repcount++)
for (i=0; i < 1000000; i++)
gcry_md_write (hd, buf, 1);
gcry_md_final (hd);
stop_timer ();
printf (" %s", elapsed_time ());
fflush (stdout);
start_timer ();
for (repcount=0; repcount < hash_repetitions; repcount++)
for (i=0; i < 1000; i++)
for (j=0; j < bufsize; j++)
gcry_md_putc (hd, buf[j]);
gcry_md_final (hd);
stop_timer ();
printf (" %s", elapsed_time ());
fflush (stdout);
gcry_md_close (hd);
/* Now 100 hash operations on 10000 bytes using the fast function.
We initialize the buffer so that all memory pages are committed
and we have repeatable values. */
if (gcry_md_get_algo_dlen (algo) > sizeof digest)
die ("digest buffer too short\n");
largebuf_base = malloc (10000+15);
if (!largebuf_base)
die ("out of core\n");
largebuf = (largebuf_base
+ ((16 - ((size_t)largebuf_base & 0x0f)) % buffer_alignment));
for (i=0; i < 10000; i++)
largebuf[i] = i;
start_timer ();
for (repcount=0; repcount < hash_repetitions; repcount++)
for (i=0; i < 100; i++)
gcry_md_hash_buffer (algo, digest, largebuf, 10000);
stop_timer ();
printf (" %s", elapsed_time ());
free (largebuf_base);
putchar ('\n');
fflush (stdout);
}
gboolean
egg_hkdf_perform (const gchar *hash_algo, gconstpointer input, gsize n_input,
gconstpointer salt, gsize n_salt, gconstpointer info,
gsize n_info, gpointer output, gsize n_output)
{
gpointer alloc = NULL;
gpointer buffer = NULL;
gcry_md_hd_t md1, md2;
guint hash_len;
gint i;
gint flags, algo;
gsize step, n_buffer;
guchar *at;
gcry_error_t gcry;
algo = gcry_md_map_name (hash_algo);
g_return_val_if_fail (algo != 0, FALSE);
hash_len = gcry_md_get_algo_dlen (algo);
g_return_val_if_fail (hash_len != 0, FALSE);
g_return_val_if_fail (n_output <= 255 * hash_len, FALSE);
/* Buffer we need to for intermediate stuff */
if (gcry_is_secure (input)) {
flags = GCRY_MD_FLAG_SECURE;
buffer = gcry_malloc_secure (hash_len);
} else {
flags = 0;
buffer = gcry_malloc (hash_len);
}
g_return_val_if_fail (buffer, FALSE);
n_buffer = 0;
/* Salt defaults to hash_len zeros */
if (!salt) {
salt = alloc = g_malloc0 (hash_len);
n_salt = hash_len;
}
/* Step 1: Extract */
gcry = gcry_md_open (&md1, algo, GCRY_MD_FLAG_HMAC | flags);
g_return_val_if_fail (gcry == 0, FALSE);
gcry = gcry_md_setkey (md1, salt, n_salt);
g_return_val_if_fail (gcry == 0, FALSE);
gcry_md_write (md1, input, n_input);
/* Step 2: Expand */
gcry = gcry_md_open (&md2, algo, GCRY_MD_FLAG_HMAC | flags);
g_return_val_if_fail (gcry == 0, FALSE);
gcry = gcry_md_setkey (md2, gcry_md_read (md1, algo), hash_len);
g_return_val_if_fail (gcry == 0, FALSE);
gcry_md_close (md1);
at = output;
for (i = 1; i < 256; ++i) {
gcry_md_reset (md2);
gcry_md_write (md2, buffer, n_buffer);
gcry_md_write (md2, info, n_info);
gcry_md_putc (md2, i);
n_buffer = hash_len;
memcpy (buffer, gcry_md_read (md2, algo), n_buffer);
step = MIN (n_buffer, n_output);
memcpy (at, buffer, step);
n_output -= step;
at += step;
if (!n_output)
break;
}
g_free (alloc);
gcry_free (buffer);
return TRUE;
}
/****************
* Copy data from INP to OUT and do some escaping if requested.
* md is updated as required by rfc2440
*/
int
copy_clearsig_text( IOBUF out, IOBUF inp, gcry_md_hd_t md,
int escape_dash, int escape_from)
{
unsigned int maxlen;
byte *buffer = NULL; /* malloced buffer */
unsigned int bufsize; /* and size of this buffer */
unsigned int n;
int truncated = 0;
int pending_lf = 0;
if( !escape_dash )
escape_from = 0;
write_status_begin_signing (md);
for(;;) {
maxlen = MAX_LINELEN;
n = iobuf_read_line( inp, &buffer, &bufsize, &maxlen );
if( !maxlen )
truncated++;
if( !n )
break; /* read_line has returned eof */
/* update the message digest */
if( escape_dash ) {
if( pending_lf ) {
gcry_md_putc ( md, '\r' );
gcry_md_putc ( md, '\n' );
}
gcry_md_write ( md, buffer,
len_without_trailing_chars (buffer, n, " \t\r\n"));
}
else
gcry_md_write ( md, buffer, n );
pending_lf = buffer[n-1] == '\n';
/* write the output */
if( ( escape_dash && *buffer == '-')
|| ( escape_from && n > 4 && !memcmp(buffer, "From ", 5 ) ) ) {
iobuf_put( out, '-' );
iobuf_put( out, ' ' );
}
#if 0 /*defined(HAVE_DOSISH_SYSTEM)*/
/* We don't use this anymore because my interpretation of rfc2440 7.1
* is that there is no conversion needed. If one decides to
* clearsign a unix file on a DOS box he will get a mixed line endings.
* If at some point it turns out, that a conversion is a nice feature
* we can make an option out of it.
*/
/* make sure the lines do end in CR,LF */
if( n > 1 && ( (buffer[n-2] == '\r' && buffer[n-1] == '\n' )
|| (buffer[n-2] == '\n' && buffer[n-1] == '\r'))) {
iobuf_write( out, buffer, n-2 );
iobuf_put( out, '\r');
iobuf_put( out, '\n');
}
else if( n && buffer[n-1] == '\n' ) {
iobuf_write( out, buffer, n-1 );
iobuf_put( out, '\r');
iobuf_put( out, '\n');
}
else
iobuf_write( out, buffer, n );
#else
iobuf_write( out, buffer, n );
#endif
}
/* at eof */
if( !pending_lf ) { /* make sure that the file ends with a LF */
iobuf_writestr( out, LF );
if( !escape_dash )
gcry_md_putc( md, '\n' );
}
if( truncated )
log_info(_("input line longer than %d characters\n"), MAX_LINELEN );
return 0; /* okay */
}
