NetBSD/lib/libkstream/kstream-des.c

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2000-06-17 10:39:32 +04:00
/* $NetBSD: kstream-des.c,v 1.2 2000/06/17 06:39:32 thorpej Exp $ */
/* DES-encrypted-stream implementation for MIT Kerberos.
Written by Ken Raeburn (Raeburn@Cygnus.COM), based on algorithms
in the original MIT Kerberos code.
Copyright (C) 1991, 1992 by Cygnus Support.
This file is distributed under the same terms as Kerberos.
For copying and distribution information, please see the file
<kerberosIV/mit-copyright.h>.
from: kstream-des.c,v 1.9 1996/06/02 07:37:27 ghudson Exp $
*/
#include <assert.h>
#include <stdio.h>
#include <errno.h>
#include <sys/types.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <des.h>
#include <kerberosIV/kstream.h>
typedef struct {
union {
long align_me;
double align_me_harder;
Key_schedule sched;
} u;
des_cblock ivec;
} kstream_des_init_block;
typedef struct {
kstream_des_init_block x;
int no_right_justify;
int protect_rlogin_oob;
char *buf1, *buf2;
size_t len1, len2;
} priv;
typedef struct kstream_data_block ksdb;
/* The data stream consists of four bytes representing a net-order
integer, followed by enough data to produce that many
cleartext bytes. This means the size of that data must be rounded
up to a multiple of 8, even though the cleartext may only be one
byte. For blocks of less than eight bytes, most software (well,
exactly half of the two already-existing programs, and all of the
ones we write using this library :-) pads on the *left* with
random values.
Some existing software that we have to be compatible with may send
blocks of data that decrypt to more than 8 bytes, but not an exact
multiple. In that case, the padding is on the right, as would be
considered "normal". This software currently will not generate such
a sequence, but a future version could. Don't break compatibility
with that mode. */
#ifdef sun
static kstream_ptr losing_realloc (old_ptr, new_size)
kstream_ptr old_ptr;
size_t new_size;
{
return old_ptr ? realloc (old_ptr, new_size) : malloc (new_size);
}
#define realloc losing_realloc
#endif
/* Do the actual encryption work. This routine will handle chunks of
any size up to 16 bytes, or any multiple of 8 over that. It makes
the padding a little easier to write it this way. Handling sizes
between 8 and 16 is an annoyance, but rlogin actually relies on being
able to send 12 bytes in one chunk. Bleah! */
static void
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do_encrypt (ksdb *out, ksdb *inp, priv *p)
{
union {
char buf[16];
int junk[16 / sizeof (int)];
} u;
ksdb in;
char *ptr;
static int seeded;
if (!seeded) {
srandom ((int) time ((time_t *) 0));
seeded = 1;
}
in = *inp;
if (in.length < 8)
{
if (! p->no_right_justify)
{
u.junk[0] = random ();
memcpy (u.buf + 8 - in.length, in.ptr, in.length);
}
else
{
u.junk[(sizeof (u.junk[0]) + 7) / sizeof (u.junk[0]) - 1] = random ();
memcpy (u.buf, in.ptr, in.length);
}
in.ptr = u.buf;
in.length = 8;
}
else if (in.length == 8)
{
memcpy (u.buf, in.ptr, 8);
in.ptr = u.buf;
}
else if (in.length < sizeof (u.buf))
{
if (in.length % 8 == 0)
abort ();
u.junk[(sizeof (u.junk) / sizeof (u.junk[0])) - 1] = random ();
memcpy (u.buf, in.ptr, in.length);
in.ptr = u.buf;
}
else if (in.length % 8 != 0)
abort ();
{
unsigned long x;
x = inp->length; /* not in.length! */
ptr = (char *) out->ptr;
ptr[3] = x & 0xff; x >>= 8;
ptr[2] = x & 0xff; x >>= 8;
ptr[1] = x & 0xff; x >>= 8;
ptr[0] = x & 0xff; x >>= 8;
ptr += 4;
if (x)
abort ();
}
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des_pcbc_encrypt (in.ptr, ptr, in.length,
p->x.u.sched, (des_cblock *)p->x.ivec, 1);
out->ptr = ptr + ((in.length + 7) & ~7);
}
static int
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encrypt (ksdb *outp, ksdb *inp, kstream k)
{
const int small_block_size = 16;
priv *p = (priv *) k->data;
if (inp->length > small_block_size && inp->length % 8 != 0)
{
/* do two */
ksdb in, out;
size_t sz;
in.ptr = inp->ptr;
in.length = inp->length & ~7;
sz = in.length + 4; /* first block */
sz += 8 + 4; /* second block */
outp->length = sz;
out.ptr = outp->ptr = p->buf1 = realloc (p->buf1, sz);
out.length = sz;
assert (out.ptr != 0 || out.length == 0);
do_encrypt (&out, &in, p);
in.ptr = (char *) in.ptr + in.length;
in.length = inp->length - in.length;
do_encrypt (&out, &in, p);
return inp->length;
}
else
{
size_t sz = (inp->length + 7) & ~7;
sz += 4;
outp->length = sz;
outp->ptr = p->buf1 = realloc (p->buf1, sz);
assert (outp->ptr != 0 || outp->length == 0);
do_encrypt (outp, inp, p);
outp->ptr = p->buf1;
return inp->length;
}
}
int _kstream_des_debug_OOB = 0;
static int
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decrypt (ksdb *outp, ksdb *inp, kstream k)
{
char *ptr = inp->ptr;
unsigned long x = 0;
int error_count = 0;
size_t sz;
priv *p = (priv *) k->data;
if(inp->length < 1) return -12; /* make sure we have at least one byte */
if (p->protect_rlogin_oob) {
/* here's where we handle an attack. The first byte ends up being the
highest. If it's not zero, skip it. If it is zero, we can't detect it,
and we still lose... */
x = *ptr & 0xff; /* get the first char */
while (x) {
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if(_kstream_des_debug_OOB) fprintf(stderr,"BAD BYTE %02lx\n\r", x);
error_count++; /* count the bad byte */
ptr++; /* and skip it */
if(inp->length == error_count) {
return -12; /* we've used up all of the input */
}
x = *ptr & 0xff; /* get the next potentially first char */
}
ptr++;
} else {
x <<= 8; x += *ptr++ & 0xff;
}
/* If we've got four bytes, we can at least determine the correct
amount that still needs to be read. If not, we can assume a
minimum of 12 good bytes (4-byte length plus one 8-byte block)
and we know how many of the ones we've got are bad. */
if (inp->length < 4 + error_count)
return inp->length - error_count - 12;
/* x <<= 8; x += *ptr++ & 0xff; */ /* x already has first byte loaded */
x <<= 8; x += *ptr++ & 0xff;
x <<= 8; x += *ptr++ & 0xff;
x <<= 8; x += *ptr++ & 0xff;
sz = (x + 7) & ~7;
if (inp->length < sz + 4 + error_count)
return - (sz + 4 + error_count - inp->length);
assert (sz <= sizeof (k->in_crypt.data));
if (p->buf1)
p->buf1 = realloc (p->buf1, sz);
else
p->buf1 = malloc (sz);
assert (p->buf1 != 0 || sz == 0);
outp->ptr = p->buf1;
outp->length = x;
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pcbc_encrypt (ptr, outp->ptr, sz, p->x.u.sched,
(des_cblock *)p->x.ivec, 0);
if (p->no_right_justify == 0
&& x < 8)
outp->ptr = p->buf1 + 8 - x;
return sz + 4 + error_count;
}
static int
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init (kstream k, void *data)
{
priv *p;
p = (priv *) malloc (sizeof (priv));
k->data = (kstream_ptr) p;
if (!p)
return errno;
p->buf1 = p->buf2 = 0;
p->len1 = p->len2 = 0;
p->no_right_justify = 0;
p->protect_rlogin_oob = 0;
p->x = * (kstream_des_init_block *) data;
return 0;
}
static int
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rcp_init (kstream k, void *data)
{
int x = init (k, data);
((priv *)(k->data))->no_right_justify = 1;
return x;
}
static int
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rlogin_init (kstream k, void *data)
{
int x = init (k, data);
((priv *)(k->data))->protect_rlogin_oob = 1;
return x;
}
static void
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destroy (kstream k)
{
priv *p = (priv *) k->data;
if (p->buf1)
free (p->buf1);
memset (p, '\\', sizeof (*p)); /* scribble to make sure it's gone */
free (p);
k->data = 0;
}
static const struct kstream_crypt_ctl_block kstream_des_ccb = {
encrypt, decrypt, rlogin_init, destroy
};
static const struct kstream_crypt_ctl_block kstream_des_rcp_ccb = {
encrypt, decrypt, rcp_init, destroy
};
kstream
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kstream_create_rlogin_from_fd (int fd, kstream_ptr P_sched,
des_cblock (*ivec))
{
Key_schedule *sched = (Key_schedule *) P_sched;
kstream_des_init_block x;
kstream k;
memcpy (&x.u.sched, sched, sizeof (Key_schedule));
memcpy (&x.ivec, ivec, sizeof (des_cblock));
k = kstream_create_from_fd (fd, &kstream_des_ccb, &x);
memset (&x, '\\', sizeof (x));
return k;
}
kstream
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kstream_create_rcp_from_fd (int fd, kstream_ptr P_sched,
des_cblock (*ivec))
{
Key_schedule *sched = (Key_schedule *) P_sched;
kstream_des_init_block x;
kstream k;
memcpy (&x.u.sched, sched, sizeof (Key_schedule));
memcpy (&x.ivec, ivec, sizeof (des_cblock));
k = kstream_create_from_fd (fd, &kstream_des_rcp_ccb, &x);
memset (&x, '\\', sizeof (x));
return k;
}