1 /** 2 * Copyright © 2020 IBM Corporation 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 #include "json_parser.hpp" 17 18 #include "conditions.hpp" 19 #include "json_config.hpp" 20 #include "nonzero_speed_trust.hpp" 21 #include "power_interface.hpp" 22 #include "power_off_rule.hpp" 23 #include "tach_sensor.hpp" 24 #include "types.hpp" 25 26 #include <fmt/format.h> 27 28 #include <nlohmann/json.hpp> 29 #include <phosphor-logging/log.hpp> 30 31 #include <algorithm> 32 #include <map> 33 #include <memory> 34 #include <optional> 35 #include <vector> 36 37 namespace phosphor::fan::monitor 38 { 39 40 using json = nlohmann::json; 41 using namespace phosphor::logging; 42 43 namespace tClass 44 { 45 46 // Get a constructed trust group class for a non-zero speed group 47 CreateGroupFunction 48 getNonZeroSpeed(const std::vector<trust::GroupDefinition>& group) 49 { 50 return [group]() { 51 return std::make_unique<trust::NonzeroSpeed>(std::move(group)); 52 }; 53 } 54 55 } // namespace tClass 56 57 const std::map<std::string, trustHandler> trusts = { 58 {"nonzerospeed", tClass::getNonZeroSpeed}}; 59 const std::map<std::string, condHandler> conditions = { 60 {"propertiesmatch", condition::getPropertiesMatch}}; 61 const std::map<std::string, size_t> methods = { 62 {"timebased", MethodMode::timebased}, {"count", MethodMode::count}}; 63 64 const std::vector<CreateGroupFunction> getTrustGrps(const json& obj) 65 { 66 std::vector<CreateGroupFunction> grpFuncs; 67 68 if (obj.contains("sensor_trust_groups")) 69 { 70 for (auto& stg : obj["sensor_trust_groups"]) 71 { 72 if (!stg.contains("class") || !stg.contains("group")) 73 { 74 // Log error on missing required parameters 75 log<level::ERR>( 76 "Missing required fan monitor trust group parameters", 77 entry("REQUIRED_PARAMETERS=%s", "{class, group}")); 78 throw std::runtime_error( 79 "Missing required fan trust group parameters"); 80 } 81 auto tgClass = stg["class"].get<std::string>(); 82 std::vector<trust::GroupDefinition> group; 83 for (auto& member : stg["group"]) 84 { 85 // Construct list of group members 86 if (!member.contains("name")) 87 { 88 // Log error on missing required parameter 89 log<level::ERR>( 90 "Missing required fan monitor trust group member name", 91 entry("CLASS=%s", tgClass.c_str())); 92 throw std::runtime_error( 93 "Missing required fan monitor trust group member name"); 94 } 95 auto in_trust = true; 96 if (member.contains("in_trust")) 97 { 98 in_trust = member["in_trust"].get<bool>(); 99 } 100 group.emplace_back(trust::GroupDefinition{ 101 member["name"].get<std::string>(), in_trust}); 102 } 103 // The class for fan sensor trust groups 104 // (Must have a supported function within the tClass namespace) 105 std::transform(tgClass.begin(), tgClass.end(), tgClass.begin(), 106 tolower); 107 auto handler = trusts.find(tgClass); 108 if (handler != trusts.end()) 109 { 110 // Call function for trust group class 111 grpFuncs.emplace_back(handler->second(group)); 112 } 113 else 114 { 115 // Log error on unsupported trust group class 116 log<level::ERR>("Invalid fan monitor trust group class", 117 entry("CLASS=%s", tgClass.c_str())); 118 throw std::runtime_error( 119 "Invalid fan monitor trust group class"); 120 } 121 } 122 } 123 124 return grpFuncs; 125 } 126 127 const std::vector<SensorDefinition> getSensorDefs(const json& sensors) 128 { 129 std::vector<SensorDefinition> sensorDefs; 130 131 for (const auto& sensor : sensors) 132 { 133 if (!sensor.contains("name") || !sensor.contains("has_target")) 134 { 135 // Log error on missing required parameters 136 log<level::ERR>( 137 "Missing required fan sensor definition parameters", 138 entry("REQUIRED_PARAMETERS=%s", "{name, has_target}")); 139 throw std::runtime_error( 140 "Missing required fan sensor definition parameters"); 141 } 142 // Target interface is optional and defaults to 143 // 'xyz.openbmc_project.Control.FanSpeed' 144 std::string targetIntf = "xyz.openbmc_project.Control.FanSpeed"; 145 if (sensor.contains("target_interface")) 146 { 147 targetIntf = sensor["target_interface"].get<std::string>(); 148 } 149 // Factor is optional and defaults to 1 150 auto factor = 1.0; 151 if (sensor.contains("factor")) 152 { 153 factor = sensor["factor"].get<double>(); 154 } 155 // Offset is optional and defaults to 0 156 auto offset = 0; 157 if (sensor.contains("offset")) 158 { 159 offset = sensor["offset"].get<int64_t>(); 160 } 161 // Threshold is optional and defaults to 1 162 auto threshold = 1; 163 if (sensor.contains("threshold")) 164 { 165 threshold = sensor["threshold"].get<size_t>(); 166 } 167 // Ignore being above the allowed max is optional, defaults to not 168 bool ignoreAboveMax = false; 169 if (sensor.contains("ignore_above_max")) 170 { 171 ignoreAboveMax = sensor["ignore_above_max"].get<bool>(); 172 } 173 174 sensorDefs.emplace_back(std::tuple( 175 sensor["name"].get<std::string>(), sensor["has_target"].get<bool>(), 176 targetIntf, factor, offset, threshold, ignoreAboveMax)); 177 } 178 179 return sensorDefs; 180 } 181 182 const std::vector<FanDefinition> getFanDefs(const json& obj) 183 { 184 std::vector<FanDefinition> fanDefs; 185 186 for (const auto& fan : obj["fans"]) 187 { 188 if (!fan.contains("inventory") || !fan.contains("deviation") || 189 !fan.contains("sensors")) 190 { 191 // Log error on missing required parameters 192 log<level::ERR>( 193 "Missing required fan monitor definition parameters", 194 entry("REQUIRED_PARAMETERS=%s", 195 "{inventory, deviation, sensors}")); 196 throw std::runtime_error( 197 "Missing required fan monitor definition parameters"); 198 } 199 // Valid deviation range is 0 - 100% 200 auto deviation = fan["deviation"].get<size_t>(); 201 if (deviation < 0 || 100 < deviation) 202 { 203 auto msg = fmt::format( 204 "Invalid deviation of {} found, must be between 0 and 100", 205 deviation); 206 207 log<level::ERR>(msg.c_str()); 208 throw std::runtime_error(msg.c_str()); 209 } 210 211 // Construct the sensor definitions for this fan 212 auto sensorDefs = getSensorDefs(fan["sensors"]); 213 214 // Functional delay is optional and defaults to 0 215 size_t funcDelay = 0; 216 if (fan.contains("functional_delay")) 217 { 218 funcDelay = fan["functional_delay"].get<size_t>(); 219 } 220 221 // Method is optional and defaults to time based functional 222 // determination 223 size_t method = MethodMode::timebased; 224 size_t countInterval = 1; 225 if (fan.contains("method")) 226 { 227 auto methodConf = fan["method"].get<std::string>(); 228 auto methodFunc = methods.find(methodConf); 229 if (methodFunc != methods.end()) 230 { 231 method = methodFunc->second; 232 } 233 else 234 { 235 // Log error on unsupported method parameter 236 log<level::ERR>("Invalid fan method"); 237 throw std::runtime_error("Invalid fan method"); 238 } 239 240 // Read the count interval value used with the count method. 241 if (method == MethodMode::count) 242 { 243 if (fan.contains("count_interval")) 244 { 245 countInterval = fan["count_interval"].get<size_t>(); 246 } 247 } 248 } 249 250 // Timeout defaults to 0 251 size_t timeout = 0; 252 if (method == MethodMode::timebased) 253 { 254 if (!fan.contains("allowed_out_of_range_time")) 255 { 256 // Log error on missing required parameter 257 log<level::ERR>( 258 "Missing required fan monitor definition parameters", 259 entry("REQUIRED_PARAMETER=%s", 260 "{allowed_out_of_range_time}")); 261 throw std::runtime_error( 262 "Missing required fan monitor definition parameters"); 263 } 264 else 265 { 266 timeout = fan["allowed_out_of_range_time"].get<size_t>(); 267 } 268 } 269 270 // Monitor start delay is optional and defaults to 0 271 size_t monitorDelay = 0; 272 if (fan.contains("monitor_start_delay")) 273 { 274 monitorDelay = fan["monitor_start_delay"].get<size_t>(); 275 } 276 277 // num_sensors_nonfunc_for_fan_nonfunc is optional and defaults 278 // to zero if not present, meaning the code will not set the 279 // parent fan to nonfunctional based on sensors. 280 size_t nonfuncSensorsCount = 0; 281 if (fan.contains("num_sensors_nonfunc_for_fan_nonfunc")) 282 { 283 nonfuncSensorsCount = 284 fan["num_sensors_nonfunc_for_fan_nonfunc"].get<size_t>(); 285 } 286 287 // nonfunc_rotor_error_delay is optional, though it will 288 // default to zero if 'fault_handling' is present. 289 std::optional<size_t> nonfuncRotorErrorDelay; 290 if (fan.contains("nonfunc_rotor_error_delay")) 291 { 292 nonfuncRotorErrorDelay = 293 fan["nonfunc_rotor_error_delay"].get<size_t>(); 294 } 295 else if (obj.contains("fault_handling")) 296 { 297 nonfuncRotorErrorDelay = 0; 298 } 299 300 // fan_missing_error_delay is optional. 301 std::optional<size_t> fanMissingErrorDelay; 302 if (fan.contains("fan_missing_error_delay")) 303 { 304 fanMissingErrorDelay = 305 fan.at("fan_missing_error_delay").get<size_t>(); 306 } 307 308 // Handle optional conditions 309 auto cond = std::optional<Condition>(); 310 if (fan.contains("condition")) 311 { 312 if (!fan["condition"].contains("name")) 313 { 314 // Log error on missing required parameter 315 log<level::ERR>( 316 "Missing required fan monitor condition parameter", 317 entry("REQUIRED_PARAMETER=%s", "{name}")); 318 throw std::runtime_error( 319 "Missing required fan monitor condition parameter"); 320 } 321 auto name = fan["condition"]["name"].get<std::string>(); 322 // The function for fan monitoring condition 323 // (Must have a supported function within the condition namespace) 324 std::transform(name.begin(), name.end(), name.begin(), tolower); 325 auto handler = conditions.find(name); 326 if (handler != conditions.end()) 327 { 328 cond = handler->second(fan["condition"]); 329 } 330 else 331 { 332 log<level::INFO>( 333 "No handler found for configured condition", 334 entry("CONDITION_NAME=%s", name.c_str()), 335 entry("JSON_DUMP=%s", fan["condition"].dump().c_str())); 336 } 337 } 338 339 // if the fan should be set to functional when plugged in 340 bool setFuncOnPresent = false; 341 if (fan.contains("set_func_on_present")) 342 { 343 setFuncOnPresent = fan["set_func_on_present"].get<bool>(); 344 } 345 346 fanDefs.emplace_back(std::tuple( 347 fan["inventory"].get<std::string>(), method, funcDelay, timeout, 348 deviation, nonfuncSensorsCount, monitorDelay, countInterval, 349 nonfuncRotorErrorDelay, fanMissingErrorDelay, sensorDefs, cond, 350 setFuncOnPresent)); 351 } 352 353 return fanDefs; 354 } 355 356 PowerRuleState getPowerOffPowerRuleState(const json& powerOffConfig) 357 { 358 // The state is optional and defaults to runtime 359 PowerRuleState ruleState{PowerRuleState::runtime}; 360 361 if (powerOffConfig.contains("state")) 362 { 363 auto state = powerOffConfig.at("state").get<std::string>(); 364 if (state == "at_pgood") 365 { 366 ruleState = PowerRuleState::atPgood; 367 } 368 else if (state != "runtime") 369 { 370 auto msg = fmt::format("Invalid power off state entry {}", state); 371 log<level::ERR>(msg.c_str()); 372 throw std::runtime_error(msg.c_str()); 373 } 374 } 375 376 return ruleState; 377 } 378 379 std::unique_ptr<PowerOffCause> getPowerOffCause(const json& powerOffConfig) 380 { 381 std::unique_ptr<PowerOffCause> cause; 382 383 if (!powerOffConfig.contains("count") || !powerOffConfig.contains("cause")) 384 { 385 const auto msg = 386 "Missing 'count' or 'cause' entries in power off config"; 387 log<level::ERR>(msg); 388 throw std::runtime_error(msg); 389 } 390 391 auto count = powerOffConfig.at("count").get<size_t>(); 392 auto powerOffCause = powerOffConfig.at("cause").get<std::string>(); 393 394 const std::map<std::string, std::function<std::unique_ptr<PowerOffCause>()>> 395 causes{ 396 {"missing_fan_frus", 397 [count]() { return std::make_unique<MissingFanFRUCause>(count); }}, 398 {"nonfunc_fan_rotors", [count]() { 399 return std::make_unique<NonfuncFanRotorCause>(count); 400 }}}; 401 402 auto it = causes.find(powerOffCause); 403 if (it != causes.end()) 404 { 405 cause = it->second(); 406 } 407 else 408 { 409 auto msg = 410 fmt::format("Invalid power off cause {} in power off config JSON", 411 powerOffCause); 412 log<level::ERR>(msg.c_str()); 413 throw std::runtime_error(msg.c_str()); 414 } 415 416 return cause; 417 } 418 419 std::unique_ptr<PowerOffAction> 420 getPowerOffAction(const json& powerOffConfig, 421 std::shared_ptr<PowerInterfaceBase>& powerInterface, 422 PowerOffAction::PrePowerOffFunc& func) 423 { 424 std::unique_ptr<PowerOffAction> action; 425 if (!powerOffConfig.contains("type")) 426 { 427 const auto msg = "Missing 'type' entry in power off config"; 428 log<level::ERR>(msg); 429 throw std::runtime_error(msg); 430 } 431 432 auto type = powerOffConfig.at("type").get<std::string>(); 433 434 if (((type == "hard") || (type == "soft")) && 435 !powerOffConfig.contains("delay")) 436 { 437 const auto msg = "Missing 'delay' entry in power off config"; 438 log<level::ERR>(msg); 439 throw std::runtime_error(msg); 440 } 441 else if ((type == "epow") && 442 (!powerOffConfig.contains("service_mode_delay") || 443 !powerOffConfig.contains("meltdown_delay"))) 444 { 445 const auto msg = "Missing 'service_mode_delay' or 'meltdown_delay' " 446 "entry in power off config"; 447 log<level::ERR>(msg); 448 throw std::runtime_error(msg); 449 } 450 451 if (type == "hard") 452 { 453 action = std::make_unique<HardPowerOff>( 454 powerOffConfig.at("delay").get<uint32_t>(), powerInterface, func); 455 } 456 else if (type == "soft") 457 { 458 action = std::make_unique<SoftPowerOff>( 459 powerOffConfig.at("delay").get<uint32_t>(), powerInterface, func); 460 } 461 else if (type == "epow") 462 { 463 action = std::make_unique<EpowPowerOff>( 464 powerOffConfig.at("service_mode_delay").get<uint32_t>(), 465 powerOffConfig.at("meltdown_delay").get<uint32_t>(), powerInterface, 466 func); 467 } 468 else 469 { 470 auto msg = 471 fmt::format("Invalid 'type' entry {} in power off config", type); 472 log<level::ERR>(msg.c_str()); 473 throw std::runtime_error(msg.c_str()); 474 } 475 476 return action; 477 } 478 479 std::vector<std::unique_ptr<PowerOffRule>> 480 getPowerOffRules(const json& obj, 481 std::shared_ptr<PowerInterfaceBase>& powerInterface, 482 PowerOffAction::PrePowerOffFunc& func) 483 { 484 std::vector<std::unique_ptr<PowerOffRule>> rules; 485 486 if (!(obj.contains("fault_handling") && 487 obj.at("fault_handling").contains("power_off_config"))) 488 { 489 return rules; 490 } 491 492 for (const auto& config : obj.at("fault_handling").at("power_off_config")) 493 { 494 auto state = getPowerOffPowerRuleState(config); 495 auto cause = getPowerOffCause(config); 496 auto action = getPowerOffAction(config, powerInterface, func); 497 498 auto rule = std::make_unique<PowerOffRule>( 499 std::move(state), std::move(cause), std::move(action)); 500 rules.push_back(std::move(rule)); 501 } 502 503 return rules; 504 } 505 506 std::optional<size_t> getNumNonfuncRotorsBeforeError(const json& obj) 507 { 508 std::optional<size_t> num; 509 510 if (obj.contains("fault_handling")) 511 { 512 // Defaults to 1 if not present inside of 'fault_handling'. 513 num = obj.at("fault_handling") 514 .value("num_nonfunc_rotors_before_error", 1); 515 } 516 517 return num; 518 } 519 520 } // namespace phosphor::fan::monitor 521