/*
* Copyright (C) 2009-2010 Martin Willi
* Hochschule fuer Technik Rapperswil
* Copyright (C) 2010 revosec AG
*
* 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.
*/
#define _GNU_SOURCE
#include <dlfcn.h>
#include <time.h>
#include "crypto_tester.h"
#include <debug.h>
#include <utils/linked_list.h>
typedef struct private_crypto_tester_t private_crypto_tester_t;
/**
* Private data of an crypto_tester_t object.
*/
struct private_crypto_tester_t {
/**
* Public crypto_tester_t interface.
*/
crypto_tester_t public;
/**
* List of crypter test vectors
*/
linked_list_t *crypter;
/**
* List of aead test vectors
*/
linked_list_t *aead;
/**
* List of signer test vectors
*/
linked_list_t *signer;
/**
* List of hasher test vectors
*/
linked_list_t *hasher;
/**
* List of PRF test vectors
*/
linked_list_t *prf;
/**
* List of RNG test vectors
*/
linked_list_t *rng;
/**
* Is a test vector required to pass a test?
*/
bool required;
/**
* should we run RNG_TRUE tests? Enough entropy?
*/
bool rng_true;
/**
* time we test each algorithm
*/
int bench_time;
/**
* size of buffer we use for benchmarking
*/
int bench_size;
};
/**
* Get the name of a test vector, if available
*/
static const char* get_name(void *sym)
{
#ifdef HAVE_DLADDR
Dl_info dli;
if (dladdr(sym, &dli))
{
return dli.dli_sname;
}
#endif
return "unknown";
}
/**
* Start a benchmark timer
*/
static void start_timing(struct timespec *start)
{
clock_gettime(CLOCK_THREAD_CPUTIME_ID, start);
}
/**
* End a benchmark timer, return ms
*/
static u_int end_timing(struct timespec *start)
{
struct timespec end;
clock_gettime(CLOCK_THREAD_CPUTIME_ID, &end);
return (end.tv_nsec - start->tv_nsec) / 1000000 +
(end.tv_sec - start->tv_sec) * 1000;
}
/**
* Benchmark a crypter
*/
static u_int bench_crypter(private_crypto_tester_t *this,
encryption_algorithm_t alg, crypter_constructor_t create)
{
crypter_t *crypter;
crypter = create(alg, 0);
if (crypter)
{
char iv[crypter->get_iv_size(crypter)];
char key[crypter->get_key_size(crypter)];
chunk_t buf;
struct timespec start;
u_int runs;
memset(iv, 0x56, sizeof(iv));
memset(key, 0x12, sizeof(key));
crypter->set_key(crypter, chunk_from_thing(key));
buf = chunk_alloc(this->bench_size);
memset(buf.ptr, 0x34, buf.len);
runs = 0;
start_timing(&start);
while (end_timing(&start) < this->bench_time)
{
crypter->encrypt(crypter, buf, chunk_from_thing(iv), NULL);
runs++;
crypter->decrypt(crypter, buf, chunk_from_thing(iv), NULL);
runs++;
}
free(buf.ptr);
crypter->destroy(crypter);
return runs;
}
return 0;
}
METHOD(crypto_tester_t, test_crypter, bool,
private_crypto_tester_t *this, encryption_algorithm_t alg, size_t key_size,
<<<<<<< HEAD
crypter_constructor_t create, u_int *speed)
=======
crypter_constructor_t create, u_int *speed, const char *plugin_name)
>>>>>>> upstream/4.5.1
{
enumerator_t *enumerator;
crypter_test_vector_t *vector;
bool failed = FALSE;
u_int tested = 0;
enumerator = this->crypter->create_enumerator(this->crypter);
while (enumerator->enumerate(enumerator, &vector))
{
crypter_t *crypter;
chunk_t key, plain, cipher, iv;
if (vector->alg != alg)
{
continue;
}
if (key_size && key_size != vector->key_size)
{ /* test only vectors with a specific key size, if key size given */
continue;
}
crypter = create(alg, vector->key_size);
if (!crypter)
<<<<<<< HEAD
{ /* key size not supported... */
=======
{
DBG1(DBG_LIB, "%N[%s]: %u bit key size not supported",
encryption_algorithm_names, alg, plugin_name,
BITS_PER_BYTE * vector->key_size);
failed = TRUE;
>>>>>>> upstream/4.5.1
continue;
}
failed = FALSE;
tested++;
key = chunk_create(vector->key, crypter->get_key_size(crypter));
crypter->set_key(crypter, key);
iv = chunk_create(vector->iv, crypter->get_iv_size(crypter));
/* allocated encryption */
plain = chunk_create(vector->plain, vector->len);
crypter->encrypt(crypter, plain, iv, &cipher);
if (!memeq(vector->cipher, cipher.ptr, cipher.len))
{
failed = TRUE;
}
/* inline decryption */
crypter->decrypt(crypter, cipher, iv, NULL);
if (!memeq(vector->plain, cipher.ptr, cipher.len))
{
failed = TRUE;
}
free(cipher.ptr);
/* allocated decryption */
cipher = chunk_create(vector->cipher, vector->len);
crypter->decrypt(crypter, cipher, iv, &plain);
if (!memeq(vector->plain, plain.ptr, plain.len))
{
failed = TRUE;
}
/* inline encryption */
crypter->encrypt(crypter, plain, iv, NULL);
if (!memeq(vector->cipher, plain.ptr, plain.len))
{
failed = TRUE;
}
free(plain.ptr);
crypter->destroy(crypter);
if (failed)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: %s test vector failed",
encryption_algorithm_names, alg, get_name(vector));
=======
DBG1(DBG_LIB, "disabled %N[%s]: %s test vector failed",
encryption_algorithm_names, alg, plugin_name, get_name(vector));
>>>>>>> upstream/4.5.1
break;
}
}
enumerator->destroy(enumerator);
if (!tested)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "%s %N: no test vectors found",
this->required ? "disabled" : "enabled ",
encryption_algorithm_names, alg);
return !this->required;
=======
if (failed)
{
DBG1(DBG_LIB,"disable %N[%s]: no key size supported",
encryption_algorithm_names, alg, plugin_name);
return FALSE;
}
else
{
DBG1(DBG_LIB, "%s %N[%s]: no test vectors found",
this->required ? "disabled" : "enabled ",
encryption_algorithm_names, alg, plugin_name);
return !this->required;
}
>>>>>>> upstream/4.5.1
}
if (!failed)
{
if (speed)
{
*speed = bench_crypter(this, alg, create);
<<<<<<< HEAD
DBG1(DBG_LIB, "enabled %N: passed %u test vectors, %d points",
encryption_algorithm_names, alg, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N: passed %u test vectors",
encryption_algorithm_names, alg, tested);
=======
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors, %d points",
encryption_algorithm_names, alg, tested, plugin_name, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors",
encryption_algorithm_names, alg, plugin_name, tested);
>>>>>>> upstream/4.5.1
}
}
return !failed;
}
/**
* Benchmark an aead transform
*/
static u_int bench_aead(private_crypto_tester_t *this,
encryption_algorithm_t alg, aead_constructor_t create)
{
aead_t *aead;
aead = create(alg, 0);
if (aead)
{
char iv[aead->get_iv_size(aead)];
char key[aead->get_key_size(aead)];
char assoc[4];
chunk_t buf;
struct timespec start;
u_int runs;
size_t icv;
memset(iv, 0x56, sizeof(iv));
memset(key, 0x12, sizeof(key));
memset(assoc, 0x78, sizeof(assoc));
aead->set_key(aead, chunk_from_thing(key));
icv = aead->get_icv_size(aead);
buf = chunk_alloc(this->bench_size + icv);
memset(buf.ptr, 0x34, buf.len);
buf.len -= icv;
runs = 0;
start_timing(&start);
while (end_timing(&start) < this->bench_time)
{
aead->encrypt(aead, buf, chunk_from_thing(assoc),
chunk_from_thing(iv), NULL);
runs += 2;
aead->decrypt(aead, chunk_create(buf.ptr, buf.len + icv),
chunk_from_thing(assoc), chunk_from_thing(iv), NULL);
runs += 2;
}
free(buf.ptr);
aead->destroy(aead);
return runs;
}
return 0;
}
METHOD(crypto_tester_t, test_aead, bool,
private_crypto_tester_t *this, encryption_algorithm_t alg, size_t key_size,
<<<<<<< HEAD
aead_constructor_t create, u_int *speed)
=======
aead_constructor_t create, u_int *speed, const char *plugin_name)
>>>>>>> upstream/4.5.1
{
enumerator_t *enumerator;
aead_test_vector_t *vector;
bool failed = FALSE;
u_int tested = 0;
enumerator = this->aead->create_enumerator(this->aead);
while (enumerator->enumerate(enumerator, &vector))
{
aead_t *aead;
chunk_t key, plain, cipher, iv, assoc;
size_t icv;
if (vector->alg != alg)
{
continue;
}
if (key_size && key_size != vector->key_size)
{ /* test only vectors with a specific key size, if key size given */
continue;
}
aead = create(alg, vector->key_size);
if (!aead)
<<<<<<< HEAD
{ /* key size not supported... */
=======
{
DBG1(DBG_LIB, "%N[%s]: %u bit key size not supported",
encryption_algorithm_names, alg, plugin_name,
BITS_PER_BYTE * vector->key_size);
failed = TRUE;
>>>>>>> upstream/4.5.1
continue;
}
failed = FALSE;
tested++;
key = chunk_create(vector->key, aead->get_key_size(aead));
aead->set_key(aead, key);
iv = chunk_create(vector->iv, aead->get_iv_size(aead));
assoc = chunk_create(vector->adata, vector->alen);
icv = aead->get_icv_size(aead);
/* allocated encryption */
plain = chunk_create(vector->plain, vector->len);
aead->encrypt(aead, plain, assoc, iv, &cipher);
if (!memeq(vector->cipher, cipher.ptr, cipher.len))
{
failed = TRUE;
}
/* inline decryption */
if (!aead->decrypt(aead, cipher, assoc, iv, NULL))
{
failed = TRUE;
}
if (!memeq(vector->plain, cipher.ptr, cipher.len - icv))
{
failed = TRUE;
}
free(cipher.ptr);
/* allocated decryption */
cipher = chunk_create(vector->cipher, vector->len + icv);
if (!aead->decrypt(aead, cipher, assoc, iv, &plain))
{
plain = chunk_empty;
failed = TRUE;
}
else if (!memeq(vector->plain, plain.ptr, plain.len))
{
failed = TRUE;
}
plain.ptr = realloc(plain.ptr, plain.len + icv);
/* inline encryption */
aead->encrypt(aead, plain, assoc, iv, NULL);
if (!memeq(vector->cipher, plain.ptr, plain.len + icv))
{
failed = TRUE;
}
free(plain.ptr);
aead->destroy(aead);
if (failed)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: %s test vector failed",
encryption_algorithm_names, alg, get_name(vector));
=======
DBG1(DBG_LIB, "disabled %N[%s]: %s test vector failed",
encryption_algorithm_names, alg, plugin_name, get_name(vector));
>>>>>>> upstream/4.5.1
break;
}
}
enumerator->destroy(enumerator);
if (!tested)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "%s %N: no test vectors found",
this->required ? "disabled" : "enabled ",
encryption_algorithm_names, alg);
return !this->required;
=======
if (failed)
{
DBG1(DBG_LIB,"disable %N[%s]: no key size supported",
encryption_algorithm_names, alg, plugin_name);
return FALSE;
}
else
{
DBG1(DBG_LIB, "%s %N[%s]: no test vectors found",
this->required ? "disabled" : "enabled ",
encryption_algorithm_names, alg, plugin_name);
return !this->required;
}
>>>>>>> upstream/4.5.1
}
if (!failed)
{
if (speed)
{
*speed = bench_aead(this, alg, create);
<<<<<<< HEAD
DBG1(DBG_LIB, "enabled %N: passed %u test vectors, %d points",
encryption_algorithm_names, alg, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N: passed %u test vectors",
encryption_algorithm_names, alg, tested);
=======
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors, %d points",
encryption_algorithm_names, alg, plugin_name, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors",
encryption_algorithm_names, alg, plugin_name, tested);
>>>>>>> upstream/4.5.1
}
}
return !failed;
}
/**
* Benchmark a signer
*/
static u_int bench_signer(private_crypto_tester_t *this,
encryption_algorithm_t alg, signer_constructor_t create)
{
signer_t *signer;
signer = create(alg);
if (signer)
{
char key[signer->get_key_size(signer)];
char mac[signer->get_block_size(signer)];
chunk_t buf;
struct timespec start;
u_int runs;
memset(key, 0x12, sizeof(key));
signer->set_key(signer, chunk_from_thing(key));
buf = chunk_alloc(this->bench_size);
memset(buf.ptr, 0x34, buf.len);
runs = 0;
start_timing(&start);
while (end_timing(&start) < this->bench_time)
{
signer->get_signature(signer, buf, mac);
runs++;
signer->verify_signature(signer, buf, chunk_from_thing(mac));
runs++;
}
free(buf.ptr);
signer->destroy(signer);
return runs;
}
return 0;
}
METHOD(crypto_tester_t, test_signer, bool,
private_crypto_tester_t *this, integrity_algorithm_t alg,
<<<<<<< HEAD
signer_constructor_t create, u_int *speed)
=======
signer_constructor_t create, u_int *speed, const char *plugin_name)
>>>>>>> upstream/4.5.1
{
enumerator_t *enumerator;
signer_test_vector_t *vector;
bool failed = FALSE;
u_int tested = 0;
enumerator = this->signer->create_enumerator(this->signer);
while (enumerator->enumerate(enumerator, &vector))
{
signer_t *signer;
chunk_t key, data, mac;
if (vector->alg != alg)
{
continue;
}
tested++;
signer = create(alg);
if (!signer)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: creating instance failed",
integrity_algorithm_names, alg);
=======
DBG1(DBG_LIB, "disabled %N[%s]: creating instance failed",
integrity_algorithm_names, alg, plugin_name);
>>>>>>> upstream/4.5.1
failed = TRUE;
break;
}
failed = FALSE;
key = chunk_create(vector->key, signer->get_key_size(signer));
signer->set_key(signer, key);
/* allocated signature */
data = chunk_create(vector->data, vector->len);
signer->allocate_signature(signer, data, &mac);
if (mac.len != signer->get_block_size(signer))
{
failed = TRUE;
}
if (!memeq(vector->mac, mac.ptr, mac.len))
{
failed = TRUE;
}
/* signature to existing buffer */
memset(mac.ptr, 0, mac.len);
signer->get_signature(signer, data, mac.ptr);
if (!memeq(vector->mac, mac.ptr, mac.len))
{
failed = TRUE;
}
/* signature verification, good case */
if (!signer->verify_signature(signer, data, mac))
{
failed = TRUE;
}
/* signature verification, bad case */
*(mac.ptr + mac.len - 1) += 1;
if (signer->verify_signature(signer, data, mac))
{
failed = TRUE;
}
/* signature to existing buffer, using append mode */
if (data.len > 2)
{
signer->allocate_signature(signer, chunk_create(data.ptr, 1), NULL);
signer->get_signature(signer, chunk_create(data.ptr + 1, 1), NULL);
if (!signer->verify_signature(signer, chunk_skip(data, 2),
chunk_create(vector->mac, mac.len)))
{
failed = TRUE;
}
}
free(mac.ptr);
signer->destroy(signer);
if (failed)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: %s test vector failed",
integrity_algorithm_names, alg, get_name(vector));
=======
DBG1(DBG_LIB, "disabled %N[%s]: %s test vector failed",
integrity_algorithm_names, alg, plugin_name, get_name(vector));
>>>>>>> upstream/4.5.1
break;
}
}
enumerator->destroy(enumerator);
if (!tested)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "%s %N: no test vectors found",
this->required ? "disabled" : "enabled ",
integrity_algorithm_names, alg);
=======
DBG1(DBG_LIB, "%s %N[%s]: no test vectors found",
this->required ? "disabled" : "enabled ",
integrity_algorithm_names, alg, plugin_name);
>>>>>>> upstream/4.5.1
return !this->required;
}
if (!failed)
{
if (speed)
{
*speed = bench_signer(this, alg, create);
<<<<<<< HEAD
DBG1(DBG_LIB, "enabled %N: passed %u test vectors, %d points",
integrity_algorithm_names, alg, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N: passed %u test vectors",
integrity_algorithm_names, alg, tested);
=======
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors, %d points",
integrity_algorithm_names, alg, plugin_name, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors",
integrity_algorithm_names, alg, plugin_name, tested);
>>>>>>> upstream/4.5.1
}
}
return !failed;
}
/**
* Benchmark a hasher
*/
static u_int bench_hasher(private_crypto_tester_t *this,
hash_algorithm_t alg, hasher_constructor_t create)
{
hasher_t *hasher;
hasher = create(alg);
if (hasher)
{
char hash[hasher->get_hash_size(hasher)];
chunk_t buf;
struct timespec start;
u_int runs;
buf = chunk_alloc(this->bench_size);
memset(buf.ptr, 0x34, buf.len);
runs = 0;
start_timing(&start);
while (end_timing(&start) < this->bench_time)
{
hasher->get_hash(hasher, buf, hash);
runs++;
}
free(buf.ptr);
hasher->destroy(hasher);
return runs;
}
return 0;
}
METHOD(crypto_tester_t, test_hasher, bool,
private_crypto_tester_t *this, hash_algorithm_t alg,
<<<<<<< HEAD
hasher_constructor_t create, u_int *speed)
=======
hasher_constructor_t create, u_int *speed, const char *plugin_name)
>>>>>>> upstream/4.5.1
{
enumerator_t *enumerator;
hasher_test_vector_t *vector;
bool failed = FALSE;
u_int tested = 0;
enumerator = this->hasher->create_enumerator(this->hasher);
while (enumerator->enumerate(enumerator, &vector))
{
hasher_t *hasher;
chunk_t data, hash;
if (vector->alg != alg)
{
continue;
}
tested++;
hasher = create(alg);
if (!hasher)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: creating instance failed",
hash_algorithm_names, alg);
=======
DBG1(DBG_LIB, "disabled %N[%s]: creating instance failed",
hash_algorithm_names, alg, plugin_name);
>>>>>>> upstream/4.5.1
failed = TRUE;
break;
}
failed = FALSE;
/* allocated hash */
data = chunk_create(vector->data, vector->len);
hasher->allocate_hash(hasher, data, &hash);
if (hash.len != hasher->get_hash_size(hasher))
{
failed = TRUE;
}
if (!memeq(vector->hash, hash.ptr, hash.len))
{
failed = TRUE;
}
/* hash to existing buffer */
memset(hash.ptr, 0, hash.len);
hasher->get_hash(hasher, data, hash.ptr);
if (!memeq(vector->hash, hash.ptr, hash.len))
{
failed = TRUE;
}
/* hasher to existing buffer, using append mode */
if (data.len > 2)
{
memset(hash.ptr, 0, hash.len);
hasher->allocate_hash(hasher, chunk_create(data.ptr, 1), NULL);
hasher->get_hash(hasher, chunk_create(data.ptr + 1, 1), NULL);
hasher->get_hash(hasher, chunk_skip(data, 2), hash.ptr);
if (!memeq(vector->hash, hash.ptr, hash.len))
{
failed = TRUE;
}
}
free(hash.ptr);
hasher->destroy(hasher);
if (failed)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: %s test vector failed",
hash_algorithm_names, alg, get_name(vector));
=======
DBG1(DBG_LIB, "disabled %N[%s]: %s test vector failed",
hash_algorithm_names, alg, plugin_name, get_name(vector));
>>>>>>> upstream/4.5.1
break;
}
}
enumerator->destroy(enumerator);
if (!tested)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "%s %N: no test vectors found",
this->required ? "disabled" : "enabled ",
hash_algorithm_names, alg);
=======
DBG1(DBG_LIB, "%s %N[%s]: no test vectors found",
this->required ? "disabled" : "enabled ",
hash_algorithm_names, alg, plugin_name);
>>>>>>> upstream/4.5.1
return !this->required;
}
if (!failed)
{
if (speed)
{
*speed = bench_hasher(this, alg, create);
<<<<<<< HEAD
DBG1(DBG_LIB, "enabled %N: passed %u test vectors, %d points",
hash_algorithm_names, alg, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N: passed %u test vectors",
hash_algorithm_names, alg, tested);
=======
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors, %d points",
hash_algorithm_names, alg, plugin_name, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors",
hash_algorithm_names, alg, plugin_name, tested);
>>>>>>> upstream/4.5.1
}
}
return !failed;
}
/**
* Benchmark a PRF
*/
static u_int bench_prf(private_crypto_tester_t *this,
pseudo_random_function_t alg, prf_constructor_t create)
{
prf_t *prf;
prf = create(alg);
if (prf)
{
char bytes[prf->get_block_size(prf)];
chunk_t buf;
struct timespec start;
u_int runs;
buf = chunk_alloc(this->bench_size);
memset(buf.ptr, 0x34, buf.len);
runs = 0;
start_timing(&start);
while (end_timing(&start) < this->bench_time)
{
prf->get_bytes(prf, buf, bytes);
runs++;
}
free(buf.ptr);
prf->destroy(prf);
return runs;
}
return 0;
}
METHOD(crypto_tester_t, test_prf, bool,
private_crypto_tester_t *this, pseudo_random_function_t alg,
<<<<<<< HEAD
prf_constructor_t create, u_int *speed)
=======
prf_constructor_t create, u_int *speed, const char *plugin_name)
>>>>>>> upstream/4.5.1
{
enumerator_t *enumerator;
prf_test_vector_t *vector;
bool failed = FALSE;
u_int tested = 0;
enumerator = this->prf->create_enumerator(this->prf);
while (enumerator->enumerate(enumerator, &vector))
{
prf_t *prf;
chunk_t key, seed, out;
if (vector->alg != alg)
{
continue;
}
tested++;
prf = create(alg);
if (!prf)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: creating instance failed",
pseudo_random_function_names, alg);
=======
DBG1(DBG_LIB, "disabled %N[%s]: creating instance failed",
pseudo_random_function_names, alg, plugin_name);
>>>>>>> upstream/4.5.1
failed = TRUE;
break;
}
failed = FALSE;
key = chunk_create(vector->key, vector->key_size);
prf->set_key(prf, key);
/* allocated bytes */
seed = chunk_create(vector->seed, vector->len);
prf->allocate_bytes(prf, seed, &out);
if (out.len != prf->get_block_size(prf))
{
failed = TRUE;
}
if (!memeq(vector->out, out.ptr, out.len))
{
failed = TRUE;
}
/* bytes to existing buffer */
memset(out.ptr, 0, out.len);
if (vector->stateful)
{
prf->set_key(prf, key);
}
prf->get_bytes(prf, seed, out.ptr);
if (!memeq(vector->out, out.ptr, out.len))
{
failed = TRUE;
}
/* bytes to existing buffer, using append mode */
if (seed.len > 2)
{
memset(out.ptr, 0, out.len);
if (vector->stateful)
{
prf->set_key(prf, key);
}
prf->allocate_bytes(prf, chunk_create(seed.ptr, 1), NULL);
prf->get_bytes(prf, chunk_create(seed.ptr + 1, 1), NULL);
prf->get_bytes(prf, chunk_skip(seed, 2), out.ptr);
if (!memeq(vector->out, out.ptr, out.len))
{
failed = TRUE;
}
}
free(out.ptr);
prf->destroy(prf);
if (failed)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: %s test vector failed",
pseudo_random_function_names, alg, get_name(vector));
=======
DBG1(DBG_LIB, "disabled %N[%s]: %s test vector failed",
pseudo_random_function_names, alg, plugin_name, get_name(vector));
>>>>>>> upstream/4.5.1
break;
}
}
enumerator->destroy(enumerator);
if (!tested)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "%s %N: no test vectors found",
this->required ? "disabled" : "enabled ",
pseudo_random_function_names, alg);
=======
DBG1(DBG_LIB, "%s %N[%s]: no test vectors found",
this->required ? "disabled" : "enabled ",
pseudo_random_function_names, alg, plugin_name);
>>>>>>> upstream/4.5.1
return !this->required;
}
if (!failed)
{
if (speed)
{
*speed = bench_prf(this, alg, create);
<<<<<<< HEAD
DBG1(DBG_LIB, "enabled %N: passed %u test vectors, %d points",
pseudo_random_function_names, alg, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N: passed %u test vectors",
pseudo_random_function_names, alg, tested);
=======
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors, %d points",
pseudo_random_function_names, alg, plugin_name, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors",
pseudo_random_function_names, alg, plugin_name, tested);
>>>>>>> upstream/4.5.1
}
}
return !failed;
}
/**
* Benchmark a RNG
*/
static u_int bench_rng(private_crypto_tester_t *this,
rng_quality_t quality, rng_constructor_t create)
{
rng_t *rng;
rng = create(quality);
if (rng)
{
struct timespec start;
chunk_t buf;
u_int runs;
runs = 0;
buf = chunk_alloc(this->bench_size);
start_timing(&start);
while (end_timing(&start) < this->bench_time)
{
rng->get_bytes(rng, buf.len, buf.ptr);
runs++;
}
free(buf.ptr);
rng->destroy(rng);
return runs;
}
return 0;
}
METHOD(crypto_tester_t, test_rng, bool,
private_crypto_tester_t *this, rng_quality_t quality,
<<<<<<< HEAD
rng_constructor_t create, u_int *speed)
=======
rng_constructor_t create, u_int *speed, const char *plugin_name)
>>>>>>> upstream/4.5.1
{
enumerator_t *enumerator;
rng_test_vector_t *vector;
bool failed = FALSE;
u_int tested = 0;
if (!this->rng_true && quality == RNG_TRUE)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "enabled %N: skipping test (disabled by config)",
rng_quality_names, quality);
=======
DBG1(DBG_LIB, "enabled %N[%s]: skipping test (disabled by config)",
rng_quality_names, quality, plugin_name);
>>>>>>> upstream/4.5.1
return TRUE;
}
enumerator = this->rng->create_enumerator(this->rng);
while (enumerator->enumerate(enumerator, &vector))
{
rng_t *rng;
chunk_t data;
if (vector->quality != quality)
{
continue;
}
tested++;
rng = create(quality);
if (!rng)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: creating instance failed",
rng_quality_names, quality);
=======
DBG1(DBG_LIB, "disabled %N[%s]: creating instance failed",
rng_quality_names, quality, plugin_name);
>>>>>>> upstream/4.5.1
failed = TRUE;
break;
}
failed = FALSE;
/* allocated bytes */
rng->allocate_bytes(rng, vector->len, &data);
if (data.len != vector->len)
{
failed = TRUE;
}
if (!vector->test(vector->user, data))
{
failed = TRUE;
}
/* bytes to existing buffer */
memset(data.ptr, 0, data.len);
rng->get_bytes(rng, vector->len, data.ptr);
if (!vector->test(vector->user, data))
{
failed = TRUE;
}
free(data.ptr);
rng->destroy(rng);
if (failed)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "disabled %N: %s test vector failed",
rng_quality_names, quality, get_name(vector));
=======
DBG1(DBG_LIB, "disabled %N[%s]: %s test vector failed",
rng_quality_names, quality, plugin_name, get_name(vector));
>>>>>>> upstream/4.5.1
break;
}
}
enumerator->destroy(enumerator);
if (!tested)
{
<<<<<<< HEAD
DBG1(DBG_LIB, "%s %N: no test vectors found",
this->required ? ", disabled" : "enabled ",
rng_quality_names, quality);
=======
DBG1(DBG_LIB, "%s %N[%s]: no test vectors found",
this->required ? ", disabled" : "enabled ",
rng_quality_names, quality, plugin_name);
>>>>>>> upstream/4.5.1
return !this->required;
}
if (!failed)
{
if (speed)
{
*speed = bench_rng(this, quality, create);
<<<<<<< HEAD
DBG1(DBG_LIB, "enabled %N: passed %u test vectors, %d points",
rng_quality_names, quality, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N: passed %u test vectors",
rng_quality_names, quality, tested);
=======
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors, %d points",
rng_quality_names, quality, plugin_name, tested, *speed);
}
else
{
DBG1(DBG_LIB, "enabled %N[%s]: passed %u test vectors",
rng_quality_names, quality, plugin_name, tested);
>>>>>>> upstream/4.5.1
}
}
return !failed;
}
METHOD(crypto_tester_t, add_crypter_vector, void,
private_crypto_tester_t *this, crypter_test_vector_t *vector)
{
this->crypter->insert_last(this->crypter, vector);
}
METHOD(crypto_tester_t, add_aead_vector, void,
private_crypto_tester_t *this, aead_test_vector_t *vector)
{
this->aead->insert_last(this->aead, vector);
}
METHOD(crypto_tester_t, add_signer_vector, void,
private_crypto_tester_t *this, signer_test_vector_t *vector)
{
this->signer->insert_last(this->signer, vector);
}
METHOD(crypto_tester_t, add_hasher_vector, void,
private_crypto_tester_t *this, hasher_test_vector_t *vector)
{
this->hasher->insert_last(this->hasher, vector);
}
METHOD(crypto_tester_t, add_prf_vector, void,
private_crypto_tester_t *this, prf_test_vector_t *vector)
{
this->prf->insert_last(this->prf, vector);
}
METHOD(crypto_tester_t, add_rng_vector, void,
private_crypto_tester_t *this, rng_test_vector_t *vector)
{
this->rng->insert_last(this->rng, vector);
}
METHOD(crypto_tester_t, destroy, void,
private_crypto_tester_t *this)
{
this->crypter->destroy(this->crypter);
this->aead->destroy(this->aead);
this->signer->destroy(this->signer);
this->hasher->destroy(this->hasher);
this->prf->destroy(this->prf);
this->rng->destroy(this->rng);
free(this);
}
/**
* See header
*/
crypto_tester_t *crypto_tester_create()
{
private_crypto_tester_t *this;
INIT(this,
.public = {
.test_crypter = _test_crypter,
.test_aead = _test_aead,
.test_signer = _test_signer,
.test_hasher = _test_hasher,
.test_prf = _test_prf,
.test_rng = _test_rng,
.add_crypter_vector = _add_crypter_vector,
.add_aead_vector = _add_aead_vector,
.add_signer_vector = _add_signer_vector,
.add_hasher_vector = _add_hasher_vector,
.add_prf_vector = _add_prf_vector,
.add_rng_vector = _add_rng_vector,
.destroy = _destroy,
},
.crypter = linked_list_create(),
.aead = linked_list_create(),
.signer = linked_list_create(),
.hasher = linked_list_create(),
.prf = linked_list_create(),
.rng = linked_list_create(),
.required = lib->settings->get_bool(lib->settings,
"libstrongswan.crypto_test.required", FALSE),
.rng_true = lib->settings->get_bool(lib->settings,
"libstrongswan.crypto_test.rng_true", FALSE),
.bench_time = lib->settings->get_int(lib->settings,
"libstrongswan.crypto_test.bench_time", 50),
.bench_size = lib->settings->get_int(lib->settings,
"libstrongswan.crypto_test.bench_size", 1024),
);
/* enforce a block size of 16, should be fine for all algorithms */
this->bench_size = this->bench_size / 16 * 16;
return &this->public;
}