/* // Copyright (c) 2019 Intel Corporation // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. */ #include "PSUSensor.hpp" #include "DeviceMgmt.hpp" #include "SensorPaths.hpp" #include "Thresholds.hpp" #include "Utils.hpp" #include "sensor.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static constexpr const char* sensorPathPrefix = "/xyz/openbmc_project/sensors/"; static constexpr bool debug = false; PSUSensor::PSUSensor( const std::string& path, const std::string& objectType, sdbusplus::asio::object_server& objectServer, std::shared_ptr& conn, boost::asio::io_context& io, const std::string& sensorName, std::vector&& thresholdsIn, const std::string& sensorConfiguration, const PowerState& powerState, const std::string& sensorUnits, unsigned int factor, double max, double min, double offset, const std::string& label, size_t tSize, double pollRate, const std::shared_ptr& i2cDevice) : Sensor(escapeName(sensorName), std::move(thresholdsIn), sensorConfiguration, objectType, false, false, max, min, conn, powerState), i2cDevice(i2cDevice), objServer(objectServer), inputDev(io, path, boost::asio::random_access_file::read_only), waitTimer(io), path(path), sensorFactor(factor), sensorOffset(offset), thresholdTimer(io) { buffer = std::make_shared>(); std::string unitPath = sensor_paths::getPathForUnits(sensorUnits); if constexpr (debug) { std::cerr << "Constructed sensor: path " << path << " type " << objectType << " config " << sensorConfiguration << " typename " << unitPath << " factor " << factor << " min " << min << " max " << max << " offset " << offset << " name \"" << sensorName << "\"\n"; } if (pollRate > 0.0) { sensorPollMs = static_cast(pollRate * 1000); } std::string dbusPath = sensorPathPrefix + unitPath + "/" + name; sensorInterface = objectServer.add_interface( dbusPath, "xyz.openbmc_project.Sensor.Value"); for (const auto& threshold : thresholds) { std::string interface = thresholds::getInterface(threshold.level); thresholdInterfaces[static_cast(threshold.level)] = objectServer.add_interface(dbusPath, interface); } // This should be called before initializing association. // createInventoryAssoc() does add more associations before doing // register and initialize "Associations" property. if (label.empty() || tSize == thresholds.size()) { setInitialProperties(sensorUnits); } else { setInitialProperties(sensorUnits, label, tSize); } association = objectServer.add_interface(dbusPath, association::interface); createInventoryAssoc(conn, association, configurationPath); } PSUSensor::~PSUSensor() { deactivate(); objServer.remove_interface(sensorInterface); for (const auto& iface : thresholdInterfaces) { objServer.remove_interface(iface); } objServer.remove_interface(association); } bool PSUSensor::isActive() { return inputDev.is_open(); } void PSUSensor::activate(const std::string& newPath, const std::shared_ptr& newI2CDevice) { if (isActive()) { // Avoid activating an active sensor return; } path = newPath; i2cDevice = newI2CDevice; inputDev.open(path, boost::asio::random_access_file::read_only); markAvailable(true); setupRead(); } void PSUSensor::deactivate() { markAvailable(false); // close the input dev to cancel async operations inputDev.close(); waitTimer.cancel(); i2cDevice = nullptr; path = ""; } void PSUSensor::setupRead() { if (!readingStateGood()) { markAvailable(false); updateValue(std::numeric_limits::quiet_NaN()); restartRead(); return; } if (buffer == nullptr) { std::cerr << "Buffer was invalid?"; return; } std::weak_ptr weak = weak_from_this(); // Note, we are building a asio buffer that is one char smaller than // the actual data structure, so that we can always append the null // terminator. This can go away once std::from_chars is available // in the standard inputDev.async_read_some_at( 0, boost::asio::buffer(buffer->data(), buffer->size() - 1), [weak, buffer{buffer}](const boost::system::error_code& ec, size_t bytesRead) { std::shared_ptr self = weak.lock(); if (!self) { return; } self->handleResponse(ec, bytesRead); }); } void PSUSensor::restartRead() { std::weak_ptr weakRef = weak_from_this(); waitTimer.expires_after(std::chrono::milliseconds(sensorPollMs)); waitTimer.async_wait([weakRef](const boost::system::error_code& ec) { if (ec == boost::asio::error::operation_aborted) { std::cerr << "Failed to reschedule\n"; return; } std::shared_ptr self = weakRef.lock(); if (self) { self->setupRead(); } }); } // Create a buffer expected to be able to hold more characters than will be // present in the input file. void PSUSensor::handleResponse(const boost::system::error_code& err, size_t bytesRead) { if (err == boost::asio::error::operation_aborted) { std::cerr << "Read aborted\n"; return; } if ((err == boost::system::errc::bad_file_descriptor) || (err == boost::asio::error::misc_errors::not_found)) { std::cerr << "Bad file descriptor for " << path << "\n"; return; } if (err || bytesRead == 0) { if (readingStateGood()) { std::cerr << name << " read failed\n"; } restartRead(); return; } // null terminate the string so we don't walk off the end std::array& bufferRef = *buffer; bufferRef[bytesRead] = '\0'; try { rawValue = std::stod(bufferRef.data()); updateValue((rawValue / sensorFactor) + sensorOffset); } catch (const std::invalid_argument&) { std::cerr << "Could not parse input from " << path << "\n"; incrementError(); } restartRead(); } void PSUSensor::checkThresholds() { if (!readingStateGood()) { return; } thresholds::checkThresholdsPowerDelay(weak_from_this(), thresholdTimer); }