#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static constexpr bool debug = false; namespace thresholds { Level findThresholdLevel(uint8_t sev) { for (const ThresholdDefinition& prop : thresProp) { if (prop.sevOrder == sev) { return prop.level; } } return Level::ERROR; } Direction findThresholdDirection(const std::string& direct) { if (direct == "greater than") { return Direction::HIGH; } if (direct == "less than") { return Direction::LOW; } return Direction::ERROR; } bool parseThresholdsFromConfig( const SensorData& sensorData, std::vector& thresholdVector, const std::string* matchLabel, const int* sensorIndex) { for (const auto& item : sensorData) { if (item.first.find("Thresholds") == std::string::npos) { continue; } if (matchLabel != nullptr) { auto labelFind = item.second.find("Label"); if (labelFind == item.second.end()) { continue; } if (std::visit(VariantToStringVisitor(), labelFind->second) != *matchLabel) { continue; } } if (sensorIndex != nullptr) { auto indexFind = item.second.find("Index"); // If we're checking for index 1, a missing Index is OK. if ((indexFind == item.second.end()) && (*sensorIndex != 1)) { continue; } if ((indexFind != item.second.end()) && (std::visit(VariantToIntVisitor(), indexFind->second) != *sensorIndex)) { continue; } } double hysteresis = std::numeric_limits::quiet_NaN(); auto hysteresisFind = item.second.find("Hysteresis"); if (hysteresisFind != item.second.end()) { hysteresis = std::visit(VariantToDoubleVisitor(), hysteresisFind->second); } auto directionFind = item.second.find("Direction"); auto severityFind = item.second.find("Severity"); auto valueFind = item.second.find("Value"); if (valueFind == item.second.end() || severityFind == item.second.end() || directionFind == item.second.end()) { std::cerr << "Malformed threshold on configuration interface " << item.first << "\n"; return false; } unsigned int severity = std::visit(VariantToUnsignedIntVisitor(), severityFind->second); std::string directions = std::visit(VariantToStringVisitor(), directionFind->second); Level level = findThresholdLevel(severity); Direction direction = findThresholdDirection(directions); if ((level == Level::ERROR) || (direction == Direction::ERROR)) { continue; } double val = std::visit(VariantToDoubleVisitor(), valueFind->second); thresholdVector.emplace_back(level, direction, val, hysteresis); } return true; } void persistThreshold(const std::string& path, const std::string& baseInterface, const thresholds::Threshold& threshold, std::shared_ptr& conn, size_t thresholdCount, const std::string& labelMatch) { for (size_t ii = 0; ii < thresholdCount; ii++) { std::string thresholdInterface = baseInterface + ".Thresholds" + std::to_string(ii); conn->async_method_call( [&, path, threshold, thresholdInterface, labelMatch]( const boost::system::error_code& ec, const boost::container::flat_map& result) { if (ec) { return; // threshold not supported } if (!labelMatch.empty()) { auto labelFind = result.find("Label"); if (labelFind == result.end()) { std::cerr << "No label in threshold configuration\n"; return; } std::string label = std::visit(VariantToStringVisitor(), labelFind->second); if (label != labelMatch) { return; } } auto directionFind = result.find("Direction"); auto severityFind = result.find("Severity"); auto valueFind = result.find("Value"); if (valueFind == result.end() || severityFind == result.end() || directionFind == result.end()) { std::cerr << "Malformed threshold in configuration\n"; return; } unsigned int severity = std::visit( VariantToUnsignedIntVisitor(), severityFind->second); std::string dir = std::visit(VariantToStringVisitor(), directionFind->second); if ((findThresholdLevel(severity) != threshold.level) || (findThresholdDirection(dir) != threshold.direction)) { return; // not the droid we're looking for } std::variant value(threshold.value); conn->async_method_call( [](const boost::system::error_code& ec) { if (ec) { std::cerr << "Error setting threshold " << ec << "\n"; } }, entityManagerName, path, "org.freedesktop.DBus.Properties", "Set", thresholdInterface, "Value", value); }, entityManagerName, path, "org.freedesktop.DBus.Properties", "GetAll", thresholdInterface); } } void updateThresholds(Sensor* sensor) { for (const auto& threshold : sensor->thresholds) { std::shared_ptr interface = sensor->getThresholdInterface(threshold.level); if (!interface) { continue; } std::string property = sensor->propertyLevel(threshold.level, threshold.direction); if (property.empty()) { continue; } interface->set_property(property, threshold.value); } } // Debugging counters static int cHiTrue = 0; static int cHiFalse = 0; static int cHiMidstate = 0; static int cLoTrue = 0; static int cLoFalse = 0; static int cLoMidstate = 0; static int cDebugThrottle = 0; static constexpr int assertLogCount = 10; struct ChangeParam { ChangeParam(Threshold whichThreshold, bool status, double value) : threshold(whichThreshold), asserted(status), assertValue(value) {} Threshold threshold; bool asserted; double assertValue; }; static std::vector checkThresholds(Sensor* sensor, double value) { std::vector thresholdChanges; if (sensor->thresholds.empty()) { return thresholdChanges; } for (auto& threshold : sensor->thresholds) { // Use "Schmitt trigger" logic to avoid threshold trigger spam, // if value is noisy while hovering very close to a threshold. // When a threshold is crossed, indicate true immediately, // but require more distance to be crossed the other direction, // before resetting the indicator back to false. if (threshold.direction == thresholds::Direction::HIGH) { if (value >= threshold.value) { thresholdChanges.emplace_back(threshold, true, value); if (++cHiTrue < assertLogCount) { std::cerr << "Sensor " << sensor->name << " high threshold " << threshold.value << " assert: value " << value << " raw data " << sensor->rawValue << "\n"; } } else if (value < (threshold.value - threshold.hysteresis)) { thresholdChanges.emplace_back(threshold, false, value); ++cHiFalse; } else { ++cHiMidstate; } } else if (threshold.direction == thresholds::Direction::LOW) { if (value <= threshold.value) { thresholdChanges.emplace_back(threshold, true, value); if (++cLoTrue < assertLogCount) { std::cerr << "Sensor " << sensor->name << " low threshold " << threshold.value << " assert: value " << sensor->value << " raw data " << sensor->rawValue << "\n"; } } else if (value > (threshold.value + threshold.hysteresis)) { thresholdChanges.emplace_back(threshold, false, value); ++cLoFalse; } else { ++cLoMidstate; } } else { std::cerr << "Error determining threshold direction\n"; } } // Throttle debug output, so that it does not continuously spam ++cDebugThrottle; if (cDebugThrottle >= 1000) { cDebugThrottle = 0; if constexpr (debug) { std::cerr << "checkThresholds: High T=" << cHiTrue << " F=" << cHiFalse << " M=" << cHiMidstate << ", Low T=" << cLoTrue << " F=" << cLoFalse << " M=" << cLoMidstate << "\n"; } } return thresholdChanges; } void ThresholdTimer::startTimer(const std::weak_ptr& weakSensor, const Threshold& threshold, bool assert, double assertValue) { struct TimerUsed timerUsed = {}; constexpr const size_t waitTime = 5; TimerPair* pair = nullptr; for (TimerPair& timer : timers) { if (!timer.first.used) { pair = &timer; break; } } if (pair == nullptr) { pair = &timers.emplace_back(timerUsed, boost::asio::deadline_timer(io)); } pair->first.used = true; pair->first.level = threshold.level; pair->first.direction = threshold.direction; pair->first.assert = assert; pair->second.expires_from_now(boost::posix_time::seconds(waitTime)); pair->second.async_wait([weakSensor, pair, threshold, assert, assertValue](boost::system::error_code ec) { auto sensorPtr = weakSensor.lock(); if (!sensorPtr) { return; // owner sensor has been destructed } // pair is valid as long as sensor is valid pair->first.used = false; if (ec == boost::asio::error::operation_aborted) { return; // we're being canceled } if (ec) { std::cerr << "timer error: " << ec.message() << "\n"; return; } if (sensorPtr->readingStateGood()) { assertThresholds(sensorPtr.get(), assertValue, threshold.level, threshold.direction, assert); } }); } bool checkThresholds(Sensor* sensor) { bool status = true; std::vector changes = checkThresholds(sensor, sensor->value); for (const auto& change : changes) { assertThresholds(sensor, change.assertValue, change.threshold.level, change.threshold.direction, change.asserted); if (change.threshold.level == thresholds::Level::CRITICAL && change.asserted) { status = false; } } return status; } void checkThresholdsPowerDelay(const std::weak_ptr& weakSensor, ThresholdTimer& thresholdTimer) { auto sensorPtr = weakSensor.lock(); if (!sensorPtr) { return; // sensor is destructed, should never be here } Sensor* sensor = sensorPtr.get(); std::vector changes = checkThresholds(sensor, sensor->value); for (const auto& change : changes) { // When CPU is powered off, some volatges are expected to // go below low thresholds. Filter these events with thresholdTimer. // 1. always delay the assertion of low events to see if they are // caused by power off event. // 2. conditional delay the de-assertion of low events if there is // an existing timer for assertion. // 3. no delays for de-assert of low events if there is an existing // de-assert for low event. This means 2nd de-assert would happen // first and when timer expires for the previous one, no additional // signal will be logged. // 4. no delays for all high events. if (change.threshold.direction == thresholds::Direction::LOW) { if (change.asserted || thresholdTimer.hasActiveTimer( change.threshold, !change.asserted)) { thresholdTimer.startTimer(weakSensor, change.threshold, change.asserted, change.assertValue); continue; } } assertThresholds(sensor, change.assertValue, change.threshold.level, change.threshold.direction, change.asserted); } } void assertThresholds(Sensor* sensor, double assertValue, thresholds::Level level, thresholds::Direction direction, bool assert) { std::shared_ptr interface = sensor->getThresholdInterface(level); if (!interface) { std::cout << "trying to set uninitialized interface\n"; return; } std::string property = sensor->propertyAlarm(level, direction); if (property.empty()) { std::cout << "Alarm property is empty \n"; return; } if (interface->set_property(property, assert)) { try { // msg.get_path() is interface->get_object_path() sdbusplus::message::message msg = interface->new_signal("ThresholdAsserted"); msg.append(sensor->name, interface->get_interface_name(), property, assert, assertValue); msg.signal_send(); } catch (const sdbusplus::exception::exception& e) { std::cerr << "Failed to send thresholdAsserted signal with assertValue\n"; } } } bool parseThresholdsFromAttr( std::vector& thresholdVector, const std::string& inputPath, const double& scaleFactor, const double& offset) { const boost::container::flat_map< std::string, std::vector>> map = { {"average", { std::make_tuple("average_min", Level::WARNING, Direction::LOW, 0.0), std::make_tuple("average_max", Level::WARNING, Direction::HIGH, 0.0), }}, {"input", { std::make_tuple("min", Level::WARNING, Direction::LOW, 0.0), std::make_tuple("max", Level::WARNING, Direction::HIGH, 0.0), std::make_tuple("lcrit", Level::CRITICAL, Direction::LOW, 0.0), std::make_tuple("crit", Level::CRITICAL, Direction::HIGH, offset), }}, }; if (auto fileParts = splitFileName(inputPath)) { auto& [type, nr, item] = *fileParts; if (map.count(item) != 0) { for (const auto& t : map.at(item)) { auto& [suffix, level, direction, offset] = t; auto attrPath = boost::replace_all_copy(inputPath, item, suffix); if (auto val = readFile(attrPath, scaleFactor)) { *val += offset; if (debug) { std::cout << "Threshold: " << attrPath << ": " << *val << "\n"; } thresholdVector.emplace_back(level, direction, *val); } } } } return true; } std::string getInterface(const Level thresholdLevel) { for (const ThresholdDefinition& thresh : thresProp) { if (thresh.level == thresholdLevel) { return std::string("xyz.openbmc_project.Sensor.Threshold.") + thresh.levelName; } } return ""; } } // namespace thresholds