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/**
* (C) 2007-18 - ntop.org and contributors
*
* 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 3 of the License, or
* (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not see see <http://www.gnu.org/licenses/>
*
*/
#include "n2n.h"
#include "n2n_transforms.h"
#ifdef N2N_HAVE_AES
#include <openssl/aes.h>
#include <openssl/sha.h>
#include <openssl/evp.h>
#include <openssl/err.h>
#define N2N_AES_TRANSFORM_VERSION 1 /* version of the transform encoding */
#define N2N_AES_IVEC_SIZE (AES_BLOCK_SIZE)
#define AES256_KEY_BYTES (256/8)
#define AES192_KEY_BYTES (192/8)
#define AES128_KEY_BYTES (128/8)
/* AES plaintext preamble */
#define TRANSOP_AES_VER_SIZE 1 /* Support minor variants in encoding in one module. */
#define TRANSOP_AES_IV_SEED_SIZE 8 /* size of transmitted random part of IV in bytes; leave it set to 8 for now */
#define TRANSOP_AES_IV_PADDING_SIZE (N2N_AES_IVEC_SIZE - TRANSOP_AES_IV_SEED_SIZE)
#define TRANSOP_AES_IV_KEY_BYTES (AES128_KEY_BYTES) /* use AES128 for IV encryption */
#define TRANSOP_AES_PREAMBLE_SIZE (TRANSOP_AES_VER_SIZE + TRANSOP_AES_IV_SEED_SIZE)
typedef unsigned char n2n_aes_ivec_t[N2N_AES_IVEC_SIZE];
typedef struct transop_aes {
EVP_CIPHER_CTX *enc_ctx; /* openssl's reusable evp_* encryption context */
EVP_CIPHER_CTX *dec_ctx; /* openssl's reusable evp_* decryption context */
const EVP_CIPHER *cipher; /* cipher to use: e.g. EVP_aes_128_cbc */
uint8_t key[32]; /* the pure key data for payload encryption & decryption */
AES_KEY iv_enc_key; /* key used to encrypt the IV */
uint8_t iv_pad_val[TRANSOP_AES_IV_PADDING_SIZE]; /* key used to pad the random IV seed to full block size */
} transop_aes_t;
static int transop_deinit_aes(n2n_trans_op_t *arg) {
transop_aes_t *priv = (transop_aes_t *)arg->priv;
EVP_CIPHER_CTX_free(priv->enc_ctx);
EVP_CIPHER_CTX_free(priv->dec_ctx);
if(priv)
free(priv);
return 0;
}
/* get any erorr message out of openssl
taken from https://en.wikibooks.org/wiki/OpenSSL/Error_handling */
char *openssl_err_as_string (void) {
BIO *bio = BIO_new (BIO_s_mem ());
ERR_print_errors (bio);
char *buf = NULL;
size_t len = BIO_get_mem_data (bio, &buf);
char *ret = (char *) calloc (1, 1 + len);
if (ret)
memcpy (ret, buf, len);
BIO_free (bio);
return ret;
}
static void set_aes_cbc_iv(transop_aes_t *priv, n2n_aes_ivec_t ivec, uint64_t iv_seed) {
uint8_t iv_full[N2N_AES_IVEC_SIZE];
/* Extend the seed to full block size with padding value */
memcpy(iv_full, priv->iv_pad_val, TRANSOP_AES_IV_PADDING_SIZE);
memcpy(iv_full + TRANSOP_AES_IV_PADDING_SIZE, &iv_seed, TRANSOP_AES_IV_SEED_SIZE);
/* Encrypt the IV with secret key to make it unpredictable.
* As discussed in https://github.com/ntop/n2n/issues/72, it's important to
* have an unpredictable IV since the initial part of the packet plaintext
* can be easily reconstructed from plaintext headers and used by an attacker
* to perform differential analysis.
*/
AES_ecb_encrypt(iv_full, ivec, &priv->iv_enc_key, AES_ENCRYPT);
}
/** The aes packet format consists of:
*
* - a 8-bit aes encoding version in clear text
* - a 64-bit random IV seed
* - encrypted payload.
*
* [V|II|DDDDDDDDDDDDDDDDDDDDD]
* |<---- encrypted ---->|
*/
static int transop_encode_aes( n2n_trans_op_t * arg,
uint8_t * outbuf,
size_t out_len,
const uint8_t * inbuf,
size_t in_len,
const uint8_t * peer_mac)
{
int len2=-1;
transop_aes_t * priv = (transop_aes_t *)arg->priv;
uint8_t assembly[N2N_PKT_BUF_SIZE] = {0};
if ( in_len <= N2N_PKT_BUF_SIZE) {
if ( (in_len + TRANSOP_AES_PREAMBLE_SIZE) <= out_len) {
int len=-1;
size_t idx=0;
uint64_t iv_seed = 0;
uint8_t padding = 0;
n2n_aes_ivec_t enc_ivec = {0};
traceEvent(TRACE_DEBUG, "encode_aes %lu", in_len);
/* Encode the aes format version. */
encode_uint8( outbuf, &idx, N2N_AES_TRANSFORM_VERSION);
/* Generate and encode the IV seed.
* Using two calls to rand() because RAND_MAX is usually < 64bit
* (e.g. linux) and sometimes < 32bit (e.g. Windows).
*/
iv_seed = ((((uint64_t)rand() & 0xFFFFFFFF)) << 32) | rand();
encode_buf(outbuf, &idx, &iv_seed, TRANSOP_AES_IV_SEED_SIZE);
/* Encrypt the assembly contents and write the ciphertext after the iv seed. */
/* len is set to the length of the cipher plain text to be encrpyted
which is (in this case) identical to original packet lentgh */
len = in_len;
/* The assembly buffer is a source for encrypting data.
* The whole contents of assembly are encrypted. */
memcpy( assembly, inbuf, in_len);
/* Need at least one encrypted byte at the end for the padding. */
len2 = ( (len / AES_BLOCK_SIZE) + 1) * AES_BLOCK_SIZE; /* Round up to next whole AES adding at least one byte. */
padding = (len2-len);
assembly[len2 - 1] = padding;
traceEvent(TRACE_DEBUG, "padding = %u, seed = %016llx", padding, iv_seed);
set_aes_cbc_iv(priv, enc_ivec, iv_seed);
EVP_CIPHER_CTX *ctx = priv->enc_ctx;
int evp_len;
int evp_ciphertext_len;
if (1 == EVP_EncryptInit_ex(ctx, priv->cipher, NULL, priv->key, enc_ivec)) {
if (1 == EVP_CIPHER_CTX_set_padding(ctx, 0)) {
if (1 == EVP_EncryptUpdate(ctx, outbuf + TRANSOP_AES_PREAMBLE_SIZE, &evp_len, assembly, len2)) {
evp_ciphertext_len = evp_len;
if (1 == EVP_EncryptFinal_ex(ctx, outbuf + TRANSOP_AES_PREAMBLE_SIZE + evp_len, &evp_len)) {
evp_ciphertext_len += evp_len;
if ( evp_ciphertext_len != len2)
traceEvent (TRACE_ERROR, "encode_aes openssl encryption: encrypted %u bytes where %u were expected.\n",
evp_ciphertext_len, len2);
} else
traceEvent(TRACE_ERROR, "encode_aes openssl final encryption: %s\n", openssl_err_as_string());
} else
traceEvent(TRACE_ERROR, "encode_aes openssl encrpytion: %s\n", openssl_err_as_string());
} else
traceEvent(TRACE_ERROR, "encode_aes openssl padding setup: %s\n", openssl_err_as_string());
} else
traceEvent(TRACE_ERROR, "encode_aes openssl init: %s\n", openssl_err_as_string());
EVP_CIPHER_CTX_reset(ctx);
len2 += TRANSOP_AES_PREAMBLE_SIZE; /* size of data carried in UDP. */
} else
traceEvent(TRACE_ERROR, "encode_aes outbuf too small.");
} else
traceEvent(TRACE_ERROR, "encode_aes inbuf too big to encrypt.");
return len2;
}
/* See transop_encode_aes for packet format */
static int transop_decode_aes( n2n_trans_op_t * arg,
uint8_t * outbuf,
size_t out_len,
const uint8_t * inbuf,
size_t in_len,
const uint8_t * peer_mac) {
int len=0;
transop_aes_t * priv = (transop_aes_t *)arg->priv;
uint8_t assembly[N2N_PKT_BUF_SIZE];
if ( ( (in_len - TRANSOP_AES_PREAMBLE_SIZE) <= N2N_PKT_BUF_SIZE) /* Cipher text fits in assembly */
&& (in_len >= TRANSOP_AES_PREAMBLE_SIZE) /* Has at least version, iv seed */
)
{
size_t rem=in_len;
size_t idx=0;
uint8_t aes_enc_ver=0;
uint64_t iv_seed=0;
/* Get the encoding version to make sure it is supported */
decode_uint8( &aes_enc_ver, inbuf, &rem, &idx );
if ( N2N_AES_TRANSFORM_VERSION == aes_enc_ver) {
/* Get the IV seed */
decode_buf((uint8_t *)&iv_seed, TRANSOP_AES_IV_SEED_SIZE, inbuf, &rem, &idx);
traceEvent(TRACE_DEBUG, "decode_aes %lu with seed %016llx", in_len, iv_seed);
len = (in_len - TRANSOP_AES_PREAMBLE_SIZE);
if ( 0 == (len % AES_BLOCK_SIZE)) {
uint8_t padding;
n2n_aes_ivec_t dec_ivec = {0};
set_aes_cbc_iv(priv, dec_ivec, iv_seed);
EVP_CIPHER_CTX *ctx = priv->dec_ctx;
int evp_len;
int evp_plaintext_len;
if (1 == EVP_DecryptInit_ex(ctx, priv->cipher, NULL, priv->key, dec_ivec)) {
if (1 == EVP_CIPHER_CTX_set_padding(ctx, 0)) {
if (1 == EVP_DecryptUpdate(ctx, assembly, &evp_len, inbuf + TRANSOP_AES_PREAMBLE_SIZE, len)) {
evp_plaintext_len = evp_len;
if (1 == EVP_DecryptFinal_ex(ctx, assembly + evp_len, &evp_len)) {
evp_plaintext_len += evp_len;
if ( evp_plaintext_len != len)
traceEvent (TRACE_ERROR, "decode_aes openssl decryption: decrypted %u bytes where %u were expected.\n",
evp_plaintext_len, len);
} else
traceEvent(TRACE_ERROR, "decode_aes openssl final decryption: %s\n", openssl_err_as_string());
} else
traceEvent(TRACE_ERROR, "decode_aes openssl decrpytion: %s\n", openssl_err_as_string());
} else
traceEvent(TRACE_ERROR, "decode_aes openssl padding setup: %s\n", openssl_err_as_string());
} else
traceEvent(TRACE_ERROR, "decode_aes openssl init: %s\n", openssl_err_as_string());
EVP_CIPHER_CTX_reset(ctx);
/* last byte is how much was padding: max value should be
* AES_BLOCKSIZE-1 */
padding = assembly[ len-1 ] & 0xff;
if ( len >= padding)
{
/* strictly speaking for this to be an ethernet packet
* it is going to need to be even bigger; but this is
* enough to prevent segfaults. */
traceEvent(TRACE_DEBUG, "padding = %u", padding);
len -= padding;
memcpy( outbuf,
assembly,
len);
} else
traceEvent(TRACE_WARNING, "UDP payload decryption failed.");
} else {
traceEvent(TRACE_WARNING, "Encrypted length %d is not a multiple of AES_BLOCK_SIZE (%d)", len, AES_BLOCK_SIZE);
len = 0;
}
} else
traceEvent(TRACE_ERROR, "decode_aes unsupported aes version %u.", aes_enc_ver);
} else
traceEvent(TRACE_ERROR, "decode_aes inbuf wrong size (%ul) to decrypt.", in_len);
return len;
}
static int setup_aes_key(transop_aes_t *priv, const uint8_t *key, ssize_t key_size) {
size_t aes_key_size_bytes;
size_t aes_key_size_bits;
uint8_t key_mat_buf[SHA512_DIGEST_LENGTH + SHA256_DIGEST_LENGTH];
size_t key_mat_buf_length;
/* Clear out any old possibly longer key matter. */
memset( &(priv->key), 0, sizeof(priv->key) );
memset( &(priv->iv_enc_key), 0, sizeof(priv->iv_enc_key) );
memset( &(priv->iv_pad_val), 0, sizeof(priv->iv_pad_val) );
/* Let the user choose the degree of encryption:
* Long input keys will pick AES192 or AES256 with more robust but expensive encryption.
*
* The input key always gets hashed to make a more unpredictable use of the key space and
* also to derive some additional material (key for IV encrpytion, IV padding).
*
* The following scheme for key setup was discussed on github:
* https://github.com/ntop/n2n/issues/101
*/
/* create a working buffer of maximal occuring hashes size and generate
* the hashes for the aes key material, key_mat_buf_lengh indicates the
* actual "filling level" of the buffer
*/
if (key_size >= 65)
{
priv->cipher = EVP_aes_256_cbc();
aes_key_size_bytes = AES256_KEY_BYTES;
SHA512(key, key_size, key_mat_buf);
key_mat_buf_length = SHA512_DIGEST_LENGTH;
}
else if (key_size >= 44)
{
priv->cipher = EVP_aes_192_cbc();
aes_key_size_bytes = AES192_KEY_BYTES;
SHA384(key, key_size, key_mat_buf);
/* append a hash of the first hash to create enough material for IV padding */
SHA256(key_mat_buf, SHA384_DIGEST_LENGTH, key_mat_buf + SHA384_DIGEST_LENGTH);
key_mat_buf_length = SHA384_DIGEST_LENGTH + SHA256_DIGEST_LENGTH;
}
else
{
priv->cipher = EVP_aes_128_cbc();
aes_key_size_bytes = AES128_KEY_BYTES;
SHA256(key, key_size, key_mat_buf);
/* append a hash of the first hash to create enough material for IV padding */
SHA256(key_mat_buf, SHA256_DIGEST_LENGTH, key_mat_buf + SHA256_DIGEST_LENGTH);
key_mat_buf_length = 2 * SHA256_DIGEST_LENGTH;
}
/* is there enough material available? */
if (key_mat_buf_length < (aes_key_size_bytes + TRANSOP_AES_IV_KEY_BYTES + TRANSOP_AES_IV_PADDING_SIZE))
{
/* this should never happen */
traceEvent( TRACE_ERROR, "AES missing %u bits hashed key material\n",
(aes_key_size_bytes + TRANSOP_AES_IV_KEY_BYTES + TRANSOP_AES_IV_PADDING_SIZE - key_mat_buf_length) * 8);
return(1);
}
/* setup of key, used for the CBC encryption */
aes_key_size_bits = 8 * aes_key_size_bytes;
memcpy (priv->key, key_mat_buf, aes_key_size_bytes);
/* setup of iv_enc_key (AES128 key) and iv_pad_val, used for generating the CBC IV */
AES_set_encrypt_key(key_mat_buf + aes_key_size_bytes, TRANSOP_AES_IV_KEY_BYTES * 8, &(priv->iv_enc_key));
memcpy(priv->iv_pad_val, key_mat_buf + aes_key_size_bytes + TRANSOP_AES_IV_KEY_BYTES, TRANSOP_AES_IV_PADDING_SIZE);
traceEvent(TRACE_DEBUG, "AES %u bits setup completed\n",
aes_key_size_bits);
return(0);
}
static void transop_tick_aes(n2n_trans_op_t * arg, time_t now) {}
/* AES initialization function */
int n2n_transop_aes_cbc_init(const n2n_edge_conf_t *conf, n2n_trans_op_t *ttt) {
transop_aes_t *priv;
const u_char *encrypt_key = (const u_char *)conf->encrypt_key;
size_t encrypt_key_len = strlen(conf->encrypt_key);
memset(ttt, 0, sizeof(*ttt));
ttt->transform_id = N2N_TRANSFORM_ID_AESCBC;
ttt->tick = transop_tick_aes;
ttt->deinit = transop_deinit_aes;
ttt->fwd = transop_encode_aes;
ttt->rev = transop_decode_aes;
priv = (transop_aes_t*) calloc(1, sizeof(transop_aes_t));
if(!priv) {
traceEvent(TRACE_ERROR, "cannot allocate transop_aes_t memory");
return(-1);
}
ttt->priv = priv;
/* Setup openssl's reusable evp_* contexts for encryption and decryption*/
if (!(priv->enc_ctx = EVP_CIPHER_CTX_new())) {
traceEvent(TRACE_ERROR, "openssl's evp_* encryption context creation: %s\n", openssl_err_as_string());
return(-1);
}
if (!(priv->dec_ctx = EVP_CIPHER_CTX_new())) {
traceEvent(TRACE_ERROR, "openssl's evp_* decryption context creation: %s\n", openssl_err_as_string());
return(-1);
}
/* Setup the cipher and key */
return(setup_aes_key(priv, encrypt_key, encrypt_key_len));
}
#endif /* N2N_HAVE_AES */