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/*
* Copyright (C) 2012 Tobias Brunner
* Copyright (C) 2008 Martin Willi
* Hochschule fuer Technik Rapperswil
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 2 of the License, or (at your
* option) any later version. See <http://www.fsf.org/copyleft/gpl.txt>.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
* or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* for more details.
*/
#include <string.h>
#include "xcbc.h"
#include <utils/debug.h>
#include <crypto/mac.h>
#include <crypto/prfs/mac_prf.h>
#include <crypto/signers/mac_signer.h>
typedef struct private_mac_t private_mac_t;
/**
* Private data of a mac_t object.
*
* The variable names are the same as in the RFC.
*/
struct private_mac_t {
/**
* Public mac_t interface.
*/
mac_t public;
/**
* Block size, in bytes
*/
u_int8_t b;
/**
* crypter using k1
*/
crypter_t *k1;
/**
* k2
*/
u_int8_t *k2;
/**
* k3
*/
u_int8_t *k3;
/**
* E
*/
u_int8_t *e;
/**
* remaining, unprocessed bytes in append mode
*/
u_int8_t *remaining;
/**
* number of bytes in remaining
*/
int remaining_bytes;
/**
* TRUE if we have zero bytes to xcbc in final()
*/
bool zero;
};
/**
* xcbc supplied data, but do not run final operation
*/
static bool update(private_mac_t *this, chunk_t data)
{
chunk_t iv;
if (data.len)
{
this->zero = FALSE;
}
if (this->remaining_bytes + data.len <= this->b)
{ /* no complete block, just copy into remaining */
memcpy(this->remaining + this->remaining_bytes, data.ptr, data.len);
this->remaining_bytes += data.len;
return TRUE;
}
iv = chunk_alloca(this->b);
memset(iv.ptr, 0, iv.len);
/* (3) For each block M[i], where i = 1 ... n-1:
* XOR M[i] with E[i-1], then encrypt the result with Key K1,
* yielding E[i].
*/
/* append data to remaining bytes, process block M[1] */
memcpy(this->remaining + this->remaining_bytes, data.ptr,
this->b - this->remaining_bytes);
data = chunk_skip(data, this->b - this->remaining_bytes);
memxor(this->e, this->remaining, this->b);
if (!this->k1->encrypt(this->k1, chunk_create(this->e, this->b), iv, NULL))
{
return FALSE;
}
/* process blocks M[2] ... M[n-1] */
while (data.len > this->b)
{
memcpy(this->remaining, data.ptr, this->b);
data = chunk_skip(data, this->b);
memxor(this->e, this->remaining, this->b);
if (!this->k1->encrypt(this->k1, chunk_create(this->e, this->b),
iv, NULL))
{
return FALSE;
}
}
/* store remaining bytes of block M[n] */
memcpy(this->remaining, data.ptr, data.len);
this->remaining_bytes = data.len;
return TRUE;
}
/**
* run last round, data is in this->e
*/
static bool final(private_mac_t *this, u_int8_t *out)
{
chunk_t iv;
iv = chunk_alloca(this->b);
memset(iv.ptr, 0, iv.len);
/* (4) For block M[n]: */
if (this->remaining_bytes == this->b && !this->zero)
{
/* a) If the blocksize of M[n] is 128 bits:
* XOR M[n] with E[n-1] and Key K2, then encrypt the result with
* Key K1, yielding E[n].
*/
memxor(this->e, this->remaining, this->b);
memxor(this->e, this->k2, this->b);
}
else
{
/* b) If the blocksize of M[n] is less than 128 bits:
*
* i) Pad M[n] with a single "1" bit, followed by the number of
* "0" bits (possibly none) required to increase M[n]'s
* blocksize to 128 bits.
*/
if (this->remaining_bytes < this->b)
{
this->remaining[this->remaining_bytes] = 0x80;
while (++this->remaining_bytes < this->b)
{
this->remaining[this->remaining_bytes] = 0x00;
}
}
/* ii) XOR M[n] with E[n-1] and Key K3, then encrypt the result
* with Key K1, yielding E[n].
*/
memxor(this->e, this->remaining, this->b);
memxor(this->e, this->k3, this->b);
}
if (!this->k1->encrypt(this->k1, chunk_create(this->e, this->b), iv, NULL))
{
return FALSE;
}
memcpy(out, this->e, this->b);
/* (2) Define E[0] = 0x00000000000000000000000000000000 */
memset(this->e, 0, this->b);
this->remaining_bytes = 0;
this->zero = TRUE;
return TRUE;
}
METHOD(mac_t, get_mac, bool,
private_mac_t *this, chunk_t data, u_int8_t *out)
{
/* update E, do not process last block */
if (!update(this, data))
{
return FALSE;
}
if (out)
{ /* if not in append mode, process last block and output result */
return final(this, out);
}
return TRUE;
}
METHOD(mac_t, get_mac_size, size_t,
private_mac_t *this)
{
return this->b;
}
METHOD(mac_t, set_key, bool,
private_mac_t *this, chunk_t key)
{
chunk_t iv, k1, lengthened;
memset(this->e, 0, this->b);
this->remaining_bytes = 0;
this->zero = TRUE;
/* we support variable keys from RFC4434 */
if (key.len == this->b)
{
lengthened = key;
}
else if (key.len < this->b)
{ /* pad short keys */
lengthened = chunk_alloca(this->b);
memset(lengthened.ptr, 0, lengthened.len);
memcpy(lengthened.ptr, key.ptr, key.len);
}
else
{ /* shorten key using xcbc */
lengthened = chunk_alloca(this->b);
memset(lengthened.ptr, 0, lengthened.len);
if (!set_key(this, lengthened) ||
!get_mac(this, key, lengthened.ptr))
{
return FALSE;
}
}
k1 = chunk_alloca(this->b);
iv = chunk_alloca(this->b);
memset(iv.ptr, 0, iv.len);
/*
* (1) Derive 3 128-bit keys (K1, K2 and K3) from the 128-bit secret
* key K, as follows:
* K1 = 0x01010101010101010101010101010101 encrypted with Key K
* K2 = 0x02020202020202020202020202020202 encrypted with Key K
* K3 = 0x03030303030303030303030303030303 encrypted with Key K
*/
memset(k1.ptr, 0x01, this->b);
memset(this->k2, 0x02, this->b);
memset(this->k3, 0x03, this->b);
if (!this->k1->set_key(this->k1, lengthened) ||
!this->k1->encrypt(this->k1, chunk_create(this->k2, this->b), iv, NULL) ||
!this->k1->encrypt(this->k1, chunk_create(this->k3, this->b), iv, NULL) ||
!this->k1->encrypt(this->k1, k1, iv, NULL) ||
!this->k1->set_key(this->k1, k1))
{
memwipe(k1.ptr, k1.len);
return FALSE;
}
memwipe(k1.ptr, k1.len);
return TRUE;
}
METHOD(mac_t, destroy, void,
private_mac_t *this)
{
this->k1->destroy(this->k1);
memwipe(this->k2, this->b);
free(this->k2);
memwipe(this->k3, this->b);
free(this->k3);
free(this->e);
free(this->remaining);
free(this);
}
/*
* Described in header
*/
static mac_t *xcbc_create(encryption_algorithm_t algo, size_t key_size)
{
private_mac_t *this;
crypter_t *crypter;
u_int8_t b;
crypter = lib->crypto->create_crypter(lib->crypto, algo, key_size);
if (!crypter)
{
return NULL;
}
b = crypter->get_block_size(crypter);
/* input and output of crypter must be equal for xcbc */
if (b != key_size)
{
crypter->destroy(crypter);
return NULL;
}
INIT(this,
.public = {
.get_mac = _get_mac,
.get_mac_size = _get_mac_size,
.set_key = _set_key,
.destroy = _destroy,
},
.b = b,
.k1 = crypter,
.k2 = malloc(b),
.k3 = malloc(b),
.e = malloc(b),
.remaining = malloc(b),
.zero = TRUE,
);
memset(this->e, 0, b);
return &this->public;
}
/*
* Described in header.
*/
prf_t *xcbc_prf_create(pseudo_random_function_t algo)
{
mac_t *xcbc;
switch (algo)
{
case PRF_AES128_XCBC:
xcbc = xcbc_create(ENCR_AES_CBC, 16);
break;
case PRF_CAMELLIA128_XCBC:
xcbc = xcbc_create(ENCR_CAMELLIA_CBC, 16);
break;
default:
return NULL;
}
if (xcbc)
{
return mac_prf_create(xcbc);
}
return NULL;
}
/*
* Described in header
*/
signer_t *xcbc_signer_create(integrity_algorithm_t algo)
{
size_t trunc;
mac_t *xcbc;
switch (algo)
{
case AUTH_AES_XCBC_96:
xcbc = xcbc_create(ENCR_AES_CBC, 16);
trunc = 12;
break;
case AUTH_CAMELLIA_XCBC_96:
xcbc = xcbc_create(ENCR_CAMELLIA_CBC, 16);
trunc = 12;
break;
default:
return NULL;
}
if (xcbc)
{
return mac_signer_create(xcbc, trunc);
}
return NULL;
}
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