#define SHARED_RANDOM_PRIVATE
#define SHARED_RANDOM_STATE_PRIVATE
#define CONFIG_PRIVATE
#define DIRVOTE_PRIVATE
#include "or.h"
#include "test.h"
#include "config.h"
#include "dirvote.h"
#include "shared_random.h"
#include "shared_random_state.h"
#include "routerkeys.h"
#include "routerlist.h"
#include "router.h"
#include "routerparse.h"
#include "networkstatus.h"
static authority_cert_t *mock_cert;
static authority_cert_t *
get_my_v3_authority_cert_m(void)
{
tor_assert(mock_cert);
return mock_cert;
}
static dir_server_t ds;
static dir_server_t *
trusteddirserver_get_by_v3_auth_digest_m(const char *digest)
{
(void) digest;
/* The shared random code only need to know if a valid pointer to a dir
* server object has been found so this is safe because it won't use the
* pointer at all never. */
return &ds;
}
/* Setup a minimal dirauth environment by initializing the SR state and
* making sure the options are set to be an authority directory. */
static void
init_authority_state(void)
{
MOCK(get_my_v3_authority_cert, get_my_v3_authority_cert_m);
or_options_t *options = get_options_mutable();
mock_cert = authority_cert_parse_from_string(AUTHORITY_CERT_1, NULL);
tt_assert(mock_cert);
options->AuthoritativeDir = 1;
tt_int_op(0, ==, load_ed_keys(options, time(NULL)));
sr_state_init(0, 0);
/* It's possible a commit has been generated in our state depending on
* the phase we are currently in which uses "now" as the starting
* timestamp. Delete it before we do any testing below. */
sr_state_delete_commits();
done:
UNMOCK(get_my_v3_authority_cert);
}
static void
test_get_sr_protocol_phase(void *arg)
{
time_t the_time;
sr_phase_t phase;
int retval;
(void) arg;
/* Initialize SR state */
init_authority_state();
{
retval = parse_rfc1123_time("Wed, 20 Apr 2015 23:59:00 UTC", &the_time);
tt_int_op(retval, ==, 0);
phase = get_sr_protocol_phase(the_time);
tt_int_op(phase, ==, SR_PHASE_REVEAL);
}
{
retval = parse_rfc1123_time("Wed, 20 Apr 2015 00:00:00 UTC", &the_time);
tt_int_op(retval, ==, 0);
phase = get_sr_protocol_phase(the_time);
tt_int_op(phase, ==, SR_PHASE_COMMIT);
}
{
retval = parse_rfc1123_time("Wed, 20 Apr 2015 00:00:01 UTC", &the_time);
tt_int_op(retval, ==, 0);
phase = get_sr_protocol_phase(the_time);
tt_int_op(phase, ==, SR_PHASE_COMMIT);
}
{
retval = parse_rfc1123_time("Wed, 20 Apr 2015 11:59:00 UTC", &the_time);
tt_int_op(retval, ==, 0);
phase = get_sr_protocol_phase(the_time);
tt_int_op(phase, ==, SR_PHASE_COMMIT);
}
{
retval = parse_rfc1123_time("Wed, 20 Apr 2015 12:00:00 UTC", &the_time);
tt_int_op(retval, ==, 0);
phase = get_sr_protocol_phase(the_time);
tt_int_op(phase, ==, SR_PHASE_REVEAL);
}
{
retval = parse_rfc1123_time("Wed, 20 Apr 2015 12:00:01 UTC", &the_time);
tt_int_op(retval, ==, 0);
phase = get_sr_protocol_phase(the_time);
tt_int_op(phase, ==, SR_PHASE_REVEAL);
}
{
retval = parse_rfc1123_time("Wed, 20 Apr 2015 13:00:00 UTC", &the_time);
tt_int_op(retval, ==, 0);
phase = get_sr_protocol_phase(the_time);
tt_int_op(phase, ==, SR_PHASE_REVEAL);
}
done:
;
}
static networkstatus_t *mock_consensus = NULL;
static void
test_get_state_valid_until_time(void *arg)
{
time_t current_time;
time_t valid_until_time;
char tbuf[ISO_TIME_LEN + 1];
int retval;
(void) arg;
{
/* Get the valid until time if called at 00:00:01 */
retval = parse_rfc1123_time("Mon, 20 Apr 2015 00:00:01 UTC",
¤t_time);
tt_int_op(retval, ==, 0);
valid_until_time = get_state_valid_until_time(current_time);
/* Compare it with the correct result */
format_iso_time(tbuf, valid_until_time);
tt_str_op("2015-04-21 00:00:00", OP_EQ, tbuf);
}
{
retval = parse_rfc1123_time("Mon, 20 Apr 2015 19:22:00 UTC",
¤t_time);
tt_int_op(retval, ==, 0);
valid_until_time = get_state_valid_until_time(current_time);
format_iso_time(tbuf, valid_until_time);
tt_str_op("2015-04-21 00:00:00", OP_EQ, tbuf);
}
{
retval = parse_rfc1123_time("Mon, 20 Apr 2015 23:59:00 UTC",
¤t_time);
tt_int_op(retval, ==, 0);
valid_until_time = get_state_valid_until_time(current_time);
format_iso_time(tbuf, valid_until_time);
tt_str_op("2015-04-21 00:00:00", OP_EQ, tbuf);
}
{
retval = parse_rfc1123_time("Mon, 20 Apr 2015 00:00:00 UTC",
¤t_time);
tt_int_op(retval, ==, 0);
valid_until_time = get_state_valid_until_time(current_time);
format_iso_time(tbuf, valid_until_time);
tt_str_op("2015-04-21 00:00:00", OP_EQ, tbuf);
}
done:
;
}
/* Mock function to immediately return our local 'mock_consensus'. */
static networkstatus_t *
mock_networkstatus_get_live_consensus(time_t now)
{
(void) now;
return mock_consensus;
}
/** Test the get_next_valid_after_time() function. */
static void
test_get_next_valid_after_time(void *arg)
{
time_t current_time;
time_t valid_after_time;
char tbuf[ISO_TIME_LEN + 1];
int retval;
(void) arg;
{
/* Setup a fake consensus just to get the times out of it, since
get_next_valid_after_time() needs them. */
mock_consensus = tor_malloc_zero(sizeof(networkstatus_t));
retval = parse_rfc1123_time("Mon, 13 Jan 2016 16:00:00 UTC",
&mock_consensus->fresh_until);
tt_int_op(retval, ==, 0);
retval = parse_rfc1123_time("Mon, 13 Jan 2016 15:00:00 UTC",
&mock_consensus->valid_after);
tt_int_op(retval, ==, 0);
MOCK(networkstatus_get_live_consensus,
mock_networkstatus_get_live_consensus);
}
{
/* Get the valid after time if called at 00:00:00 */
retval = parse_rfc1123_time("Mon, 20 Apr 2015 00:00:00 UTC",
¤t_time);
tt_int_op(retval, ==, 0);
valid_after_time = get_next_valid_after_time(current_time);
/* Compare it with the correct result */
format_iso_time(tbuf, valid_after_time);
tt_str_op("2015-04-20 01:00:00", OP_EQ, tbuf);
}
{
/* Get the valid until time if called at 00:00:01 */
retval = parse_rfc1123_time("Mon, 20 Apr 2015 00:00:01 UTC",
¤t_time);
tt_int_op(retval, ==, 0);
valid_after_time = get_next_valid_after_time(current_time);
/* Compare it with the correct result */
format_iso_time(tbuf, valid_after_time);
tt_str_op("2015-04-20 01:00:00", OP_EQ, tbuf);
}
{
retval = parse_rfc1123_time("Mon, 20 Apr 2015 23:30:01 UTC",
¤t_time);
tt_int_op(retval, ==, 0);
valid_after_time = get_next_valid_after_time(current_time);
/* Compare it with the correct result */
format_iso_time(tbuf, valid_after_time);
tt_str_op("2015-04-21 00:00:00", OP_EQ, tbuf);
}
done:
networkstatus_vote_free(mock_consensus);
}
/* In this test we are going to generate a sr_commit_t object and validate
* it. We first generate our values, and then we parse them as if they were
* received from the network. After we parse both the commit and the reveal,
* we verify that they indeed match. */
static void
test_sr_commit(void *arg)
{
authority_cert_t *auth_cert = NULL;
time_t now = time(NULL);
sr_commit_t *our_commit = NULL;
smartlist_t *args = smartlist_new();
(void) arg;
{ /* Setup a minimal dirauth environment for this test */
or_options_t *options = get_options_mutable();
auth_cert = authority_cert_parse_from_string(AUTHORITY_CERT_1, NULL);
tt_assert(auth_cert);
options->AuthoritativeDir = 1;
tt_int_op(0, ==, load_ed_keys(options, now));
}
/* Generate our commit object and validate it has the appropriate field
* that we can then use to build a representation that we'll find in a
* vote coming from the network. */
{
sr_commit_t test_commit;
our_commit = sr_generate_our_commit(now, auth_cert);
tt_assert(our_commit);
/* Default and only supported algorithm for now. */
tt_assert(our_commit->alg == DIGEST_SHA3_256);
/* We should have a reveal value. */
tt_assert(commit_has_reveal_value(our_commit));
/* We should have a random value. */
tt_assert(!tor_mem_is_zero((char *) our_commit->random_number,
sizeof(our_commit->random_number)));
/* Commit and reveal timestamp should be the same. */
tt_u64_op(our_commit->commit_ts, ==, our_commit->reveal_ts);
/* We should have a hashed reveal. */
tt_assert(!tor_mem_is_zero(our_commit->hashed_reveal,
sizeof(our_commit->hashed_reveal)));
/* Do we have a valid encoded commit and reveal. Note the following only
* tests if the generated values are correct. Their could be a bug in
* the decode function but we test them seperately. */
tt_int_op(0, ==, reveal_decode(our_commit->encoded_reveal,
&test_commit));
tt_int_op(0, ==, commit_decode(our_commit->encoded_commit,
&test_commit));
tt_int_op(0, ==, verify_commit_and_reveal(our_commit));
}
/* Let's make sure our verify commit and reveal function works. We'll
* make it fail a bit with known failure case. */
{
/* Copy our commit so we don't alter it for the rest of testing. */
sr_commit_t test_commit;
memcpy(&test_commit, our_commit, sizeof(test_commit));
/* Timestamp MUST match. */
test_commit.commit_ts = test_commit.reveal_ts - 42;
tt_int_op(-1, ==, verify_commit_and_reveal(&test_commit));
memcpy(&test_commit, our_commit, sizeof(test_commit));
tt_int_op(0, ==, verify_commit_and_reveal(&test_commit));
/* Hashed reveal must match the H(encoded_reveal). */
memset(test_commit.hashed_reveal, 'X',
sizeof(test_commit.hashed_reveal));
tt_int_op(-1, ==, verify_commit_and_reveal(&test_commit));
memcpy(&test_commit, our_commit, sizeof(test_commit));
tt_int_op(0, ==, verify_commit_and_reveal(&test_commit));
}
/* We'll build a list of values from our commit that our parsing function
* takes from a vote line and see if we can parse it correctly. */
{
sr_commit_t *parsed_commit;
smartlist_add(args, tor_strdup("1"));
smartlist_add(args,
tor_strdup(crypto_digest_algorithm_get_name(our_commit->alg)));
smartlist_add(args, tor_strdup(sr_commit_get_rsa_fpr(our_commit)));
smartlist_add(args, our_commit->encoded_commit);
smartlist_add(args, our_commit->encoded_reveal);
parsed_commit = sr_parse_commit(args);
tt_assert(parsed_commit);
/* That parsed commit should be _EXACTLY_ like our original commit (we
* have to explicitly set the valid flag though). */
parsed_commit->valid = 1;
tt_mem_op(parsed_commit, OP_EQ, our_commit, sizeof(*parsed_commit));
/* Cleanup */
tor_free(smartlist_get(args, 0)); /* strdup here. */
tor_free(smartlist_get(args, 1)); /* strdup here. */
smartlist_clear(args);
sr_commit_free(parsed_commit);
}
done:
smartlist_free(args);
sr_commit_free(our_commit);
}
/* Test the encoding and decoding function for commit and reveal values. */
static void
test_encoding(void *arg)
{
(void) arg;
int ret, duper_rand = 42;
/* Random number is 32 bytes. */
char raw_rand[32];
time_t ts = 1454333590;
char hashed_rand[DIGEST256_LEN], hashed_reveal[DIGEST256_LEN];
sr_commit_t parsed_commit;
/* Encoded commit is: base64-encode( 1454333590 || H(H(42)) ). Remember
* that we do no expose the raw bytes of our PRNG to the network thus
* explaining the double H(). */
static const char *encoded_commit =
"AAAAAFavXpZbx2LRneYFSLPCP8DLp9BXfeH5FXzbkxM4iRXKGeA54g==";
/* Encoded reveal is: base64-encode( 1454333590 || H(42) ). */
static const char *encoded_reveal =
"AAAAAFavXpYk9x9kTjiQWUqjHwSAEOdPAfCaurXgjPy173SzYjeC2g==";
/* Set up our raw random bytes array. */
memset(raw_rand, 0, sizeof(raw_rand));
memcpy(raw_rand, &duper_rand, sizeof(duper_rand));
/* Hash random number. */
ret = crypto_digest256(hashed_rand, raw_rand,
sizeof(raw_rand), SR_DIGEST_ALG);
tt_int_op(0, ==, ret);
/* Hash reveal value. */
tt_int_op(SR_REVEAL_BASE64_LEN, ==, strlen(encoded_reveal));
ret = crypto_digest256(hashed_reveal, encoded_reveal,
strlen(encoded_reveal), SR_DIGEST_ALG);
tt_int_op(0, ==, ret);
tt_int_op(SR_COMMIT_BASE64_LEN, ==, strlen(encoded_commit));
/* Test our commit/reveal decode functions. */
{
/* Test the reveal encoded value. */
tt_int_op(0, ==, reveal_decode(encoded_reveal, &parsed_commit));
tt_u64_op(ts, ==, parsed_commit.reveal_ts);
tt_mem_op(hashed_rand, OP_EQ, parsed_commit.random_number,
sizeof(hashed_rand));
/* Test the commit encoded value. */
memset(&parsed_commit, 0, sizeof(parsed_commit));
tt_int_op(0, ==, commit_decode(encoded_commit, &parsed_commit));
tt_u64_op(ts, ==, parsed_commit.commit_ts);
tt_mem_op(encoded_commit, OP_EQ, parsed_commit.encoded_commit,
sizeof(parsed_commit.encoded_commit));
tt_mem_op(hashed_reveal, OP_EQ, parsed_commit.hashed_reveal,
sizeof(hashed_reveal));
}
/* Test our commit/reveal encode functions. */
{
/* Test the reveal encode. */
char encoded[SR_REVEAL_BASE64_LEN + 1];
parsed_commit.reveal_ts = ts;
memcpy(parsed_commit.random_number, hashed_rand,
sizeof(parsed_commit.random_number));
ret = reveal_encode(&parsed_commit, encoded, sizeof(encoded));
tt_int_op(SR_REVEAL_BASE64_LEN, ==, ret);
tt_mem_op(encoded_reveal, OP_EQ, encoded, strlen(encoded_reveal));
}
{
/* Test the commit encode. */
char encoded[SR_COMMIT_BASE64_LEN + 1];
parsed_commit.commit_ts = ts;
memcpy(parsed_commit.hashed_reveal, hashed_reveal,
sizeof(parsed_commit.hashed_reveal));
ret = commit_encode(&parsed_commit, encoded, sizeof(encoded));
tt_int_op(SR_COMMIT_BASE64_LEN, ==, ret);
tt_mem_op(encoded_commit, OP_EQ, encoded, strlen(encoded_commit));
}
done:
;
}
/** Setup some SRVs in our SR state. If also_current is set, then set
* both current and previous SRVs.
* Helper of test_vote() and test_sr_compute_srv(). */
static void
test_sr_setup_srv(int also_current)
{
sr_srv_t *srv = tor_malloc_zero(sizeof(sr_srv_t));
srv->num_reveals = 42;
memcpy(srv->value,
"ZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZ",
sizeof(srv->value));
sr_state_set_previous_srv(srv);
if (also_current) {
srv = tor_malloc_zero(sizeof(sr_srv_t));
srv->num_reveals = 128;
memcpy(srv->value,
"NNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNN",
sizeof(srv->value));
sr_state_set_current_srv(srv);
}
}
/* Test anything that has to do with SR protocol and vote. */
static void
test_vote(void *arg)
{
int ret;
time_t now = time(NULL);
sr_commit_t *our_commit = NULL;
(void) arg;
MOCK(trusteddirserver_get_by_v3_auth_digest,
trusteddirserver_get_by_v3_auth_digest_m);
{ /* Setup a minimal dirauth environment for this test */
init_authority_state();
/* Set ourself in reveal phase so we can parse the reveal value in the
* vote as well. */
set_sr_phase(SR_PHASE_REVEAL);
}
/* Generate our commit object and validate it has the appropriate field
* that we can then use to build a representation that we'll find in a
* vote coming from the network. */
{
sr_commit_t *saved_commit;
our_commit = sr_generate_our_commit(now, mock_cert);
tt_assert(our_commit);
sr_state_add_commit(our_commit);
/* Make sure it's there. */
saved_commit = sr_state_get_commit(our_commit->rsa_identity);
tt_assert(saved_commit);
}
/* Also setup the SRVs */
test_sr_setup_srv(1);
{ /* Now test the vote generation */
smartlist_t *chunks = smartlist_new();
smartlist_t *tokens = smartlist_new();
/* Get our vote line and validate it. */
char *lines = sr_get_string_for_vote();
tt_assert(lines);
/* Split the lines. We expect 2 here. */
ret = smartlist_split_string(chunks, lines, "\n", SPLIT_IGNORE_BLANK, 0);
tt_int_op(ret, ==, 4);
tt_str_op(smartlist_get(chunks, 0), OP_EQ, "shared-rand-participate");
/* Get our commitment line and will validate it agains our commit. The
* format is as follow:
* "shared-rand-commitment" SP version SP algname SP identity
* SP COMMIT [SP REVEAL] NL
*/
char *commit_line = smartlist_get(chunks, 1);
tt_assert(commit_line);
ret = smartlist_split_string(tokens, commit_line, " ", 0, 0);
tt_int_op(ret, ==, 6);
tt_str_op(smartlist_get(tokens, 0), OP_EQ, "shared-rand-commit");
tt_str_op(smartlist_get(tokens, 1), OP_EQ, "1");
tt_str_op(smartlist_get(tokens, 2), OP_EQ,
crypto_digest_algorithm_get_name(DIGEST_SHA3_256));
char digest[DIGEST_LEN];
base16_decode(digest, sizeof(digest), smartlist_get(tokens, 3),
HEX_DIGEST_LEN);
tt_mem_op(digest, ==, our_commit->rsa_identity, sizeof(digest));
tt_str_op(smartlist_get(tokens, 4), OP_EQ, our_commit->encoded_commit);
tt_str_op(smartlist_get(tokens, 5), OP_EQ, our_commit->encoded_reveal);
/* Finally, does this vote line creates a valid commit object? */
smartlist_t *args = smartlist_new();
smartlist_add(args, smartlist_get(tokens, 1));
smartlist_add(args, smartlist_get(tokens, 2));
smartlist_add(args, smartlist_get(tokens, 3));
smartlist_add(args, smartlist_get(tokens, 4));
smartlist_add(args, smartlist_get(tokens, 5));
sr_commit_t *parsed_commit = sr_parse_commit(args);
tt_assert(parsed_commit);
/* Set valid flag explicitly here to compare since it's not set by
* simply parsing the commit. */
parsed_commit->valid = 1;
tt_mem_op(parsed_commit, ==, our_commit, sizeof(*our_commit));
/* minor cleanup */
SMARTLIST_FOREACH(tokens, char *, s, tor_free(s));
smartlist_clear(tokens);
/* Now test the previous SRV */
char *prev_srv_line = smartlist_get(chunks, 2);
tt_assert(prev_srv_line);
ret = smartlist_split_string(tokens, prev_srv_line, " ", 0, 0);
tt_int_op(ret, ==, 3);
tt_str_op(smartlist_get(tokens, 0), OP_EQ, "shared-rand-previous-value");
tt_str_op(smartlist_get(tokens, 1), OP_EQ, "42");
tt_str_op(smartlist_get(tokens, 2), OP_EQ,
"WlpaWlpaWlpaWlpaWlpaWlpaWlpaWlpaWlpaWlpaWlo=");
/* minor cleanup */
SMARTLIST_FOREACH(tokens, char *, s, tor_free(s));
smartlist_clear(tokens);
/* Now test the current SRV */
char *current_srv_line = smartlist_get(chunks, 3);
tt_assert(current_srv_line);
ret = smartlist_split_string(tokens, current_srv_line, " ", 0, 0);
tt_int_op(ret, ==, 3);
tt_str_op(smartlist_get(tokens, 0), OP_EQ, "shared-rand-current-value");
tt_str_op(smartlist_get(tokens, 1), OP_EQ, "128");
tt_str_op(smartlist_get(tokens, 2), OP_EQ,
"Tk5OTk5OTk5OTk5OTk5OTk5OTk5OTk5OTk5OTk5OTk4=");
/* Clean up */
sr_commit_free(parsed_commit);
SMARTLIST_FOREACH(chunks, char *, s, tor_free(s));
smartlist_free(chunks);
SMARTLIST_FOREACH(tokens, char *, s, tor_free(s));
smartlist_free(tokens);
smartlist_clear(args);
smartlist_free(args);
}
done:
sr_commit_free(our_commit);
UNMOCK(trusteddirserver_get_by_v3_auth_digest);
}
static const char *sr_state_str = "Version 1\n"
"TorVersion 0.2.9.0-alpha-dev\n"
"ValidAfter 2037-04-19 07:16:00\n"
"ValidUntil 2037-04-20 07:16:00\n"
"Commit 1 sha3-256 FA3CEC2C99DC68D3166B9B6E4FA21A4026C2AB1C "
"7M8GdubCAAdh7WUG0DiwRyxTYRKji7HATa7LLJEZ/UAAAAAAVmfUSg== "
"AAAAAFZn1EojfIheIw42bjK3VqkpYyjsQFSbv/dxNna3Q8hUEPKpOw==\n"
"Commit 1 sha3-256 41E89EDFBFBA44983E21F18F2230A4ECB5BFB543 "
"17aUsYuMeRjd2N1r8yNyg7aHqRa6gf4z7QPoxxAZbp0AAAAAVmfUSg==\n"
"Commit 1 sha3-256 36637026573A04110CF3E6B1D201FB9A98B88734 "
"DDDYtripvdOU+XPEUm5xpU64d9IURSds1xSwQsgeB8oAAAAAVmfUSg==\n"
"SharedRandPreviousValue 4 qqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqqo=\n"
"SharedRandCurrentValue 3 8dWeW12KEzTGEiLGgO1UVJ7Z91CekoRcxt6Q9KhnOFI=\n";
/** Create an SR disk state, parse it and validate that the parsing went
* well. Yes! */
static void
test_state_load_from_disk(void *arg)
{
int ret;
char *dir = tor_strdup(get_fname("test_sr_state"));
char *sr_state_path = tor_strdup(get_fname("test_sr_state/sr_state"));
sr_state_t *the_sr_state = NULL;
(void) arg;
MOCK(trusteddirserver_get_by_v3_auth_digest,
trusteddirserver_get_by_v3_auth_digest_m);
/* First try with a nonexistent path. */
ret = disk_state_load_from_disk_impl("NONEXISTENTNONEXISTENT");
tt_assert(ret == -ENOENT);
/* Now create a mock state directory and state file */
#ifdef _WIN32
ret = mkdir(dir);
#else
ret = mkdir(dir, 0700);
#endif
tt_assert(ret == 0);
ret = write_str_to_file(sr_state_path, sr_state_str, 0);
tt_assert(ret == 0);
/* Try to load the directory itself. Should fail. */
ret = disk_state_load_from_disk_impl(dir);
tt_int_op(ret, OP_LT, 0);
/* State should be non-existent at this point. */
the_sr_state = get_sr_state();
tt_assert(!the_sr_state);
/* Now try to load the correct file! */
ret = disk_state_load_from_disk_impl(sr_state_path);
tt_assert(ret == 0);
/* Check the content of the state */
/* XXX check more deeply!!! */
the_sr_state = get_sr_state();
tt_assert(the_sr_state);
tt_assert(the_sr_state->version == 1);
tt_assert(digestmap_size(the_sr_state->commits) == 3);
tt_assert(the_sr_state->current_srv);
tt_assert(the_sr_state->current_srv->num_reveals == 3);
tt_assert(the_sr_state->previous_srv);
/* XXX Now also try loading corrupted state files and make sure parsing
fails */
done:
tor_free(dir);
tor_free(sr_state_path);
UNMOCK(trusteddirserver_get_by_v3_auth_digest);
}
/** Generate three specially crafted commits (based on the test
* vector at sr_srv_calc_ref.py). Helper of test_sr_compute_srv(). */
static void
test_sr_setup_commits(void)
{
time_t now = time(NULL);
sr_commit_t *commit_a, *commit_b, *commit_c, *commit_d;
sr_commit_t *place_holder = tor_malloc_zero(sizeof(*place_holder));
authority_cert_t *auth_cert = NULL;
{ /* Setup a minimal dirauth environment for this test */
or_options_t *options = get_options_mutable();
auth_cert = authority_cert_parse_from_string(AUTHORITY_CERT_1, NULL);
tt_assert(auth_cert);
options->AuthoritativeDir = 1;
tt_int_op(0, ==, load_ed_keys(options, now));
}
/* Generate three dummy commits according to sr_srv_calc_ref.py . Then
register them to the SR state. Also register a fourth commit 'd' with no
reveal info, to make sure that it will get ignored during SRV
calculation. */
{ /* Commit from auth 'a' */
commit_a = sr_generate_our_commit(now, auth_cert);
tt_assert(commit_a);
/* Do some surgery on the commit */
memset(commit_a->rsa_identity, 'A', sizeof(commit_a->rsa_identity));
base16_encode(commit_a->rsa_identity_hex,
sizeof(commit_a->rsa_identity_hex), commit_a->rsa_identity,
sizeof(commit_a->rsa_identity));
strlcpy(commit_a->encoded_reveal,
"AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA",
sizeof(commit_a->encoded_reveal));
memcpy(commit_a->hashed_reveal,
"AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA",
sizeof(commit_a->hashed_reveal));
}
{ /* Commit from auth 'b' */
commit_b = sr_generate_our_commit(now, auth_cert);
tt_assert(commit_b);
/* Do some surgery on the commit */
memset(commit_b->rsa_identity, 'B', sizeof(commit_b->rsa_identity));
base16_encode(commit_b->rsa_identity_hex,
sizeof(commit_b->rsa_identity_hex), commit_b->rsa_identity,
sizeof(commit_b->rsa_identity));
strlcpy(commit_b->encoded_reveal,
"BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB",
sizeof(commit_b->encoded_reveal));
memcpy(commit_b->hashed_reveal,
"BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB",
sizeof(commit_b->hashed_reveal));
}
{ /* Commit from auth 'c' */
commit_c = sr_generate_our_commit(now, auth_cert);
tt_assert(commit_c);
/* Do some surgery on the commit */
memset(commit_c->rsa_identity, 'C', sizeof(commit_c->rsa_identity));
base16_encode(commit_c->rsa_identity_hex,
sizeof(commit_c->rsa_identity_hex), commit_c->rsa_identity,
sizeof(commit_c->rsa_identity));
strlcpy(commit_c->encoded_reveal,
"CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC",
sizeof(commit_c->encoded_reveal));
memcpy(commit_c->hashed_reveal,
"CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC",
sizeof(commit_c->hashed_reveal));
}
{ /* Commit from auth 'd' */
commit_d = sr_generate_our_commit(now, auth_cert);
tt_assert(commit_d);
/* Do some surgery on the commit */
memset(commit_d->rsa_identity, 'D', sizeof(commit_d->rsa_identity));
base16_encode(commit_d->rsa_identity_hex,
sizeof(commit_d->rsa_identity_hex), commit_d->rsa_identity,
sizeof(commit_d->rsa_identity));
strlcpy(commit_d->encoded_reveal,
"DDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDD",
sizeof(commit_d->encoded_reveal));
memcpy(commit_d->hashed_reveal,
"DDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDD",
sizeof(commit_d->hashed_reveal));
/* Clean up its reveal info */
memcpy(place_holder, commit_d, sizeof(*place_holder));
memset(commit_d->encoded_reveal, 0, sizeof(commit_d->encoded_reveal));
tt_assert(!commit_has_reveal_value(commit_d));
}
/* Register commits to state (during commit phase) */
set_sr_phase(SR_PHASE_COMMIT);
save_commit_to_state(commit_a);
save_commit_to_state(commit_b);
save_commit_to_state(commit_c);
save_commit_to_state(commit_d);
tt_int_op(digestmap_size(get_sr_state()->commits), ==, 4);
/* Now during REVEAL phase save commit D by restoring its reveal. */
set_sr_phase(SR_PHASE_REVEAL);
save_commit_to_state(place_holder);
tt_str_op(commit_d->encoded_reveal, OP_EQ,
"DDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDDD");
/* Go back to an empty encoded reveal value. */
memset(commit_d->encoded_reveal, 0, sizeof(commit_d->encoded_reveal));
memset(commit_d->random_number, 0, sizeof(commit_d->random_number));
tt_assert(!commit_has_reveal_value(commit_d));
done:
return;
}
/** Verify that the SRV generation procedure is proper by testing it against
* the test vector from ./sr_srv_calc_ref.py. */
static void
test_sr_compute_srv(void *arg)
{
(void) arg;
const sr_srv_t *current_srv = NULL;
#define SRV_TEST_VECTOR \
"2A9B1D6237DAB312A40F575DA85C147663E7ED3F80E9555395F15B515C74253D"
MOCK(trusteddirserver_get_by_v3_auth_digest,
trusteddirserver_get_by_v3_auth_digest_m);
init_authority_state();
/* Setup the commits for this unittest */
test_sr_setup_commits();
test_sr_setup_srv(0);
/* Now switch to reveal phase */
set_sr_phase(SR_PHASE_REVEAL);
/* Compute the SRV */
sr_compute_srv();
/* Check the result against the test vector */
current_srv = sr_state_get_current_srv();
tt_assert(current_srv);
tt_u64_op(current_srv->num_reveals, ==, 3);
tt_str_op(hex_str((char*)current_srv->value, 32),
==,
SRV_TEST_VECTOR);
done:
UNMOCK(trusteddirserver_get_by_v3_auth_digest);
}
/** Return a minimal vote document with a current SRV value set to
* srv. */
static networkstatus_t *
get_test_vote_with_curr_srv(const char *srv)
{
networkstatus_t *vote = tor_malloc_zero(sizeof(networkstatus_t));
vote->type = NS_TYPE_VOTE;
vote->sr_info.participate = 1;
vote->sr_info.current_srv = tor_malloc_zero(sizeof(sr_srv_t));
vote->sr_info.current_srv->num_reveals = 42;
memcpy(vote->sr_info.current_srv->value,
srv,
sizeof(vote->sr_info.current_srv->value));
return vote;
}
/* Test the function that picks the right SRV given a bunch of votes. Make sure
* that the function returns an SRV iff the majority/agreement requirements are
* met. */
static void
test_sr_get_majority_srv_from_votes(void *arg)
{
sr_srv_t *chosen_srv;
smartlist_t *votes = smartlist_new();
#define SRV_1 "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA"
#define SRV_2 "BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB"
(void) arg;
init_authority_state();
/* Make sure our SRV is fresh so we can consider the super majority with
* the consensus params of number of agreements needed. */
sr_state_set_fresh_srv();
/* The test relies on the dirauth list being initialized. */
clear_dir_servers();
add_default_trusted_dir_authorities(V3_DIRINFO);
{ /* Prepare voting environment with just a single vote. */
networkstatus_t *vote = get_test_vote_with_curr_srv(SRV_1);
smartlist_add(votes, vote);
}
/* Since it's only one vote with an SRV, it should not achieve majority and
hence no SRV will be returned. */
chosen_srv = get_majority_srv_from_votes(votes, 1);
tt_assert(!chosen_srv);
{ /* Now put in 8 more votes. Let SRV_1 have majority. */
int i;
/* Now 7 votes believe in SRV_1 */
for (i = 0; i < 3; i++) {
networkstatus_t *vote = get_test_vote_with_curr_srv(SRV_1);
smartlist_add(votes, vote);
}
/* and 2 votes believe in SRV_2 */
for (i = 0; i < 2; i++) {
networkstatus_t *vote = get_test_vote_with_curr_srv(SRV_2);
smartlist_add(votes, vote);
}
for (i = 0; i < 3; i++) {
networkstatus_t *vote = get_test_vote_with_curr_srv(SRV_1);
smartlist_add(votes, vote);
}
tt_int_op(smartlist_len(votes), ==, 9);
}
/* Now we achieve majority for SRV_1, but not the AuthDirNumSRVAgreements
requirement. So still not picking an SRV. */
set_num_srv_agreements(8);
chosen_srv = get_majority_srv_from_votes(votes, 1);
tt_assert(!chosen_srv);
/* We will now lower the AuthDirNumSRVAgreements requirement by tweaking the
* consensus parameter and we will try again. This time it should work. */
set_num_srv_agreements(7);
chosen_srv = get_majority_srv_from_votes(votes, 1);
tt_assert(chosen_srv);
tt_u64_op(chosen_srv->num_reveals, ==, 42);
tt_mem_op(chosen_srv->value, OP_EQ, SRV_1, sizeof(chosen_srv->value));
done:
SMARTLIST_FOREACH(votes, networkstatus_t *, vote,
networkstatus_vote_free(vote));
smartlist_free(votes);
}
static void
test_utils(void *arg)
{
(void) arg;
/* Testing srv_dup(). */
{
sr_srv_t *srv = NULL, *dup_srv = NULL;
const char *srv_value =
"1BDB7C3E973936E4D13A49F37C859B3DC69C429334CF9412E3FEF6399C52D47A";
srv = tor_malloc_zero(sizeof(*srv));
srv->num_reveals = 42;
memcpy(srv->value, srv_value, sizeof(srv->value));
dup_srv = srv_dup(srv);
tt_assert(dup_srv);
tt_u64_op(dup_srv->num_reveals, ==, srv->num_reveals);
tt_mem_op(dup_srv->value, OP_EQ, srv->value, sizeof(srv->value));
tor_free(srv);
tor_free(dup_srv);
}
/* Testing commitments_are_the_same(). Currently, the check is to test the
* value of the encoded commit so let's make sure that actually works. */
{
/* Payload of 57 bytes that is the length of sr_commit_t->encoded_commit.
* 56 bytes of payload and a NUL terminated byte at the end ('\x00')
* which comes down to SR_COMMIT_BASE64_LEN + 1. */
const char *payload =
"\x5d\xb9\x60\xb6\xcc\x51\x68\x52\x31\xd9\x88\x88\x71\x71\xe0\x30"
"\x59\x55\x7f\xcd\x61\xc0\x4b\x05\xb8\xcd\xc1\x48\xe9\xcd\x16\x1f"
"\x70\x15\x0c\xfc\xd3\x1a\x75\xd0\x93\x6c\xc4\xe0\x5c\xbe\xe2\x18"
"\xc7\xaf\x72\xb6\x7c\x9b\x52\x00";
sr_commit_t commit1, commit2;
memcpy(commit1.encoded_commit, payload, sizeof(commit1.encoded_commit));
memcpy(commit2.encoded_commit, payload, sizeof(commit2.encoded_commit));
tt_int_op(commitments_are_the_same(&commit1, &commit2), ==, 1);
/* Let's corrupt one of them. */
memset(commit1.encoded_commit, 'A', sizeof(commit1.encoded_commit));
tt_int_op(commitments_are_the_same(&commit1, &commit2), ==, 0);
}
/* Testing commit_is_authoritative(). */
{
crypto_pk_t *k = crypto_pk_new();
char digest[DIGEST_LEN];
sr_commit_t commit;
tt_assert(!crypto_pk_generate_key(k));
tt_int_op(0, ==, crypto_pk_get_digest(k, digest));
memcpy(commit.rsa_identity, digest, sizeof(commit.rsa_identity));
tt_int_op(commit_is_authoritative(&commit, digest), ==, 1);
/* Change the pubkey. */
memset(commit.rsa_identity, 0, sizeof(commit.rsa_identity));
tt_int_op(commit_is_authoritative(&commit, digest), ==, 0);
}
/* Testing get_phase_str(). */
{
tt_str_op(get_phase_str(SR_PHASE_REVEAL), ==, "reveal");
tt_str_op(get_phase_str(SR_PHASE_COMMIT), ==, "commit");
}
/* Testing phase transition */
{
init_authority_state();
set_sr_phase(SR_PHASE_COMMIT);
tt_int_op(is_phase_transition(SR_PHASE_REVEAL), ==, 1);
tt_int_op(is_phase_transition(SR_PHASE_COMMIT), ==, 0);
set_sr_phase(SR_PHASE_REVEAL);
tt_int_op(is_phase_transition(SR_PHASE_REVEAL), ==, 0);
tt_int_op(is_phase_transition(SR_PHASE_COMMIT), ==, 1);
/* Junk. */
tt_int_op(is_phase_transition(42), ==, 1);
}
done:
return;
}
static void
test_state_transition(void *arg)
{
sr_state_t *state = NULL;
time_t now = time(NULL);
(void) arg;
{ /* Setup a minimal dirauth environment for this test */
init_authority_state();
state = get_sr_state();
tt_assert(state);
}
/* Test our state reset for a new protocol run. */
{
/* Add a commit to the state so we can test if the reset cleans the
* commits. Also, change all params that we expect to be updated. */
sr_commit_t *commit = sr_generate_our_commit(now, mock_cert);
tt_assert(commit);
sr_state_add_commit(commit);
tt_int_op(digestmap_size(state->commits), ==, 1);
/* Let's test our delete feature. */
sr_state_delete_commits();
tt_int_op(digestmap_size(state->commits), ==, 0);
/* Add it back so we can continue the rest of the test because after
* deletiong our commit will be freed so generate a new one. */
commit = sr_generate_our_commit(now, mock_cert);
tt_assert(commit);
sr_state_add_commit(commit);
tt_int_op(digestmap_size(state->commits), ==, 1);
state->n_reveal_rounds = 42;
state->n_commit_rounds = 43;
state->n_protocol_runs = 44;
reset_state_for_new_protocol_run(now);
tt_int_op(state->n_reveal_rounds, ==, 0);
tt_int_op(state->n_commit_rounds, ==, 0);
tt_u64_op(state->n_protocol_runs, ==, 45);
tt_int_op(digestmap_size(state->commits), ==, 0);
}
/* Test SRV rotation in our state. */
{
const sr_srv_t *cur, *prev;
test_sr_setup_srv(1);
cur = sr_state_get_current_srv();
tt_assert(cur);
/* After, current srv should be the previous and then set to NULL. */
state_rotate_srv();
prev = sr_state_get_previous_srv();
tt_assert(prev == cur);
tt_assert(!sr_state_get_current_srv());
}
/* New protocol run. */
{
const sr_srv_t *cur;
/* Setup some new SRVs so we can confirm that a new protocol run
* actually makes them rotate and compute new ones. */
test_sr_setup_srv(1);
cur = sr_state_get_current_srv();
tt_assert(cur);
set_sr_phase(SR_PHASE_REVEAL);
MOCK(get_my_v3_authority_cert, get_my_v3_authority_cert_m);
new_protocol_run(now);
UNMOCK(get_my_v3_authority_cert);
/* Rotation happened. */
tt_assert(sr_state_get_previous_srv() == cur);
/* We are going into COMMIT phase so we had to rotate our SRVs. Usually
* our current SRV would be NULL but a new protocol run should make us
* compute a new SRV. */
tt_assert(sr_state_get_current_srv());
/* Also, make sure we did change the current. */
tt_assert(sr_state_get_current_srv() != cur);
/* We should have our commitment alone. */
tt_int_op(digestmap_size(state->commits), ==, 1);
tt_int_op(state->n_reveal_rounds, ==, 0);
tt_int_op(state->n_commit_rounds, ==, 0);
/* 46 here since we were at 45 just before. */
tt_u64_op(state->n_protocol_runs, ==, 46);
}
/* Cleanup of SRVs. */
{
sr_state_clean_srvs();
tt_assert(!sr_state_get_current_srv());
tt_assert(!sr_state_get_previous_srv());
}
done:
return;
}
static void
test_keep_commit(void *arg)
{
char fp[FINGERPRINT_LEN + 1];
sr_commit_t *commit = NULL, *dup_commit = NULL;
sr_state_t *state;
time_t now = time(NULL);
(void) arg;
MOCK(trusteddirserver_get_by_v3_auth_digest,
trusteddirserver_get_by_v3_auth_digest_m);
{ /* Setup a minimal dirauth environment for this test */
crypto_pk_t *k = crypto_pk_new();
/* Have a key that is not the one from our commit. */
tt_int_op(0, ==, crypto_pk_generate_key(k));
tt_int_op(0, ==, crypto_pk_get_fingerprint(k, fp, 0));
init_authority_state();
state = get_sr_state();
}
/* Test this very important function that tells us if we should keep a
* commit or not in our state. Most of it depends on the phase and what's
* in the commit so we'll change the commit as we go. */
commit = sr_generate_our_commit(now, mock_cert);
tt_assert(commit);
/* Set us in COMMIT phase for starter. */
set_sr_phase(SR_PHASE_COMMIT);
/* We should never keep a commit from a non authoritative authority. */
tt_int_op(should_keep_commit(commit, fp, SR_PHASE_COMMIT), ==, 0);
/* This should NOT be kept because it has a reveal value in it. */
tt_assert(commit_has_reveal_value(commit));
tt_int_op(should_keep_commit(commit, commit->rsa_identity,
SR_PHASE_COMMIT), ==, 0);
/* Add it to the state which should return to not keep it. */
sr_state_add_commit(commit);
tt_int_op(should_keep_commit(commit, commit->rsa_identity,
SR_PHASE_COMMIT), ==, 0);
/* Remove it from state so we can continue our testing. */
digestmap_remove(state->commits, commit->rsa_identity);
/* Let's remove our reveal value which should make it OK to keep it. */
memset(commit->encoded_reveal, 0, sizeof(commit->encoded_reveal));
tt_int_op(should_keep_commit(commit, commit->rsa_identity,
SR_PHASE_COMMIT), ==, 1);
/* Let's reset our commit and go into REVEAL phase. */
sr_commit_free(commit);
commit = sr_generate_our_commit(now, mock_cert);
tt_assert(commit);
/* Dup the commit so we have one with and one without a reveal value. */
dup_commit = tor_malloc_zero(sizeof(*dup_commit));
memcpy(dup_commit, commit, sizeof(*dup_commit));
memset(dup_commit->encoded_reveal, 0, sizeof(dup_commit->encoded_reveal));
set_sr_phase(SR_PHASE_REVEAL);
/* We should never keep a commit from a non authoritative authority. */
tt_int_op(should_keep_commit(commit, fp, SR_PHASE_REVEAL), ==, 0);
/* We shouldn't accept a commit that is not in our state. */
tt_int_op(should_keep_commit(commit, commit->rsa_identity,
SR_PHASE_REVEAL), ==, 0);
/* Important to add the commit _without_ the reveal here. */
sr_state_add_commit(dup_commit);
tt_int_op(digestmap_size(state->commits), ==, 1);
/* Our commit should be valid that is authoritative, contains a reveal, be
* in the state and commitment and reveal values match. */
tt_int_op(should_keep_commit(commit, commit->rsa_identity,
SR_PHASE_REVEAL), ==, 1);
/* The commit shouldn't be kept if it's not verified that is no matchin
* hashed reveal. */
{
/* Let's save the hash reveal so we can restore it. */
sr_commit_t place_holder;
memcpy(place_holder.hashed_reveal, commit->hashed_reveal,
sizeof(place_holder.hashed_reveal));
memset(commit->hashed_reveal, 0, sizeof(commit->hashed_reveal));
tt_int_op(should_keep_commit(commit, commit->rsa_identity,
SR_PHASE_REVEAL), ==, 0);
memcpy(commit->hashed_reveal, place_holder.hashed_reveal,
sizeof(commit->hashed_reveal));
}
/* We shouldn't keep a commit that has no reveal. */
tt_int_op(should_keep_commit(dup_commit, dup_commit->rsa_identity,
SR_PHASE_REVEAL), ==, 0);
/* We must not keep a commit that is not the same from the commit phase. */
memset(commit->encoded_commit, 0, sizeof(commit->encoded_commit));
tt_int_op(should_keep_commit(commit, commit->rsa_identity,
SR_PHASE_REVEAL), ==, 0);
done:
sr_commit_free(commit);
sr_commit_free(dup_commit);
UNMOCK(trusteddirserver_get_by_v3_auth_digest);
}
static void
test_state_update(void *arg)
{
time_t commit_phase_time = 1452076000;
time_t reveal_phase_time = 1452086800;
sr_state_t *state;
(void) arg;
{
init_authority_state();
state = get_sr_state();
set_sr_phase(SR_PHASE_COMMIT);
/* We'll cheat a bit here and reset the creation time of the state which
* will avoid us to compute a valid_after time that fits the commit
* phase. */
state->valid_after = 0;
state->n_reveal_rounds = 0;
state->n_commit_rounds = 0;
state->n_protocol_runs = 0;
}
/* We need to mock for the state update function call. */
MOCK(get_my_v3_authority_cert, get_my_v3_authority_cert_m);
/* We are in COMMIT phase here and we'll trigger a state update but no
* transition. */
sr_state_update(commit_phase_time);
tt_int_op(state->valid_after, ==, commit_phase_time);
tt_int_op(state->n_commit_rounds, ==, 1);
tt_int_op(state->phase, ==, SR_PHASE_COMMIT);
tt_int_op(digestmap_size(state->commits), ==, 1);
/* We are still in the COMMIT phase here but we'll trigger a state
* transition to the REVEAL phase. */
sr_state_update(reveal_phase_time);
tt_int_op(state->phase, ==, SR_PHASE_REVEAL);
tt_int_op(state->valid_after, ==, reveal_phase_time);
/* Only our commit should be in there. */
tt_int_op(digestmap_size(state->commits), ==, 1);
tt_int_op(state->n_reveal_rounds, ==, 1);
/* We can't update a state with a valid after _lower_ than the creation
* time so here it is. */
sr_state_update(commit_phase_time);
tt_int_op(state->valid_after, ==, reveal_phase_time);
/* Finally, let's go back in COMMIT phase so we can test the state update
* of a new protocol run. */
state->valid_after = 0;
sr_state_update(commit_phase_time);
tt_int_op(state->valid_after, ==, commit_phase_time);
tt_int_op(state->n_commit_rounds, ==, 1);
tt_int_op(state->n_reveal_rounds, ==, 0);
tt_u64_op(state->n_protocol_runs, ==, 1);
tt_int_op(state->phase, ==, SR_PHASE_COMMIT);
tt_int_op(digestmap_size(state->commits), ==, 1);
tt_assert(state->current_srv);
done:
sr_state_free();
UNMOCK(get_my_v3_authority_cert);
}
struct testcase_t sr_tests[] = {
{ "get_sr_protocol_phase", test_get_sr_protocol_phase, TT_FORK,
NULL, NULL },
{ "sr_commit", test_sr_commit, TT_FORK,
NULL, NULL },
{ "keep_commit", test_keep_commit, TT_FORK,
NULL, NULL },
{ "encoding", test_encoding, TT_FORK,
NULL, NULL },
{ "get_next_valid_after_time", test_get_next_valid_after_time, TT_FORK,
NULL, NULL },
{ "get_state_valid_until_time", test_get_state_valid_until_time, TT_FORK,
NULL, NULL },
{ "vote", test_vote, TT_FORK,
NULL, NULL },
{ "state_load_from_disk", test_state_load_from_disk, TT_FORK,
NULL, NULL },
{ "sr_compute_srv", test_sr_compute_srv, TT_FORK, NULL, NULL },
{ "sr_get_majority_srv_from_votes", test_sr_get_majority_srv_from_votes,
TT_FORK, NULL, NULL },
{ "utils", test_utils, TT_FORK, NULL, NULL },
{ "state_transition", test_state_transition, TT_FORK, NULL, NULL },
{ "state_update", test_state_update, TT_FORK,
NULL, NULL },
END_OF_TESTCASES
};