/*
* OpenVPN -- An application to securely tunnel IP networks
* over a single TCP/UDP port, with support for SSL/TLS-based
* session authentication and key exchange,
* packet encryption, packet authentication, and
* packet compression.
*
* Copyright (C) 2002-2009 OpenVPN Technologies, Inc. <sales@openvpn.net>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2
* as published by the Free Software Foundation.
*
* 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 (see the file COPYING included with this
* distribution); if not, write to the Free Software Foundation, Inc.,
* 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include "syshead.h"
#ifdef USE_CRYPTO
#include "crypto.h"
#include "error.h"
#include "misc.h"
#include "thread.h"
#include "memdbg.h"
/*
* Check for key size creepage.
*/
#if MAX_CIPHER_KEY_LENGTH < EVP_MAX_KEY_LENGTH
#warning Some OpenSSL EVP ciphers now support key lengths greater than MAX_CIPHER_KEY_LENGTH -- consider increasing MAX_CIPHER_KEY_LENGTH
#endif
#if MAX_HMAC_KEY_LENGTH < EVP_MAX_MD_SIZE
#warning Some OpenSSL HMAC message digests now support key lengths greater than MAX_HMAC_KEY_LENGTH -- consider increasing MAX_HMAC_KEY_LENGTH
#endif
/*
* Encryption and Compression Routines.
*
* On entry, buf contains the input data and length.
* On exit, it should be set to the output data and length.
*
* If buf->len is <= 0 we should return
* If buf->len is set to 0 on exit it tells the caller to ignore the packet.
*
* work is a workspace buffer we are given of size BUF_SIZE.
* work may be used to return output data, or the input buffer
* may be modified and returned as output. If output data is
* returned in work, the data should start after FRAME_HEADROOM bytes
* of padding to leave room for downstream routines to prepend.
*
* Up to a total of FRAME_HEADROOM bytes may be prepended to the input buf
* by all routines (encryption, decryption, compression, and decompression).
*
* Note that the buf_prepend return will assert if we try to
* make a header bigger than FRAME_HEADROOM. This should not
* happen unless the frame parameters are wrong.
*/
#define CRYPT_ERROR(format) \
do { msg (D_CRYPT_ERRORS, "%s: " format, error_prefix); goto error_exit; } while (false)
void
openvpn_encrypt (struct buffer *buf, struct buffer work,
const struct crypto_options *opt,
const struct frame* frame)
{
struct gc_arena gc;
gc_init (&gc);
if (buf->len > 0 && opt->key_ctx_bi)
{
struct key_ctx *ctx = &opt->key_ctx_bi->encrypt;
/* Do Encrypt from buf -> work */
if (ctx->cipher)
{
uint8_t iv_buf[EVP_MAX_IV_LENGTH];
const int iv_size = EVP_CIPHER_CTX_iv_length (ctx->cipher);
const unsigned int mode = EVP_CIPHER_CTX_mode (ctx->cipher);
int outlen;
if (mode == EVP_CIPH_CBC_MODE)
{
CLEAR (iv_buf);
/* generate pseudo-random IV */
if (opt->flags & CO_USE_IV)
prng_bytes (iv_buf, iv_size);
/* Put packet ID in plaintext buffer or IV, depending on cipher mode */
if (opt->packet_id)
{
struct packet_id_net pin;
packet_id_alloc_outgoing (&opt->packet_id->send, &pin, BOOL_CAST (opt->flags & CO_PACKET_ID_LONG_FORM));
ASSERT (packet_id_write (&pin, buf, BOOL_CAST (opt->flags & CO_PACKET_ID_LONG_FORM), true));
}
}
else if (mode == EVP_CIPH_CFB_MODE || mode == EVP_CIPH_OFB_MODE)
{
struct packet_id_net pin;
struct buffer b;
ASSERT (opt->flags & CO_USE_IV); /* IV and packet-ID required */
ASSERT (opt->packet_id); /* for this mode. */
packet_id_alloc_outgoing (&opt->packet_id->send, &pin, true);
memset (iv_buf, 0, iv_size);
buf_set_write (&b, iv_buf, iv_size);
ASSERT (packet_id_write (&pin, &b, true, false));
}
else /* We only support CBC, CFB, or OFB modes right now */
{
ASSERT (0);
}
/* initialize work buffer with FRAME_HEADROOM bytes of prepend capacity */
ASSERT (buf_init (&work, FRAME_HEADROOM (frame)));
/* set the IV pseudo-randomly */
if (opt->flags & CO_USE_IV)
dmsg (D_PACKET_CONTENT, "ENCRYPT IV: %s", format_hex (iv_buf, iv_size, 0, &gc));
dmsg (D_PACKET_CONTENT, "ENCRYPT FROM: %s",
format_hex (BPTR (buf), BLEN (buf), 80, &gc));
/* cipher_ctx was already initialized with key & keylen */
ASSERT (EVP_CipherInit_ov (ctx->cipher, NULL, NULL, iv_buf, DO_ENCRYPT));
/* Buffer overflow check */
if (!buf_safe (&work, buf->len + EVP_CIPHER_CTX_block_size (ctx->cipher)))
{
msg (D_CRYPT_ERRORS, "ENCRYPT: buffer size error, bc=%d bo=%d bl=%d wc=%d wo=%d wl=%d cbs=%d",
buf->capacity,
buf->offset,
buf->len,
work.capacity,
work.offset,
work.len,
EVP_CIPHER_CTX_block_size (ctx->cipher));
goto err;
}
/* Encrypt packet ID, payload */
ASSERT (EVP_CipherUpdate_ov (ctx->cipher, BPTR (&work), &outlen, BPTR (buf), BLEN (buf)));
work.len += outlen;
/* Flush the encryption buffer */
ASSERT (EVP_CipherFinal (ctx->cipher, BPTR (&work) + outlen, &outlen));
work.len += outlen;
ASSERT (outlen == iv_size);
/* prepend the IV to the ciphertext */
if (opt->flags & CO_USE_IV)
{
uint8_t *output = buf_prepend (&work, iv_size);
ASSERT (output);
memcpy (output, iv_buf, iv_size);
}
dmsg (D_PACKET_CONTENT, "ENCRYPT TO: %s",
format_hex (BPTR (&work), BLEN (&work), 80, &gc));
}
else /* No Encryption */
{
if (opt->packet_id)
{
struct packet_id_net pin;
packet_id_alloc_outgoing (&opt->packet_id->send, &pin, BOOL_CAST (opt->flags & CO_PACKET_ID_LONG_FORM));
ASSERT (packet_id_write (&pin, buf, BOOL_CAST (opt->flags & CO_PACKET_ID_LONG_FORM), true));
}
work = *buf;
}
/* HMAC the ciphertext (or plaintext if !cipher) */
if (ctx->hmac)
{
int hmac_len;
uint8_t *output;
HMAC_Init_ex (ctx->hmac, NULL, 0, NULL, NULL);
HMAC_Update (ctx->hmac, BPTR (&work), BLEN (&work));
output = buf_prepend (&work, HMAC_size (ctx->hmac));
ASSERT (output);
HMAC_Final (ctx->hmac, output, (unsigned int *)&hmac_len);
ASSERT (hmac_len == HMAC_size (ctx->hmac));
}
*buf = work;
}
gc_free (&gc);
return;
err:
ERR_clear_error ();
buf->len = 0;
gc_free (&gc);
return;
}
/*
* If (opt->flags & CO_USE_IV) is not NULL, we will read an IV from the packet.
*
* Set buf->len to 0 and return false on decrypt error.
*
* On success, buf is set to point to plaintext, true
* is returned.
*/
bool
openvpn_decrypt (struct buffer *buf, struct buffer work,
const struct crypto_options *opt,
const struct frame* frame)
{
static const char error_prefix[] = "Authenticate/Decrypt packet error";
struct gc_arena gc;
gc_init (&gc);
if (buf->len > 0 && opt->key_ctx_bi)
{
struct key_ctx *ctx = &opt->key_ctx_bi->decrypt;
struct packet_id_net pin;
bool have_pin = false;
/* Verify the HMAC */
if (ctx->hmac)
{
int hmac_len;
uint8_t local_hmac[MAX_HMAC_KEY_LENGTH]; /* HMAC of ciphertext computed locally */
int in_hmac_len;
HMAC_Init_ex (ctx->hmac, NULL, 0, NULL, NULL);
/* Assume the length of the input HMAC */
hmac_len = HMAC_size (ctx->hmac);
/* Authentication fails if insufficient data in packet for HMAC */
if (buf->len < hmac_len)
CRYPT_ERROR ("missing authentication info");
HMAC_Update (ctx->hmac, BPTR (buf) + hmac_len,
BLEN (buf) - hmac_len);
HMAC_Final (ctx->hmac, local_hmac, (unsigned int *)&in_hmac_len);
ASSERT (hmac_len == in_hmac_len);
/* Compare locally computed HMAC with packet HMAC */
if (memcmp (local_hmac, BPTR (buf), hmac_len))
CRYPT_ERROR ("packet HMAC authentication failed");
ASSERT (buf_advance (buf, hmac_len));
}
/* Decrypt packet ID + payload */
if (ctx->cipher)
{
const unsigned int mode = EVP_CIPHER_CTX_mode (ctx->cipher);
const int iv_size = EVP_CIPHER_CTX_iv_length (ctx->cipher);
uint8_t iv_buf[EVP_MAX_IV_LENGTH];
int outlen;
/* initialize work buffer with FRAME_HEADROOM bytes of prepend capacity */
ASSERT (buf_init (&work, FRAME_HEADROOM_ADJ (frame, FRAME_HEADROOM_MARKER_DECRYPT)));
/* use IV if user requested it */
CLEAR (iv_buf);
if (opt->flags & CO_USE_IV)
{
if (buf->len < iv_size)
CRYPT_ERROR ("missing IV info");
memcpy (iv_buf, BPTR (buf), iv_size);
ASSERT (buf_advance (buf, iv_size));
}
/* show the IV's initial state */
if (opt->flags & CO_USE_IV)
dmsg (D_PACKET_CONTENT, "DECRYPT IV: %s", format_hex (iv_buf, iv_size, 0, &gc));
if (buf->len < 1)
CRYPT_ERROR ("missing payload");
/* ctx->cipher was already initialized with key & keylen */
if (!EVP_CipherInit_ov (ctx->cipher, NULL, NULL, iv_buf, DO_DECRYPT))
CRYPT_ERROR ("cipher init failed");
/* Buffer overflow check (should never happen) */
if (!buf_safe (&work, buf->len))
CRYPT_ERROR ("buffer overflow");
/* Decrypt packet ID, payload */
if (!EVP_CipherUpdate_ov (ctx->cipher, BPTR (&work), &outlen, BPTR (buf), BLEN (buf)))
CRYPT_ERROR ("cipher update failed");
work.len += outlen;
/* Flush the decryption buffer */
if (!EVP_CipherFinal (ctx->cipher, BPTR (&work) + outlen, &outlen))
CRYPT_ERROR ("cipher final failed");
work.len += outlen;
dmsg (D_PACKET_CONTENT, "DECRYPT TO: %s",
format_hex (BPTR (&work), BLEN (&work), 80, &gc));
/* Get packet ID from plaintext buffer or IV, depending on cipher mode */
{
if (mode == EVP_CIPH_CBC_MODE)
{
if (opt->packet_id)
{
if (!packet_id_read (&pin, &work, BOOL_CAST (opt->flags & CO_PACKET_ID_LONG_FORM)))
CRYPT_ERROR ("error reading CBC packet-id");
have_pin = true;
}
}
else if (mode == EVP_CIPH_CFB_MODE || mode == EVP_CIPH_OFB_MODE)
{
struct buffer b;
ASSERT (opt->flags & CO_USE_IV); /* IV and packet-ID required */
ASSERT (opt->packet_id); /* for this mode. */
buf_set_read (&b, iv_buf, iv_size);
if (!packet_id_read (&pin, &b, true))
CRYPT_ERROR ("error reading CFB/OFB packet-id");
have_pin = true;
}
else /* We only support CBC, CFB, or OFB modes right now */
{
ASSERT (0);
}
}
}
else
{
work = *buf;
if (opt->packet_id)
{
if (!packet_id_read (&pin, &work, BOOL_CAST (opt->flags & CO_PACKET_ID_LONG_FORM)))
CRYPT_ERROR ("error reading packet-id");
have_pin = !BOOL_CAST (opt->flags & CO_IGNORE_PACKET_ID);
}
}
if (have_pin)
{
packet_id_reap_test (&opt->packet_id->rec);
if (packet_id_test (&opt->packet_id->rec, &pin))
{
packet_id_add (&opt->packet_id->rec, &pin);
if (opt->pid_persist && (opt->flags & CO_PACKET_ID_LONG_FORM))
packet_id_persist_save_obj (opt->pid_persist, opt->packet_id);
}
else
{
if (!(opt->flags & CO_MUTE_REPLAY_WARNINGS))
msg (D_REPLAY_ERRORS, "%s: bad packet ID (may be a replay): %s -- see the man page entry for --no-replay and --replay-window for more info or silence this warning with --mute-replay-warnings",
error_prefix, packet_id_net_print (&pin, true, &gc));
goto error_exit;
}
}
*buf = work;
}
gc_free (&gc);
return true;
error_exit:
ERR_clear_error ();
buf->len = 0;
gc_free (&gc);
return false;
}
/*
* How many bytes will we add to frame buffer for a given
* set of crypto options?
*/
void
crypto_adjust_frame_parameters(struct frame *frame,
const struct key_type* kt,
bool cipher_defined,
bool use_iv,
bool packet_id,
bool packet_id_long_form)
{
frame_add_to_extra_frame (frame,
(packet_id ? packet_id_size (packet_id_long_form) : 0) +
((cipher_defined && use_iv) ? EVP_CIPHER_iv_length (kt->cipher) : 0) +
(cipher_defined ? EVP_CIPHER_block_size (kt->cipher) : 0) + /* worst case padding expansion */
kt->hmac_length);
}
static const EVP_CIPHER *
get_cipher (const char *ciphername)
{
const EVP_CIPHER *cipher = NULL;
ASSERT (ciphername);
cipher = EVP_get_cipherbyname (ciphername);
if ( !(cipher && cipher_ok (OBJ_nid2sn (EVP_CIPHER_nid (cipher)))))
msg (M_SSLERR, "Cipher algorithm '%s' not found", ciphername);
if (EVP_CIPHER_key_length (cipher) > MAX_CIPHER_KEY_LENGTH)
msg (M_FATAL, "Cipher algorithm '%s' uses a default key size (%d bytes) which is larger than " PACKAGE_NAME "'s current maximum key size (%d bytes)",
ciphername,
EVP_CIPHER_key_length (cipher),
MAX_CIPHER_KEY_LENGTH);
return cipher;
}
static const EVP_MD *
get_md (const char *digest)
{
const EVP_MD *md = NULL;
ASSERT (digest);
md = EVP_get_digestbyname (digest);
if (!md)
msg (M_SSLERR, "Message hash algorithm '%s' not found", digest);
if (EVP_MD_size (md) > MAX_HMAC_KEY_LENGTH)
msg (M_FATAL, "Message hash algorithm '%s' uses a default hash size (%d bytes) which is larger than " PACKAGE_NAME "'s current maximum hash size (%d bytes)",
digest,
EVP_MD_size (md),
MAX_HMAC_KEY_LENGTH);
return md;
}
static void
init_cipher (EVP_CIPHER_CTX *ctx, const EVP_CIPHER *cipher,
struct key *key, const struct key_type *kt, int enc,
const char *prefix)
{
struct gc_arena gc = gc_new ();
EVP_CIPHER_CTX_init (ctx);
if (!EVP_CipherInit_ov (ctx, cipher, NULL, NULL, enc))
msg (M_SSLERR, "EVP cipher init #1");
#ifdef HAVE_EVP_CIPHER_CTX_SET_KEY_LENGTH
if (!EVP_CIPHER_CTX_set_key_length (ctx, kt->cipher_length))
msg (M_SSLERR, "EVP set key size");
#endif
if (!EVP_CipherInit_ov (ctx, NULL, key->cipher, NULL, enc))
msg (M_SSLERR, "EVP cipher init #2");
msg (D_HANDSHAKE, "%s: Cipher '%s' initialized with %d bit key",
prefix,
OBJ_nid2sn (EVP_CIPHER_CTX_nid (ctx)),
EVP_CIPHER_CTX_key_length (ctx) * 8);
/* make sure we used a big enough key */
ASSERT (EVP_CIPHER_CTX_key_length (ctx) <= kt->cipher_length);
dmsg (D_SHOW_KEYS, "%s: CIPHER KEY: %s", prefix,
format_hex (key->cipher, kt->cipher_length, 0, &gc));
dmsg (D_CRYPTO_DEBUG, "%s: CIPHER block_size=%d iv_size=%d",
prefix,
EVP_CIPHER_CTX_block_size (ctx),
EVP_CIPHER_CTX_iv_length (ctx));
gc_free (&gc);
}
static void
init_hmac (HMAC_CTX *ctx, const EVP_MD *digest,
struct key *key, const struct key_type *kt, const char *prefix)
{
struct gc_arena gc = gc_new ();
HMAC_CTX_init (ctx);
HMAC_Init_ex (ctx, key->hmac, kt->hmac_length, digest, NULL);
msg (D_HANDSHAKE,
"%s: Using %d bit message hash '%s' for HMAC authentication",
prefix, HMAC_size (ctx) * 8, OBJ_nid2sn (EVP_MD_type (digest)));
/* make sure we used a big enough key */
ASSERT (HMAC_size (ctx) <= kt->hmac_length);
dmsg (D_SHOW_KEYS, "%s: HMAC KEY: %s", prefix,
format_hex (key->hmac, kt->hmac_length, 0, &gc));
dmsg (D_CRYPTO_DEBUG, "%s: HMAC size=%d block_size=%d",
prefix,
EVP_MD_size (digest),
EVP_MD_block_size (digest));
gc_free (&gc);
}
/*
* Build a struct key_type.
*/
void
init_key_type (struct key_type *kt, const char *ciphername,
bool ciphername_defined, const char *authname,
bool authname_defined, int keysize,
bool cfb_ofb_allowed, bool warn)
{
CLEAR (*kt);
if (ciphername && ciphername_defined)
{
kt->cipher = get_cipher (ciphername);
kt->cipher_length = EVP_CIPHER_key_length (kt->cipher);
if (keysize > 0 && keysize <= MAX_CIPHER_KEY_LENGTH)
kt->cipher_length = keysize;
/* check legal cipher mode */
{
const unsigned int mode = EVP_CIPHER_mode (kt->cipher);
if (!(mode == EVP_CIPH_CBC_MODE
#ifdef ALLOW_NON_CBC_CIPHERS
|| (cfb_ofb_allowed && (mode == EVP_CIPH_CFB_MODE || mode == EVP_CIPH_OFB_MODE))
#endif
))
#ifdef ENABLE_SMALL
msg (M_FATAL, "Cipher '%s' mode not supported", ciphername);
#else
msg (M_FATAL, "Cipher '%s' uses a mode not supported by " PACKAGE_NAME " in your current configuration. CBC mode is always supported, while CFB and OFB modes are supported only when using SSL/TLS authentication and key exchange mode, and when " PACKAGE_NAME " has been built with ALLOW_NON_CBC_CIPHERS.", ciphername);
#endif
}
}
else
{
if (warn)
msg (M_WARN, "******* WARNING *******: null cipher specified, no encryption will be used");
}
if (authname && authname_defined)
{
kt->digest = get_md (authname);
kt->hmac_length = EVP_MD_size (kt->digest);
}
else
{
if (warn)
msg (M_WARN, "******* WARNING *******: null MAC specified, no authentication will be used");
}
}
const char *
kt_cipher_name (const struct key_type *kt)
{
if (kt->cipher)
return EVP_CIPHER_name (kt->cipher);
else
return "[null-cipher]";
}
const char *
kt_digest_name (const struct key_type *kt)
{
if (kt->digest)
return EVP_MD_name (kt->digest);
else
return "[null-digest]";
}
int
kt_key_size (const struct key_type *kt)
{
if (kt->cipher_length)
return kt->cipher_length * 8;
else if (kt->cipher)
return EVP_CIPHER_key_length (kt->cipher) * 8;
else
return 0;
}
/* given a key and key_type, build a key_ctx */
void
init_key_ctx (struct key_ctx *ctx, struct key *key,
const struct key_type *kt, int enc,
const char *prefix)
{
CLEAR (*ctx);
if (kt->cipher && kt->cipher_length > 0)
{
ALLOC_OBJ (ctx->cipher, EVP_CIPHER_CTX);
init_cipher (ctx->cipher, kt->cipher, key, kt, enc, prefix);
}
if (kt->digest && kt->hmac_length > 0)
{
ALLOC_OBJ (ctx->hmac, HMAC_CTX);
init_hmac (ctx->hmac, kt->digest, key, kt, prefix);
}
}
void
free_key_ctx (struct key_ctx *ctx)
{
if (ctx->cipher)
{
EVP_CIPHER_CTX_cleanup (ctx->cipher);
free (ctx->cipher);
ctx->cipher = NULL;
}
if (ctx->hmac)
{
HMAC_CTX_cleanup (ctx->hmac);
free (ctx->hmac);
ctx->hmac = NULL;
}
}
void
free_key_ctx_bi (struct key_ctx_bi *ctx)
{
free_key_ctx(&ctx->encrypt);
free_key_ctx(&ctx->decrypt);
}
/*
* Return number of DES cblocks for the current
* key type or 0 if not a DES cipher.
*/
static int
n_DES_cblocks (const struct key_type *kt)
{
int ret = 0;
const char *name = OBJ_nid2sn (EVP_CIPHER_nid (kt->cipher));
if (name)
{
if (!strncmp (name, "DES-", 4))
{
ret = EVP_CIPHER_key_length (kt->cipher) / sizeof (DES_cblock);
}
else if (!strncmp (name, "DESX-", 5))
{
ret = 1;
}
}
dmsg (D_CRYPTO_DEBUG, "CRYPTO INFO: n_DES_cblocks=%d", ret);
return ret;
}
static bool
check_key_DES (struct key *key, const struct key_type *kt, int ndc)
{
int i;
struct buffer b;
buf_set_read (&b, key->cipher, kt->cipher_length);
for (i = 0; i < ndc; ++i)
{
DES_cblock *dc = (DES_cblock*) buf_read_alloc (&b, sizeof (DES_cblock));
if (!dc)
{
msg (D_CRYPT_ERRORS, "CRYPTO INFO: check_key_DES: insufficient key material");
goto err;
}
if (DES_is_weak_key(dc))
{
msg (D_CRYPT_ERRORS, "CRYPTO INFO: check_key_DES: weak key detected");
goto err;
}
if (!DES_check_key_parity (dc))
{
msg (D_CRYPT_ERRORS, "CRYPTO INFO: check_key_DES: bad parity detected");
goto err;
}
}
return true;
err:
ERR_clear_error ();
return false;
}
static void
fixup_key_DES (struct key *key, const struct key_type *kt, int ndc)
{
int i;
struct buffer b;
buf_set_read (&b, key->cipher, kt->cipher_length);
for (i = 0; i < ndc; ++i)
{
DES_cblock *dc = (DES_cblock*) buf_read_alloc(&b, sizeof(DES_cblock));
if (!dc)
{
msg (D_CRYPT_ERRORS, "CRYPTO INFO: fixup_key_DES: insufficient key material");
ERR_clear_error ();
return;
}
DES_set_odd_parity (dc);
}
}
static bool
key_is_zero (struct key *key, const struct key_type *kt)
{
int i;
for (i = 0; i < kt->cipher_length; ++i)
if (key->cipher[i])
return false;
msg (D_CRYPT_ERRORS, "CRYPTO INFO: WARNING: zero key detected");
return true;
}
/*
* Make sure that cipher key is a valid key for current key_type.
*/
bool
check_key (struct key *key, const struct key_type *kt)
{
if (kt->cipher)
{
/*
* Check for zero key
*/
if (key_is_zero(key, kt))
return false;
/*
* Check for weak or semi-weak DES keys.
*/
{
const int ndc = n_DES_cblocks (kt);
if (ndc)
return check_key_DES (key, kt, ndc);
else
return true;
}
}
return true;
}
/*
* Make safe mutations to key to ensure it is valid,
* such as ensuring correct parity on DES keys.
*
* This routine cannot guarantee it will generate a good
* key. You must always call check_key after this routine
* to make sure.
*/
void
fixup_key (struct key *key, const struct key_type *kt)
{
struct gc_arena gc = gc_new ();
if (kt->cipher)
{
#ifdef ENABLE_DEBUG
const struct key orig = *key;
#endif
const int ndc = n_DES_cblocks (kt);
if (ndc)
fixup_key_DES (key, kt, ndc);
#ifdef ENABLE_DEBUG
if (check_debug_level (D_CRYPTO_DEBUG))
{
if (memcmp (orig.cipher, key->cipher, kt->cipher_length))
dmsg (D_CRYPTO_DEBUG, "CRYPTO INFO: fixup_key: before=%s after=%s",
format_hex (orig.cipher, kt->cipher_length, 0, &gc),
format_hex (key->cipher, kt->cipher_length, 0, &gc));
}
#endif
}
gc_free (&gc);
}
void
check_replay_iv_consistency (const struct key_type *kt, bool packet_id, bool use_iv)
{
if (cfb_ofb_mode (kt) && !(packet_id && use_iv))
msg (M_FATAL, "--no-replay or --no-iv cannot be used with a CFB or OFB mode cipher");
}
bool
cfb_ofb_mode (const struct key_type* kt)
{
if (kt->cipher) {
const unsigned int mode = EVP_CIPHER_mode (kt->cipher);
return mode == EVP_CIPH_CFB_MODE || mode == EVP_CIPH_OFB_MODE;
} else
return false;
}
/*
* Generate a random key. If key_type is provided, make
* sure generated key is valid for key_type.
*/
void
generate_key_random (struct key *key, const struct key_type *kt)
{
int cipher_len = MAX_CIPHER_KEY_LENGTH;
int hmac_len = MAX_HMAC_KEY_LENGTH;
struct gc_arena gc = gc_new ();
do {
CLEAR (*key);
if (kt)
{
if (kt->cipher && kt->cipher_length > 0 && kt->cipher_length <= cipher_len)
cipher_len = kt->cipher_length;
if (kt->digest && kt->hmac_length > 0 && kt->hmac_length <= hmac_len)
hmac_len = kt->hmac_length;
}
if (!RAND_bytes (key->cipher, cipher_len)
|| !RAND_bytes (key->hmac, hmac_len))
msg (M_FATAL, "ERROR: Random number generator cannot obtain entropy for key generation");
dmsg (D_SHOW_KEY_SOURCE, "Cipher source entropy: %s", format_hex (key->cipher, cipher_len, 0, &gc));
dmsg (D_SHOW_KEY_SOURCE, "HMAC source entropy: %s", format_hex (key->hmac, hmac_len, 0, &gc));
if (kt)
fixup_key (key, kt);
} while (kt && !check_key (key, kt));
gc_free (&gc);
}
/*
* Print key material
*/
void
key2_print (const struct key2* k,
const struct key_type *kt,
const char* prefix0,
const char* prefix1)
{
struct gc_arena gc = gc_new ();
ASSERT (k->n == 2);
dmsg (D_SHOW_KEY_SOURCE, "%s (cipher): %s",
prefix0,
format_hex (k->keys[0].cipher, kt->cipher_length, 0, &gc));
dmsg (D_SHOW_KEY_SOURCE, "%s (hmac): %s",
prefix0,
format_hex (k->keys[0].hmac, kt->hmac_length, 0, &gc));
dmsg (D_SHOW_KEY_SOURCE, "%s (cipher): %s",
prefix1,
format_hex (k->keys[1].cipher, kt->cipher_length, 0, &gc));
dmsg (D_SHOW_KEY_SOURCE, "%s (hmac): %s",
prefix1,
format_hex (k->keys[1].hmac, kt->hmac_length, 0, &gc));
gc_free (&gc);
}
void
test_crypto (const struct crypto_options *co, struct frame* frame)
{
int i, j;
struct gc_arena gc = gc_new ();
struct buffer src = alloc_buf_gc (TUN_MTU_SIZE (frame), &gc);
struct buffer work = alloc_buf_gc (BUF_SIZE (frame), &gc);
struct buffer encrypt_workspace = alloc_buf_gc (BUF_SIZE (frame), &gc);
struct buffer decrypt_workspace = alloc_buf_gc (BUF_SIZE (frame), &gc);
struct buffer buf = clear_buf();
/* init work */
ASSERT (buf_init (&work, FRAME_HEADROOM (frame)));
msg (M_INFO, "Entering " PACKAGE_NAME " crypto self-test mode.");
for (i = 1; i <= TUN_MTU_SIZE (frame); ++i)
{
update_time ();
msg (M_INFO, "TESTING ENCRYPT/DECRYPT of packet length=%d", i);
/*
* Load src with random data.
*/
ASSERT (buf_init (&src, 0));
ASSERT (i <= src.capacity);
src.len = i;
ASSERT (RAND_pseudo_bytes (BPTR (&src), BLEN (&src)));
/* copy source to input buf */
buf = work;
memcpy (buf_write_alloc (&buf, BLEN (&src)), BPTR (&src), BLEN (&src));
/* encrypt */
openvpn_encrypt (&buf, encrypt_workspace, co, frame);
/* decrypt */
openvpn_decrypt (&buf, decrypt_workspace, co, frame);
/* compare */
if (buf.len != src.len)
msg (M_FATAL, "SELF TEST FAILED, src.len=%d buf.len=%d", src.len, buf.len);
for (j = 0; j < i; ++j)
{
const uint8_t in = *(BPTR (&src) + j);
const uint8_t out = *(BPTR (&buf) + j);
if (in != out)
msg (M_FATAL, "SELF TEST FAILED, pos=%d in=%d out=%d", j, in, out);
}
}
msg (M_INFO, PACKAGE_NAME " crypto self-test mode SUCCEEDED.");
gc_free (&gc);
}
#ifdef USE_SSL
void
get_tls_handshake_key (const struct key_type *key_type,
struct key_ctx_bi *ctx,
const char *passphrase_file,
const int key_direction,
const unsigned int flags)
{
if (passphrase_file && key_type->hmac_length)
{
struct key2 key2;
struct key_type kt = *key_type;
struct key_direction_state kds;
/* for control channel we are only authenticating, not encrypting */
kt.cipher_length = 0;
kt.cipher = NULL;
#if ENABLE_INLINE_FILES
if (flags & GHK_INLINE)
{
/* key was specified inline, key text is in passphrase_file */
read_key_file (&key2, passphrase_file, RKF_INLINE|RKF_MUST_SUCCEED);
/* succeeded? */
if (key2.n == 2)
msg (M_INFO, "Control Channel Authentication: tls-auth using INLINE static key file");
else
msg (M_FATAL, "INLINE tls-auth file lacks the requisite 2 keys");
}
else
#endif
{
/* first try to parse as an OpenVPN static key file */
read_key_file (&key2, passphrase_file, 0);
/* succeeded? */
if (key2.n == 2)
{
msg (M_INFO,
"Control Channel Authentication: using '%s' as a " PACKAGE_NAME " static key file",
passphrase_file);
}
else
{
int hash_size;
CLEAR (key2);
/* failed, now try to get hash from a freeform file */
hash_size = read_passphrase_hash (passphrase_file,
kt.digest,
key2.keys[0].hmac,
MAX_HMAC_KEY_LENGTH);
ASSERT (hash_size == kt.hmac_length);
/* suceeded */
key2.n = 1;
msg (M_INFO,
"Control Channel Authentication: using '%s' as a free-form passphrase file",
passphrase_file);
}
}
/* handle key direction */
key_direction_state_init (&kds, key_direction);
must_have_n_keys (passphrase_file, "tls-auth", &key2, kds.need_keys);
/* initialize hmac key in both directions */
init_key_ctx (&ctx->encrypt, &key2.keys[kds.out_key], &kt, DO_ENCRYPT,
"Outgoing Control Channel Authentication");
init_key_ctx (&ctx->decrypt, &key2.keys[kds.in_key], &kt, DO_DECRYPT,
"Incoming Control Channel Authentication");
CLEAR (key2);
}
else
{
CLEAR (*ctx);
}
}
#endif
/* header and footer for static key file */
static const char static_key_head[] = "-----BEGIN " PACKAGE_NAME " Static key V1-----";
static const char static_key_foot[] = "-----END " PACKAGE_NAME " Static key V1-----";
static const char printable_char_fmt[] =
"Non-Hex character ('%c') found at line %d in key file '%s' (%d/%d/%d bytes found/min/max)";
static const char unprintable_char_fmt[] =
"Non-Hex, unprintable character (0x%02x) found at line %d in key file '%s' (%d/%d/%d bytes found/min/max)";
/* read key from file */
void
read_key_file (struct key2 *key2, const char *file, const unsigned int flags)
{
struct gc_arena gc = gc_new ();
struct buffer in;
int fd, size;
uint8_t hex_byte[3] = {0, 0, 0};
const char *error_filename = file;
/* parse info */
const unsigned char *cp;
int hb_index = 0;
int line_num = 1;
int line_index = 0;
int match = 0;
/* output */
uint8_t* out = (uint8_t*) &key2->keys;
const int keylen = sizeof (key2->keys);
int count = 0;
/* parse states */
# define PARSE_INITIAL 0
# define PARSE_HEAD 1
# define PARSE_DATA 2
# define PARSE_DATA_COMPLETE 3
# define PARSE_FOOT 4
# define PARSE_FINISHED 5
int state = PARSE_INITIAL;
/* constants */
const int hlen = strlen (static_key_head);
const int flen = strlen (static_key_foot);
const int onekeylen = sizeof (key2->keys[0]);
CLEAR (*key2);
/*
* Key can be provided as a filename in 'file' or if RKF_INLINE
* is set, the actual key data itself in ascii form.
*/
#if ENABLE_INLINE_FILES
if (flags & RKF_INLINE) /* 'file' is a string containing ascii representation of key */
{
size = strlen (file) + 1;
buf_set_read (&in, (const uint8_t *)file, size);
error_filename = INLINE_FILE_TAG;
}
else /* 'file' is a filename which refers to a file containing the ascii key */
#endif
{
in = alloc_buf_gc (2048, &gc);
fd = open (file, O_RDONLY);
if (fd == -1)
msg (M_ERR, "Cannot open file key file '%s'", file);
size = read (fd, in.data, in.capacity);
if (size < 0)
msg (M_FATAL, "Read error on key file ('%s')", file);
if (size == in.capacity)
msg (M_FATAL, "Key file ('%s') can be a maximum of %d bytes", file, (int)in.capacity);
close (fd);
}
cp = (unsigned char *)in.data;
while (size > 0)
{
const unsigned char c = *cp;
#if 0
msg (M_INFO, "char='%c' s=%d ln=%d li=%d m=%d c=%d",
c, state, line_num, line_index, match, count);
#endif
if (c == '\n')
{
line_index = match = 0;
++line_num;
}
else
{
/* first char of new line */
if (!line_index)
{
/* first char of line after header line? */
if (state == PARSE_HEAD)
state = PARSE_DATA;
/* first char of footer */
if ((state == PARSE_DATA || state == PARSE_DATA_COMPLETE) && c == '-')
state = PARSE_FOOT;
}
/* compare read chars with header line */
if (state == PARSE_INITIAL)
{
if (line_index < hlen && c == static_key_head[line_index])
{
if (++match == hlen)
state = PARSE_HEAD;
}
}
/* compare read chars with footer line */
if (state == PARSE_FOOT)
{
if (line_index < flen && c == static_key_foot[line_index])
{
if (++match == flen)
state = PARSE_FINISHED;
}
}
/* reading key */
if (state == PARSE_DATA)
{
if (isxdigit(c))
{
ASSERT (hb_index >= 0 && hb_index < 2);
hex_byte[hb_index++] = c;
if (hb_index == 2)
{
unsigned int u;
ASSERT(sscanf((const char *)hex_byte, "%x", &u) == 1);
*out++ = u;
hb_index = 0;
if (++count == keylen)
state = PARSE_DATA_COMPLETE;
}
}
else if (isspace(c))
;
else
{
msg (M_FATAL,
(isprint (c) ? printable_char_fmt : unprintable_char_fmt),
c, line_num, error_filename, count, onekeylen, keylen);
}
}
++line_index;
}
++cp;
--size;
}
/*
* Normally we will read either 1 or 2 keys from file.
*/
key2->n = count / onekeylen;
ASSERT (key2->n >= 0 && key2->n <= (int) SIZE (key2->keys));
if (flags & RKF_MUST_SUCCEED)
{
if (!key2->n)
msg (M_FATAL, "Insufficient key material or header text not found found in file '%s' (%d/%d/%d bytes found/min/max)",
error_filename, count, onekeylen, keylen);
if (state != PARSE_FINISHED)
msg (M_FATAL, "Footer text not found in file '%s' (%d/%d/%d bytes found/min/max)",
error_filename, count, onekeylen, keylen);
}
/* zero file read buffer if not an inline file */
#if ENABLE_INLINE_FILES
if (!(flags & RKF_INLINE))
#endif
buf_clear (&in);
if (key2->n)
warn_if_group_others_accessible (error_filename);
#if 0
/* DEBUGGING */
{
int i;
printf ("KEY READ, n=%d\n", key2->n);
for (i = 0; i < (int) SIZE (key2->keys); ++i)
{
/* format key as ascii */
const char *fmt = format_hex_ex ((const uint8_t*)&key2->keys[i],
sizeof (key2->keys[i]),
0,
16,
"\n",
&gc);
printf ("[%d]\n%s\n\n", i, fmt);
}
}
#endif
/* pop our garbage collection level */
gc_free (&gc);
}
int
read_passphrase_hash (const char *passphrase_file,
const EVP_MD *digest,
uint8_t *output,
int len)
{
unsigned int outlen = 0;
EVP_MD_CTX md;
ASSERT (len >= EVP_MD_size (digest));
memset (output, 0, len);
EVP_DigestInit (&md, digest);
/* read passphrase file */
{
const int min_passphrase_size = 8;
uint8_t buf[64];
int total_size = 0;
int fd = open (passphrase_file, O_RDONLY);
if (fd == -1)
msg (M_ERR, "Cannot open passphrase file: '%s'", passphrase_file);
for (;;)
{
int size = read (fd, buf, sizeof (buf));
if (size == 0)
break;
if (size == -1)
msg (M_ERR, "Read error on passphrase file: '%s'",
passphrase_file);
EVP_DigestUpdate (&md, buf, size);
total_size += size;
}
close (fd);
warn_if_group_others_accessible (passphrase_file);
if (total_size < min_passphrase_size)
msg (M_FATAL,
"Passphrase file '%s' is too small (must have at least %d characters)",
passphrase_file, min_passphrase_size);
}
EVP_DigestFinal (&md, output, &outlen);
EVP_MD_CTX_cleanup (&md);
return outlen;
}
/*
* Write key to file, return number of random bits
* written.
*/
int
write_key_file (const int nkeys, const char *filename)
{
struct gc_arena gc = gc_new ();
int fd, i;
int nbits = 0;
/* must be large enough to hold full key file */
struct buffer out = alloc_buf_gc (2048, &gc);
struct buffer nbits_head_text = alloc_buf_gc (128, &gc);
/* how to format the ascii file representation of key */
const int bytes_per_line = 16;
/* open key file */
fd = open (filename, O_CREAT | O_TRUNC | O_WRONLY, S_IRUSR | S_IWUSR);
if (fd == -1)
msg (M_ERR, "Cannot open shared secret file '%s' for write", filename);
buf_printf (&out, "%s\n", static_key_head);
for (i = 0; i < nkeys; ++i)
{
struct key key;
char* fmt;
/* generate random bits */
generate_key_random (&key, NULL);
/* format key as ascii */
fmt = format_hex_ex ((const uint8_t*)&key,
sizeof (key),
0,
bytes_per_line,
"\n",
&gc);
/* increment random bits counter */
nbits += sizeof (key) * 8;
/* write to holding buffer */
buf_printf (&out, "%s\n", fmt);
/* zero memory which held key component (will be freed by GC) */
memset (fmt, 0, strlen(fmt));
CLEAR (key);
}
buf_printf (&out, "%s\n", static_key_foot);
/* write number of bits */
buf_printf (&nbits_head_text, "#\n# %d bit " PACKAGE_NAME " static key\n#\n", nbits);
buf_write_string_file (&nbits_head_text, filename, fd);
/* write key file, now formatted in out, to file */
buf_write_string_file (&out, filename, fd);
if (close (fd))
msg (M_ERR, "Close error on shared secret file %s", filename);
/* zero memory which held file content (memory will be freed by GC) */
buf_clear (&out);
/* pop our garbage collection level */
gc_free (&gc);
return nbits;
}
void
must_have_n_keys (const char *filename, const char *option, const struct key2 *key2, int n)
{
if (key2->n < n)
{
#ifdef ENABLE_SMALL
msg (M_FATAL, "Key file '%s' used in --%s contains insufficient key material [keys found=%d required=%d]", filename, option, key2->n, n);
#else
msg (M_FATAL, "Key file '%s' used in --%s contains insufficient key material [keys found=%d required=%d] -- try generating a new key file with '" PACKAGE " --genkey --secret [file]', or use the existing key file in bidirectional mode by specifying --%s without a key direction parameter", filename, option, key2->n, n, option);
#endif
}
}
int
ascii2keydirection (int msglevel, const char *str)
{
if (!str)
return KEY_DIRECTION_BIDIRECTIONAL;
else if (!strcmp (str, "0"))
return KEY_DIRECTION_NORMAL;
else if (!strcmp (str, "1"))
return KEY_DIRECTION_INVERSE;
else
{
msg (msglevel, "Unknown key direction '%s' -- must be '0' or '1'", str);
return -1;
}
return KEY_DIRECTION_BIDIRECTIONAL; /* NOTREACHED */
}
const char *
keydirection2ascii (int kd, bool remote)
{
if (kd == KEY_DIRECTION_BIDIRECTIONAL)
return NULL;
else if (kd == KEY_DIRECTION_NORMAL)
return remote ? "1" : "0";
else if (kd == KEY_DIRECTION_INVERSE)
return remote ? "0" : "1";
else
{
ASSERT (0);
}
return NULL; /* NOTREACHED */
}
void
key_direction_state_init (struct key_direction_state *kds, int key_direction)
{
CLEAR (*kds);
switch (key_direction)
{
case KEY_DIRECTION_NORMAL:
kds->out_key = 0;
kds->in_key = 1;
kds->need_keys = 2;
break;
case KEY_DIRECTION_INVERSE:
kds->out_key = 1;
kds->in_key = 0;
kds->need_keys = 2;
break;
case KEY_DIRECTION_BIDIRECTIONAL:
kds->out_key = 0;
kds->in_key = 0;
kds->need_keys = 1;
break;
default:
ASSERT (0);
}
}
void
verify_fix_key2 (struct key2 *key2, const struct key_type *kt, const char *shared_secret_file)
{
int i;
for (i = 0; i < key2->n; ++i)
{
/* Fix parity for DES keys and make sure not a weak key */
fixup_key (&key2->keys[i], kt);
/* This should be a very improbable failure */
if (!check_key (&key2->keys[i], kt))
msg (M_FATAL, "Key #%d in '%s' is bad. Try making a new key with --genkey.",
i+1, shared_secret_file);
}
}
/* given a key and key_type, write key to buffer */
bool
write_key (const struct key *key, const struct key_type *kt,
struct buffer *buf)
{
ASSERT (kt->cipher_length <= MAX_CIPHER_KEY_LENGTH
&& kt->hmac_length <= MAX_HMAC_KEY_LENGTH);
if (!buf_write (buf, &kt->cipher_length, 1))
return false;
if (!buf_write (buf, &kt->hmac_length, 1))
return false;
if (!buf_write (buf, key->cipher, kt->cipher_length))
return false;
if (!buf_write (buf, key->hmac, kt->hmac_length))
return false;
return true;
}
/*
* Given a key_type and buffer, read key from buffer.
* Return: 1 on success
* -1 read failure
* 0 on key length mismatch
*/
int
read_key (struct key *key, const struct key_type *kt, struct buffer *buf)
{
uint8_t cipher_length;
uint8_t hmac_length;
CLEAR (*key);
if (!buf_read (buf, &cipher_length, 1))
goto read_err;
if (!buf_read (buf, &hmac_length, 1))
goto read_err;
if (!buf_read (buf, key->cipher, cipher_length))
goto read_err;
if (!buf_read (buf, key->hmac, hmac_length))
goto read_err;
if (cipher_length != kt->cipher_length || hmac_length != kt->hmac_length)
goto key_len_err;
return 1;
read_err:
msg (D_TLS_ERRORS, "TLS Error: error reading key from remote");
return -1;
key_len_err:
msg (D_TLS_ERRORS,
"TLS Error: key length mismatch, local cipher/hmac %d/%d, remote cipher/hmac %d/%d",
kt->cipher_length, kt->hmac_length, cipher_length, hmac_length);
return 0;
}
void
show_available_ciphers ()
{
int nid;
#ifndef ENABLE_SMALL
printf ("The following ciphers and cipher modes are available\n"
"for use with " PACKAGE_NAME ". Each cipher shown below may be\n"
"used as a parameter to the --cipher option. The default\n"
"key size is shown as well as whether or not it can be\n"
"changed with the --keysize directive. Using a CBC mode\n"
"is recommended.\n\n");
#endif
for (nid = 0; nid < 10000; ++nid) /* is there a better way to get the size of the nid list? */
{
const EVP_CIPHER *cipher = EVP_get_cipherbynid (nid);
if (cipher && cipher_ok (OBJ_nid2sn (nid)))
{
const unsigned int mode = EVP_CIPHER_mode (cipher);
if (mode == EVP_CIPH_CBC_MODE
#ifdef ALLOW_NON_CBC_CIPHERS
|| mode == EVP_CIPH_CFB_MODE || mode == EVP_CIPH_OFB_MODE
#endif
)
printf ("%s %d bit default key (%s)\n",
OBJ_nid2sn (nid),
EVP_CIPHER_key_length (cipher) * 8,
((EVP_CIPHER_flags (cipher) & EVP_CIPH_VARIABLE_LENGTH) ?
"variable" : "fixed"));
}
}
printf ("\n");
}
void
show_available_digests ()
{
int nid;
#ifndef ENABLE_SMALL
printf ("The following message digests are available for use with\n"
PACKAGE_NAME ". A message digest is used in conjunction with\n"
"the HMAC function, to authenticate received packets.\n"
"You can specify a message digest as parameter to\n"
"the --auth option.\n\n");
#endif
for (nid = 0; nid < 10000; ++nid)
{
const EVP_MD *digest = EVP_get_digestbynid (nid);
if (digest)
{
printf ("%s %d bit digest size\n",
OBJ_nid2sn (nid), EVP_MD_size (digest) * 8);
}
}
printf ("\n");
}
void
show_available_engines ()
{
#if CRYPTO_ENGINE
ENGINE *e;
printf ("OpenSSL Crypto Engines\n\n");
ENGINE_load_builtin_engines ();
e = ENGINE_get_first ();
while (e)
{
printf ("%s [%s]\n",
ENGINE_get_name (e),
ENGINE_get_id (e));
e = ENGINE_get_next (e);
}
ENGINE_cleanup ();
#else
printf ("Sorry, OpenSSL hardware crypto engine functionality is not available.\n");
#endif
}
/*
* Enable crypto acceleration, if available
*/
static bool engine_initialized = false; /* GLOBAL */
#if CRYPTO_ENGINE
static ENGINE *engine_persist = NULL; /* GLOBAL */
/* Try to load an engine in a shareable library */
static ENGINE *
try_load_engine (const char *engine)
{
ENGINE *e = ENGINE_by_id ("dynamic");
if (e)
{
if (!ENGINE_ctrl_cmd_string (e, "SO_PATH", engine, 0)
|| !ENGINE_ctrl_cmd_string (e, "LOAD", NULL, 0))
{
ENGINE_free (e);
e = NULL;
}
}
return e;
}
static ENGINE *
setup_engine (const char *engine)
{
ENGINE *e = NULL;
ENGINE_load_builtin_engines ();
if (engine)
{
if (strcmp (engine, "auto") == 0)
{
msg (M_INFO, "Initializing OpenSSL auto engine support");
ENGINE_register_all_complete ();
return NULL;
}
if ((e = ENGINE_by_id (engine)) == NULL
&& (e = try_load_engine (engine)) == NULL)
{
msg (M_FATAL, "OpenSSL error: cannot load engine '%s'", engine);
}
if (!ENGINE_set_default (e, ENGINE_METHOD_ALL))
{
msg (M_FATAL, "OpenSSL error: ENGINE_set_default failed on engine '%s'",
engine);
}
msg (M_INFO, "Initializing OpenSSL support for engine '%s'",
ENGINE_get_id (e));
}
return e;
}
#endif
void
init_crypto_lib_engine (const char *engine_name)
{
if (!engine_initialized)
{
#if CRYPTO_ENGINE
ASSERT (engine_name);
ASSERT (!engine_persist);
engine_persist = setup_engine (engine_name);
#else
msg (M_WARN, "Note: OpenSSL hardware crypto engine functionality is not available");
#endif
engine_initialized = true;
}
}
/*
* This routine should have additional OpenSSL crypto library initialisations
* used by both crypto and ssl components of OpenVPN.
*/
void init_crypto_lib ()
{
}
void uninit_crypto_lib ()
{
#if CRYPTO_ENGINE
if (engine_initialized)
{
ENGINE_cleanup ();
engine_persist = NULL;
engine_initialized = false;
}
#endif
prng_uninit ();
}
/*
* Random number functions, used in cases where we want
* reasonably strong cryptographic random number generation
* without depleting our entropy pool. Used for random
* IV values and a number of other miscellaneous tasks.
*/
static uint8_t *nonce_data; /* GLOBAL */
static const EVP_MD *nonce_md = NULL; /* GLOBAL */
static int nonce_secret_len; /* GLOBAL */
void
prng_init (const char *md_name, const int nonce_secret_len_parm)
{
prng_uninit ();
nonce_md = md_name ? get_md (md_name) : NULL;
if (nonce_md)
{
ASSERT (nonce_secret_len_parm >= NONCE_SECRET_LEN_MIN && nonce_secret_len_parm <= NONCE_SECRET_LEN_MAX);
nonce_secret_len = nonce_secret_len_parm;
{
const int size = EVP_MD_size (nonce_md) + nonce_secret_len;
dmsg (D_CRYPTO_DEBUG, "PRNG init md=%s size=%d", EVP_MD_name (nonce_md), size);
nonce_data = (uint8_t*) malloc (size);
check_malloc_return (nonce_data);
#if 1 /* Must be 1 for real usage */
if (!RAND_bytes (nonce_data, size))
msg (M_FATAL, "ERROR: Random number generator cannot obtain entropy for PRNG");
#else
/* Only for testing -- will cause a predictable PRNG sequence */
{
int i;
for (i = 0; i < size; ++i)
nonce_data[i] = (uint8_t) i;
}
#endif
}
}
}
void
prng_uninit (void)
{
free (nonce_data);
nonce_data = NULL;
nonce_md = NULL;
nonce_secret_len = 0;
}
void
prng_bytes (uint8_t *output, int len)
{
if (nonce_md)
{
EVP_MD_CTX ctx;
const int md_size = EVP_MD_size (nonce_md);
mutex_lock_static (L_PRNG);
while (len > 0)
{
unsigned int outlen = 0;
const int blen = min_int (len, md_size);
EVP_DigestInit (&ctx, nonce_md);
EVP_DigestUpdate (&ctx, nonce_data, md_size + nonce_secret_len);
EVP_DigestFinal (&ctx, nonce_data, &outlen);
ASSERT (outlen == md_size);
EVP_MD_CTX_cleanup (&ctx);
memcpy (output, nonce_data, blen);
output += blen;
len -= blen;
}
mutex_unlock_static (L_PRNG);
}
else
RAND_bytes (output, len);
}
/* an analogue to the random() function, but use prng_bytes */
long int
get_random()
{
long int l;
prng_bytes ((unsigned char *)&l, sizeof(l));
if (l < 0)
l = -l;
return l;
}
const char *
md5sum (uint8_t *buf, int len, int n_print_chars, struct gc_arena *gc)
{
uint8_t digest[MD5_DIGEST_LENGTH];
MD5 (buf, len, digest);
return format_hex (digest, MD5_DIGEST_LENGTH, n_print_chars, gc);
}
/*
* OpenSSL memory debugging. If dmalloc debugging is enabled, tell
* OpenSSL to use our private malloc/realloc/free functions so that
* we can dispatch them to dmalloc.
*/
#ifdef DMALLOC
static void *
crypto_malloc (size_t size, const char *file, int line)
{
return dmalloc_malloc(file, line, size, DMALLOC_FUNC_MALLOC, 0, 0);
}
static void *
crypto_realloc (void *ptr, size_t size, const char *file, int line)
{
return dmalloc_realloc(file, line, ptr, size, DMALLOC_FUNC_REALLOC, 0);
}
static void
crypto_free (void *ptr)
{
dmalloc_free (__FILE__, __LINE__, ptr, DMALLOC_FUNC_FREE);
}
void
openssl_dmalloc_init (void)
{
CRYPTO_set_mem_ex_functions (crypto_malloc,
crypto_realloc,
crypto_free);
}
#endif /* DMALLOC */
#ifndef USE_SSL
void
init_ssl_lib (void)
{
ERR_load_crypto_strings ();
OpenSSL_add_all_algorithms ();
init_crypto_lib ();
}
void
free_ssl_lib (void)
{
uninit_crypto_lib ();
EVP_cleanup ();
ERR_free_strings ();
}
#endif /* USE_SSL */
#endif /* USE_CRYPTO */