/* // 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 "utils.hpp" #include #include #include #include #include #include #include #include #include extern "C" { #include #include } constexpr const char* configType = "xyz.openbmc_project.Configuration.Intel_HSBP_CPLD"; constexpr size_t scanRateSeconds = 5; constexpr size_t maxDrives = 8; // only 1 byte alloted boost::asio::io_context io; auto conn = std::make_shared(io); sdbusplus::asio::object_server objServer(conn); static std::string zeroPad(const uint8_t val) { std::ostringstream version; version << std::setw(2) << std::setfill('0') << static_cast(val); return version.str(); } struct Mux { Mux(size_t busIn, size_t addressIn) : bus(busIn), address(addressIn) { } size_t bus; size_t address; }; struct Drive { Drive(size_t driveIndex, bool isPresent, bool isOperational, bool nvme, bool rebuilding) : isNvme(nvme) { constexpr const char* basePath = "/xyz/openbmc_project/inventory/item/drive/Drive_"; itemIface = objServer.add_interface( basePath + std::to_string(driveIndex), inventory::interface); itemIface->register_property("Present", isPresent); itemIface->register_property("PrettyName", "Drive " + std::to_string(driveIndex)); itemIface->initialize(); operationalIface = objServer.add_interface( itemIface->get_object_path(), "xyz.openbmc_project.State.Decorator.OperationalStatus"); operationalIface->register_property("Functional", isOperational); operationalIface->initialize(); rebuildingIface = objServer.add_interface( itemIface->get_object_path(), "xyz.openbmc_project.State.Drive"); rebuildingIface->register_property("Rebuilding", rebuilding); rebuildingIface->initialize(); } ~Drive() { objServer.remove_interface(itemIface); objServer.remove_interface(operationalIface); objServer.remove_interface(rebuildingIface); objServer.remove_interface(associationIface); } void createAssociation(const std::string& path) { if (associationIface != nullptr) { return; } associationIface = objServer.add_interface( itemIface->get_object_path(), "xyz.openbmc_project.Association.Definitions"); std::vector associations; associations.emplace_back("inventory", "drive", path); associationIface->register_property("Associations", associations); associationIface->initialize(); } std::shared_ptr itemIface; std::shared_ptr operationalIface; std::shared_ptr rebuildingIface; std::shared_ptr associationIface; bool isNvme; }; struct Backplane { Backplane(size_t busIn, size_t addressIn, size_t backplaneIndexIn, const std::string& nameIn) : bus(busIn), address(addressIn), backplaneIndex(backplaneIndexIn - 1), name(nameIn), timer(std::make_shared(io)), muxes(std::make_shared>()) { } void run() { file = open(("/dev/i2c-" + std::to_string(bus)).c_str(), O_RDWR); if (file < 0) { std::cerr << "unable to open bus " << bus << "\n"; return; } if (ioctl(file, I2C_SLAVE_FORCE, address) < 0) { std::cerr << "unable to set address to " << address << "\n"; return; } if (!getPresent()) { std::cerr << "Cannot detect CPLD\n"; return; } getBootVer(bootVer); getFPGAVer(fpgaVer); getSecurityRev(securityRev); std::string dbusName = boost::replace_all_copy(name, " ", "_"); hsbpItemIface = objServer.add_interface( "/xyz/openbmc_project/inventory/item/hsbp/" + dbusName, inventory::interface); hsbpItemIface->register_property("Present", true); hsbpItemIface->register_property("PrettyName", name); hsbpItemIface->initialize(); versionIface = objServer.add_interface(hsbpItemIface->get_object_path(), "xyz.openbmc_project.Software.Version"); versionIface->register_property("Version", zeroPad(bootVer) + "." + zeroPad(fpgaVer) + "." + zeroPad(securityRev)); versionIface->register_property( "Purpose", std::string( "xyz.openbmc_project.Software.Version.VersionPurpose.HSBP")); versionIface->initialize(); getPresence(presence); getIFDET(ifdet); createDrives(); runTimer(); } void runTimer() { timer->expires_after(std::chrono::seconds(scanRateSeconds)); timer->async_wait([this](boost::system::error_code ec) { if (ec == boost::asio::error::operation_aborted) { // we're being destroyed return; } else if (ec) { std::cerr << "timer error " << ec.message() << "\n"; return; } uint8_t curPresence = 0; uint8_t curIFDET = 0; uint8_t curFailed = 0; uint8_t curRebuild = 0; getPresence(curPresence); getIFDET(curIFDET); getFailed(curFailed); getRebuild(curRebuild); if (curPresence != presence || curIFDET != ifdet || curFailed != failed || curRebuild != rebuilding) { presence = curPresence; ifdet = curIFDET; failed = curFailed; rebuilding = curRebuild; updateDrives(); } runTimer(); }); } void createDrives() { uint8_t nvme = ifdet ^ presence; for (size_t ii = 0; ii < maxDrives; ii++) { bool isNvme = nvme & (1 << ii); bool isPresent = isNvme || (presence & (1 << ii)); bool isFailed = !isPresent || failed & (1 << ii); bool isRebuilding = !isPresent && (rebuilding & (1 << ii)); // +1 to convert from 0 based to 1 based size_t driveIndex = (backplaneIndex * maxDrives) + ii + 1; drives.emplace_back(driveIndex, isPresent, !isFailed, isNvme, isRebuilding); } } void updateDrives() { uint8_t nvme = ifdet ^ presence; for (size_t ii = 0; ii < maxDrives; ii++) { bool isNvme = nvme & (1 << ii); bool isPresent = isNvme || (presence & (1 << ii)); bool isFailed = !isPresent || (failed & (1 << ii)); bool isRebuilding = isPresent && (rebuilding & (1 << ii)); Drive& drive = drives[ii]; drive.isNvme = isNvme; drive.itemIface->set_property("Present", isPresent); drive.operationalIface->set_property("Functional", !isFailed); drive.rebuildingIface->set_property("Rebuilding", isRebuilding); } } bool getPresent() { present = i2c_smbus_read_byte(file) >= 0; return present; } bool getTypeID(uint8_t& val) { constexpr uint8_t addr = 2; int ret = i2c_smbus_read_byte_data(file, addr); if (ret < 0) { std::cerr << "Error " << __FUNCTION__ << "\n"; return false; } val = static_cast(ret); return true; } bool getBootVer(uint8_t& val) { constexpr uint8_t addr = 3; int ret = i2c_smbus_read_byte_data(file, addr); if (ret < 0) { std::cerr << "Error " << __FUNCTION__ << "\n"; return false; } val = static_cast(ret); return true; } bool getFPGAVer(uint8_t& val) { constexpr uint8_t addr = 4; int ret = i2c_smbus_read_byte_data(file, addr); if (ret < 0) { std::cerr << "Error " << __FUNCTION__ << "\n"; return false; } val = static_cast(ret); return true; } bool getSecurityRev(uint8_t& val) { constexpr uint8_t addr = 5; int ret = i2c_smbus_read_byte_data(file, addr); if (ret < 0) { std::cerr << "Error " << __FUNCTION__ << "\n"; return false; } val = static_cast(ret); return true; } bool getPresence(uint8_t& val) { // NVMe drives do not assert PRSNTn, and as such do not get reported as // PRESENT in this register constexpr uint8_t addr = 8; int ret = i2c_smbus_read_byte_data(file, addr); if (ret < 0) { std::cerr << "Error " << __FUNCTION__ << "\n"; return false; } // presence is inverted val = static_cast(~ret); return true; } bool getIFDET(uint8_t& val) { // This register is a bitmap of parallel GPIO pins connected to the // IFDETn pin of a drive slot. SATA, SAS, and NVMe drives all assert // IFDETn low when they are inserted into the HSBP.This register, in // combination with the PRESENCE register, are used by the BMC to detect // the presence of NVMe drives. constexpr uint8_t addr = 9; int ret = i2c_smbus_read_byte_data(file, addr); if (ret < 0) { std::cerr << "Error " << __FUNCTION__ << "\n"; return false; } // ifdet is inverted val = static_cast(~ret); return true; } bool getFailed(uint8_t& val) { constexpr uint8_t addr = 0xC; int ret = i2c_smbus_read_byte_data(file, addr); if (ret < 0) { std::cerr << "Error " << __FUNCTION__ << "\n"; return false; } val = static_cast(ret); return true; } bool getRebuild(uint8_t& val) { constexpr uint8_t addr = 0xD; int ret = i2c_smbus_read_byte_data(file, addr); if (ret < 0) { std::cerr << "Error " << __FUNCTION__ << "\n"; return false; } val = static_cast(ret); return true; } ~Backplane() { objServer.remove_interface(hsbpItemIface); objServer.remove_interface(versionIface); if (file >= 0) { close(file); } } size_t bus; size_t address; size_t backplaneIndex; std::string name; std::shared_ptr timer; bool present = false; uint8_t typeId = 0; uint8_t bootVer = 0; uint8_t fpgaVer = 0; uint8_t securityRev = 0; uint8_t funSupported = 0; uint8_t presence = 0; uint8_t ifdet = 0; uint8_t failed = 0; uint8_t rebuilding = 0; int file = -1; std::string type; std::shared_ptr hsbpItemIface; std::shared_ptr versionIface; std::vector drives; std::shared_ptr> muxes; }; std::unordered_map backplanes; void updateAssociations() { constexpr const char* driveType = "xyz.openbmc_project.Inventory.Item.Drive"; conn->async_method_call( [](const boost::system::error_code ec, const GetSubTreeType& subtree) { if (ec) { std::cerr << "Error contacting mapper " << ec.message() << "\n"; return; } for (const auto& [path, objDict] : subtree) { if (objDict.empty()) { continue; } const std::string& owner = objDict.begin()->first; conn->async_method_call( [path](const boost::system::error_code ec2, const boost::container::flat_map< std::string, std::variant>& values) { if (ec2) { std::cerr << "Error Getting Config " << ec2.message() << " " << __FUNCTION__ << "\n"; return; } auto findBus = values.find("Bus"); auto findIndex = values.find("Index"); if (findBus == values.end() || findIndex == values.end()) { std::cerr << "Illegal interface at " << path << "\n"; return; } size_t muxBus = static_cast( std::get(findBus->second)); size_t driveIndex = static_cast( std::get(findIndex->second)); std::filesystem::path muxPath = "/sys/bus/i2c/devices/i2c-" + std::to_string(muxBus) + "/mux_device"; if (!std::filesystem::is_symlink(muxPath)) { std::cerr << path << " mux does not exist\n"; return; } // we should be getting something of the form 7-0052 for // bus 7 addr 52 std::string fname = std::filesystem::read_symlink(muxPath).filename(); auto findDash = fname.find('-'); if (findDash == std::string::npos || findDash + 1 >= fname.size()) { std::cerr << path << " mux path invalid\n"; return; } std::string busStr = fname.substr(0, findDash); std::string muxStr = fname.substr(findDash + 1); size_t bus = static_cast(std::stoi(busStr)); size_t addr = static_cast(std::stoi(muxStr, nullptr, 16)); Backplane* parent = nullptr; for (auto& [name, backplane] : backplanes) { for (const Mux& mux : *(backplane.muxes)) { if (bus == mux.bus && addr == mux.address) { parent = &backplane; break; } } } if (parent == nullptr) { std::cerr << "Failed to find mux at bus " << bus << ", addr " << addr << "\n"; return; } if (parent->drives.size() <= driveIndex) { std::cerr << "Illegal drive index at " << path << " " << driveIndex << "\n"; return; } Drive& drive = parent->drives[driveIndex]; drive.createAssociation(path); }, owner, path, "org.freedesktop.DBus.Properties", "GetAll", "xyz.openbmc_project.Inventory.Item.Drive"); } }, mapper::busName, mapper::path, mapper::interface, mapper::subtree, "/", 0, std::array{driveType}); } void populateMuxes(std::shared_ptr> muxes, std::string& rootPath) { const static std::array muxTypes = { "xyz.openbmc_project.Configuration.PCA9543Mux", "xyz.openbmc_project.Configuration.PCA9544Mux", "xyz.openbmc_project.Configuration.PCA9545Mux", "xyz.openbmc_project.Configuration.PCA9546Mux"}; conn->async_method_call( [muxes](const boost::system::error_code ec, const GetSubTreeType& subtree) { if (ec) { std::cerr << "Error contacting mapper " << ec.message() << "\n"; return; } std::shared_ptr> callback = std::make_shared>( []() { updateAssociations(); }); for (const auto& [path, objDict] : subtree) { if (objDict.empty() || objDict.begin()->second.empty()) { continue; } const std::string& owner = objDict.begin()->first; const std::vector& interfaces = objDict.begin()->second; const std::string* interface = nullptr; for (const std::string& iface : interfaces) { if (std::find(muxTypes.begin(), muxTypes.end(), iface) != muxTypes.end()) { interface = &iface; break; } } if (interface == nullptr) { std::cerr << "Cannot get mux type\n"; continue; } conn->async_method_call( [path, muxes, callback]( const boost::system::error_code ec2, const boost::container::flat_map< std::string, std::variant>& values) { if (ec2) { std::cerr << "Error Getting Config " << ec2.message() << " " << __FUNCTION__ << "\n"; return; } auto findBus = values.find("Bus"); auto findAddress = values.find("Address"); if (findBus == values.end() || findAddress == values.end()) { std::cerr << "Illegal configuration at " << path << "\n"; return; } size_t bus = static_cast( std::get(findBus->second)); size_t address = static_cast( std::get(findAddress->second)); muxes->emplace_back(bus, address); if (callback.use_count() == 1) { (*callback)(); } }, owner, path, "org.freedesktop.DBus.Properties", "GetAll", *interface); } }, mapper::busName, mapper::path, mapper::interface, mapper::subtree, rootPath, 1, muxTypes); } void populate() { conn->async_method_call( [](const boost::system::error_code ec, const GetSubTreeType& subtree) { if (ec) { std::cerr << "Error contacting mapper " << ec.message() << "\n"; return; } for (const auto& [path, objDict] : subtree) { if (objDict.empty()) { continue; } const std::string& owner = objDict.begin()->first; conn->async_method_call( [path](const boost::system::error_code ec2, const boost::container::flat_map< std::string, BasicVariantType>& resp) { if (ec2) { std::cerr << "Error Getting Config " << ec2.message() << "\n"; return; } backplanes.clear(); std::optional bus; std::optional address; std::optional backplaneIndex; std::optional name; for (const auto& [key, value] : resp) { if (key == "Bus") { bus = std::get(value); } else if (key == "Address") { address = std::get(value); } else if (key == "Index") { backplaneIndex = std::get(value); } else if (key == "Name") { name = std::get(value); } } if (!bus || !address || !name || !backplaneIndex) { std::cerr << "Illegal configuration at " << path << "\n"; return; } std::string parentPath = std::filesystem::path(path).parent_path(); const auto& [backplane, status] = backplanes.emplace( *name, Backplane(*bus, *address, *backplaneIndex, *name)); backplane->second.run(); populateMuxes(backplane->second.muxes, parentPath); }, owner, path, "org.freedesktop.DBus.Properties", "GetAll", configType); } }, mapper::busName, mapper::path, mapper::interface, mapper::subtree, "/", 0, std::array{configType}); } int main() { boost::asio::steady_timer callbackTimer(io); conn->request_name("xyz.openbmc_project.HsbpManager"); sdbusplus::bus::match::match match( *conn, "type='signal',member='PropertiesChanged',arg0='" + std::string(configType) + "'", [&callbackTimer](sdbusplus::message::message&) { callbackTimer.expires_after(std::chrono::seconds(2)); callbackTimer.async_wait([](const boost::system::error_code ec) { if (ec == boost::asio::error::operation_aborted) { // timer was restarted return; } else if (ec) { std::cerr << "Timer error" << ec.message() << "\n"; return; } populate(); }); }); sdbusplus::bus::match::match drive( *conn, "type='signal',member='PropertiesChanged',arg0='xyz.openbmc_project." "Inventory.Item.Drive'", [&callbackTimer](sdbusplus::message::message&) { callbackTimer.expires_after(std::chrono::seconds(2)); callbackTimer.async_wait([](const boost::system::error_code ec) { if (ec == boost::asio::error::operation_aborted) { // timer was restarted return; } else if (ec) { std::cerr << "Timer error" << ec.message() << "\n"; return; } populate(); }); }); io.post([]() { populate(); }); io.run(); }