#include #include #include #include #include #include #ifdef _WIN32 #include #else #include #endif /** * Sleeps for a specified number of milliseconds using Sleep() on Windows and sleep() on *nix. * * @param ms The number of milliseconds to sleep. */ void sleep_ms(uint32_t ms) { #ifdef _WIN32 Sleep(ms); #else sleep(ms / 1000); #endif } /** * Prints all events * * @param device_description A description of the device used in the output. */ void print_events(const char* device_description); /** * Prints an error message with the given string and error code. * * If the error code is not icsneoc2_error_success, prints the error string for the given error code * and returns the error code. * * @param message The message to print. * @param error The error code to print. * @return error as int */ int print_error_code(const char* message, icsneoc2_error_t error) { char error_str[64]; size_t error_str_len = sizeof(error_str); icsneoc2_error_t res = icsneoc2_error_code_get(error, error_str, &error_str_len); if(res != icsneoc2_error_success) { printf("%s: Failed to get string for error code %d with error code %d\n", message, error, res); return res; } printf("%s: \"%s\" (%u)\n", message, error_str, error); return (int)error; } /** * Processes a list of messages from a device. * * This function iterates over a given array of messages received from a specified device. * For each message in the array, it retrieves and prints the message type and bus type. * If an error occurs while retrieving these details, an error message is printed. * * @param messages An array of pointers to icsneoc2_message_t structures containing the messages to process. * @param messages_count The number of messages in the messages array. * * @return An icsneoc2_error_t value indicating success or failure of the message processing. */ int process_message(icsneoc2_message_t** messages, size_t messages_count); int transmit_can_messages(icsneoc2_device_t* device); int main() { // Open the first available device with default options printf("Opening first available device...\n"); icsneoc2_device_t* open_device = NULL; icsneoc2_error_t res = icsneoc2_device_open_first(0, icsneoc2_open_options_default, &open_device); if(res != icsneoc2_error_success) { return print_error_code("\tFailed to open first device", res); }; // Get a description of the opened device char description[255] = {0}; size_t description_length = 255; res = icsneoc2_device_description_get(open_device, description, &description_length); if(res != icsneoc2_error_success) { icsneoc2_device_free(open_device); return print_error_code("\tFailed to get device description", res); }; printf("\tOpened device: %s\n", description); // Transmit messages for debugging purposes // transmit_can_messages(open_device); // sleep_ms(1000); // Get the messages icsneoc2_message_t* messages[20000] = {0}; size_t message_count = 20000; time_t start_time = time(NULL); printf("\tGetting messages from device with timeout of 3000ms on %s...\n", description); for(size_t i = 0; i < message_count; ++i) { res = icsneoc2_device_message_get(open_device, &messages[i], 0); if(res != icsneoc2_error_success) { print_events(description); icsneoc2_device_free(open_device); return print_error_code("\tFailed to get messages from device", res); }; if(messages[i] == NULL) { // no more messages message_count = i; break; } } if(res != icsneoc2_error_success) { print_events(description); icsneoc2_device_free(open_device); return print_error_code("\tFailed to get messages from device", res); } time_t end_time = time(NULL); printf("\tGot %zu messages in %lld seconds\n", message_count, (long long)(end_time - start_time)); // Process the messages res = process_message(messages, message_count); if(res != icsneoc2_error_success) { print_events(description); icsneoc2_device_free(open_device); return print_error_code("\tFailed to process messages", res); } // Finally, close the device. printf("\tClosing device: %s...\n", description); res = icsneoc2_device_close(open_device); if(res != icsneoc2_error_success) { print_events(description); icsneoc2_device_free(open_device); return print_error_code("\tFailed to close device", res); }; icsneoc2_device_free(open_device); printf("\n"); return 0; } void print_events(const char* device_description) { icsneoc2_event_t* events[1024] = {0}; size_t events_count = 1024; for(size_t i = 0; i < events_count; ++i) { // no device filter, get all events icsneoc2_error_t res = icsneoc2_event_get(&events[i], NULL); if(res != icsneoc2_error_success) { (void)print_error_code("\tFailed to get device events", res); return; } if(events[i] == NULL) { events_count = i; break; } } // Loop over each event and describe it. for(size_t i = 0; i < events_count; i++) { char event_description[255] = {0}; size_t event_description_length = 255; icsneoc2_error_t res = icsneoc2_event_description_get(events[i], event_description, &event_description_length); if(res != icsneoc2_error_success) { print_error_code("\tFailed to get event description", res); continue; } printf("\t%s: Event %zu: %s\n", device_description, i, event_description); } for(size_t i = 0; i < events_count; i++) { icsneoc2_event_free(events[i]); } printf("\t%s: Received %zu events\n", device_description, events_count); } int process_message(icsneoc2_message_t** messages, size_t messages_count) { // Print the type and bus type of each message size_t tx_count = 0; size_t can_error_count = 0; icsneoc2_error_t res = icsneoc2_error_success; for(size_t i = 0; i < messages_count; i++) { icsneoc2_message_t* message = messages[i]; bool is_can_error = false; res = icsneoc2_message_is_can_error(message, &is_can_error); if(res != icsneoc2_error_success) { return print_error_code("\tFailed to check if message is a CAN error", res); } if(is_can_error) { icsneoc2_network_type_t network_type; uint8_t tec = 0; uint8_t rec = 0; icsneoc2_can_error_code_t error_code = 0; icsneoc2_can_error_code_t data_error_code = 0; icsneoc2_message_can_error_flags_t error_flags = 0; icsneoc2_netid_t netid = 0; char network_type_name[128] = {0}; size_t network_type_name_length = 128; char netid_name[128] = {0}; size_t netid_name_length = 128; res = icsneoc2_message_network_type_get(message, &network_type); res += icsneoc2_network_type_name_get(network_type, network_type_name, &network_type_name_length); res += icsneoc2_message_netid_get(message, &netid); res += icsneoc2_netid_name_get(netid, netid_name, &netid_name_length); res += icsneoc2_message_can_error_props_get(message, &tec, &rec, &error_code, &data_error_code, &error_flags); if(res != icsneoc2_error_success) { return print_error_code("\tFailed to get CAN error properties", res); } printf("\t%zd) CAN Error on %s [%s] (0x%x): TEC=%u REC=%u ErrorCode=%u DataErrorCode=%u%s%s%s\n", i, netid_name, network_type_name, netid, tec, rec, error_code, data_error_code, (error_flags & ICSNEOC2_MESSAGE_CAN_ERROR_FLAGS_BUS_OFF) ? " [BusOff]" : "", (error_flags & ICSNEOC2_MESSAGE_CAN_ERROR_FLAGS_ERROR_PASSIVE) ? " [ErrorPassive]" : "", (error_flags & ICSNEOC2_MESSAGE_CAN_ERROR_FLAGS_ERROR_WARN) ? " [ErrorWarn]" : ""); can_error_count++; continue; } bool is_frame = false; res = icsneoc2_message_is_frame(message, &is_frame); if(res != icsneoc2_error_success) { return print_error_code("\tFailed to check if message is a frame", res); } if(!is_frame) { printf("Ignoring non-frame message at index %zu\n", i); continue; } icsneoc2_network_type_t network_type; res = icsneoc2_message_network_type_get(message, &network_type); if(res != icsneoc2_error_success) { return print_error_code("\tFailed to get message network type", res); } char network_type_name[128] = {0}; size_t network_type_name_length = 128; res = icsneoc2_network_type_name_get(network_type, network_type_name, &network_type_name_length); if(res != icsneoc2_error_success) { return print_error_code("\tFailed to get message bus type name", res); } if(res != icsneoc2_error_success) { return print_error_code("\tFailed to get message is transmit", res); } printf("\t%zd) network type: %s (%u)\n", i, network_type_name, network_type); if(network_type == icsneoc2_network_type_can) { uint64_t timestamp = 0; uint64_t arbid = 0; int32_t dlc = 0; icsneoc2_netid_t netid = 0; icsneoc2_message_can_flags_t can_flags = 0; uint8_t data[64] = {0}; size_t data_length = 64; char netid_name[128] = {0}; size_t netid_name_length = 128; bool is_error = false; bool is_tx = false; icsneoc2_error_t result = icsneoc2_message_netid_get(message, &netid); result += icsneoc2_netid_name_get(netid, netid_name, &netid_name_length); result += icsneoc2_message_timestamp_get(message, ×tamp); result += icsneoc2_message_can_props_get(message, &arbid, &can_flags); result += icsneoc2_message_data_get(message, data, &data_length); result += icsneoc2_message_is_transmit(message, &is_tx); result += icsneoc2_message_is_error(message, &is_error); if(result != icsneoc2_error_success) { printf("\tFailed get get CAN parameters (error: %u) for index %zu\n", result, i); continue; } tx_count += is_tx ? 1 : 0; bool is_remote = (can_flags & ICSNEOC2_MESSAGE_CAN_FLAGS_RTR) != 0; bool is_extended = (can_flags & ICSNEOC2_MESSAGE_CAN_FLAGS_IDE) != 0; bool is_canfd = (can_flags & ICSNEOC2_MESSAGE_CAN_FLAGS_FDF) != 0; bool is_brs = (can_flags & ICSNEOC2_MESSAGE_CAN_FLAGS_BRS) != 0; bool is_esi = (can_flags & ICSNEOC2_MESSAGE_CAN_FLAGS_ESI) != 0; bool tx_aborted = (can_flags & ICSNEOC2_MESSAGE_CAN_FLAGS_TX_ABORTED) != 0; bool tx_lost_arb = (can_flags & ICSNEOC2_MESSAGE_CAN_FLAGS_TX_LOST_ARB) != 0; bool tx_error = (can_flags & ICSNEOC2_MESSAGE_CAN_FLAGS_TX_ERROR) != 0; dlc = (int32_t)data_length; printf("\t %s%s\n", is_tx ? "TX" : "RX", is_error ? " [Error]" : ""); printf("\t Timestamp: %" PRIu64 " ns since 2007-01-01 UTC\n", timestamp); printf("\t NetID: %s (0x%x)\tArbID: 0x%llx\tDLC: %u\tLen: %zu\n", netid_name, netid, (unsigned long long)arbid, dlc, data_length); printf("\t Flags:%s%s%s%s%s%s%s%s\n", is_remote ? " RTR" : "", is_extended ? " IDE" : "", is_canfd ? " FDF" : "", is_brs ? " BRS" : "", is_esi ? " ESI" : "", tx_aborted ? " TX_ABORTED" : "", tx_lost_arb ? " TX_LOST_ARB" : "", tx_error ? " TX_ERROR" : ""); printf("\t Data: ["); for(size_t x = 0; x < data_length; x++) { printf(" 0x%x", data[x]); } printf(" ]\n"); } } printf("\tReceived %zu messages total, %zu were TX messages, %zu were CAN errors\n", messages_count, tx_count, can_error_count); return icsneoc2_error_success; } int transmit_can_messages(icsneoc2_device_t* device) { uint64_t counter = 0; const size_t msg_count = 10; printf("\tTransmitting %zd messages...\n", msg_count); for(size_t i = 0; i < msg_count; i++) { // Create the message icsneoc2_message_t* message = NULL; icsneoc2_error_t res = icsneoc2_message_can_create(&message); if(res != icsneoc2_error_success) { return print_error_code("\tFailed to create messages", res); } // Set the message attributes res = icsneoc2_message_netid_set(message, icsneoc2_netid_dwcan_01); uint64_t arb_id = 0x10; uint64_t flags = 0; res += icsneoc2_message_can_props_set(message, &arb_id, &flags); res += icsneoc2_message_data_set(message, (uint8_t*)&counter, sizeof(counter)); if(res != icsneoc2_error_success) { icsneoc2_message_free(message); return print_error_code("\tFailed to modify message", res); } res = icsneoc2_device_message_transmit(device, message); res += icsneoc2_message_free(message); if(res != icsneoc2_error_success) { return print_error_code("\tFailed to transmit message", res); } counter++; } return icsneoc2_error_success; }