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realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / ad9e5eb68d3d2c1d962b08e4da3f58b67daea94e / . / third_party / rawrtc / rawrtc / tools / data-channel-sctp-throughput.c
blob: 3bd9aea5d9b5e59032c3de7c1d74afb9e415eea7 [file] [log] [blame]
#include "helper/handler.h"
#include "helper/parameters.h"
#include "helper/utils.h"
#include <rawrtc.h>
#include <rawrtcc.h>
#include <rawrtcdc.h>
#include <re.h>
#include <stdlib.h> // exit
#include <string.h> // memcpy
#include <unistd.h> // STDIN_FILENO
#define DEBUG_MODULE "data-channel-sctp-throughput-app"
#define DEBUG_LEVEL 7
#include <re_dbg.h>
enum {
TRANSPORT_BUFFER_LENGTH = 1048576, // 1 MiB
};
struct parameters {
struct rawrtc_ice_parameters* ice_parameters;
struct rawrtc_ice_candidates* ice_candidates;
struct rawrtc_dtls_parameters* dtls_parameters;
struct sctp_parameters sctp_parameters;
};
// Note: Shadows struct client
struct data_channel_sctp_throughput_client {
char* name;
char** ice_candidate_types;
size_t n_ice_candidate_types;
uint64_t message_size;
uint16_t n_times_left;
uint32_t buffer_length;
enum rawrtc_sctp_transport_congestion_ctrl congestion_ctrl_algorithm;
uint32_t mtu;
struct rawrtc_ice_gather_options* gather_options;
enum rawrtc_ice_role role;
struct mbuf* start_buffer;
struct mbuf* throughput_buffer;
struct rawrtc_certificate* certificate;
struct rawrtc_ice_gatherer* gatherer;
struct rawrtc_ice_transport* ice_transport;
struct rawrtc_dtls_transport* dtls_transport;
struct rawrtc_sctp_transport* sctp_transport;
struct rawrtc_data_transport* data_transport;
struct data_channel_helper* data_channel;
struct parameters local_parameters;
struct parameters remote_parameters;
uint64_t start_time;
};
static void print_local_parameters(struct data_channel_sctp_throughput_client* client);
static struct tmr timer = {0};
static void timer_handler(void* arg) {
struct data_channel_helper* const channel = arg;
struct data_channel_sctp_throughput_client* const client =
(struct data_channel_sctp_throughput_client*) channel->client;
enum rawrtc_code error;
enum rawrtc_dtls_role role;
// Send start indicator
mbuf_set_pos(client->start_buffer, 0);
DEBUG_PRINTF("(%s) Sending start indicator\n", client->name);
error = rawrtc_data_channel_send(channel->channel, client->start_buffer, false);
if (error) {
DEBUG_WARNING("Could not send, reason: %s\n", rawrtc_code_to_str(error));
goto out;
}
// Send message
DEBUG_PRINTF(
"(%s) Sending %zu bytes\n", client->name, mbuf_get_left(client->throughput_buffer));
error = rawrtc_data_channel_send(channel->channel, client->throughput_buffer, true);
if (error) {
DEBUG_WARNING("Could not send, reason: %s\n", rawrtc_code_to_str(error));
goto out;
}
out:
// Get DTLS role
EOE(rawrtc_dtls_parameters_get_role(&role, client->local_parameters.dtls_parameters));
if (role == RAWRTC_DTLS_ROLE_CLIENT) {
// Close bear-noises
DEBUG_PRINTF("(%s) Closing channel\n", client->name, channel->label);
EOR(rawrtc_data_channel_close(client->data_channel->channel));
}
}
static void data_channel_message_handler(
struct mbuf* const buffer, enum rawrtc_data_channel_message_flag const flags, void* const arg) {
struct data_channel_helper* const channel = arg;
struct data_channel_sctp_throughput_client* const client =
(struct data_channel_sctp_throughput_client*) channel->client;
size_t const length = mbuf_get_left(buffer);
// Check role
if (client->role != RAWRTC_ICE_ROLE_CONTROLLED) {
DEBUG_WARNING(
"(%s) Unexpected message on data channel %s of size %zu\n", client->name,
channel->label, length);
}
if (flags & RAWRTC_DATA_CHANNEL_MESSAGE_FLAG_IS_STRING) {
// Start indicator message
uint64_t expected_size;
// Check size
if (mbuf_get_left(buffer) < 8) {
EOE(RAWRTC_CODE_INVALID_MESSAGE);
}
// Parse message
expected_size = sys_ntohll(mbuf_read_u64(buffer));
EOE(expected_size > 0 ? RAWRTC_CODE_SUCCESS : RAWRTC_CODE_INVALID_MESSAGE);
client->start_time = tmr_jiffies();
DEBUG_INFO(
"(%s) Started throughput test of %.2f MiB\n", client->name,
((double) expected_size) / 1048576);
return;
} else if (flags & RAWRTC_DATA_CHANNEL_MESSAGE_FLAG_IS_BINARY) {
// Check expected message size and print results
double const delta = ((double) (tmr_jiffies() - client->start_time)) / 1000;
DEBUG_INFO(
"(%s) Completed throughput test after %.2f seconds: %.2f Mbit/s\n", client->name, delta,
((double) length) / 131072 / delta);
// Check size
if (length != client->message_size) {
DEBUG_WARNING(
"(%s) Expected %zu bytes, received %zu bytes\n", client->name, client->message_size,
length);
return;
}
}
}
static void start_throughput_test(struct data_channel_helper* const channel) {
struct data_channel_sctp_throughput_client* const client =
(struct data_channel_sctp_throughput_client*) channel->client;
// Start throughput test delayed (if controlling)
if (client->role == RAWRTC_ICE_ROLE_CONTROLLING && client->n_times_left > 0) {
size_t length;
mbuf_set_pos(client->throughput_buffer, 0);
length = mbuf_get_left(client->throughput_buffer);
DEBUG_INFO(
"Starting throughput test of %.2f MiB in 1 second\n",
(double) length / (double) 1048576);
tmr_start(&timer, 1000, timer_handler, channel);
--client->n_times_left;
}
}
static void data_channel_buffered_amount_low_handler(void* const arg) {
struct data_channel_helper* const channel = arg;
// Print buffered amount low event
default_data_channel_buffered_amount_low_handler(arg);
// Restart throughput test
start_throughput_test(channel);
}
static void data_channel_open_handler(void* const arg) {
struct data_channel_helper* const channel = arg;
// Print open event
default_data_channel_open_handler(arg);
// Start throughput test
start_throughput_test(channel);
}
static void ice_gatherer_local_candidate_handler(
struct rawrtc_ice_candidate* const candidate,
char const* const url, // read-only
void* const arg) {
struct data_channel_sctp_throughput_client* const client = arg;
// Print local candidate
default_ice_gatherer_local_candidate_handler(candidate, url, arg);
// Print local parameters (if last candidate)
if (!candidate) {
print_local_parameters(client);
}
}
static void client_init(struct data_channel_sctp_throughput_client* const client) {
struct rawrtc_certificate* certificates[1];
struct rawrtc_data_channel_parameters* channel_parameters;
// Generate certificates
EOE(rawrtc_certificate_generate(&client->certificate, NULL));
certificates[0] = client->certificate;
// Create ICE gatherer
EOE(rawrtc_ice_gatherer_create(
&client->gatherer, client->gather_options, default_ice_gatherer_state_change_handler,
default_ice_gatherer_error_handler, ice_gatherer_local_candidate_handler, client));
// Create ICE transport
EOE(rawrtc_ice_transport_create(
&client->ice_transport, client->gatherer, default_ice_transport_state_change_handler,
default_ice_transport_candidate_pair_change_handler, client));
// Create DTLS transport
EOE(rawrtc_dtls_transport_create(
&client->dtls_transport, client->ice_transport, certificates, ARRAY_SIZE(certificates),
default_dtls_transport_state_change_handler, default_dtls_transport_error_handler, client));
// Create SCTP transport
EOE(rawrtc_sctp_transport_create(
&client->sctp_transport, client->dtls_transport,
client->local_parameters.sctp_parameters.port, default_data_channel_handler,
default_sctp_transport_state_change_handler, client));
EOE(rawrtc_sctp_transport_set_buffer_length(
client->sctp_transport, client->buffer_length, client->buffer_length));
EOE(rawrtc_sctp_transport_set_congestion_ctrl_algorithm(
client->sctp_transport, client->congestion_ctrl_algorithm));
// Get data transport
EOE(rawrtc_sctp_transport_get_data_transport(&client->data_transport, client->sctp_transport));
// Create data channel helper
data_channel_helper_create(&client->data_channel, (struct client*) client, "throughput");
// Create data channel parameters
EOE(rawrtc_data_channel_parameters_create(
&channel_parameters, client->data_channel->label, RAWRTC_DATA_CHANNEL_TYPE_RELIABLE_ORDERED,
0, NULL, true, 0));
// Create pre-negotiated data channel
EOE(rawrtc_data_channel_create(
&client->data_channel->channel, client->data_transport, channel_parameters,
data_channel_open_handler, data_channel_buffered_amount_low_handler,
default_data_channel_error_handler, default_data_channel_close_handler,
data_channel_message_handler, client->data_channel));
// Un-reference
mem_deref(channel_parameters);
}
static void client_start_gathering(struct data_channel_sctp_throughput_client* const client) {
// Start gathering
EOE(rawrtc_ice_gatherer_gather(client->gatherer, NULL));
}
static void client_start_transports(struct data_channel_sctp_throughput_client* const client) {
struct parameters* const remote_parameters = &client->remote_parameters;
// Start ICE transport
EOE(rawrtc_ice_transport_start(
client->ice_transport, client->gatherer, remote_parameters->ice_parameters, client->role));
// Start DTLS transport
EOE(rawrtc_dtls_transport_start(client->dtls_transport, remote_parameters->dtls_parameters));
// Start SCTP transport
EOE(rawrtc_sctp_transport_start(
client->sctp_transport, remote_parameters->sctp_parameters.capabilities,
remote_parameters->sctp_parameters.port));
if (client->mtu != 0) {
EOE(rawrtc_sctp_transport_set_mtu(client->sctp_transport, client->mtu));
}
}
static void parameters_destroy(struct parameters* const parameters) {
// Un-reference
parameters->ice_parameters = mem_deref(parameters->ice_parameters);
parameters->ice_candidates = mem_deref(parameters->ice_candidates);
parameters->dtls_parameters = mem_deref(parameters->dtls_parameters);
if (parameters->sctp_parameters.capabilities) {
parameters->sctp_parameters.capabilities =
mem_deref(parameters->sctp_parameters.capabilities);
}
}
static void client_stop(struct data_channel_sctp_throughput_client* const client) {
if (client->sctp_transport) {
EOE(rawrtc_sctp_transport_stop(client->sctp_transport));
}
if (client->dtls_transport) {
EOE(rawrtc_dtls_transport_stop(client->dtls_transport));
}
if (client->ice_transport) {
EOE(rawrtc_ice_transport_stop(client->ice_transport));
}
if (client->gatherer) {
EOE(rawrtc_ice_gatherer_close(client->gatherer));
}
// Un-reference & close
parameters_destroy(&client->remote_parameters);
parameters_destroy(&client->local_parameters);
client->data_channel = mem_deref(client->data_channel);
client->data_transport = mem_deref(client->data_transport);
client->sctp_transport = mem_deref(client->sctp_transport);
client->dtls_transport = mem_deref(client->dtls_transport);
client->ice_transport = mem_deref(client->ice_transport);
client->gatherer = mem_deref(client->gatherer);
client->certificate = mem_deref(client->certificate);
client->throughput_buffer = mem_deref(client->throughput_buffer);
client->start_buffer = mem_deref(client->start_buffer);
client->gather_options = mem_deref(client->gather_options);
// Stop listening on STDIN
fd_close(STDIN_FILENO);
}
static void client_set_parameters(struct data_channel_sctp_throughput_client* const client) {
struct parameters* const remote_parameters = &client->remote_parameters;
// Set remote ICE candidates
EOE(rawrtc_ice_transport_set_remote_candidates(
client->ice_transport, remote_parameters->ice_candidates->candidates,
remote_parameters->ice_candidates->n_candidates));
}
static void parse_remote_parameters(int flags, void* arg) {
struct data_channel_sctp_throughput_client* const client = arg;
enum rawrtc_code error;
struct odict* dict = NULL;
struct odict* node = NULL;
struct rawrtc_ice_parameters* ice_parameters = NULL;
struct rawrtc_ice_candidates* ice_candidates = NULL;
struct rawrtc_dtls_parameters* dtls_parameters = NULL;
struct sctp_parameters sctp_parameters = {0};
(void) flags;
// Get dict from JSON
error = get_json_stdin(&dict);
if (error) {
goto out;
}
// Decode JSON
error |= dict_get_entry(&node, dict, "iceParameters", ODICT_OBJECT, true);
error |= get_ice_parameters(&ice_parameters, node);
error |= dict_get_entry(&node, dict, "iceCandidates", ODICT_ARRAY, true);
error |= get_ice_candidates(&ice_candidates, node, arg);
error |= dict_get_entry(&node, dict, "dtlsParameters", ODICT_OBJECT, true);
error |= get_dtls_parameters(&dtls_parameters, node);
error |= dict_get_entry(&node, dict, "sctpParameters", ODICT_OBJECT, true);
error |= get_sctp_parameters(&sctp_parameters, node);
// Ok?
if (error) {
DEBUG_WARNING("Invalid remote parameters\n");
if (sctp_parameters.capabilities) {
mem_deref(sctp_parameters.capabilities);
}
goto out;
}
// Set parameters & start transports
client->remote_parameters.ice_parameters = mem_ref(ice_parameters);
client->remote_parameters.ice_candidates = mem_ref(ice_candidates);
client->remote_parameters.dtls_parameters = mem_ref(dtls_parameters);
memcpy(&client->remote_parameters.sctp_parameters, &sctp_parameters, sizeof(sctp_parameters));
DEBUG_INFO("Applying remote parameters\n");
client_set_parameters(client);
client_start_transports(client);
out:
// Un-reference
mem_deref(dtls_parameters);
mem_deref(ice_candidates);
mem_deref(ice_parameters);
mem_deref(dict);
// Exit?
if (error == RAWRTC_CODE_NO_VALUE) {
DEBUG_NOTICE("Exiting\n");
// Stop client & bye
client_stop(client);
tmr_cancel(&timer);
re_cancel();
}
}
static void client_get_parameters(struct data_channel_sctp_throughput_client* const client) {
struct parameters* const local_parameters = &client->local_parameters;
// Get local ICE parameters
EOE(rawrtc_ice_gatherer_get_local_parameters(
&local_parameters->ice_parameters, client->gatherer));
// Get local ICE candidates
EOE(rawrtc_ice_gatherer_get_local_candidates(
&local_parameters->ice_candidates, client->gatherer));
// Get local DTLS parameters
EOE(rawrtc_dtls_transport_get_local_parameters(
&local_parameters->dtls_parameters, client->dtls_transport));
// Get local SCTP parameters
EOE(rawrtc_sctp_transport_get_capabilities(&local_parameters->sctp_parameters.capabilities));
EOE(rawrtc_sctp_transport_get_port(
&local_parameters->sctp_parameters.port, client->sctp_transport));
}
static void print_local_parameters(struct data_channel_sctp_throughput_client* client) {
struct odict* dict;
struct odict* node;
// Get local parameters
client_get_parameters(client);
// Create dict
EOR(odict_alloc(&dict, 16));
// Create nodes
EOR(odict_alloc(&node, 16));
set_ice_parameters(client->local_parameters.ice_parameters, node);
EOR(odict_entry_add(dict, "iceParameters", ODICT_OBJECT, node));
mem_deref(node);
EOR(odict_alloc(&node, 16));
set_ice_candidates(client->local_parameters.ice_candidates, node);
EOR(odict_entry_add(dict, "iceCandidates", ODICT_ARRAY, node));
mem_deref(node);
EOR(odict_alloc(&node, 16));
set_dtls_parameters(client->local_parameters.dtls_parameters, node);
EOR(odict_entry_add(dict, "dtlsParameters", ODICT_OBJECT, node));
mem_deref(node);
EOR(odict_alloc(&node, 16));
set_sctp_parameters(client->sctp_transport, &client->local_parameters.sctp_parameters, node);
EOR(odict_entry_add(dict, "sctpParameters", ODICT_OBJECT, node));
mem_deref(node);
// Print JSON
DEBUG_INFO("Local Parameters:\n%H\n", json_encode_odict, dict);
// Un-reference
mem_deref(dict);
}
static void exit_with_usage(char* program) {
DEBUG_WARNING(
"Usage: %s <0|1 (ice-role)> <message-size> [<n-times>] [<sctp-port>] "
"[<buffer-length>] [<cc-algorithm>] [<mtu>] [<ice-candidate-type> ...]\n",
program);
exit(1);
}
int main(int argc, char* argv[argc + 1]) {
char** ice_candidate_types = NULL;
size_t n_ice_candidate_types = 0;
enum rawrtc_ice_role role;
struct rawrtc_ice_gather_options* gather_options;
struct data_channel_sctp_throughput_client client = {0};
(void) client.ice_candidate_types;
(void) client.n_ice_candidate_types;
// Debug
dbg_init(DBG_DEBUG, DBG_ALL);
DEBUG_PRINTF("Init\n");
// Initialise
EOE(rawrtc_init(true));
// Check arguments length
if (argc < 3) {
exit_with_usage(argv[0]);
}
// Get ICE role
if (get_ice_role(&role, argv[1])) {
exit_with_usage(argv[0]);
}
// Get message size
if (!str_to_uint64(&client.message_size, argv[2])) {
exit_with_usage(argv[0]);
}
// Get number of times the test should run (optional)
client.n_times_left = 1;
if (argc >= 4 && !str_to_uint16(&client.n_times_left, argv[3])) {
exit_with_usage(argv[0]);
}
// TODO: Add possibility to turn checksum generation/validation on or off
// Get SCTP port (optional)
if (argc >= 5 && !str_to_uint16(&client.local_parameters.sctp_parameters.port, argv[4])) {
exit_with_usage(argv[0]);
}
// Get send/receiver buffer length (optional)
client.buffer_length = TRANSPORT_BUFFER_LENGTH;
if (argc >= 6 && !str_to_uint32(&client.buffer_length, argv[5])) {
exit_with_usage(argv[0]);
}
// Get congestion control algorithm (optional)
client.congestion_ctrl_algorithm = RAWRTC_SCTP_TRANSPORT_CONGESTION_CTRL_RFC2581;
if (argc >= 7 && get_congestion_control_algorithm(&client.congestion_ctrl_algorithm, argv[6])) {
exit_with_usage(argv[0]);
}
// Get MTU (optional)
if (argc >= 8 && !str_to_uint32(&client.mtu, argv[7])) {
exit_with_usage(argv[0]);
}
// Get enabled ICE candidate types to be added (optional)
if (argc >= 9) {
ice_candidate_types = &argv[8];
n_ice_candidate_types = (size_t) argc - 8;
}
// Create ICE gather options
EOE(rawrtc_ice_gather_options_create(&gather_options, RAWRTC_ICE_GATHER_POLICY_ALL));
// Set client fields
client.name = "A";
client.ice_candidate_types = ice_candidate_types;
client.n_ice_candidate_types = n_ice_candidate_types;
client.gather_options = gather_options;
client.role = role;
// Pre-generate messages (if 'controlling')
if (role == RAWRTC_ICE_ROLE_CONTROLLING) {
// Start indicator
client.start_buffer = mbuf_alloc(8);
EOE(client.start_buffer ? RAWRTC_CODE_SUCCESS : RAWRTC_CODE_NO_MEMORY);
EOR(mbuf_write_u64(client.start_buffer, sys_htonll(client.message_size)));
// Throughput test buffer
client.throughput_buffer = mbuf_alloc(client.message_size);
EOE(client.throughput_buffer ? RAWRTC_CODE_SUCCESS : RAWRTC_CODE_NO_MEMORY);
EOR(mbuf_fill(client.throughput_buffer, 0x01, mbuf_get_space(client.throughput_buffer)));
}
// Setup client
client_init(&client);
// Start gathering
client_start_gathering(&client);
// Listen on stdin
EOR(fd_listen(STDIN_FILENO, FD_READ, parse_remote_parameters, &client));
// Start main loop
EOR(re_main(default_signal_handler));
// Stop client & bye
client_stop(&client);
before_exit();
return 0;
}