RD_BOOL rdpsnd_init(char *optarg) {
struct audio_driver *pos;
char *driver = NULL, *options = NULL;
drivers = NULL;
packet.data = (uint8 *) xmalloc(65536);
packet.p = packet.end = packet.data;
packet.size = 0;
rdpsnd_channel = channel_register("rdpsnd",
CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_ENCRYPT_RDP,
rdpsnd_process);
rdpsnddbg_channel = channel_register("snddbg",
CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_ENCRYPT_RDP,
rdpsnddbg_process);
if ((rdpsnd_channel == NULL) || (rdpsnddbg_channel == NULL)) {
error("channel_register\n");
return False;
}
rdpsnd_queue_init();
if (optarg != NULL && strlen(optarg) > 0) {
driver = options = optarg;
while (*options != '\0' && *options != ':')
options++;
if (*options == ':') {
*options = '\0';
options++;
}
if (*options == '\0')
options = NULL;
}
rdpsnd_register_drivers(options);
if (!driver)
return True;
pos = drivers;
while (pos != NULL) {
if (!strcmp(pos->name, driver)) {
DEBUG(("selected %s\n", pos->name));
current_driver = pos;
return True;
}
pos = pos->next;
}
return False;
}
/* Initialize this module: Register the lspci channel */
BOOL
lspci_init(void)
{
lspci_channel =
channel_register("lspci", CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_ENCRYPT_RDP,
lspci_process);
return (lspci_channel != NULL);
}
/* Initialize this module: Register the lspci channel */
BOOL
lspci_init(RDPCLIENT * This)
{
lspci_channel =
channel_register(This, "lspci", CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_ENCRYPT_RDP,
lspci_process);
return (lspci_channel != NULL);
}
BOOL
rdpsnd_init(void)
{
rdpsnd_channel =
channel_register("rdpsnd", CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_ENCRYPT_RDP,
rdpsnd_process);
return (rdpsnd_channel != NULL);
}
BOOL
cliprdr_init(void)
{
cliprdr_channel =
channel_register("cliprdr",
CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_ENCRYPT_RDP |
CHANNEL_OPTION_COMPRESS_RDP | CHANNEL_OPTION_SHOW_PROTOCOL,
cliprdr_process);
return (cliprdr_channel != NULL);
}
RD_BOOL
rdpdr_init()
{
rdpdr_channel =
channel_register("rdpdr",
CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_COMPRESS_RDP,
rdpdr_process);
return (rdpdr_channel != NULL);
}
BOOL
rdpdr_init(RDPCLIENT * This)
{
if (This->num_devices > 0)
{
This->rdpdr.channel =
channel_register(This, "rdpdr",
CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_COMPRESS_RDP,
rdpdr_process);
}
return (This->rdpdr.channel != NULL);
}
RD_BOOL
rdpusb_init(void)
{
bool fUseUsbfs;
if (RT_SUCCESS(USBProxyLinuxChooseMethod(&fUseUsbfs, &g_pcszDevicesRoot)))
{
g_fUseSysfs = !fUseUsbfs;
rdpusb_channel =
channel_register("vrdpusb", CHANNEL_OPTION_INITIALIZED | CHANNEL_OPTION_ENCRYPT_RDP,
rdpusb_process);
return (rdpusb_channel != NULL);
}
return false;
}
/*
* Request ads
* The response is plain XML
*
*/
int cmd_requestad (SESSION * session, unsigned char ad_type)
{
CHANNEL *ch;
int ret;
char buf[100];
struct buf* b = buf_new();
_snprintf(buf, sizeof(buf), "RequestAd-with-type-%d", ad_type);
ch = channel_register (buf, dump_generic, NULL);
DSFYDEBUG
("allocated channel %d, retrieving ads with type id %d\n",
ch->channel_id, ad_type);
buf_append_u16(b, ch->channel_id);
buf_append_u8(b, ad_type);
ret = packet_write (session, CMD_REQUESTAD, b->ptr, b->len);
DSFYDEBUG ("packet_write() returned %d\n", ret);
buf_free(b);
return ret;
}
static void
test_channel_lifecycle_2(void *arg)
{
channel_t *ch = NULL;
(void)arg;
/* Mock these for the whole lifecycle test */
MOCK(scheduler_channel_doesnt_want_writes,
scheduler_channel_doesnt_want_writes_mock);
MOCK(scheduler_release_channel,
scheduler_release_channel_mock);
/* Accept cells to lower layer */
test_chan_accept_cells = 1;
ch = new_fake_channel();
tt_assert(ch);
/* Start it off in OPENING */
ch->state = CHANNEL_STATE_OPENING;
/* Try to register it */
channel_register(ch);
tt_assert(ch->registered);
/* Try to close it */
channel_mark_for_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSING);
/* Finish closing it */
chan_test_finish_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSED);
channel_run_cleanup();
ch = NULL;
/* Now try OPENING->OPEN->CLOSING->ERROR */
ch = new_fake_channel();
tt_assert(ch);
ch->state = CHANNEL_STATE_OPENING;
channel_register(ch);
tt_assert(ch->registered);
/* Finish opening it */
channel_change_state_open(ch);
/* Error exit from lower layer */
chan_test_error(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSING);
chan_test_finish_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_ERROR);
channel_run_cleanup();
ch = NULL;
/* OPENING->OPEN->MAINT->CLOSING->CLOSED close from maintenance state */
ch = new_fake_channel();
tt_assert(ch);
ch->state = CHANNEL_STATE_OPENING;
channel_register(ch);
tt_assert(ch->registered);
/* Finish opening it */
channel_change_state_open(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_OPEN);
/* Go to maintenance state */
channel_change_state(ch, CHANNEL_STATE_MAINT);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_MAINT);
/* Lower layer close */
channel_mark_for_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSING);
/* Finish */
chan_test_finish_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSED);
channel_run_cleanup();
ch = NULL;
/*
* OPENING->OPEN->MAINT->CLOSING->CLOSED lower-layer close during
* maintenance state
*/
ch = new_fake_channel();
tt_assert(ch);
ch->state = CHANNEL_STATE_OPENING;
channel_register(ch);
tt_assert(ch->registered);
/* Finish opening it */
channel_change_state_open(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_OPEN);
/* Go to maintenance state */
channel_change_state(ch, CHANNEL_STATE_MAINT);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_MAINT);
/* Lower layer close */
channel_close_from_lower_layer(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSING);
/* Finish */
chan_test_finish_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSED);
channel_run_cleanup();
ch = NULL;
/* OPENING->OPEN->MAINT->CLOSING->ERROR */
ch = new_fake_channel();
tt_assert(ch);
ch->state = CHANNEL_STATE_OPENING;
channel_register(ch);
tt_assert(ch->registered);
/* Finish opening it */
channel_change_state_open(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_OPEN);
/* Go to maintenance state */
channel_change_state(ch, CHANNEL_STATE_MAINT);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_MAINT);
/* Lower layer close */
chan_test_error(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSING);
/* Finish */
chan_test_finish_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_ERROR);
channel_run_cleanup();
ch = NULL;
/* Shut down channels */
channel_free_all();
done:
tor_free(ch);
UNMOCK(scheduler_channel_doesnt_want_writes);
UNMOCK(scheduler_release_channel);
return;
}
static void
test_channel_lifecycle(void *arg)
{
channel_t *ch1 = NULL, *ch2 = NULL;
packed_cell_t *p_cell = NULL;
int old_count, init_doesnt_want_writes_count;
int init_releases_count;
(void)arg;
/* Mock these for the whole lifecycle test */
MOCK(scheduler_channel_doesnt_want_writes,
scheduler_channel_doesnt_want_writes_mock);
MOCK(scheduler_release_channel,
scheduler_release_channel_mock);
/* Cache some initial counter values */
init_doesnt_want_writes_count = test_doesnt_want_writes_count;
init_releases_count = test_releases_count;
/* Accept cells to lower layer */
test_chan_accept_cells = 1;
ch1 = new_fake_channel();
tt_assert(ch1);
/* Start it off in OPENING */
ch1->state = CHANNEL_STATE_OPENING;
/* Try to register it */
channel_register(ch1);
tt_assert(ch1->registered);
/* Try to write a cell through (should queue) */
p_cell = packed_cell_new();
old_count = test_cells_written;
channel_write_packed_cell(ch1, p_cell);
tt_int_op(old_count, OP_EQ, test_cells_written);
/* Move it to OPEN and flush */
channel_change_state_open(ch1);
/* Get another one */
ch2 = new_fake_channel();
tt_assert(ch2);
ch2->state = CHANNEL_STATE_OPENING;
/* Register */
channel_register(ch2);
tt_assert(ch2->registered);
/* Check counters */
tt_int_op(test_doesnt_want_writes_count, OP_EQ,
init_doesnt_want_writes_count);
tt_int_op(test_releases_count, OP_EQ, init_releases_count);
/* Move ch1 to MAINT */
channel_change_state(ch1, CHANNEL_STATE_MAINT);
tt_int_op(test_doesnt_want_writes_count, OP_EQ,
init_doesnt_want_writes_count + 1);
tt_int_op(test_releases_count, OP_EQ, init_releases_count);
/* Move ch2 to OPEN */
channel_change_state_open(ch2);
tt_int_op(test_doesnt_want_writes_count, OP_EQ,
init_doesnt_want_writes_count + 1);
tt_int_op(test_releases_count, OP_EQ, init_releases_count);
/* Move ch1 back to OPEN */
channel_change_state_open(ch1);
tt_int_op(test_doesnt_want_writes_count, OP_EQ,
init_doesnt_want_writes_count + 1);
tt_int_op(test_releases_count, OP_EQ, init_releases_count);
/* Mark ch2 for close */
channel_mark_for_close(ch2);
tt_int_op(ch2->state, OP_EQ, CHANNEL_STATE_CLOSING);
tt_int_op(test_doesnt_want_writes_count, OP_EQ,
init_doesnt_want_writes_count + 1);
tt_int_op(test_releases_count, OP_EQ, init_releases_count + 1);
/* Shut down channels */
channel_free_all();
ch1 = ch2 = NULL;
tt_int_op(test_doesnt_want_writes_count, OP_EQ,
init_doesnt_want_writes_count + 1);
/* channel_free() calls scheduler_release_channel() */
tt_int_op(test_releases_count, OP_EQ, init_releases_count + 4);
done:
free_fake_channel(ch1);
free_fake_channel(ch2);
UNMOCK(scheduler_channel_doesnt_want_writes);
UNMOCK(scheduler_release_channel);
}
/* Test inbound cell. The callstack is:
* channel_process_cell()
* -> chan->cell_handler()
*
* This test is about checking if we can process an inbound cell down to the
* channel handler. */
static void
test_channel_inbound_cell(void *arg)
{
channel_t *chan = NULL;
cell_t *cell = NULL;
int old_count;
(void) arg;
/* The channel will be freed so we need to hijack this so the scheduler
* doesn't get confused. */
MOCK(scheduler_release_channel, scheduler_release_channel_mock);
/* Accept cells to lower layer */
test_chan_accept_cells = 1;
chan = new_fake_channel();
tt_assert(chan);
/* Start it off in OPENING */
chan->state = CHANNEL_STATE_OPENING;
/* Try to register it */
channel_register(chan);
tt_int_op(chan->registered, OP_EQ, 1);
/* Open it */
channel_change_state_open(chan);
tt_int_op(chan->state, OP_EQ, CHANNEL_STATE_OPEN);
tt_int_op(chan->has_been_open, OP_EQ, 1);
/* Receive a cell now. */
cell = tor_malloc_zero(sizeof(*cell));
make_fake_cell(cell);
old_count = test_chan_fixed_cells_recved;
channel_process_cell(chan, cell);
tt_int_op(test_chan_fixed_cells_recved, OP_EQ, old_count);
tt_assert(monotime_coarse_is_zero(&chan->timestamp_xfer));
tt_u64_op(chan->timestamp_active, OP_EQ, 0);
tt_u64_op(chan->timestamp_recv, OP_EQ, 0);
/* Setup incoming cell handlers. We don't care about var cell, the channel
* layers is not handling those. */
channel_set_cell_handlers(chan, chan_test_cell_handler, NULL);
tt_ptr_op(chan->cell_handler, OP_EQ, chan_test_cell_handler);
/* Now process the cell, we should see it. */
old_count = test_chan_fixed_cells_recved;
channel_process_cell(chan, cell);
tt_int_op(test_chan_fixed_cells_recved, OP_EQ, old_count + 1);
/* We should have a series of timestamp set. */
tt_assert(!monotime_coarse_is_zero(&chan->timestamp_xfer));
tt_u64_op(chan->timestamp_active, OP_NE, 0);
tt_u64_op(chan->timestamp_recv, OP_NE, 0);
tt_assert(monotime_coarse_is_zero(&chan->next_padding_time));
tt_u64_op(chan->n_cells_recved, OP_EQ, 1);
tt_u64_op(chan->n_bytes_recved, OP_EQ, get_cell_network_size(0));
/* Close it */
old_count = test_close_called;
channel_mark_for_close(chan);
tt_int_op(chan->state, OP_EQ, CHANNEL_STATE_CLOSING);
tt_int_op(chan->reason_for_closing, OP_EQ, CHANNEL_CLOSE_REQUESTED);
tt_int_op(test_close_called, OP_EQ, old_count + 1);
/* This closes the channe so it calls in the scheduler, make sure of it. */
old_count = test_releases_count;
chan_test_finish_close(chan);
tt_int_op(test_releases_count, OP_EQ, old_count + 1);
tt_int_op(chan->state, OP_EQ, CHANNEL_STATE_CLOSED);
/* The channel will be free, lets make sure it is not accessible. */
uint64_t chan_id = chan->global_identifier;
tt_ptr_op(channel_find_by_global_id(chan_id), OP_EQ, chan);
channel_run_cleanup();
chan = channel_find_by_global_id(chan_id);
tt_assert(chan == NULL);
done:
tor_free(cell);
UNMOCK(scheduler_release_channel);
}
/* Test outbound cell. The callstack is:
* channel_flush_some_cells()
* -> channel_flush_from_first_active_circuit()
* -> channel_write_packed_cell()
* -> write_packed_cell()
* -> chan->write_packed_cell() fct ptr.
*
* This test goes from a cell in a circuit up to the channel write handler
* that should put them on the connection outbuf. */
static void
test_channel_outbound_cell(void *arg)
{
int old_count;
channel_t *chan = NULL;
packed_cell_t *p_cell = NULL, *p_cell2 = NULL;
origin_circuit_t *circ = NULL;
cell_queue_t *queue;
(void) arg;
/* Set the test time to be mocked, since this test assumes that no
* time will pass, ewma values will not need to be re-scaled, and so on */
monotime_enable_test_mocking();
monotime_set_mock_time_nsec(U64_LITERAL(1000000000) * 12345);
cmux_ewma_set_options(NULL,NULL);
/* The channel will be freed so we need to hijack this so the scheduler
* doesn't get confused. */
MOCK(scheduler_release_channel, scheduler_release_channel_mock);
/* Accept cells to lower layer */
test_chan_accept_cells = 1;
/* Setup a valid circuit to queue a cell. */
circ = origin_circuit_new();
tt_assert(circ);
/* Circuit needs an origin purpose to be considered origin. */
TO_CIRCUIT(circ)->purpose = CIRCUIT_PURPOSE_C_GENERAL;
TO_CIRCUIT(circ)->n_circ_id = 42;
/* This is the outbound test so use the next channel queue. */
queue = &TO_CIRCUIT(circ)->n_chan_cells;
/* Setup packed cell to queue on the circuit. */
p_cell = packed_cell_new();
tt_assert(p_cell);
p_cell2 = packed_cell_new();
tt_assert(p_cell2);
/* Setup a channel to put the circuit on. */
chan = new_fake_channel();
tt_assert(chan);
chan->state = CHANNEL_STATE_OPENING;
channel_change_state_open(chan);
/* Outbound channel. */
channel_mark_outgoing(chan);
/* Try to register it so we can clean it through the channel cleanup
* process. */
channel_register(chan);
tt_int_op(chan->registered, OP_EQ, 1);
/* Set EWMA policy so we can pick it when flushing. */
circuitmux_set_policy(chan->cmux, &ewma_policy);
tt_ptr_op(circuitmux_get_policy(chan->cmux), OP_EQ, &ewma_policy);
/* Register circuit to the channel circid map which will attach the circuit
* to the channel's cmux as well. */
circuit_set_n_circid_chan(TO_CIRCUIT(circ), 42, chan);
tt_int_op(channel_num_circuits(chan), OP_EQ, 1);
/* Test the cmux state. */
tt_ptr_op(TO_CIRCUIT(circ)->n_mux, OP_EQ, chan->cmux);
tt_int_op(circuitmux_is_circuit_attached(chan->cmux, TO_CIRCUIT(circ)),
OP_EQ, 1);
/* Flush the channel without any cell on it. */
old_count = test_cells_written;
ssize_t flushed = channel_flush_some_cells(chan, 1);
tt_i64_op(flushed, OP_EQ, 0);
tt_int_op(test_cells_written, OP_EQ, old_count);
tt_int_op(channel_more_to_flush(chan), OP_EQ, 0);
tt_int_op(circuitmux_num_active_circuits(chan->cmux), OP_EQ, 0);
tt_int_op(circuitmux_num_cells(chan->cmux), OP_EQ, 0);
tt_int_op(circuitmux_is_circuit_active(chan->cmux, TO_CIRCUIT(circ)),
OP_EQ, 0);
tt_u64_op(chan->n_cells_xmitted, OP_EQ, 0);
tt_u64_op(chan->n_bytes_xmitted, OP_EQ, 0);
/* Queue cell onto the next queue that is the outbound direction. Than
* update its cmux so the circuit can be picked when flushing cells. */
cell_queue_append(queue, p_cell);
p_cell = NULL;
tt_int_op(queue->n, OP_EQ, 1);
cell_queue_append(queue, p_cell2);
p_cell2 = NULL;
tt_int_op(queue->n, OP_EQ, 2);
update_circuit_on_cmux(TO_CIRCUIT(circ), CELL_DIRECTION_OUT);
tt_int_op(circuitmux_num_active_circuits(chan->cmux), OP_EQ, 1);
tt_int_op(circuitmux_num_cells(chan->cmux), OP_EQ, 2);
tt_int_op(circuitmux_is_circuit_active(chan->cmux, TO_CIRCUIT(circ)),
OP_EQ, 1);
/* From this point on, we have a queued cell on an active circuit attached
* to the channel's cmux. */
/* Flush the first cell. This is going to go down the call stack. */
old_count = test_cells_written;
flushed = channel_flush_some_cells(chan, 1);
tt_i64_op(flushed, OP_EQ, 1);
tt_int_op(test_cells_written, OP_EQ, old_count + 1);
tt_int_op(circuitmux_num_cells(chan->cmux), OP_EQ, 1);
tt_int_op(channel_more_to_flush(chan), OP_EQ, 1);
/* Circuit should remain active because there is a second cell queued. */
tt_int_op(circuitmux_is_circuit_active(chan->cmux, TO_CIRCUIT(circ)),
OP_EQ, 1);
/* Should still be attached. */
tt_int_op(circuitmux_is_circuit_attached(chan->cmux, TO_CIRCUIT(circ)),
OP_EQ, 1);
tt_u64_op(chan->n_cells_xmitted, OP_EQ, 1);
tt_u64_op(chan->n_bytes_xmitted, OP_EQ, get_cell_network_size(0));
/* Flush second cell. This is going to go down the call stack. */
old_count = test_cells_written;
flushed = channel_flush_some_cells(chan, 1);
tt_i64_op(flushed, OP_EQ, 1);
tt_int_op(test_cells_written, OP_EQ, old_count + 1);
tt_int_op(circuitmux_num_cells(chan->cmux), OP_EQ, 0);
tt_int_op(channel_more_to_flush(chan), OP_EQ, 0);
/* No more cells should make the circuit inactive. */
tt_int_op(circuitmux_is_circuit_active(chan->cmux, TO_CIRCUIT(circ)),
OP_EQ, 0);
/* Should still be attached. */
tt_int_op(circuitmux_is_circuit_attached(chan->cmux, TO_CIRCUIT(circ)),
OP_EQ, 1);
tt_u64_op(chan->n_cells_xmitted, OP_EQ, 2);
tt_u64_op(chan->n_bytes_xmitted, OP_EQ, get_cell_network_size(0) * 2);
done:
if (circ) {
circuit_free_(TO_CIRCUIT(circ));
}
tor_free(p_cell);
channel_free_all();
UNMOCK(scheduler_release_channel);
monotime_disable_test_mocking();
}
static void
test_channel_dumpstats(void *arg)
{
channel_t *ch = NULL;
cell_t *cell = NULL;
packed_cell_t *p_cell = NULL;
int old_count;
(void)arg;
/* Mock these for duration of the test */
MOCK(scheduler_channel_doesnt_want_writes,
scheduler_channel_doesnt_want_writes_mock);
MOCK(scheduler_release_channel,
scheduler_release_channel_mock);
/* Set up a new fake channel */
ch = new_fake_channel();
tt_assert(ch);
/* Try to register it */
channel_register(ch);
tt_assert(ch->registered);
/* Set up mock */
dump_statistics_mock_target = ch;
dump_statistics_mock_matches = 0;
MOCK(channel_dump_statistics,
chan_test_channel_dump_statistics_mock);
/* Call channel_dumpstats() */
channel_dumpstats(LOG_DEBUG);
/* Assert that we hit the mock */
tt_int_op(dump_statistics_mock_matches, OP_EQ, 1);
/* Close the channel */
channel_mark_for_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSING);
chan_test_finish_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSED);
/* Try again and hit the finished channel */
channel_dumpstats(LOG_DEBUG);
tt_int_op(dump_statistics_mock_matches, OP_EQ, 2);
channel_run_cleanup();
ch = NULL;
/* Now we should hit nothing */
channel_dumpstats(LOG_DEBUG);
tt_int_op(dump_statistics_mock_matches, OP_EQ, 2);
/* Unmock */
UNMOCK(channel_dump_statistics);
dump_statistics_mock_target = NULL;
dump_statistics_mock_matches = 0;
/* Now make another channel */
ch = new_fake_channel();
tt_assert(ch);
channel_register(ch);
tt_int_op(ch->registered, OP_EQ, 1);
/* Lie about its age so dumpstats gets coverage for rate calculations */
ch->timestamp_created = time(NULL) - 30;
tt_int_op(ch->timestamp_created, OP_GT, 0);
tt_int_op(time(NULL), OP_GT, ch->timestamp_created);
/* Put cells through it both ways to make the counters non-zero */
p_cell = packed_cell_new();
test_chan_accept_cells = 1;
old_count = test_cells_written;
channel_write_packed_cell(ch, p_cell);
tt_int_op(test_cells_written, OP_EQ, old_count + 1);
tt_u64_op(ch->n_bytes_xmitted, OP_GT, 0);
tt_u64_op(ch->n_cells_xmitted, OP_GT, 0);
/* Receive path */
channel_set_cell_handlers(ch,
chan_test_cell_handler,
chan_test_var_cell_handler);
tt_ptr_op(channel_get_cell_handler(ch), OP_EQ, chan_test_cell_handler);
tt_ptr_op(channel_get_var_cell_handler(ch), OP_EQ,
chan_test_var_cell_handler);
cell = tor_malloc_zero(sizeof(*cell));
old_count = test_chan_fixed_cells_recved;
channel_process_cell(ch, cell);
tt_int_op(test_chan_fixed_cells_recved, OP_EQ, old_count + 1);
tt_u64_op(ch->n_bytes_recved, OP_GT, 0);
tt_u64_op(ch->n_cells_recved, OP_GT, 0);
/* Test channel_dump_statistics */
ch->describe_transport = chan_test_describe_transport;
ch->dumpstats = chan_test_dumpstats;
test_chan_should_be_canonical = 1;
ch->is_canonical = test_chan_is_canonical;
old_count = test_dumpstats_calls;
channel_dump_statistics(ch, LOG_DEBUG);
tt_int_op(test_dumpstats_calls, OP_EQ, old_count + 1);
/* Close the channel */
channel_mark_for_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSING);
chan_test_finish_close(ch);
tt_int_op(ch->state, OP_EQ, CHANNEL_STATE_CLOSED);
channel_run_cleanup();
ch = NULL;
done:
free_fake_channel(ch);
tor_free(cell);
UNMOCK(scheduler_channel_doesnt_want_writes);
UNMOCK(scheduler_release_channel);
return;
}
static void
test_channel_for_extend(void *arg)
{
channel_t *chan1 = NULL, *chan2 = NULL;
channel_t *ret_chan = NULL;
char digest[DIGEST_LEN];
ed25519_public_key_t ed_id;
tor_addr_t addr;
const char *msg;
int launch;
time_t now = time(NULL);
(void) arg;
memset(digest, 'A', sizeof(digest));
memset(&ed_id, 'B', sizeof(ed_id));
chan1 = new_fake_channel();
tt_assert(chan1);
/* Need to be registered to get added to the id map. */
channel_register(chan1);
tt_int_op(chan1->registered, OP_EQ, 1);
/* We need those for the test. */
chan1->is_canonical = test_chan_is_canonical;
chan1->matches_target = test_chan_matches_target;
chan1->timestamp_created = now - 9;
chan2 = new_fake_channel();
tt_assert(chan2);
/* Need to be registered to get added to the id map. */
channel_register(chan2);
tt_int_op(chan2->registered, OP_EQ, 1);
/* We need those for the test. */
chan2->is_canonical = test_chan_is_canonical;
chan2->matches_target = test_chan_matches_target;
/* Make it older than chan1. */
chan2->timestamp_created = chan1->timestamp_created - 1;
/* Set channel identities and add it to the channel map. The last one to be
* added is made the first one in the list so the lookup will always return
* that one first. */
channel_set_identity_digest(chan2, digest, &ed_id);
channel_set_identity_digest(chan1, digest, &ed_id);
tt_ptr_op(channel_find_by_remote_identity(digest, NULL), OP_EQ, chan1);
tt_ptr_op(channel_find_by_remote_identity(digest, &ed_id), OP_EQ, chan1);
/* The expected result is chan2 because it is older than chan1. */
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(ret_chan);
tt_ptr_op(ret_chan, OP_EQ, chan2);
tt_int_op(launch, OP_EQ, 0);
tt_str_op(msg, OP_EQ, "Connection is fine; using it.");
/* Switch that around from previous test. */
chan2->timestamp_created = chan1->timestamp_created + 1;
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(ret_chan);
tt_ptr_op(ret_chan, OP_EQ, chan1);
tt_int_op(launch, OP_EQ, 0);
tt_str_op(msg, OP_EQ, "Connection is fine; using it.");
/* Same creation time, num circuits will be used and they both have 0 so the
* channel 2 should be picked due to how channel_is_better() work. */
chan2->timestamp_created = chan1->timestamp_created;
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(ret_chan);
tt_ptr_op(ret_chan, OP_EQ, chan1);
tt_int_op(launch, OP_EQ, 0);
tt_str_op(msg, OP_EQ, "Connection is fine; using it.");
/* For the rest of the tests, we need channel 1 to be the older. */
chan2->timestamp_created = chan1->timestamp_created + 1;
/* Condemned the older channel. */
chan1->state = CHANNEL_STATE_CLOSING;
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(ret_chan);
tt_ptr_op(ret_chan, OP_EQ, chan2);
tt_int_op(launch, OP_EQ, 0);
tt_str_op(msg, OP_EQ, "Connection is fine; using it.");
chan1->state = CHANNEL_STATE_OPEN;
/* Make the older channel a client one. */
channel_mark_client(chan1);
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(ret_chan);
tt_ptr_op(ret_chan, OP_EQ, chan2);
tt_int_op(launch, OP_EQ, 0);
tt_str_op(msg, OP_EQ, "Connection is fine; using it.");
channel_clear_client(chan1);
/* Non matching ed identity with valid digest. */
ed25519_public_key_t dumb_ed_id;
memset(&dumb_ed_id, 0, sizeof(dumb_ed_id));
ret_chan = channel_get_for_extend(digest, &dumb_ed_id, &addr, &msg,
&launch);
tt_assert(!ret_chan);
tt_str_op(msg, OP_EQ, "Not connected. Connecting.");
tt_int_op(launch, OP_EQ, 1);
/* Opening channel, we'll check if the target address matches. */
test_chan_should_match_target = 1;
chan1->state = CHANNEL_STATE_OPENING;
chan2->state = CHANNEL_STATE_OPENING;
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(!ret_chan);
tt_str_op(msg, OP_EQ, "Connection in progress; waiting.");
tt_int_op(launch, OP_EQ, 0);
chan1->state = CHANNEL_STATE_OPEN;
chan2->state = CHANNEL_STATE_OPEN;
/* Mark channel 1 as bad for circuits. */
channel_mark_bad_for_new_circs(chan1);
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(ret_chan);
tt_ptr_op(ret_chan, OP_EQ, chan2);
tt_int_op(launch, OP_EQ, 0);
tt_str_op(msg, OP_EQ, "Connection is fine; using it.");
chan1->is_bad_for_new_circs = 0;
/* Mark both channels as unusable. */
channel_mark_bad_for_new_circs(chan1);
channel_mark_bad_for_new_circs(chan2);
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(!ret_chan);
tt_str_op(msg, OP_EQ, "Connections all too old, or too non-canonical. "
" Launching a new one.");
tt_int_op(launch, OP_EQ, 1);
chan1->is_bad_for_new_circs = 0;
chan2->is_bad_for_new_circs = 0;
/* Non canonical channels. */
test_chan_should_match_target = 0;
test_chan_canonical_should_be_reliable = 1;
ret_chan = channel_get_for_extend(digest, &ed_id, &addr, &msg, &launch);
tt_assert(!ret_chan);
tt_str_op(msg, OP_EQ, "Connections all too old, or too non-canonical. "
" Launching a new one.");
tt_int_op(launch, OP_EQ, 1);
done:
free_fake_channel(chan1);
free_fake_channel(chan2);
}
static void
test_channel_id_map(void *arg)
{
(void)arg;
#define N_CHAN 6
char rsa_id[N_CHAN][DIGEST_LEN];
ed25519_public_key_t *ed_id[N_CHAN];
channel_t *chan[N_CHAN];
int i;
ed25519_public_key_t ed_zero;
memset(&ed_zero, 0, sizeof(ed_zero));
tt_int_op(DIGEST_LEN, OP_EQ, sizeof(rsa_id[0])); // Do I remember C?
for (i = 0; i < N_CHAN; ++i) {
crypto_rand(rsa_id[i], DIGEST_LEN);
ed_id[i] = tor_malloc_zero(sizeof(*ed_id[i]));
crypto_rand((char*)ed_id[i]->pubkey, sizeof(ed_id[i]->pubkey));
}
/* For channel 3, have no Ed identity. */
tor_free(ed_id[3]);
/* Channel 2 and 4 have same ROSA identity */
memcpy(rsa_id[4], rsa_id[2], DIGEST_LEN);
/* Channel 2 and 4 and 5 have same RSA identity */
memcpy(rsa_id[4], rsa_id[2], DIGEST_LEN);
memcpy(rsa_id[5], rsa_id[2], DIGEST_LEN);
/* Channels 2 and 5 have same Ed25519 identity */
memcpy(ed_id[5], ed_id[2], sizeof(*ed_id[2]));
for (i = 0; i < N_CHAN; ++i) {
chan[i] = new_fake_channel();
channel_register(chan[i]);
channel_set_identity_digest(chan[i], rsa_id[i], ed_id[i]);
}
/* Lookup by RSA id only */
tt_ptr_op(chan[0], OP_EQ,
channel_find_by_remote_identity(rsa_id[0], NULL));
tt_ptr_op(chan[1], OP_EQ,
channel_find_by_remote_identity(rsa_id[1], NULL));
tt_ptr_op(chan[3], OP_EQ,
channel_find_by_remote_identity(rsa_id[3], NULL));
channel_t *ch;
ch = channel_find_by_remote_identity(rsa_id[2], NULL);
tt_assert(ch == chan[2] || ch == chan[4] || ch == chan[5]);
ch = channel_next_with_rsa_identity(ch);
tt_assert(ch == chan[2] || ch == chan[4] || ch == chan[5]);
ch = channel_next_with_rsa_identity(ch);
tt_assert(ch == chan[2] || ch == chan[4] || ch == chan[5]);
ch = channel_next_with_rsa_identity(ch);
tt_ptr_op(ch, OP_EQ, NULL);
/* As above, but with zero Ed25519 ID (meaning "any ID") */
tt_ptr_op(chan[0], OP_EQ,
channel_find_by_remote_identity(rsa_id[0], &ed_zero));
tt_ptr_op(chan[1], OP_EQ,
channel_find_by_remote_identity(rsa_id[1], &ed_zero));
tt_ptr_op(chan[3], OP_EQ,
channel_find_by_remote_identity(rsa_id[3], &ed_zero));
ch = channel_find_by_remote_identity(rsa_id[2], &ed_zero);
tt_assert(ch == chan[2] || ch == chan[4] || ch == chan[5]);
ch = channel_next_with_rsa_identity(ch);
tt_assert(ch == chan[2] || ch == chan[4] || ch == chan[5]);
ch = channel_next_with_rsa_identity(ch);
tt_assert(ch == chan[2] || ch == chan[4] || ch == chan[5]);
ch = channel_next_with_rsa_identity(ch);
tt_ptr_op(ch, OP_EQ, NULL);
/* Lookup nonexistent RSA identity */
tt_ptr_op(NULL, OP_EQ,
channel_find_by_remote_identity("!!!!!!!!!!!!!!!!!!!!", NULL));
/* Look up by full identity pair */
tt_ptr_op(chan[0], OP_EQ,
channel_find_by_remote_identity(rsa_id[0], ed_id[0]));
tt_ptr_op(chan[1], OP_EQ,
channel_find_by_remote_identity(rsa_id[1], ed_id[1]));
tt_ptr_op(chan[3], OP_EQ,
channel_find_by_remote_identity(rsa_id[3], ed_id[3] /*NULL*/));
tt_ptr_op(chan[4], OP_EQ,
channel_find_by_remote_identity(rsa_id[4], ed_id[4]));
ch = channel_find_by_remote_identity(rsa_id[2], ed_id[2]);
tt_assert(ch == chan[2] || ch == chan[5]);
/* Look up RSA identity with wrong ed25519 identity */
tt_ptr_op(NULL, OP_EQ,
channel_find_by_remote_identity(rsa_id[4], ed_id[0]));
tt_ptr_op(NULL, OP_EQ,
channel_find_by_remote_identity(rsa_id[2], ed_id[1]));
tt_ptr_op(NULL, OP_EQ,
channel_find_by_remote_identity(rsa_id[3], ed_id[1]));
done:
for (i = 0; i < N_CHAN; ++i) {
channel_clear_identity_digest(chan[i]);
channel_unregister(chan[i]);
free_fake_channel(chan[i]);
tor_free(ed_id[i]);
}
#undef N_CHAN
}
