tor/src/test/test_hs_common.c

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/* Copyright (c) 2017, The Tor Project, Inc. */
/* See LICENSE for licensing information */
/**
* \file test_hs_common.c
* \brief Test hidden service common functionalities.
*/
#define HS_COMMON_PRIVATE
#define HS_SERVICE_PRIVATE
#include "test.h"
#include "test_helpers.h"
#include "log_test_helpers.h"
#include "hs_test_helpers.h"
#include "connection_edge.h"
#include "hs_common.h"
#include "hs_service.h"
#include "config.h"
#include "networkstatus.h"
#include "directory.h"
#include "nodelist.h"
#include "statefile.h"
/** Test the validation of HS v3 addresses */
static void
test_validate_address(void *arg)
{
int ret;
(void) arg;
/* Address too short and too long. */
setup_full_capture_of_logs(LOG_WARN);
ret = hs_address_is_valid("blah");
tt_int_op(ret, OP_EQ, 0);
expect_log_msg_containing("has an invalid length");
teardown_capture_of_logs();
setup_full_capture_of_logs(LOG_WARN);
ret = hs_address_is_valid(
"p3xnclpu4mu22dwaurjtsybyqk4xfjmcfz6z62yl24uwmhjatiwnlnadb");
tt_int_op(ret, OP_EQ, 0);
expect_log_msg_containing("has an invalid length");
teardown_capture_of_logs();
/* Invalid checksum (taken from prop224) */
setup_full_capture_of_logs(LOG_WARN);
ret = hs_address_is_valid(
"l5satjgud6gucryazcyvyvhuxhr74u6ygigiuyixe3a6ysis67ororad");
tt_int_op(ret, OP_EQ, 0);
expect_log_msg_containing("invalid checksum");
teardown_capture_of_logs();
setup_full_capture_of_logs(LOG_WARN);
ret = hs_address_is_valid(
"btojiu7nu5y5iwut64eufevogqdw4wmqzugnoluw232r4t3ecsfv37ad");
tt_int_op(ret, OP_EQ, 0);
expect_log_msg_containing("invalid checksum");
teardown_capture_of_logs();
/* Non base32 decodable string. */
setup_full_capture_of_logs(LOG_WARN);
ret = hs_address_is_valid(
"????????????????????????????????????????????????????????");
tt_int_op(ret, OP_EQ, 0);
expect_log_msg_containing("can't be decoded");
teardown_capture_of_logs();
/* Valid address. */
ret = hs_address_is_valid(
"p3xnclpu4mu22dwaurjtsybyqk4xfjmcfz6z62yl24uwmhjatiwnlnad");
tt_int_op(ret, OP_EQ, 1);
done:
;
}
static int
mock_write_str_to_file(const char *path, const char *str, int bin)
{
(void)bin;
tt_str_op(path, OP_EQ, "/double/five"PATH_SEPARATOR"squared");
tt_str_op(str, OP_EQ,
"ijbeeqscijbeeqscijbeeqscijbeeqscijbeeqscijbeeqscijbezhid.onion\n");
done:
return 0;
}
/** Test building HS v3 onion addresses */
static void
test_build_address(void *arg)
{
int ret;
char onion_addr[HS_SERVICE_ADDR_LEN_BASE32 + 1];
ed25519_public_key_t pubkey;
hs_service_t *service = NULL;
(void) arg;
MOCK(write_str_to_file, mock_write_str_to_file);
/* The following has been created with hs_build_address.py script that
* follows proposal 224 specification to build an onion address. */
static const char *test_addr =
"ijbeeqscijbeeqscijbeeqscijbeeqscijbeeqscijbeeqscijbezhid";
/* Let's try to build the same onion address that the script can do. Key is
* a long set of very random \x42 :). */
memset(&pubkey, '\x42', sizeof(pubkey));
hs_build_address(&pubkey, HS_VERSION_THREE, onion_addr);
tt_str_op(test_addr, OP_EQ, onion_addr);
/* Validate that address. */
ret = hs_address_is_valid(onion_addr);
tt_int_op(ret, OP_EQ, 1);
service = tor_malloc_zero(sizeof(hs_service_t));
memcpy(service->onion_address, onion_addr, sizeof(service->onion_address));
tor_asprintf(&service->config.directory_path, "/double/five");
ret = write_address_to_file(service, "squared");
tt_int_op(ret, OP_EQ, 0);
done:
hs_service_free(service);
}
/** Test that our HS time period calculation functions work properly */
static void
test_time_period(void *arg)
{
(void) arg;
uint64_t tn;
int retval;
time_t fake_time, correct_time, start_time;
/* Let's do the example in prop224 section [TIME-PERIODS] */
retval = parse_rfc1123_time("Wed, 13 Apr 2016 11:00:00 UTC",
&fake_time);
tt_int_op(retval, OP_EQ, 0);
/* Check that the time period number is right */
tn = hs_get_time_period_num(fake_time);
tt_u64_op(tn, OP_EQ, 16903);
/* Increase current time to 11:59:59 UTC and check that the time period
number is still the same */
fake_time += 3599;
tn = hs_get_time_period_num(fake_time);
tt_u64_op(tn, OP_EQ, 16903);
{ /* Check start time of next time period */
retval = parse_rfc1123_time("Wed, 13 Apr 2016 12:00:00 UTC",
&correct_time);
tt_int_op(retval, OP_EQ, 0);
start_time = hs_get_start_time_of_next_time_period(fake_time);
tt_int_op(start_time, OP_EQ, correct_time);
}
/* Now take time to 12:00:00 UTC and check that the time period rotated */
fake_time += 1;
tn = hs_get_time_period_num(fake_time);
tt_u64_op(tn, OP_EQ, 16904);
/* Now also check our hs_get_next_time_period_num() function */
tn = hs_get_next_time_period_num(fake_time);
tt_u64_op(tn, OP_EQ, 16905);
{ /* Check start time of next time period again */
retval = parse_rfc1123_time("Wed, 14 Apr 2016 12:00:00 UTC",
&correct_time);
tt_int_op(retval, OP_EQ, 0);
start_time = hs_get_start_time_of_next_time_period(fake_time);
tt_int_op(start_time, OP_EQ, correct_time);
}
/* Now do another sanity check: The time period number at the start of the
* next time period, must be the same time period number as the one returned
* from hs_get_next_time_period_num() */
{
time_t next_tp_start = hs_get_start_time_of_next_time_period(fake_time);
2017-08-09 14:32:39 +02:00
tt_u64_op(hs_get_time_period_num(next_tp_start), OP_EQ,
hs_get_next_time_period_num(fake_time));
}
done:
;
}
/** Test that we can correctly find the start time of the next time period */
static void
test_start_time_of_next_time_period(void *arg)
{
(void) arg;
int retval;
time_t fake_time;
char tbuf[ISO_TIME_LEN + 1];
time_t next_tp_start_time;
/* Do some basic tests */
retval = parse_rfc1123_time("Wed, 13 Apr 2016 11:00:00 UTC",
&fake_time);
tt_int_op(retval, OP_EQ, 0);
next_tp_start_time = hs_get_start_time_of_next_time_period(fake_time);
/* Compare it with the correct result */
format_iso_time(tbuf, next_tp_start_time);
tt_str_op("2016-04-13 12:00:00", OP_EQ, tbuf);
/* Another test with an edge-case time (start of TP) */
retval = parse_rfc1123_time("Wed, 13 Apr 2016 12:00:00 UTC",
&fake_time);
tt_int_op(retval, OP_EQ, 0);
next_tp_start_time = hs_get_start_time_of_next_time_period(fake_time);
format_iso_time(tbuf, next_tp_start_time);
tt_str_op("2016-04-14 12:00:00", OP_EQ, tbuf);
{
/* Now pretend we are on a testing network and alter the voting schedule to
be every 10 seconds. This means that a time period has length 10*24
seconds (4 minutes). It also means that we apply a rotational offset of
120 seconds to the time period, so that it starts at 00:02:00 instead of
00:00:00. */
or_options_t *options = get_options_mutable();
options->TestingTorNetwork = 1;
options->V3AuthVotingInterval = 10;
options->TestingV3AuthInitialVotingInterval = 10;
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:00:00 UTC",
&fake_time);
tt_int_op(retval, OP_EQ, 0);
next_tp_start_time = hs_get_start_time_of_next_time_period(fake_time);
/* Compare it with the correct result */
format_iso_time(tbuf, next_tp_start_time);
tt_str_op("2016-04-13 00:02:00", OP_EQ, tbuf);
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:02:00 UTC",
&fake_time);
tt_int_op(retval, OP_EQ, 0);
next_tp_start_time = hs_get_start_time_of_next_time_period(fake_time);
/* Compare it with the correct result */
format_iso_time(tbuf, next_tp_start_time);
tt_str_op("2016-04-13 00:06:00", OP_EQ, tbuf);
}
done:
;
}
/** Test that our HS overlap period functions work properly. */
static void
test_desc_overlap_period(void *arg)
{
(void) arg;
int retval;
time_t now = time(NULL);
networkstatus_t *dummy_consensus = NULL;
/* First try with a consensus just inside the overlap period */
dummy_consensus = tor_malloc_zero(sizeof(networkstatus_t));
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:00:00 UTC",
&dummy_consensus->valid_after);
tt_int_op(retval, OP_EQ, 0);
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 1);
/* Now increase the valid_after so that it goes to 11:00:00 UTC. Overlap
period is still active. */
dummy_consensus->valid_after += 3600*11;
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 1);
/* Now increase the valid_after so that it goes to 11:59:59 UTC. Overlap
period is still active. */
dummy_consensus->valid_after += 3599;
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 1);
/* Now increase the valid_after so that it drifts to noon, and check that
overlap mode is not active anymore. */
dummy_consensus->valid_after += 1;
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 0);
/* Check that overlap mode is also inactive at 23:59:59 UTC */
retval = parse_rfc1123_time("Wed, 13 Apr 2016 23:59:59 UTC",
&dummy_consensus->valid_after);
tt_int_op(retval, OP_EQ, 0);
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 0);
done:
tor_free(dummy_consensus);
}
/* Test the overlap period functions on a testnet with altered voting
* schedule */
static void
test_desc_overlap_period_testnet(void *arg)
{
int retval;
time_t now = approx_time();
networkstatus_t *dummy_consensus = NULL;
or_options_t *options = get_options_mutable();
(void) arg;
/* Set the testnet option and a 10-second voting interval */
options->TestingTorNetwork = 1;
options->V3AuthVotingInterval = 10;
options->TestingV3AuthInitialVotingInterval = 10;
dummy_consensus = tor_malloc_zero(sizeof(networkstatus_t));
/* A 10-second voting interval means that the lengths of an SRV run and of a
* time period are both 10*24 seconds (4 minutes). The SRV gets published at
* 00:00:00 and the TP starts at 00:02:00 (rotation offset: 2 mins). Those
* two minutes between SRV publish and TP start is the overlap period
* window. Let's test it: */
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:00:00 UTC",
&dummy_consensus->valid_after);
tt_int_op(retval, OP_EQ, 0);
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 1);
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:01:59 UTC",
&dummy_consensus->valid_after);
tt_int_op(retval, OP_EQ, 0);
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 1);
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:02:00 UTC",
&dummy_consensus->valid_after);
tt_int_op(retval, OP_EQ, 0);
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 0);
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:04:00 UTC",
&dummy_consensus->valid_after);
tt_int_op(retval, OP_EQ, 0);
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 1);
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:05:59 UTC",
&dummy_consensus->valid_after);
tt_int_op(retval, OP_EQ, 0);
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 1);
retval = parse_rfc1123_time("Wed, 13 Apr 2016 00:06:00 UTC",
&dummy_consensus->valid_after);
tt_int_op(retval, OP_EQ, 0);
retval = hs_overlap_mode_is_active(dummy_consensus, now);
tt_int_op(retval, OP_EQ, 0);
done:
tor_free(dummy_consensus);
}
static void
helper_add_hsdir_to_networkstatus(networkstatus_t *ns,
int identity_idx,
const char *nickname,
int is_hsdir)
{
routerstatus_t *rs = tor_malloc_zero(sizeof(routerstatus_t));
routerinfo_t *ri = tor_malloc_zero(sizeof(routerinfo_t));
uint8_t identity[DIGEST_LEN];
uint8_t curr_hsdir_index[DIGEST256_LEN];
tor_addr_t ipv4_addr;
memset(identity, identity_idx, sizeof(identity));
memset(curr_hsdir_index, identity_idx, sizeof(curr_hsdir_index));
memcpy(rs->identity_digest, identity, DIGEST_LEN);
rs->is_hs_dir = is_hsdir;
rs->supports_v3_hsdir = 1;
tor_addr_parse(&ipv4_addr, "1.2.3.4");
ri->addr = tor_addr_to_ipv4h(&ipv4_addr);
ri->nickname = tor_strdup(nickname);
ri->protocol_list = tor_strdup("HSDir=1-2 LinkAuth=3");
memcpy(ri->cache_info.identity_digest, identity, DIGEST_LEN);
tt_assert(nodelist_set_routerinfo(ri, NULL));
node_t *node = node_get_mutable_by_id(ri->cache_info.identity_digest);
tt_assert(node);
node->rs = rs;
memcpy(node->hsdir_index->current, curr_hsdir_index,
sizeof(node->hsdir_index->current));
smartlist_add(ns->routerstatus_list, rs);
done:
;
}
static networkstatus_t *mock_ns = NULL;
static networkstatus_t *
mock_networkstatus_get_latest_consensus(void)
{
time_t now = approx_time();
/* If initialized, return it */
if (mock_ns) {
return mock_ns;
}
/* Initialize fake consensus */
mock_ns = tor_malloc_zero(sizeof(networkstatus_t));
/* This consensus is live */
mock_ns->valid_after = now-1;
mock_ns->fresh_until = now+1;
mock_ns->valid_until = now+2;
/* Create routerstatus list */
mock_ns->routerstatus_list = smartlist_new();
return mock_ns;
}
/** Test the responsible HSDirs calculation function */
static void
test_responsible_hsdirs(void *arg)
{
time_t now = approx_time();
smartlist_t *responsible_dirs = smartlist_new();
networkstatus_t *ns = NULL;
int retval;
(void) arg;
hs_init();
MOCK(networkstatus_get_latest_consensus,
mock_networkstatus_get_latest_consensus);
ns = networkstatus_get_latest_consensus();
{ /* First router: HSdir */
helper_add_hsdir_to_networkstatus(ns, 1, "igor", 1);
}
{ /* Second HSDir */
helper_add_hsdir_to_networkstatus(ns, 2, "victor", 1);
}
{ /* Third relay but not HSDir */
helper_add_hsdir_to_networkstatus(ns, 3, "spyro", 0);
}
ed25519_keypair_t kp;
retval = ed25519_keypair_generate(&kp, 0);
tt_int_op(retval, OP_EQ , 0);
uint64_t time_period_num = hs_get_time_period_num(now);
hs_get_responsible_hsdirs(&kp.pubkey, time_period_num,
0, 0, responsible_dirs);
/* Make sure that we only found 2 responsible HSDirs.
* The third relay was not an hsdir! */
tt_int_op(smartlist_len(responsible_dirs), OP_EQ, 2);
/** TODO: Build a bigger network and do more tests here */
done:
SMARTLIST_FOREACH(ns->routerstatus_list,
routerstatus_t *, rs, routerstatus_free(rs));
smartlist_free(responsible_dirs);
smartlist_clear(ns->routerstatus_list);
networkstatus_vote_free(mock_ns);
}
static void
mock_directory_initiate_request(directory_request_t *req)
{
(void)req;
return;
}
static int
mock_hs_desc_encode_descriptor(const hs_descriptor_t *desc,
const ed25519_keypair_t *signing_kp,
char **encoded_out)
{
(void)desc;
(void)signing_kp;
tor_asprintf(encoded_out, "lulu");
return 0;
}
static or_state_t dummy_state;
/* Mock function to get fake or state (used for rev counters) */
static or_state_t *
get_or_state_replacement(void)
{
return &dummy_state;
}
static int
mock_router_have_minimum_dir_info(void)
{
return 1;
}
/** Test that we correctly detect when the HSDir hash ring changes so that we
* reupload our descriptor. */
static void
test_desc_reupload_logic(void *arg)
{
networkstatus_t *ns = NULL;
(void) arg;
hs_init();
MOCK(router_have_minimum_dir_info,
mock_router_have_minimum_dir_info);
MOCK(get_or_state,
get_or_state_replacement);
MOCK(networkstatus_get_latest_consensus,
mock_networkstatus_get_latest_consensus);
MOCK(directory_initiate_request,
mock_directory_initiate_request);
MOCK(hs_desc_encode_descriptor,
mock_hs_desc_encode_descriptor);
ns = networkstatus_get_latest_consensus();
/** Test logic:
* 1) Upload descriptor to HSDirs
* CHECK that previous_hsdirs list was populated.
* 2) Then call router_dir_info_changed() without an HSDir set change.
* CHECK that no reuplod occurs.
* 3) Now change the HSDir set, and call dir_info_changed() again.
* CHECK that reupload occurs.
* 4) Finally call service_desc_schedule_upload().
* CHECK that previous_hsdirs list was cleared.
**/
/* Let's start by building our descriptor and service */
hs_service_descriptor_t *desc = service_descriptor_new();
hs_service_t *service = NULL;
char onion_addr[HS_SERVICE_ADDR_LEN_BASE32 + 1];
ed25519_public_key_t pubkey;
memset(&pubkey, '\x42', sizeof(pubkey));
hs_build_address(&pubkey, HS_VERSION_THREE, onion_addr);
service = tor_malloc_zero(sizeof(hs_service_t));
memcpy(service->onion_address, onion_addr, sizeof(service->onion_address));
ed25519_secret_key_generate(&service->keys.identity_sk, 0);
ed25519_public_key_generate(&service->keys.identity_pk,
&service->keys.identity_sk);
service->desc_current = desc;
/* Also add service to service map */
hs_service_ht *service_map = get_hs_service_map();
tt_assert(service_map);
tt_int_op(hs_service_get_num_services(), OP_EQ, 0);
register_service(service_map, service);
tt_int_op(hs_service_get_num_services(), OP_EQ, 1);
/* Now let's create our hash ring: */
{ /* First HSDir */
helper_add_hsdir_to_networkstatus(ns, 1, "dingus", 1);
}
{ /* Second HSDir */
helper_add_hsdir_to_networkstatus(ns, 2, "clive", 1);
}
/* Now let's upload our desc to all hsdirs */
upload_descriptor_to_all(service, desc, 0);
/* Check that previous hsdirs were populated */
tt_int_op(smartlist_len(desc->previous_hsdirs), OP_EQ, 2);
/* Poison next upload time so that we can see if it was changed by
* router_dir_info_changed(). No changes in hash ring so far, so the upload
* time should stay as is. */
desc->next_upload_time = 42;
router_dir_info_changed();
tt_int_op(desc->next_upload_time, OP_EQ, 42);
/* Now change the HSDir hash ring by adding another node */
{ /* Third HSDir */
helper_add_hsdir_to_networkstatus(ns, 3, "ringo", 1);
}
/* Now call service_desc_hsdirs_changed() and see that it detected the hash
ring change */
time_t now = approx_time();
tt_assert(now);
tt_int_op(service_desc_hsdirs_changed(service, desc), OP_EQ, 1);
/* Now pretend that the descriptor changed, and order a reupload to all
HSDirs. Make sure that the set of previous HSDirs was cleared. */
service_desc_schedule_upload(desc, now, 1);
tt_int_op(smartlist_len(desc->previous_hsdirs), OP_EQ, 0);
/* Now reupload again: see that the prev hsdir set got populated again. */
upload_descriptor_to_all(service, desc, 0);
tt_int_op(smartlist_len(desc->previous_hsdirs), OP_EQ, 3);
done:
hs_free_all();
}
/** Test disaster SRV computation and caching */
static void
test_disaster_srv(void *arg)
{
uint8_t *cached_disaster_srv_one = NULL;
uint8_t *cached_disaster_srv_two = NULL;
uint8_t srv_one[DIGEST256_LEN] = {0};
uint8_t srv_two[DIGEST256_LEN] = {0};
uint8_t srv_three[DIGEST256_LEN] = {0};
uint8_t srv_four[DIGEST256_LEN] = {0};
uint8_t srv_five[DIGEST256_LEN] = {0};
(void) arg;
/* Get the cached SRVs: we gonna use them later for verification */
cached_disaster_srv_one = get_first_cached_disaster_srv();
cached_disaster_srv_two = get_second_cached_disaster_srv();
/* Compute some srvs */
get_disaster_srv(1, srv_one);
get_disaster_srv(2, srv_two);
/* Check that the cached ones where updated */
tt_mem_op(cached_disaster_srv_one, OP_EQ, srv_one, DIGEST256_LEN);
tt_mem_op(cached_disaster_srv_two, OP_EQ, srv_two, DIGEST256_LEN);
/* Ask for an SRV that has already been computed */
get_disaster_srv(2, srv_two);
/* and check that the cache entries have not changed */
tt_mem_op(cached_disaster_srv_one, OP_EQ, srv_one, DIGEST256_LEN);
tt_mem_op(cached_disaster_srv_two, OP_EQ, srv_two, DIGEST256_LEN);
/* Ask for a new SRV */
get_disaster_srv(3, srv_three);
tt_mem_op(cached_disaster_srv_one, OP_EQ, srv_three, DIGEST256_LEN);
tt_mem_op(cached_disaster_srv_two, OP_EQ, srv_two, DIGEST256_LEN);
/* Ask for another SRV: none of the original SRVs should now be cached */
get_disaster_srv(4, srv_four);
tt_mem_op(cached_disaster_srv_one, OP_EQ, srv_three, DIGEST256_LEN);
tt_mem_op(cached_disaster_srv_two, OP_EQ, srv_four, DIGEST256_LEN);
/* Ask for yet another SRV */
get_disaster_srv(5, srv_five);
tt_mem_op(cached_disaster_srv_one, OP_EQ, srv_five, DIGEST256_LEN);
tt_mem_op(cached_disaster_srv_two, OP_EQ, srv_four, DIGEST256_LEN);
done:
;
}
/** Test our HS descriptor request tracker by making various requests and
* checking whether they get tracked properly. */
static void
test_hid_serv_request_tracker(void *arg)
{
(void) arg;
time_t retval;
routerstatus_t *hsdir = NULL, *hsdir2 = NULL, *hsdir3 = NULL;
time_t now = approx_time();
const char *req_key_str_first =
"vd4zb6zesaubtrjvdqcr2w7x7lhw2up4Xnw4526ThUNbL5o1go+EdUuEqlKxHkNbnK41pRzizzs";
const char *req_key_str_second =
"g53o7iavcd62oihswhr24u6czmqws5kpXnw4526ThUNbL5o1go+EdUuEqlKxHkNbnK41pRzizzs";
const char *req_key_str_small = "ZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZZ";
/*************************** basic test *******************************/
/* Get request tracker and make sure it's empty */
strmap_t *request_tracker = get_last_hid_serv_requests();
tt_int_op(strmap_size(request_tracker),OP_EQ, 0);
/* Let's register a hid serv request */
hsdir = tor_malloc_zero(sizeof(routerstatus_t));
memset(hsdir->identity_digest, 'Z', DIGEST_LEN);
retval = hs_lookup_last_hid_serv_request(hsdir, req_key_str_first,
now, 1);
tt_int_op(retval, OP_EQ, now);
tt_int_op(strmap_size(request_tracker),OP_EQ, 1);
/* Let's lookup a non-existent hidserv request */
retval = hs_lookup_last_hid_serv_request(hsdir, req_key_str_second,
now+1, 0);
tt_int_op(retval, OP_EQ, 0);
tt_int_op(strmap_size(request_tracker),OP_EQ, 1);
/* Let's lookup a real hidserv request */
retval = hs_lookup_last_hid_serv_request(hsdir, req_key_str_first,
now+2, 0);
tt_int_op(retval, OP_EQ, now); /* we got it */
tt_int_op(strmap_size(request_tracker),OP_EQ, 1);
/**********************************************************************/
/* Let's add another request for the same HS but on a different HSDir. */
hsdir2 = tor_malloc_zero(sizeof(routerstatus_t));
memset(hsdir2->identity_digest, 2, DIGEST_LEN);
retval = hs_lookup_last_hid_serv_request(hsdir2, req_key_str_first,
now+3, 1);
tt_int_op(retval, OP_EQ, now+3);
tt_int_op(strmap_size(request_tracker),OP_EQ, 2);
/* Check that we can clean the first request based on time */
hs_clean_last_hid_serv_requests(now+3+REND_HID_SERV_DIR_REQUERY_PERIOD);
tt_int_op(strmap_size(request_tracker),OP_EQ, 1);
/* Check that it doesn't exist anymore */
retval = hs_lookup_last_hid_serv_request(hsdir, req_key_str_first,
now+2, 0);
tt_int_op(retval, OP_EQ, 0);
/* Now let's add a smaller req key str */
hsdir3 = tor_malloc_zero(sizeof(routerstatus_t));
memset(hsdir3->identity_digest, 3, DIGEST_LEN);
retval = hs_lookup_last_hid_serv_request(hsdir3, req_key_str_small,
now+4, 1);
tt_int_op(retval, OP_EQ, now+4);
tt_int_op(strmap_size(request_tracker),OP_EQ, 2);
/*************************** deleting entries **************************/
/* Add another request with very short key */
retval = hs_lookup_last_hid_serv_request(hsdir, "l", now, 1);
tt_int_op(strmap_size(request_tracker),OP_EQ, 3);
/* Try deleting entries with a dummy key. Check that our previous requests
* are still there */
tor_capture_bugs_(1);
hs_purge_hid_serv_from_last_hid_serv_requests("a");
tt_int_op(strmap_size(request_tracker),OP_EQ, 3);
tor_end_capture_bugs_();
/* Try another dummy key. Check that requests are still there */
{
char dummy[2000];
memset(dummy, 'Z', 2000);
dummy[1999] = '\x00';
hs_purge_hid_serv_from_last_hid_serv_requests(dummy);
tt_int_op(strmap_size(request_tracker),OP_EQ, 3);
}
/* Another dummy key! */
hs_purge_hid_serv_from_last_hid_serv_requests(req_key_str_second);
tt_int_op(strmap_size(request_tracker),OP_EQ, 3);
/* Now actually delete a request! */
hs_purge_hid_serv_from_last_hid_serv_requests(req_key_str_first);
tt_int_op(strmap_size(request_tracker),OP_EQ, 2);
/* Purge it all! */
hs_purge_last_hid_serv_requests();
request_tracker = get_last_hid_serv_requests();
tt_int_op(strmap_size(request_tracker),OP_EQ, 0);
done:
tor_free(hsdir);
tor_free(hsdir2);
tor_free(hsdir3);
}
static void
test_parse_extended_hostname(void *arg)
{
(void) arg;
char address1[] = "fooaddress.onion";
char address2[] = "aaaaaaaaaaaaaaaa.onion";
char address3[] = "fooaddress.exit";
char address4[] = "www.torproject.org";
char address5[] = "foo.abcdefghijklmnop.onion";
char address6[] = "foo.bar.abcdefghijklmnop.onion";
char address7[] = ".abcdefghijklmnop.onion";
char address8[] =
"www.p3xnclpu4mu22dwaurjtsybyqk4xfjmcfz6z62yl24uwmhjatiwnlnad.onion";
tt_assert(BAD_HOSTNAME == parse_extended_hostname(address1));
tt_assert(ONION_V2_HOSTNAME == parse_extended_hostname(address2));
tt_str_op(address2,OP_EQ, "aaaaaaaaaaaaaaaa");
tt_assert(EXIT_HOSTNAME == parse_extended_hostname(address3));
tt_assert(NORMAL_HOSTNAME == parse_extended_hostname(address4));
tt_assert(ONION_V2_HOSTNAME == parse_extended_hostname(address5));
tt_str_op(address5,OP_EQ, "abcdefghijklmnop");
tt_assert(ONION_V2_HOSTNAME == parse_extended_hostname(address6));
tt_str_op(address6,OP_EQ, "abcdefghijklmnop");
tt_assert(BAD_HOSTNAME == parse_extended_hostname(address7));
tt_assert(ONION_V3_HOSTNAME == parse_extended_hostname(address8));
tt_str_op(address8, OP_EQ,
"p3xnclpu4mu22dwaurjtsybyqk4xfjmcfz6z62yl24uwmhjatiwnlnad");
done: ;
}
struct testcase_t hs_common_tests[] = {
{ "build_address", test_build_address, TT_FORK,
NULL, NULL },
{ "validate_address", test_validate_address, TT_FORK,
NULL, NULL },
{ "time_period", test_time_period, TT_FORK,
NULL, NULL },
{ "start_time_of_next_time_period", test_start_time_of_next_time_period,
TT_FORK, NULL, NULL },
{ "desc_overlap_period", test_desc_overlap_period, TT_FORK,
NULL, NULL },
{ "desc_overlap_period_testnet", test_desc_overlap_period_testnet, TT_FORK,
NULL, NULL },
{ "responsible_hsdirs", test_responsible_hsdirs, TT_FORK,
NULL, NULL },
{ "desc_reupload_logic", test_desc_reupload_logic, TT_FORK,
NULL, NULL },
{ "disaster_srv", test_disaster_srv, TT_FORK,
NULL, NULL },
{ "hid_serv_request_tracker", test_hid_serv_request_tracker, TT_FORK,
NULL, NULL },
{ "parse_extended_hostname", test_parse_extended_hostname, TT_FORK,
NULL, NULL },
END_OF_TESTCASES
};