* limitations under the License.
*/
-#include "obd2/diagnostic-manager.hpp"
+#include <systemd/sd-event.h>
+#include <algorithm>
+#include "diagnostic-manager.hpp"
+
+#include "uds/uds.h"
+#include "../utils/openxc-utils.hpp"
#include "../configuration.hpp"
-#include "../low-can-binding.hpp"
-#define MAX_REQUEST_ENTRIES 50
-diagnostic_manager_t::diagnostic_manager_t()
- : request_list_entries_(MAX_REQUEST_ENTRIES, active_diagnostic_request_t())
-{}
+#define MAX_RECURRING_DIAGNOSTIC_FREQUENCY_HZ 10
+#define MAX_SIMULTANEOUS_DIAG_REQUESTS 50
+#define TIMERFD_ACCURACY 0
+#define MICRO 1000000
-diagnostic_manager_t::diagnostic_manager_t(can_bus_dev_t& bus)
- : bus_(&bus), request_list_entries_(MAX_REQUEST_ENTRIES, active_diagnostic_request_t())
+diagnostic_manager_t::diagnostic_manager_t()
+ : initialized_{false}
{}
-bool shims_send(const uint32_t arbitration_id, const uint8_t* data, const uint8_t size)
-{
- can_bus_dev_t *can_bus_dev = config->get_diagnostic_manager().get_can_bus_dev();
- return can_bus_dev->shims_send(arbitration_id, data, size);
-}
-
-void diagnostic_manager_t::shims_logger(const char* m, ...)
+bool diagnostic_manager_t::initialize()
{
- DEBUG(binder_interface, "%s", m);
-}
+ // Mandatory to set the bus before intiliaze shims.
+ bus_ = configuration_t::instance().get_diagnostic_bus();
-void diagnostic_manager_t::shims_timer()
-{}
+ init_diagnostic_shims();
+ reset();
-can_bus_dev_t* diagnostic_manager_t::get_can_bus_dev()
-{
- return bus_;
+ initialized_ = true;
+ DEBUG(binder_interface, "initialize: Diagnostic Manager initialized");
+ return initialized_;
}
+
/**
* @brief initialize shims used by UDS lib and set initialized_ to true.
* It is needed before used the diagnostic manager fully because shims are
*/
void diagnostic_manager_t::init_diagnostic_shims()
{
- DiagnosticShims shims_ = diagnostic_init_shims(shims_logger, shims_send, NULL);
- initialized_ = true;
-}
\ No newline at end of file
+ shims_ = diagnostic_init_shims(shims_logger, shims_send, NULL);
+ DEBUG(binder_interface, "init_diagnostic_shims: Shims initialized");
+}
+
+void diagnostic_manager_t::reset()
+{
+ if(initialized_)
+ {
+ DEBUG(binder_interface, "Clearing existing diagnostic requests");
+ cleanup_active_requests(true);
+ }
+}
+
+
+void diagnostic_manager_t::find_and_erase(active_diagnostic_request_t* entry, std::vector<active_diagnostic_request_t*>& requests_list)
+{
+ auto i = std::find(requests_list.begin(), requests_list.end(), entry);
+ if ( i != requests_list.end())
+ requests_list.erase(i);
+}
+
+/// Move the entry to the free list and decrement the lock count for any
+/// CAN filters it used.
+void diagnostic_manager_t::cancel_request(active_diagnostic_request_t* entry)
+{
+
+ /* TODO: implement acceptance filters.
+ if(entry.arbitration_id_ == OBD2_FUNCTIONAL_BROADCAST_ID) {
+ for(uint32_t filter = OBD2_FUNCTIONAL_RESPONSE_START;
+ filter < OBD2_FUNCTIONAL_RESPONSE_START +
+ OBD2_FUNCTIONAL_RESPONSE_COUNT;
+ filter++) {
+ removeAcceptanceFilter(entry.bus_, filter,
+ CanMessageFormat::STANDARD, getCanBuses(),
+ getCanBusCount());
+ }
+ } else {
+ removeAcceptanceFilter(entry.bus_,
+ entry.arbitration_id_ +
+ DIAGNOSTIC_RESPONSE_ARBITRATION_ID_OFFSET,
+ CanMessageFormat::STANDARD, getCanBuses(), getCanBusCount());
+ }*/
+}
+
+void diagnostic_manager_t::cleanup_request(active_diagnostic_request_t* entry, bool force)
+{
+ if(force || (entry->get_in_flight() && entry->request_completed()))
+ {
+ entry->set_in_flight(false);
+
+ char request_string[128] = {0};
+ diagnostic_request_to_string(&entry->get_handle()->request,
+ request_string, sizeof(request_string));
+ if(entry->get_recurring())
+ {
+ find_and_erase(entry, recurring_requests_);
+ if(force)
+ cancel_request(entry);
+ }
+ else
+ {
+ DEBUG(binder_interface, "cleanup_request: Cancelling completed, non-recurring request: %s", request_string);
+ find_and_erase(entry, non_recurring_requests_);
+ cancel_request(entry);
+ }
+ }
+}
+
+/// @brief Clean up the request list
+void diagnostic_manager_t::cleanup_active_requests(bool force)
+{
+ for(auto& entry : non_recurring_requests_)
+ if (entry != nullptr)
+ cleanup_request(entry, force);
+
+ for(auto& entry : recurring_requests_)
+ if (entry != nullptr)
+ cleanup_request(entry, force);
+}
+
+/// @brief Will return the active_diagnostic_request_t pointer of found request or nullptr if
+/// not found.
+active_diagnostic_request_t* diagnostic_manager_t::find_recurring_request(const DiagnosticRequest* request)
+{
+ for (auto& entry : recurring_requests_)
+ {
+ if(entry != nullptr)
+ {
+ if(diagnostic_request_equals(&entry->get_handle()->request, request))
+ {
+ return entry;
+ break;
+ }
+ }
+ }
+ return nullptr;
+}
+
+std::shared_ptr<can_bus_dev_t> diagnostic_manager_t::get_can_bus_dev()
+{
+ return can_bus_t::get_can_device(bus_);
+}
+
+bool diagnostic_manager_t::add_request(DiagnosticRequest* request, const std::string name,
+ bool wait_for_multiple_responses, const DiagnosticResponseDecoder decoder,
+ const DiagnosticResponseCallback callback)
+{
+ cleanup_active_requests(false);
+
+ bool added = true;
+
+ if (non_recurring_requests_.size() <= MAX_SIMULTANEOUS_DIAG_REQUESTS)
+ {
+ // TODO: implement Acceptance Filter
+ // if(updateRequiredAcceptanceFilters(bus, request)) {
+ active_diagnostic_request_t* entry = new active_diagnostic_request_t(bus_, request, name,
+ wait_for_multiple_responses, decoder, callback, 0);
+ entry->set_handle(shims_, request);
+
+ char request_string[128] = {0};
+ diagnostic_request_to_string(&entry->get_handle()->request, request_string,
+ sizeof(request_string));
+
+ find_and_erase(entry, non_recurring_requests_);
+ DEBUG(binder_interface, "Added one-time diagnostic request on bus %s: %s",
+ bus_, request_string);
+
+ non_recurring_requests_.push_back(entry);
+ }
+ else
+ {
+ WARNING(binder_interface, "There isn't enough request entry. Vector exhausted %d/%d", (int)non_recurring_requests_.size());
+ non_recurring_requests_.resize(MAX_SIMULTANEOUS_DIAG_REQUESTS);
+ added = false;
+ }
+ return added;
+}
+
+bool diagnostic_manager_t::validate_optional_request_attributes(float frequencyHz)
+{
+ if(frequencyHz > MAX_RECURRING_DIAGNOSTIC_FREQUENCY_HZ) {
+ DEBUG(binder_interface, "Requested recurring diagnostic frequency %d is higher than maximum of %d",
+ frequencyHz, MAX_RECURRING_DIAGNOSTIC_FREQUENCY_HZ);
+ return false;
+ }
+ return true;
+}
+
+bool diagnostic_manager_t::add_recurring_request(DiagnosticRequest* request, const char* name,
+ bool wait_for_multiple_responses, const DiagnosticResponseDecoder decoder,
+ const DiagnosticResponseCallback callback, float frequencyHz)
+{
+ if(!validate_optional_request_attributes(frequencyHz))
+ return false;
+
+ cleanup_active_requests(false);
+
+ bool added = true;
+ if(find_recurring_request(request) == nullptr)
+ {
+ if(recurring_requests_.size() <= MAX_SIMULTANEOUS_DIAG_REQUESTS)
+ {
+ sd_event_source *source;
+ // TODO: implement Acceptance Filter
+ //if(updateRequiredAcceptanceFilters(bus, request)) {
+ active_diagnostic_request_t* entry = new active_diagnostic_request_t(bus_, request, name,
+ wait_for_multiple_responses, decoder, callback, frequencyHz);
+ entry->set_handle(shims_, request);
+
+ char request_string[128] = {0};
+ diagnostic_request_to_string(&entry->get_handle()->request, request_string,
+ sizeof(request_string));
+
+ DEBUG(binder_interface, "add_recurring_request: Added recurring diagnostic request (freq: %f) on bus %s: %s",
+ frequencyHz, bus_.c_str(), request_string);
+
+ uint64_t usec;
+ sd_event_now(afb_daemon_get_event_loop(binder_interface->daemon), CLOCK_MONOTONIC, &usec);
+ if(sd_event_add_time(afb_daemon_get_event_loop(binder_interface->daemon), &source,
+ CLOCK_MONOTONIC, usec, TIMERFD_ACCURACY, send_request, request) < 0)
+ {
+ ERROR(binder_interface, "add_recurring_request: Request fails to be schedule through event loop");
+ added = false;
+ }
+ recurring_requests_.push_back(entry);
+ }
+ else
+ {
+ WARNING(binder_interface, "add_recurring_request: There isn't enough request entry. Vector exhausted %d/%d", (int)recurring_requests_.size(), MAX_SIMULTANEOUS_DIAG_REQUESTS);
+ recurring_requests_.resize(MAX_SIMULTANEOUS_DIAG_REQUESTS);
+ added = false;
+ }
+ }
+ else
+ {
+ DEBUG(binder_interface, "add_recurring_request: Can't add request, one already exists with same key");
+ added = false;
+ }
+ return added;
+}
+
+
+bool diagnostic_manager_t::conflicting(active_diagnostic_request_t* request, active_diagnostic_request_t* candidate) const
+{
+ return (candidate->get_in_flight() && candidate != request &&
+ candidate->get_can_bus_dev() == request->get_can_bus_dev() &&
+ candidate->get_id() == request->get_id());
+}
+
+
+/// @brief Returns true if there are no other active requests to the same arbitration ID.
+bool diagnostic_manager_t::clear_to_send(active_diagnostic_request_t* request) const
+{
+ for ( auto entry : non_recurring_requests_)
+ {
+ if(conflicting(request, entry))
+ return false;
+ }
+
+ for ( auto entry : recurring_requests_)
+ {
+ if(conflicting(request, entry))
+ return false;
+ }
+ return true;
+}
+
+int diagnostic_manager_t::send_request(sd_event_source *s, uint64_t usec, void *userdata)
+{
+ diagnostic_manager_t& dm = configuration_t::instance().get_diagnostic_manager();
+ DiagnosticRequest* request = (DiagnosticRequest*)userdata;
+ active_diagnostic_request_t* adr = dm.find_recurring_request(request);
+
+// if(adr != nullptr && adr->get_can_bus_dev() == dm.get_can_bus_dev() && adr->should_send() &&
+// dm.clear_to_send(adr))
+ if(adr != nullptr && adr->get_can_bus_dev() == dm.get_can_bus_dev())
+ {
+ adr->get_frequency_clock().tick();
+ start_diagnostic_request(&dm.shims_, adr->get_handle());
+ if(adr->get_handle()->completed && !adr->get_handle()->success)
+ {
+ DEBUG(binder_interface, "send_request: Fatal error sending diagnostic request");
+ return 0;
+ }
+ adr->get_timeout_clock().tick();
+ adr->set_in_flight(true);
+
+ if(adr->get_recurring())
+ {
+ usec = usec + (uint64_t)(frequency_clock_t::frequency_to_period(adr->get_frequency_clock().get_frequency())*MICRO);
+ DEBUG(binder_interface, "send_request: Event loop state: %d. usec: %ld", sd_event_get_state(afb_daemon_get_event_loop(binder_interface->daemon)), usec);
+ if(sd_event_source_set_time(s, usec+1000000) >= 0)
+ if(sd_event_source_set_enabled(s, SD_EVENT_ON) >= 0)
+ return 1;
+ }
+ }
+ sd_event_source_unref(s);
+ ERROR(binder_interface, "send_request: Something goes wrong when submitting a new request to the CAN bus");
+ return -1;
+}
+
+openxc_VehicleMessage diagnostic_manager_t::relay_diagnostic_response(active_diagnostic_request_t* adr, const DiagnosticResponse& response) const
+{
+ openxc_VehicleMessage message = build_VehicleMessage();
+ float value = (float)diagnostic_payload_to_integer(&response);
+ if(adr->get_decoder() != nullptr)
+ {
+ value = adr->get_decoder()(&response, value);
+ }
+
+ if((response.success && strnlen(adr->get_name().c_str(), adr->get_name().size())) > 0)
+ {
+ // If name, include 'value' instead of payload, and leave of response
+ // details.
+ message = build_VehicleMessage(build_SimpleMessage(adr->get_name(), build_DynamicField(value)));
+ }
+ else
+ {
+ // If no name, send full details of response but still include 'value'
+ // instead of 'payload' if they provided a decoder. The one case you
+ // can't get is the full detailed response with 'value'. We could add
+ // another parameter for that but it's onerous to carry that around.
+ message = build_VehicleMessage(adr, response, value);
+ }
+
+ if(adr->get_callback() != nullptr)
+ {
+ adr->get_callback()(adr, &response, value);
+ }
+
+ return message;
+}
+
+/// @brief Will take the CAN message and pass it to the receive functions that will process
+/// diagnostic handle for each active diagnostic request then depending on the result we will
+/// return pass the diagnostic response to decode it.
+///
+/// @param[in] entry - A pointer to an active diagnostic request holding a valid diagnostic handle
+/// @param[in] cm - A raw CAN message.
+///
+/// @return A pointer to a filled openxc_VehicleMessage or a nullptr if nothing has been found.
+openxc_VehicleMessage diagnostic_manager_t::relay_diagnostic_handle(active_diagnostic_request_t* entry, const can_message_t& cm)
+{
+ DiagnosticResponse response = diagnostic_receive_can_frame(&shims_, entry->get_handle(), cm.get_id(), cm.get_data(), cm.get_length());
+ if(response.completed && entry->get_handle()->completed)
+ {
+ if(entry->get_handle()->success)
+ return relay_diagnostic_response(entry, response);
+ }
+ else if(!response.completed && response.multi_frame)
+ {
+ // Reset the timeout clock while completing the multi-frame receive
+ entry->get_timeout_clock().tick();
+ }
+
+ return build_VehicleMessage();
+}
+
+/// @brief Find the active diagnostic request with the correct DiagnosticRequestHandle
+/// member that will understand the CAN message using diagnostic_receive_can_frame function
+/// from UDS-C library. Then decode it with an ad-hoc method.
+///
+/// @param[in] cm - Raw CAN message received
+///
+/// @return VehicleMessage with decoded value.
+openxc_VehicleMessage diagnostic_manager_t::find_and_decode_adr(const can_message_t& cm)
+{
+ openxc_VehicleMessage vehicle_message = build_VehicleMessage();
+
+ for ( auto entry : non_recurring_requests_)
+ {
+ vehicle_message = relay_diagnostic_handle(entry, cm);
+ if (is_valid(vehicle_message))
+ return vehicle_message;
+ }
+
+ for ( auto entry : recurring_requests_)
+ {
+ vehicle_message = relay_diagnostic_handle(entry, cm);
+ if (is_valid(vehicle_message))
+ return vehicle_message;
+ }
+
+ return vehicle_message;
+}
+
+/// @brief Tell if the CAN message received is a diagnostic response.
+/// Request broadcast ID use 0x7DF and assigned ID goes from 0x7E0 to Ox7E7. That allows up to 8 ECU to respond
+/// at the same time. The response is the assigned ID + 0x8, so response ID can goes from 0x7E8 to 0x7EF.
+///
+/// @param[in] cm - CAN message received from the socket.
+///
+/// @return True if the active diagnostic request match the response.
+bool diagnostic_manager_t::is_diagnostic_response(const can_message_t& cm)
+{
+ if (cm.get_id() >= 0x7e8 && cm.get_id() <= 0x7ef)
+ return true;
+ return false;
+}
+
+DiagnosticShims& diagnostic_manager_t::get_shims()
+{
+ return shims_;
+}
+
+bool diagnostic_manager_t::shims_send(const uint32_t arbitration_id, const uint8_t* data, const uint8_t size)
+{
+ std::shared_ptr<can_bus_dev_t> can_bus_dev = can_bus_t::get_can_device(configuration_t::instance().get_diagnostic_manager().bus_);
+ return can_bus_dev->shims_send(arbitration_id, data, size);
+}
+
+void diagnostic_manager_t::shims_logger(const char* format, ...)
+{
+ va_list args;
+ va_start(args, format);
+
+ char buffer[256];
+ vsnprintf(buffer, 256, format, args);
+
+ DEBUG(binder_interface, "shims_logger: %s", buffer);
+}
+
+void diagnostic_manager_t::shims_timer()
+{}