1 /*
2 // Copyright (c) 2018 Intel 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 "dbusconfiguration.hpp"
17 
18 #include "conf.hpp"
19 #include "dbushelper.hpp"
20 #include "dbusutil.hpp"
21 #include "util.hpp"
22 
23 #include <boost/asio/steady_timer.hpp>
24 #include <sdbusplus/bus.hpp>
25 #include <sdbusplus/bus/match.hpp>
26 #include <sdbusplus/exception.hpp>
27 
28 #include <algorithm>
29 #include <chrono>
30 #include <functional>
31 #include <iostream>
32 #include <list>
33 #include <set>
34 #include <unordered_map>
35 #include <variant>
36 
37 namespace pid_control
38 {
39 
40 constexpr const char* pidConfigurationInterface =
41     "xyz.openbmc_project.Configuration.Pid";
42 constexpr const char* objectManagerInterface =
43     "org.freedesktop.DBus.ObjectManager";
44 constexpr const char* pidZoneConfigurationInterface =
45     "xyz.openbmc_project.Configuration.Pid.Zone";
46 constexpr const char* stepwiseConfigurationInterface =
47     "xyz.openbmc_project.Configuration.Stepwise";
48 constexpr const char* thermalControlIface =
49     "xyz.openbmc_project.Control.ThermalMode";
50 constexpr const char* sensorInterface = "xyz.openbmc_project.Sensor.Value";
51 constexpr const char* defaultPwmInterface =
52     "xyz.openbmc_project.Control.FanPwm";
53 
54 using Association = std::tuple<std::string, std::string, std::string>;
55 using Associations = std::vector<Association>;
56 
57 namespace thresholds
58 {
59 constexpr const char* warningInterface =
60     "xyz.openbmc_project.Sensor.Threshold.Warning";
61 constexpr const char* criticalInterface =
62     "xyz.openbmc_project.Sensor.Threshold.Critical";
63 const std::array<const char*, 4> types = {"CriticalLow", "CriticalHigh",
64                                           "WarningLow", "WarningHigh"};
65 
66 } // namespace thresholds
67 
68 namespace dbus_configuration
69 {
70 using SensorInterfaceType = std::pair<std::string, std::string>;
71 
72 inline std::string getSensorNameFromPath(const std::string& dbusPath)
73 {
74     return dbusPath.substr(dbusPath.find_last_of("/") + 1);
75 }
76 
77 inline std::string sensorNameToDbusName(const std::string& sensorName)
78 {
79     std::string retString = sensorName;
80     std::replace(retString.begin(), retString.end(), ' ', '_');
81     return retString;
82 }
83 
84 std::vector<std::string> getSelectedProfiles(sdbusplus::bus_t& bus)
85 {
86     std::vector<std::string> ret;
87     auto mapper =
88         bus.new_method_call("xyz.openbmc_project.ObjectMapper",
89                             "/xyz/openbmc_project/object_mapper",
90                             "xyz.openbmc_project.ObjectMapper", "GetSubTree");
91     mapper.append("/", 0, std::array<const char*, 1>{thermalControlIface});
92     std::unordered_map<
93         std::string, std::unordered_map<std::string, std::vector<std::string>>>
94         respData;
95 
96     try
97     {
98         auto resp = bus.call(mapper);
99         resp.read(respData);
100     }
101     catch (const sdbusplus::exception_t&)
102     {
103         // can't do anything without mapper call data
104         throw std::runtime_error("ObjectMapper Call Failure");
105     }
106     if (respData.empty())
107     {
108         // if the user has profiles but doesn't expose the interface to select
109         // one, just go ahead without using profiles
110         return ret;
111     }
112 
113     // assumption is that we should only have a small handful of selected
114     // profiles at a time (probably only 1), so calling each individually should
115     // not incur a large cost
116     for (const auto& objectPair : respData)
117     {
118         const std::string& path = objectPair.first;
119         for (const auto& ownerPair : objectPair.second)
120         {
121             const std::string& busName = ownerPair.first;
122             auto getProfile =
123                 bus.new_method_call(busName.c_str(), path.c_str(),
124                                     "org.freedesktop.DBus.Properties", "Get");
125             getProfile.append(thermalControlIface, "Current");
126             std::variant<std::string> variantResp;
127             try
128             {
129                 auto resp = bus.call(getProfile);
130                 resp.read(variantResp);
131             }
132             catch (const sdbusplus::exception_t&)
133             {
134                 throw std::runtime_error("Failure getting profile");
135             }
136             std::string mode = std::get<std::string>(variantResp);
137             ret.emplace_back(std::move(mode));
138         }
139     }
140     if constexpr (pid_control::conf::DEBUG)
141     {
142         std::cout << "Profiles selected: ";
143         for (const auto& profile : ret)
144         {
145             std::cout << profile << " ";
146         }
147         std::cout << "\n";
148     }
149     return ret;
150 }
151 
152 int eventHandler(sd_bus_message* m, void* context, sd_bus_error*)
153 {
154 
155     if (context == nullptr || m == nullptr)
156     {
157         throw std::runtime_error("Invalid match");
158     }
159 
160     // we skip associations because the mapper populates these, not the sensors
161     const std::array<const char*, 1> skipList = {
162         "xyz.openbmc_project.Association"};
163 
164     sdbusplus::message_t message(m);
165     if (std::string(message.get_member()) == "InterfacesAdded")
166     {
167         sdbusplus::message::object_path path;
168         std::unordered_map<
169             std::string,
170             std::unordered_map<std::string, std::variant<Associations, bool>>>
171             data;
172 
173         message.read(path, data);
174 
175         for (const char* skip : skipList)
176         {
177             auto find = data.find(skip);
178             if (find != data.end())
179             {
180                 data.erase(find);
181                 if (data.empty())
182                 {
183                     return 1;
184                 }
185             }
186         }
187     }
188 
189     boost::asio::steady_timer* timer =
190         static_cast<boost::asio::steady_timer*>(context);
191 
192     // do a brief sleep as we tend to get a bunch of these events at
193     // once
194     timer->expires_after(std::chrono::seconds(2));
195     timer->async_wait([](const boost::system::error_code ec) {
196         if (ec == boost::asio::error::operation_aborted)
197         {
198             /* another timer started*/
199             return;
200         }
201 
202         std::cout << "New configuration detected, reloading\n.";
203         tryRestartControlLoops();
204     });
205 
206     return 1;
207 }
208 
209 void createMatches(sdbusplus::bus_t& bus, boost::asio::steady_timer& timer)
210 {
211     // this is a list because the matches can't be moved
212     static std::list<sdbusplus::bus::match_t> matches;
213 
214     const std::array<std::string, 4> interfaces = {
215         thermalControlIface, pidConfigurationInterface,
216         pidZoneConfigurationInterface, stepwiseConfigurationInterface};
217 
218     // this list only needs to be created once
219     if (!matches.empty())
220     {
221         return;
222     }
223 
224     // we restart when the configuration changes or there are new sensors
225     for (const auto& interface : interfaces)
226     {
227         matches.emplace_back(
228             bus,
229             "type='signal',member='PropertiesChanged',arg0namespace='" +
230                 interface + "'",
231             eventHandler, &timer);
232     }
233     matches.emplace_back(
234         bus,
235         "type='signal',member='InterfacesAdded',arg0path='/xyz/openbmc_project/"
236         "sensors/'",
237         eventHandler, &timer);
238 }
239 
240 /**
241  * retrieve an attribute from the pid configuration map
242  * @param[in] base - the PID configuration map, keys are the attributes and
243  * value is the variant associated with that attribute.
244  * @param attributeName - the name of the attribute
245  * @return a variant holding the value associated with a key
246  * @throw runtime_error : attributeName is not in base
247  */
248 inline DbusVariantType getPIDAttribute(
249     const std::unordered_map<std::string, DbusVariantType>& base,
250     const std::string& attributeName)
251 {
252     auto search = base.find(attributeName);
253     if (search == base.end())
254     {
255         throw std::runtime_error("missing attribute " + attributeName);
256     }
257     return search->second;
258 }
259 
260 void populatePidInfo(
261     [[maybe_unused]] sdbusplus::bus_t& bus,
262     const std::unordered_map<std::string, DbusVariantType>& base,
263     conf::ControllerInfo& info, const std::string* thresholdProperty,
264     const std::map<std::string, conf::SensorConfig>& sensorConfig)
265 {
266     info.type = std::get<std::string>(getPIDAttribute(base, "Class"));
267     if (info.type == "fan")
268     {
269         info.setpoint = 0;
270     }
271     else
272     {
273         info.setpoint = std::visit(VariantToDoubleVisitor(),
274                                    getPIDAttribute(base, "SetPoint"));
275     }
276 
277     if (thresholdProperty != nullptr)
278     {
279         std::string interface;
280         if (*thresholdProperty == "WarningHigh" ||
281             *thresholdProperty == "WarningLow")
282         {
283             interface = thresholds::warningInterface;
284         }
285         else
286         {
287             interface = thresholds::criticalInterface;
288         }
289         const std::string& path = sensorConfig.at(info.inputs.front()).readPath;
290 
291         DbusHelper helper(sdbusplus::bus::new_system());
292         std::string service = helper.getService(interface, path);
293         double reading = 0;
294         try
295         {
296             helper.getProperty(service, path, interface, *thresholdProperty,
297                                reading);
298         }
299         catch (const sdbusplus::exception_t& ex)
300         {
301             // unsupported threshold, leaving reading at 0
302         }
303 
304         info.setpoint += reading;
305     }
306 
307     info.pidInfo.ts = 1.0; // currently unused
308     info.pidInfo.proportionalCoeff = std::visit(
309         VariantToDoubleVisitor(), getPIDAttribute(base, "PCoefficient"));
310     info.pidInfo.integralCoeff = std::visit(
311         VariantToDoubleVisitor(), getPIDAttribute(base, "ICoefficient"));
312     info.pidInfo.feedFwdOffset = std::visit(
313         VariantToDoubleVisitor(), getPIDAttribute(base, "FFOffCoefficient"));
314     info.pidInfo.feedFwdGain = std::visit(
315         VariantToDoubleVisitor(), getPIDAttribute(base, "FFGainCoefficient"));
316     info.pidInfo.integralLimit.max = std::visit(
317         VariantToDoubleVisitor(), getPIDAttribute(base, "ILimitMax"));
318     info.pidInfo.integralLimit.min = std::visit(
319         VariantToDoubleVisitor(), getPIDAttribute(base, "ILimitMin"));
320     info.pidInfo.outLim.max = std::visit(VariantToDoubleVisitor(),
321                                          getPIDAttribute(base, "OutLimitMax"));
322     info.pidInfo.outLim.min = std::visit(VariantToDoubleVisitor(),
323                                          getPIDAttribute(base, "OutLimitMin"));
324     info.pidInfo.slewNeg =
325         std::visit(VariantToDoubleVisitor(), getPIDAttribute(base, "SlewNeg"));
326     info.pidInfo.slewPos =
327         std::visit(VariantToDoubleVisitor(), getPIDAttribute(base, "SlewPos"));
328     double negativeHysteresis = 0;
329     double positiveHysteresis = 0;
330 
331     auto findNeg = base.find("NegativeHysteresis");
332     auto findPos = base.find("PositiveHysteresis");
333 
334     if (findNeg != base.end())
335     {
336         negativeHysteresis =
337             std::visit(VariantToDoubleVisitor(), findNeg->second);
338     }
339 
340     if (findPos != base.end())
341     {
342         positiveHysteresis =
343             std::visit(VariantToDoubleVisitor(), findPos->second);
344     }
345     info.pidInfo.negativeHysteresis = negativeHysteresis;
346     info.pidInfo.positiveHysteresis = positiveHysteresis;
347 }
348 
349 bool init(sdbusplus::bus_t& bus, boost::asio::steady_timer& timer,
350           std::map<std::string, conf::SensorConfig>& sensorConfig,
351           std::map<int64_t, conf::PIDConf>& zoneConfig,
352           std::map<int64_t, conf::ZoneConfig>& zoneDetailsConfig)
353 {
354 
355     sensorConfig.clear();
356     zoneConfig.clear();
357     zoneDetailsConfig.clear();
358 
359     createMatches(bus, timer);
360 
361     auto mapper =
362         bus.new_method_call("xyz.openbmc_project.ObjectMapper",
363                             "/xyz/openbmc_project/object_mapper",
364                             "xyz.openbmc_project.ObjectMapper", "GetSubTree");
365     mapper.append("/", 0,
366                   std::array<const char*, 6>{
367                       objectManagerInterface, pidConfigurationInterface,
368                       pidZoneConfigurationInterface,
369                       stepwiseConfigurationInterface, sensorInterface,
370                       defaultPwmInterface});
371     std::unordered_map<
372         std::string, std::unordered_map<std::string, std::vector<std::string>>>
373         respData;
374     try
375     {
376         auto resp = bus.call(mapper);
377         resp.read(respData);
378     }
379     catch (const sdbusplus::exception_t&)
380     {
381         // can't do anything without mapper call data
382         throw std::runtime_error("ObjectMapper Call Failure");
383     }
384 
385     if (respData.empty())
386     {
387         // can't do anything without mapper call data
388         throw std::runtime_error("No configuration data available from Mapper");
389     }
390     // create a map of pair of <has pid configuration, ObjectManager path>
391     std::unordered_map<std::string, std::pair<bool, std::string>> owners;
392     // and a map of <path, interface> for sensors
393     std::unordered_map<std::string, std::string> sensors;
394     for (const auto& objectPair : respData)
395     {
396         for (const auto& ownerPair : objectPair.second)
397         {
398             auto& owner = owners[ownerPair.first];
399             for (const std::string& interface : ownerPair.second)
400             {
401 
402                 if (interface == objectManagerInterface)
403                 {
404                     owner.second = objectPair.first;
405                 }
406                 if (interface == pidConfigurationInterface ||
407                     interface == pidZoneConfigurationInterface ||
408                     interface == stepwiseConfigurationInterface)
409                 {
410                     owner.first = true;
411                 }
412                 if (interface == sensorInterface ||
413                     interface == defaultPwmInterface)
414                 {
415                     // we're not interested in pwm sensors, just pwm control
416                     if (interface == sensorInterface &&
417                         objectPair.first.find("pwm") != std::string::npos)
418                     {
419                         continue;
420                     }
421                     sensors[objectPair.first] = interface;
422                 }
423             }
424         }
425     }
426     ManagedObjectType configurations;
427     for (const auto& owner : owners)
428     {
429         // skip if no pid configuration (means probably a sensor)
430         if (!owner.second.first)
431         {
432             continue;
433         }
434         auto endpoint = bus.new_method_call(
435             owner.first.c_str(), owner.second.second.c_str(),
436             "org.freedesktop.DBus.ObjectManager", "GetManagedObjects");
437         ManagedObjectType configuration;
438         try
439         {
440             auto responce = bus.call(endpoint);
441             responce.read(configuration);
442         }
443         catch (const sdbusplus::exception_t&)
444         {
445             // this shouldn't happen, probably means daemon crashed
446             throw std::runtime_error("Error getting managed objects from " +
447                                      owner.first);
448         }
449 
450         for (auto& pathPair : configuration)
451         {
452             if (pathPair.second.find(pidConfigurationInterface) !=
453                     pathPair.second.end() ||
454                 pathPair.second.find(pidZoneConfigurationInterface) !=
455                     pathPair.second.end() ||
456                 pathPair.second.find(stepwiseConfigurationInterface) !=
457                     pathPair.second.end())
458             {
459                 configurations.emplace(pathPair);
460             }
461         }
462     }
463 
464     // remove controllers from config that aren't in the current profile(s)
465     std::vector<std::string> selectedProfiles = getSelectedProfiles(bus);
466     if (selectedProfiles.size())
467     {
468         for (auto pathIt = configurations.begin();
469              pathIt != configurations.end();)
470         {
471             for (auto confIt = pathIt->second.begin();
472                  confIt != pathIt->second.end();)
473             {
474                 auto profilesFind = confIt->second.find("Profiles");
475                 if (profilesFind == confIt->second.end())
476                 {
477                     confIt++;
478                     continue; // if no profiles selected, apply always
479                 }
480                 auto profiles =
481                     std::get<std::vector<std::string>>(profilesFind->second);
482                 if (profiles.empty())
483                 {
484                     confIt++;
485                     continue;
486                 }
487 
488                 bool found = false;
489                 for (const std::string& profile : profiles)
490                 {
491                     if (std::find(selectedProfiles.begin(),
492                                   selectedProfiles.end(),
493                                   profile) != selectedProfiles.end())
494                     {
495                         found = true;
496                         break;
497                     }
498                 }
499                 if (found)
500                 {
501                     confIt++;
502                 }
503                 else
504                 {
505                     confIt = pathIt->second.erase(confIt);
506                 }
507             }
508             if (pathIt->second.empty())
509             {
510                 pathIt = configurations.erase(pathIt);
511             }
512             else
513             {
514                 pathIt++;
515             }
516         }
517     }
518 
519     // On D-Bus, although not necessary,
520     // having the "zoneID" field can still be useful,
521     // as it is used for diagnostic messages,
522     // logging file names, and so on.
523     // Accept optional "ZoneIndex" parameter to explicitly specify.
524     // If not present, or not unique, auto-assign index,
525     // using 0-based numbering, ensuring uniqueness.
526     std::map<std::string, int64_t> foundZones;
527     for (const auto& configuration : configurations)
528     {
529         auto findZone =
530             configuration.second.find(pidZoneConfigurationInterface);
531         if (findZone != configuration.second.end())
532         {
533             const auto& zone = findZone->second;
534 
535             const std::string& name = std::get<std::string>(zone.at("Name"));
536 
537             auto findZoneIndex = zone.find("ZoneIndex");
538             if (findZoneIndex == zone.end())
539             {
540                 continue;
541             }
542 
543             auto ptrZoneIndex = std::get_if<double>(&(findZoneIndex->second));
544             if (!ptrZoneIndex)
545             {
546                 continue;
547             }
548 
549             auto desiredIndex = static_cast<int64_t>(*ptrZoneIndex);
550             auto grantedIndex = setZoneIndex(name, foundZones, desiredIndex);
551             std::cout << "Zone " << name << " is at ZoneIndex " << grantedIndex
552                       << "\n";
553         }
554     }
555 
556     for (const auto& configuration : configurations)
557     {
558         auto findZone =
559             configuration.second.find(pidZoneConfigurationInterface);
560         if (findZone != configuration.second.end())
561         {
562             const auto& zone = findZone->second;
563 
564             const std::string& name = std::get<std::string>(zone.at("Name"));
565 
566             auto index = getZoneIndex(name, foundZones);
567 
568             auto& details = zoneDetailsConfig[index];
569 
570             details.minThermalOutput = std::visit(VariantToDoubleVisitor(),
571                                                   zone.at("MinThermalOutput"));
572             details.failsafePercent = std::visit(VariantToDoubleVisitor(),
573                                                  zone.at("FailSafePercent"));
574         }
575         auto findBase = configuration.second.find(pidConfigurationInterface);
576         // loop through all the PID configurations and fill out a sensor config
577         if (findBase != configuration.second.end())
578         {
579             const auto& base =
580                 configuration.second.at(pidConfigurationInterface);
581             const std::string pidName = std::get<std::string>(base.at("Name"));
582             const std::string pidClass =
583                 std::get<std::string>(base.at("Class"));
584             const std::vector<std::string>& zones =
585                 std::get<std::vector<std::string>>(base.at("Zones"));
586             for (const std::string& zone : zones)
587             {
588                 auto index = getZoneIndex(zone, foundZones);
589 
590                 conf::PIDConf& conf = zoneConfig[index];
591                 std::vector<std::string> inputSensorNames(
592                     std::get<std::vector<std::string>>(base.at("Inputs")));
593                 std::vector<std::string> outputSensorNames;
594 
595                 // assumption: all fan pids must have at least one output
596                 if (pidClass == "fan")
597                 {
598                     outputSensorNames = std::get<std::vector<std::string>>(
599                         getPIDAttribute(base, "Outputs"));
600                 }
601 
602                 bool unavailableAsFailed = true;
603                 auto findUnavailableAsFailed =
604                     base.find("InputUnavailableAsFailed");
605                 if (findUnavailableAsFailed != base.end())
606                 {
607                     unavailableAsFailed =
608                         std::get<bool>(findUnavailableAsFailed->second);
609                 }
610 
611                 std::vector<SensorInterfaceType> inputSensorInterfaces;
612                 std::vector<SensorInterfaceType> outputSensorInterfaces;
613                 /* populate an interface list for different sensor direction
614                  * types (input,output)
615                  */
616                 /* take the Inputs from the configuration and generate
617                  * a list of dbus descriptors (path, interface).
618                  * Mapping can be many-to-one since an element of Inputs can be
619                  * a regex
620                  */
621                 for (const std::string& sensorName : inputSensorNames)
622                 {
623                     findSensors(sensors, sensorNameToDbusName(sensorName),
624                                 inputSensorInterfaces);
625                 }
626                 for (const std::string& sensorName : outputSensorNames)
627                 {
628                     findSensors(sensors, sensorNameToDbusName(sensorName),
629                                 outputSensorInterfaces);
630                 }
631 
632                 inputSensorNames.clear();
633                 for (const SensorInterfaceType& inputSensorInterface :
634                      inputSensorInterfaces)
635                 {
636                     const std::string& dbusInterface =
637                         inputSensorInterface.second;
638                     const std::string& inputSensorPath =
639                         inputSensorInterface.first;
640                     // todo: maybe un-hardcode this if we run into slower
641                     // timeouts with sensors
642                     if (pidClass == "temp")
643                     {
644                         std::string inputSensorName =
645                             getSensorNameFromPath(inputSensorPath);
646                         auto& config = sensorConfig[inputSensorName];
647                         inputSensorNames.push_back(inputSensorName);
648                         config.type = pidClass;
649                         config.readPath = inputSensorInterface.first;
650                         config.timeout = 0;
651                         config.ignoreDbusMinMax = true;
652                         config.unavailableAsFailed = unavailableAsFailed;
653                     }
654                     if (dbusInterface != sensorInterface)
655                     {
656                         /* all expected inputs in the configuration are expected
657                          * to be sensor interfaces
658                          */
659                         throw std::runtime_error(
660                             "sensor at dbus path [" + inputSensorPath +
661                             "] has an interface [" + dbusInterface +
662                             "] that does not match the expected interface of " +
663                             sensorInterface);
664                     }
665                 }
666 
667                 /* fan pids need to pair up tach sensors with their pwm
668                  * counterparts
669                  */
670                 if (pidClass == "fan")
671                 {
672                     /* If a PID is a fan there should be either
673                      * (1) one output(pwm) per input(tach)
674                      * OR
675                      * (2) one putput(pwm) for all inputs(tach)
676                      * everything else indicates a bad configuration.
677                      */
678                     bool singlePwm = false;
679                     if (outputSensorInterfaces.size() == 1)
680                     {
681                         /* one pwm, set write paths for all fan sensors to it */
682                         singlePwm = true;
683                     }
684                     else if (inputSensorInterfaces.size() ==
685                              outputSensorInterfaces.size())
686                     {
687                         /* one to one mapping, each fan sensor gets its own pwm
688                          * control */
689                         singlePwm = false;
690                     }
691                     else
692                     {
693                         throw std::runtime_error(
694                             "fan PID has invalid number of Outputs");
695                     }
696                     std::string fanSensorName;
697                     std::string pwmPath;
698                     std::string pwmInterface;
699                     std::string pwmSensorName;
700                     if (singlePwm)
701                     {
702                         /* if just a single output(pwm) is provided then use
703                          * that pwm control path for all the fan sensor write
704                          * path configs
705                          */
706                         pwmPath = outputSensorInterfaces.at(0).first;
707                         pwmInterface = outputSensorInterfaces.at(0).second;
708                     }
709                     for (uint32_t idx = 0; idx < inputSensorInterfaces.size();
710                          idx++)
711                     {
712                         if (!singlePwm)
713                         {
714                             pwmPath = outputSensorInterfaces.at(idx).first;
715                             pwmInterface =
716                                 outputSensorInterfaces.at(idx).second;
717                         }
718                         if (defaultPwmInterface != pwmInterface)
719                         {
720                             throw std::runtime_error(
721                                 "fan pwm control at dbus path [" + pwmPath +
722                                 "] has an interface [" + pwmInterface +
723                                 "] that does not match the expected interface "
724                                 "of " +
725                                 defaultPwmInterface);
726                         }
727                         const std::string& fanPath =
728                             inputSensorInterfaces.at(idx).first;
729                         fanSensorName = getSensorNameFromPath(fanPath);
730                         pwmSensorName = getSensorNameFromPath(pwmPath);
731                         std::string fanPwmIndex = fanSensorName + pwmSensorName;
732                         inputSensorNames.push_back(fanPwmIndex);
733                         auto& fanConfig = sensorConfig[fanPwmIndex];
734                         fanConfig.type = pidClass;
735                         fanConfig.readPath = fanPath;
736                         fanConfig.writePath = pwmPath;
737                         // todo: un-hardcode this if there are fans with
738                         // different ranges
739                         fanConfig.max = 255;
740                         fanConfig.min = 0;
741                     }
742                 }
743                 // if the sensors aren't available in the current state, don't
744                 // add them to the configuration.
745                 if (inputSensorNames.empty())
746                 {
747                     continue;
748                 }
749 
750                 std::string offsetType;
751 
752                 // SetPointOffset is a threshold value to pull from the sensor
753                 // to apply an offset. For upper thresholds this means the
754                 // setpoint is usually negative.
755                 auto findSetpointOffset = base.find("SetPointOffset");
756                 if (findSetpointOffset != base.end())
757                 {
758                     offsetType =
759                         std::get<std::string>(findSetpointOffset->second);
760                     if (std::find(thresholds::types.begin(),
761                                   thresholds::types.end(),
762                                   offsetType) == thresholds::types.end())
763                     {
764                         throw std::runtime_error("Unsupported type: " +
765                                                  offsetType);
766                     }
767                 }
768 
769                 if (offsetType.empty())
770                 {
771                     conf::ControllerInfo& info =
772                         conf[std::get<std::string>(base.at("Name"))];
773                     info.inputs = std::move(inputSensorNames);
774                     populatePidInfo(bus, base, info, nullptr, sensorConfig);
775                 }
776                 else
777                 {
778                     // we have to split up the inputs, as in practice t-control
779                     // values will differ, making setpoints differ
780                     for (const std::string& input : inputSensorNames)
781                     {
782                         conf::ControllerInfo& info = conf[input];
783                         info.inputs.emplace_back(input);
784                         populatePidInfo(bus, base, info, &offsetType,
785                                         sensorConfig);
786                     }
787                 }
788             }
789         }
790         auto findStepwise =
791             configuration.second.find(stepwiseConfigurationInterface);
792         if (findStepwise != configuration.second.end())
793         {
794             const auto& base = findStepwise->second;
795             const std::vector<std::string>& zones =
796                 std::get<std::vector<std::string>>(base.at("Zones"));
797             for (const std::string& zone : zones)
798             {
799                 auto index = getZoneIndex(zone, foundZones);
800 
801                 conf::PIDConf& conf = zoneConfig[index];
802 
803                 std::vector<std::string> inputs;
804                 std::vector<std::string> sensorNames =
805                     std::get<std::vector<std::string>>(base.at("Inputs"));
806 
807                 bool unavailableAsFailed = true;
808                 auto findUnavailableAsFailed =
809                     base.find("InputUnavailableAsFailed");
810                 if (findUnavailableAsFailed != base.end())
811                 {
812                     unavailableAsFailed =
813                         std::get<bool>(findUnavailableAsFailed->second);
814                 }
815 
816                 bool sensorFound = false;
817                 for (const std::string& sensorName : sensorNames)
818                 {
819                     std::vector<std::pair<std::string, std::string>>
820                         sensorPathIfacePairs;
821                     if (!findSensors(sensors, sensorNameToDbusName(sensorName),
822                                      sensorPathIfacePairs))
823                     {
824                         break;
825                     }
826 
827                     for (const auto& sensorPathIfacePair : sensorPathIfacePairs)
828                     {
829                         size_t idx =
830                             sensorPathIfacePair.first.find_last_of("/") + 1;
831                         std::string shortName =
832                             sensorPathIfacePair.first.substr(idx);
833 
834                         inputs.push_back(shortName);
835                         auto& config = sensorConfig[shortName];
836                         config.readPath = sensorPathIfacePair.first;
837                         config.type = "temp";
838                         config.ignoreDbusMinMax = true;
839                         config.unavailableAsFailed = unavailableAsFailed;
840                         // todo: maybe un-hardcode this if we run into slower
841                         // timeouts with sensors
842 
843                         config.timeout = 0;
844                         sensorFound = true;
845                     }
846                 }
847                 if (!sensorFound)
848                 {
849                     continue;
850                 }
851                 conf::ControllerInfo& info =
852                     conf[std::get<std::string>(base.at("Name"))];
853                 info.inputs = std::move(inputs);
854 
855                 info.type = "stepwise";
856                 info.stepwiseInfo.ts = 1.0; // currently unused
857                 info.stepwiseInfo.positiveHysteresis = 0.0;
858                 info.stepwiseInfo.negativeHysteresis = 0.0;
859                 std::string subtype = std::get<std::string>(base.at("Class"));
860 
861                 info.stepwiseInfo.isCeiling = (subtype == "Ceiling");
862                 auto findPosHyst = base.find("PositiveHysteresis");
863                 auto findNegHyst = base.find("NegativeHysteresis");
864                 if (findPosHyst != base.end())
865                 {
866                     info.stepwiseInfo.positiveHysteresis = std::visit(
867                         VariantToDoubleVisitor(), findPosHyst->second);
868                 }
869                 if (findNegHyst != base.end())
870                 {
871                     info.stepwiseInfo.negativeHysteresis = std::visit(
872                         VariantToDoubleVisitor(), findNegHyst->second);
873                 }
874                 std::vector<double> readings =
875                     std::get<std::vector<double>>(base.at("Reading"));
876                 if (readings.size() > ec::maxStepwisePoints)
877                 {
878                     throw std::invalid_argument("Too many stepwise points.");
879                 }
880                 if (readings.empty())
881                 {
882                     throw std::invalid_argument(
883                         "Must have one stepwise point.");
884                 }
885                 std::copy(readings.begin(), readings.end(),
886                           info.stepwiseInfo.reading);
887                 if (readings.size() < ec::maxStepwisePoints)
888                 {
889                     info.stepwiseInfo.reading[readings.size()] =
890                         std::numeric_limits<double>::quiet_NaN();
891                 }
892                 std::vector<double> outputs =
893                     std::get<std::vector<double>>(base.at("Output"));
894                 if (readings.size() != outputs.size())
895                 {
896                     throw std::invalid_argument(
897                         "Outputs size must match readings");
898                 }
899                 std::copy(outputs.begin(), outputs.end(),
900                           info.stepwiseInfo.output);
901                 if (outputs.size() < ec::maxStepwisePoints)
902                 {
903                     info.stepwiseInfo.output[outputs.size()] =
904                         std::numeric_limits<double>::quiet_NaN();
905                 }
906             }
907         }
908     }
909     if constexpr (pid_control::conf::DEBUG)
910     {
911         debugPrint(sensorConfig, zoneConfig, zoneDetailsConfig);
912     }
913     if (zoneConfig.empty() || zoneDetailsConfig.empty())
914     {
915         std::cerr
916             << "No fan zones, application pausing until new configuration\n";
917         return false;
918     }
919     return true;
920 }
921 
922 } // namespace dbus_configuration
923 } // namespace pid_control
924