/// to have 1 diagnostic bus which are the first bus declared in the JSON
/// description file. Configuration instance will return it.
///
-/// this will initialize DiagnosticShims and cancel all active requests
+/// this will initialize DiagnosticShims and cancel all active requests
/// if there are any.
bool diagnostic_manager_t::initialize()
{
reset();
initialized_ = true;
- DEBUG("Diagnostic Manager initialized");
+ AFB_DEBUG("Diagnostic Manager initialized");
return initialized_;
}
void diagnostic_manager_t::init_diagnostic_shims()
{
shims_ = diagnostic_init_shims(shims_logger, shims_send, NULL);
- DEBUG("Shims initialized");
+ AFB_DEBUG("Shims initialized");
}
/// @brief Force cleanup all active requests.
void diagnostic_manager_t::reset()
{
- DEBUG("Clearing existing diagnostic requests");
+ AFB_DEBUG("Clearing existing diagnostic requests");
cleanup_active_requests(true);
}
/// @param[in] data - The data payload for the message. NULL is valid if size is also 0.
/// @param[in] size - The size of the data payload, in bytes.
///
-/// @return true if the CAN message was sent successfully.
+/// @return true if the CAN message was sent successfully.
bool diagnostic_manager_t::shims_send(const uint32_t arbitration_id, const uint8_t* data, const uint8_t size)
{
diagnostic_manager_t& dm = application_t::instance().get_diagnostic_manager();
char buffer[256];
vsnprintf(buffer, 256, format, args);
- DEBUG("%s", buffer);
+ AFB_DEBUG("%s", buffer);
va_end(args);
}
}
/// @brief Cleanup a specific request if it isn't running and get complete. As it is almost
-/// impossible to get that state for a recurring request without waiting for that, you can
+/// impossible to get that state for a recurring request without waiting for that, you can
/// force the cleaning operation.
///
/// @param[in] entry - the request to clean
{
cancel_request(entry);
find_and_erase(entry, recurring_requests_);
- DEBUG("Cancelling completed, recurring request: %s", request_string);
+ AFB_DEBUG("Cancelling completed, recurring request: %s", request_string);
}
else if (!entry->get_recurring())
{
- DEBUG("Cancelling completed, non-recurring request: %s", request_string);
+ AFB_DEBUG("Cancelling completed, non-recurring request: %s", request_string);
cancel_request(entry);
find_and_erase(entry, non_recurring_requests_);
}
// Erase any existing request not already cleaned.
cleanup_request(entry, true);
- DEBUG("Added one-time diagnostic request on bus %s: %s",
+ AFB_DEBUG("Added one-time diagnostic request on bus %s: %s",
bus_.c_str(), request_string);
non_recurring_requests_.push_back(entry);
}
else
{
- WARNING("There isn't enough request entry. Vector exhausted %d/%d", (int)non_recurring_requests_.size(), MAX_SIMULTANEOUS_DIAG_REQUESTS);
+ AFB_WARNING("There isn't enough request entry. Vector exhausted %d/%d", (int)non_recurring_requests_.size(), MAX_SIMULTANEOUS_DIAG_REQUESTS);
non_recurring_requests_.resize(MAX_SIMULTANEOUS_DIAG_REQUESTS);
}
return entry;
bool diagnostic_manager_t::validate_optional_request_attributes(float frequencyHz)
{
if(frequencyHz > MAX_RECURRING_DIAGNOSTIC_FREQUENCY_HZ) {
- DEBUG("Requested recurring diagnostic frequency %lf is higher than maximum of %d",
+ AFB_DEBUG("Requested recurring diagnostic frequency %lf is higher than maximum of %d",
frequencyHz, MAX_RECURRING_DIAGNOSTIC_FREQUENCY_HZ);
return false;
}
recurring_requests_.push_back(entry);
entry->set_handle(shims_, request);
- start_diagnostic_request(&shims_, entry->get_handle());
+ start_diagnostic_request(&shims_, entry->get_handle());
}
else
{
- WARNING("There isn't enough request entry. Vector exhausted %d/%d", (int)recurring_requests_.size(), MAX_SIMULTANEOUS_DIAG_REQUESTS);
+ AFB_WARNING("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);
}
}
else
- { DEBUG("Can't add request, one already exists with same key");}
+ { AFB_DEBUG("Can't add request, one already exists with same key");}
return entry;
}
found_signals = utils::signals_manager_t::instance().find_signals(build_DynamicField(adr->get_name()));
found_signals.diagnostic_messages.front()->set_supported(false);
cleanup_request(adr, true);
- NOTICE("PID not supported or ill formed. Please unsubscribe from it. Error code : %d", response.negative_response_code);
+ AFB_NOTICE("PID not supported or ill formed. Please unsubscribe from it. Error code : %d", response.negative_response_code);
message = build_VehicleMessage(build_SimpleMessage(adr->get_name(), build_DynamicField("This PID isn't supported by your vehicle.")));
}
}
/// @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
+/// 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
}
/// @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
+/// 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.