1 /** 2 * Copyright © 2019 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 "src.hpp" 17 18 #include "device_callouts.hpp" 19 #include "json_utils.hpp" 20 #include "pel_values.hpp" 21 #ifdef PELTOOL 22 #include <Python.h> 23 24 #include <nlohmann/json.hpp> 25 26 #include <sstream> 27 #endif 28 #include <phosphor-logging/lg2.hpp> 29 30 #include <format> 31 32 namespace openpower 33 { 34 namespace pels 35 { 36 namespace pv = openpower::pels::pel_values; 37 namespace rg = openpower::pels::message; 38 using namespace std::string_literals; 39 40 constexpr size_t ccinSize = 4; 41 42 #ifdef PELTOOL 43 using orderedJSON = nlohmann::ordered_json; 44 45 void pyDecRef(PyObject* pyObj) 46 { 47 Py_XDECREF(pyObj); 48 } 49 50 /** 51 * @brief Returns a JSON string to append to SRC section. 52 * 53 * The returning string will contain a JSON object, but without 54 * the outer {}. If the input JSON isn't a JSON object (dict), then 55 * one will be created with the input added to a 'SRC Details' key. 56 * 57 * @param[in] json - The JSON to convert to a string 58 * 59 * @return std::string - The JSON string 60 */ 61 std::string prettyJSON(const orderedJSON& json) 62 { 63 orderedJSON output; 64 if (!json.is_object()) 65 { 66 output["SRC Details"] = json; 67 } 68 else 69 { 70 for (const auto& [key, value] : json.items()) 71 { 72 output["SRC Details"][key] = value; 73 } 74 } 75 76 // Let nlohmann do the pretty printing. 77 std::stringstream stream; 78 stream << std::setw(4) << output; 79 80 auto jsonString = stream.str(); 81 82 // Now it looks like: 83 // { 84 // "Key": "Value", 85 // ... 86 // } 87 88 // Replace the { and the following newline, and the } and its 89 // preceeding newline. 90 jsonString.erase(0, 2); 91 92 auto pos = jsonString.find_last_of('}'); 93 jsonString.erase(pos - 1); 94 95 return jsonString; 96 } 97 98 /** 99 * @brief Call Python modules to parse the data into a JSON string 100 * 101 * The module to call is based on the Creator Subsystem ID under the namespace 102 * "srcparsers". For example: "srcparsers.xsrc.xsrc" where "x" is the Creator 103 * Subsystem ID in ASCII lowercase. 104 * 105 * All modules must provide the following: 106 * Function: parseSRCToJson 107 * Argument list: 108 * 1. (str) ASCII string (Hex Word 1) 109 * 2. (str) Hex Word 2 110 * 3. (str) Hex Word 3 111 * 4. (str) Hex Word 4 112 * 5. (str) Hex Word 5 113 * 6. (str) Hex Word 6 114 * 7. (str) Hex Word 7 115 * 8. (str) Hex Word 8 116 * 9. (str) Hex Word 9 117 *-Return data: 118 * 1. (str) JSON string 119 * 120 * @param[in] hexwords - Vector of strings of Hexwords 1-9 121 * @param[in] creatorID - The creatorID from the Private Header section 122 * @return std::optional<std::string> - The JSON string if it could be created, 123 * else std::nullopt 124 */ 125 std::optional<std::string> getPythonJSON(std::vector<std::string>& hexwords, 126 uint8_t creatorID) 127 { 128 PyObject *pName, *pModule, *eType, *eValue, *eTraceback; 129 std::string pErrStr; 130 std::string module = getNumberString("%c", tolower(creatorID)) + "src"; 131 pName = PyUnicode_FromString( 132 std::string("srcparsers." + module + "." + module).c_str()); 133 std::unique_ptr<PyObject, decltype(&pyDecRef)> modNamePtr(pName, &pyDecRef); 134 pModule = PyImport_Import(pName); 135 if (pModule == NULL) 136 { 137 pErrStr = "No error string found"; 138 PyErr_Fetch(&eType, &eValue, &eTraceback); 139 if (eType) 140 { 141 Py_XDECREF(eType); 142 } 143 if (eTraceback) 144 { 145 Py_XDECREF(eTraceback); 146 } 147 if (eValue) 148 { 149 PyObject* pStr = PyObject_Str(eValue); 150 Py_XDECREF(eValue); 151 if (pStr) 152 { 153 pErrStr = PyUnicode_AsUTF8(pStr); 154 Py_XDECREF(pStr); 155 } 156 } 157 } 158 else 159 { 160 std::unique_ptr<PyObject, decltype(&pyDecRef)> modPtr( 161 pModule, &pyDecRef); 162 std::string funcToCall = "parseSRCToJson"; 163 PyObject* pKey = PyUnicode_FromString(funcToCall.c_str()); 164 std::unique_ptr<PyObject, decltype(&pyDecRef)> keyPtr(pKey, &pyDecRef); 165 PyObject* pDict = PyModule_GetDict(pModule); 166 Py_INCREF(pDict); 167 if (!PyDict_Contains(pDict, pKey)) 168 { 169 Py_DECREF(pDict); 170 lg2::error( 171 "Python module error. Function missing: {FUNC}, SRC = {SRC}, module = {MODULE}", 172 "FUNC", funcToCall, "SRC", hexwords.front(), "MODULE", module); 173 return std::nullopt; 174 } 175 PyObject* pFunc = PyDict_GetItemString(pDict, funcToCall.c_str()); 176 Py_DECREF(pDict); 177 Py_INCREF(pFunc); 178 if (PyCallable_Check(pFunc)) 179 { 180 PyObject* pArgs = PyTuple_New(9); 181 std::unique_ptr<PyObject, decltype(&pyDecRef)> argPtr( 182 pArgs, &pyDecRef); 183 for (size_t i = 0; i < 9; i++) 184 { 185 std::string arg{"00000000"}; 186 if (i < hexwords.size()) 187 { 188 arg = hexwords[i]; 189 } 190 PyTuple_SetItem(pArgs, i, Py_BuildValue("s", arg.c_str())); 191 } 192 PyObject* pResult = PyObject_CallObject(pFunc, pArgs); 193 Py_DECREF(pFunc); 194 if (pResult) 195 { 196 std::unique_ptr<PyObject, decltype(&pyDecRef)> resPtr( 197 pResult, &pyDecRef); 198 199 if (pResult == Py_None) 200 { 201 return std::nullopt; 202 } 203 204 PyObject* pBytes = 205 PyUnicode_AsEncodedString(pResult, "utf-8", "~E~"); 206 std::unique_ptr<PyObject, decltype(&pyDecRef)> pyBytePtr( 207 pBytes, &pyDecRef); 208 const char* output = PyBytes_AS_STRING(pBytes); 209 try 210 { 211 orderedJSON json = orderedJSON::parse(output); 212 if ((json.is_object() && !json.empty()) || 213 (json.is_array() && json.size() > 0) || 214 (json.is_string() && json != "")) 215 { 216 return prettyJSON(json); 217 } 218 } 219 catch (const std::exception& e) 220 { 221 lg2::error( 222 "Bad JSON from parser. Error = {ERROR}, SRC = {SRC}, module = {MODULE}", 223 "ERROR", e, "SRC", hexwords.front(), "MODULE", module); 224 return std::nullopt; 225 } 226 } 227 else 228 { 229 pErrStr = "No error string found"; 230 PyErr_Fetch(&eType, &eValue, &eTraceback); 231 if (eType) 232 { 233 Py_XDECREF(eType); 234 } 235 if (eTraceback) 236 { 237 Py_XDECREF(eTraceback); 238 } 239 if (eValue) 240 { 241 PyObject* pStr = PyObject_Str(eValue); 242 Py_XDECREF(eValue); 243 if (pStr) 244 { 245 pErrStr = PyUnicode_AsUTF8(pStr); 246 Py_XDECREF(pStr); 247 } 248 } 249 } 250 } 251 } 252 if (!pErrStr.empty()) 253 { 254 lg2::debug("Python exception thrown by parser. Error = {ERROR}, " 255 "SRC = {SRC}, module = {MODULE}", 256 "ERROR", pErrStr, "SRC", hexwords.front(), "MODULE", module); 257 } 258 return std::nullopt; 259 } 260 #endif 261 262 void SRC::unflatten(Stream& stream) 263 { 264 stream >> _header >> _version >> _flags >> _reserved1B >> _wordCount >> 265 _reserved2B >> _size; 266 267 for (auto& word : _hexData) 268 { 269 stream >> word; 270 } 271 272 _asciiString = std::make_unique<src::AsciiString>(stream); 273 274 if (hasAdditionalSections()) 275 { 276 // The callouts section is currently the only extra subsection type 277 _callouts = std::make_unique<src::Callouts>(stream); 278 } 279 } 280 281 void SRC::flatten(Stream& stream) const 282 { 283 stream << _header << _version << _flags << _reserved1B << _wordCount 284 << _reserved2B << _size; 285 286 for (auto& word : _hexData) 287 { 288 stream << word; 289 } 290 291 _asciiString->flatten(stream); 292 293 if (_callouts) 294 { 295 _callouts->flatten(stream); 296 } 297 } 298 299 SRC::SRC(Stream& pel) 300 { 301 try 302 { 303 unflatten(pel); 304 validate(); 305 } 306 catch (const std::exception& e) 307 { 308 lg2::error("Cannot unflatten SRC, error = {ERROR}", "ERROR", e); 309 _valid = false; 310 } 311 } 312 313 SRC::SRC(const message::Entry& regEntry, const AdditionalData& additionalData, 314 const nlohmann::json& jsonCallouts, const DataInterfaceBase& dataIface) 315 { 316 _header.id = static_cast<uint16_t>(SectionID::primarySRC); 317 _header.version = srcSectionVersion; 318 _header.subType = srcSectionSubtype; 319 _header.componentID = regEntry.componentID; 320 321 _version = srcVersion; 322 323 _flags = 0; 324 325 _reserved1B = 0; 326 327 _wordCount = numSRCHexDataWords + 1; 328 329 _reserved2B = 0; 330 331 // There are multiple fields encoded in the hex data words. 332 std::for_each(_hexData.begin(), _hexData.end(), 333 [](auto& word) { word = 0; }); 334 335 // Hex Word 2 Nibbles: 336 // MIGVEPFF 337 // M: Partition dump status = 0 338 // I: System boot state = TODO 339 // G: Partition Boot type = 0 340 // V: BMC dump status 341 // E: Platform boot mode = 0 (side = temporary, speed = fast) 342 // P: Platform dump status 343 // FF: SRC format, set below 344 345 setProgressCode(dataIface); 346 setBMCFormat(); 347 setBMCPosition(); 348 setMotherboardCCIN(dataIface); 349 350 if (regEntry.src.checkstopFlag) 351 { 352 setErrorStatusFlag(ErrorStatusFlags::hwCheckstop); 353 } 354 355 if (regEntry.src.deconfigFlag) 356 { 357 setErrorStatusFlag(ErrorStatusFlags::deconfigured); 358 } 359 360 // Fill in the last 4 words from the AdditionalData property contents. 361 setUserDefinedHexWords(regEntry, additionalData); 362 363 _asciiString = std::make_unique<src::AsciiString>(regEntry); 364 365 // Check for additional data - PEL_SUBSYSTEM 366 auto ss = additionalData.getValue("PEL_SUBSYSTEM"); 367 if (ss) 368 { 369 auto eventSubsystem = std::stoul(*ss, nullptr, 16); 370 std::string subsystem = 371 pv::getValue(eventSubsystem, pel_values::subsystemValues); 372 if (subsystem == "invalid") 373 { 374 lg2::warning("SRC: Invalid SubSystem value: {VAL}", "VAL", lg2::hex, 375 eventSubsystem); 376 } 377 else 378 { 379 _asciiString->setByte(2, eventSubsystem); 380 } 381 } 382 383 addCallouts(regEntry, additionalData, jsonCallouts, dataIface); 384 385 _size = baseSRCSize; 386 _size += _callouts ? _callouts->flattenedSize() : 0; 387 _header.size = Section::headerSize() + _size; 388 389 _valid = true; 390 } 391 392 void SRC::setUserDefinedHexWords(const message::Entry& regEntry, 393 const AdditionalData& ad) 394 { 395 if (!regEntry.src.hexwordADFields) 396 { 397 return; 398 } 399 400 // Save the AdditionalData value corresponding to the first element of 401 // adName tuple into _hexData[wordNum]. 402 for (const auto& [wordNum, adName] : *regEntry.src.hexwordADFields) 403 { 404 // Can only set words 6 - 9 405 if (!isUserDefinedWord(wordNum)) 406 { 407 std::string msg = 408 "SRC user data word out of range: " + std::to_string(wordNum); 409 addDebugData(msg); 410 continue; 411 } 412 413 auto value = ad.getValue(std::get<0>(adName)); 414 if (value) 415 { 416 _hexData[getWordIndexFromWordNum(wordNum)] = 417 std::strtoul(value.value().c_str(), nullptr, 0); 418 } 419 else 420 { 421 std::string msg = "Source for user data SRC word not found: " + 422 std::get<0>(adName); 423 addDebugData(msg); 424 } 425 } 426 } 427 428 void SRC::setMotherboardCCIN(const DataInterfaceBase& dataIface) 429 { 430 uint32_t ccin = 0; 431 auto ccinString = dataIface.getMotherboardCCIN(); 432 433 try 434 { 435 if (ccinString.size() == ccinSize) 436 { 437 ccin = std::stoi(ccinString, nullptr, 16); 438 } 439 } 440 catch (const std::exception& e) 441 { 442 lg2::warning("Could not convert motherboard CCIN {CCIN} to a number", 443 "CCIN", ccinString); 444 return; 445 } 446 447 // Set the first 2 bytes 448 _hexData[1] |= ccin << 16; 449 } 450 451 void SRC::validate() 452 { 453 bool failed = false; 454 455 if ((header().id != static_cast<uint16_t>(SectionID::primarySRC)) && 456 (header().id != static_cast<uint16_t>(SectionID::secondarySRC))) 457 { 458 lg2::error("Invalid SRC section ID: {ID}", "ID", lg2::hex, header().id); 459 failed = true; 460 } 461 462 // Check the version in the SRC, not in the header 463 if (_version != srcVersion) 464 { 465 lg2::error("Invalid SRC version: {VERSION}", "VERSION", lg2::hex, 466 header().version); 467 failed = true; 468 } 469 470 _valid = failed ? false : true; 471 } 472 473 bool SRC::isBMCSRC() const 474 { 475 auto as = asciiString(); 476 if (as.length() >= 2) 477 { 478 uint8_t errorType = strtoul(as.substr(0, 2).c_str(), nullptr, 16); 479 return (errorType == static_cast<uint8_t>(SRCType::bmcError) || 480 errorType == static_cast<uint8_t>(SRCType::powerError)); 481 } 482 return false; 483 } 484 485 bool SRC::isHostbootSRC() const 486 { 487 auto as = asciiString(); 488 if (as.length() >= 2) 489 { 490 uint8_t errorType = strtoul(as.substr(0, 2).c_str(), nullptr, 16); 491 return errorType == static_cast<uint8_t>(SRCType::hostbootError); 492 } 493 return false; 494 } 495 496 std::optional<std::string> SRC::getErrorDetails( 497 message::Registry& registry, DetailLevel type, bool toCache) const 498 { 499 const std::string jsonIndent(indentLevel, 0x20); 500 std::string errorOut; 501 if (isBMCSRC()) 502 { 503 auto entry = registry.lookup("0x" + asciiString().substr(4, 4), 504 rg::LookupType::reasonCode, toCache); 505 if (entry) 506 { 507 errorOut.append(jsonIndent + "\"Error Details\": {\n"); 508 auto errorMsg = getErrorMessage(*entry); 509 if (errorMsg) 510 { 511 if (type == DetailLevel::message) 512 { 513 return errorMsg.value(); 514 } 515 else 516 { 517 jsonInsert(errorOut, "Message", errorMsg.value(), 2); 518 } 519 } 520 if (entry->src.hexwordADFields) 521 { 522 std::map<size_t, std::tuple<std::string, std::string>> 523 adFields = entry->src.hexwordADFields.value(); 524 for (const auto& hexwordMap : adFields) 525 { 526 auto srcValue = getNumberString( 527 "0x%X", 528 _hexData[getWordIndexFromWordNum(hexwordMap.first)]); 529 530 auto srcKey = std::get<0>(hexwordMap.second); 531 auto srcDesc = std::get<1>(hexwordMap.second); 532 533 // Only include this hex word in the error details if the 534 // description exists. 535 if (!srcDesc.empty()) 536 { 537 std::vector<std::string> valueDescr; 538 valueDescr.push_back(srcValue); 539 valueDescr.push_back(srcDesc); 540 jsonInsertArray(errorOut, srcKey, valueDescr, 2); 541 } 542 } 543 } 544 errorOut.erase(errorOut.size() - 2); 545 errorOut.append("\n"); 546 errorOut.append(jsonIndent + "},\n"); 547 return errorOut; 548 } 549 } 550 return std::nullopt; 551 } 552 553 std::optional<std::string> SRC::getErrorMessage( 554 const message::Entry& regEntry) const 555 { 556 try 557 { 558 if (regEntry.doc.messageArgSources) 559 { 560 std::vector<uint32_t> argSourceVals; 561 std::string message; 562 const auto& argValues = regEntry.doc.messageArgSources.value(); 563 for (size_t i = 0; i < argValues.size(); ++i) 564 { 565 argSourceVals.push_back(_hexData[getWordIndexFromWordNum( 566 argValues[i].back() - '0')]); 567 } 568 569 auto it = std::begin(regEntry.doc.message); 570 auto it_end = std::end(regEntry.doc.message); 571 572 while (it != it_end) 573 { 574 if (*it == '%') 575 { 576 ++it; 577 578 size_t wordIndex = *it - '0'; 579 if (isdigit(*it) && wordIndex >= 1 && 580 static_cast<uint16_t>(wordIndex) <= 581 argSourceVals.size()) 582 { 583 message.append(getNumberString( 584 "0x%08X", argSourceVals[wordIndex - 1])); 585 } 586 else 587 { 588 message.append("%" + std::string(1, *it)); 589 } 590 } 591 else 592 { 593 message.push_back(*it); 594 } 595 ++it; 596 } 597 598 return message; 599 } 600 else 601 { 602 return regEntry.doc.message; 603 } 604 } 605 catch (const std::exception& e) 606 { 607 lg2::error( 608 "Cannot get error message from registry entry, error = {ERROR}", 609 "ERROR", e); 610 } 611 return std::nullopt; 612 } 613 614 std::optional<std::string> SRC::getCallouts() const 615 { 616 if (!_callouts) 617 { 618 return std::nullopt; 619 } 620 std::string printOut; 621 const std::string jsonIndent(indentLevel, 0x20); 622 const auto& callout = _callouts->callouts(); 623 const auto& compDescrp = pv::failingComponentType; 624 printOut.append(jsonIndent + "\"Callout Section\": {\n"); 625 jsonInsert(printOut, "Callout Count", std::to_string(callout.size()), 2); 626 printOut.append(jsonIndent + jsonIndent + "\"Callouts\": ["); 627 for (auto& entry : callout) 628 { 629 printOut.append("{\n"); 630 if (entry->fruIdentity()) 631 { 632 jsonInsert( 633 printOut, "FRU Type", 634 compDescrp.at(entry->fruIdentity()->failingComponentType()), 3); 635 jsonInsert(printOut, "Priority", 636 pv::getValue(entry->priority(), 637 pel_values::calloutPriorityValues), 638 3); 639 if (!entry->locationCode().empty()) 640 { 641 jsonInsert(printOut, "Location Code", entry->locationCode(), 3); 642 } 643 if (entry->fruIdentity()->getPN().has_value()) 644 { 645 jsonInsert(printOut, "Part Number", 646 entry->fruIdentity()->getPN().value(), 3); 647 } 648 if (entry->fruIdentity()->getMaintProc().has_value()) 649 { 650 jsonInsert(printOut, "Procedure", 651 entry->fruIdentity()->getMaintProc().value(), 3); 652 if (pv::procedureDesc.find( 653 entry->fruIdentity()->getMaintProc().value()) != 654 pv::procedureDesc.end()) 655 { 656 jsonInsert( 657 printOut, "Description", 658 pv::procedureDesc.at( 659 entry->fruIdentity()->getMaintProc().value()), 660 3); 661 } 662 } 663 if (entry->fruIdentity()->getCCIN().has_value()) 664 { 665 jsonInsert(printOut, "CCIN", 666 entry->fruIdentity()->getCCIN().value(), 3); 667 } 668 if (entry->fruIdentity()->getSN().has_value()) 669 { 670 jsonInsert(printOut, "Serial Number", 671 entry->fruIdentity()->getSN().value(), 3); 672 } 673 } 674 if (entry->pceIdentity()) 675 { 676 const auto& pceIdentMtms = entry->pceIdentity()->mtms(); 677 if (!pceIdentMtms.machineTypeAndModel().empty()) 678 { 679 jsonInsert(printOut, "PCE MTMS", 680 pceIdentMtms.machineTypeAndModel() + "_" + 681 pceIdentMtms.machineSerialNumber(), 682 3); 683 } 684 if (!entry->pceIdentity()->enclosureName().empty()) 685 { 686 jsonInsert(printOut, "PCE Name", 687 entry->pceIdentity()->enclosureName(), 3); 688 } 689 } 690 if (entry->mru()) 691 { 692 const auto& mruCallouts = entry->mru()->mrus(); 693 std::string mruId; 694 for (auto& element : mruCallouts) 695 { 696 if (!mruId.empty()) 697 { 698 mruId.append(", " + getNumberString("%08X", element.id)); 699 } 700 else 701 { 702 mruId.append(getNumberString("%08X", element.id)); 703 } 704 } 705 jsonInsert(printOut, "MRU Id", mruId, 3); 706 } 707 printOut.erase(printOut.size() - 2); 708 printOut.append("\n" + jsonIndent + jsonIndent + "}, "); 709 }; 710 printOut.erase(printOut.size() - 2); 711 printOut.append("]\n" + jsonIndent + "}"); 712 return printOut; 713 } 714 715 std::optional<std::string> SRC::getJSON(message::Registry& registry, 716 const std::vector<std::string>& plugins 717 [[maybe_unused]], 718 uint8_t creatorID) const 719 { 720 std::string ps; 721 std::vector<std::string> hexwords; 722 jsonInsert(ps, pv::sectionVer, getNumberString("%d", _header.version), 1); 723 jsonInsert(ps, pv::subSection, getNumberString("%d", _header.subType), 1); 724 jsonInsert(ps, pv::createdBy, 725 getComponentName(_header.componentID, creatorID), 1); 726 jsonInsert(ps, "SRC Version", getNumberString("0x%02X", _version), 1); 727 jsonInsert(ps, "SRC Format", getNumberString("0x%02X", _hexData[0] & 0xFF), 728 1); 729 jsonInsert(ps, "Virtual Progress SRC", 730 pv::boolString.at(_flags & virtualProgressSRC), 1); 731 jsonInsert(ps, "I5/OS Service Event Bit", 732 pv::boolString.at(_flags & i5OSServiceEventBit), 1); 733 jsonInsert(ps, "Hypervisor Dump Initiated", 734 pv::boolString.at(_flags & hypDumpInit), 1); 735 736 if (isBMCSRC()) 737 { 738 std::string ccinString; 739 uint32_t ccin = _hexData[1] >> 16; 740 741 if (ccin) 742 { 743 ccinString = getNumberString("%04X", ccin); 744 } 745 // The PEL spec calls it a backplane, so call it that here. 746 jsonInsert(ps, "Backplane CCIN", ccinString, 1); 747 748 jsonInsert(ps, "Terminate FW Error", 749 pv::boolString.at( 750 _hexData[3] & 751 static_cast<uint32_t>(ErrorStatusFlags::terminateFwErr)), 752 1); 753 } 754 755 if (isBMCSRC() || isHostbootSRC()) 756 { 757 jsonInsert(ps, "Deconfigured", 758 pv::boolString.at( 759 _hexData[3] & 760 static_cast<uint32_t>(ErrorStatusFlags::deconfigured)), 761 1); 762 763 jsonInsert( 764 ps, "Guarded", 765 pv::boolString.at( 766 _hexData[3] & static_cast<uint32_t>(ErrorStatusFlags::guarded)), 767 1); 768 } 769 770 auto errorDetails = getErrorDetails(registry, DetailLevel::json, true); 771 if (errorDetails) 772 { 773 ps.append(errorDetails.value()); 774 } 775 jsonInsert(ps, "Valid Word Count", getNumberString("0x%02X", _wordCount), 776 1); 777 std::string refcode = asciiString(); 778 hexwords.push_back(refcode); 779 std::string extRefcode; 780 size_t pos = refcode.find(0x20); 781 if (pos != std::string::npos) 782 { 783 size_t nextPos = refcode.find_first_not_of(0x20, pos); 784 if (nextPos != std::string::npos) 785 { 786 extRefcode = trimEnd(refcode.substr(nextPos)); 787 } 788 refcode.erase(pos); 789 } 790 jsonInsert(ps, "Reference Code", refcode, 1); 791 if (!extRefcode.empty()) 792 { 793 jsonInsert(ps, "Extended Reference Code", extRefcode, 1); 794 } 795 for (size_t i = 2; i <= _wordCount; i++) 796 { 797 std::string tmpWord = 798 getNumberString("%08X", _hexData[getWordIndexFromWordNum(i)]); 799 jsonInsert(ps, "Hex Word " + std::to_string(i), tmpWord, 1); 800 hexwords.push_back(tmpWord); 801 } 802 auto calloutJson = getCallouts(); 803 if (calloutJson) 804 { 805 ps.append(calloutJson.value()); 806 ps.append(",\n"); 807 } 808 std::string subsystem = getNumberString("%c", tolower(creatorID)); 809 bool srcDetailExists = false; 810 #ifdef PELTOOL 811 if (std::find(plugins.begin(), plugins.end(), subsystem + "src") != 812 plugins.end()) 813 { 814 auto pyJson = getPythonJSON(hexwords, creatorID); 815 if (pyJson) 816 { 817 ps.append(pyJson.value()); 818 srcDetailExists = true; 819 } 820 } 821 #endif 822 if (!srcDetailExists) 823 { 824 ps.erase(ps.size() - 2); 825 } 826 return ps; 827 } 828 829 void SRC::addCallouts(const message::Entry& regEntry, 830 const AdditionalData& additionalData, 831 const nlohmann::json& jsonCallouts, 832 const DataInterfaceBase& dataIface) 833 { 834 auto registryCallouts = 835 getRegistryCallouts(regEntry, additionalData, dataIface); 836 837 auto item = additionalData.getValue("CALLOUT_INVENTORY_PATH"); 838 auto priority = additionalData.getValue("CALLOUT_PRIORITY"); 839 840 std::optional<CalloutPriority> calloutPriority; 841 842 // Only H, M or L priority values. 843 if (priority && !(*priority).empty()) 844 { 845 uint8_t p = (*priority)[0]; 846 if (p == 'H' || p == 'M' || p == 'L') 847 { 848 calloutPriority = static_cast<CalloutPriority>(p); 849 } 850 } 851 // If the first registry callout says to use the passed in inventory 852 // path to get the location code for a symbolic FRU callout with a 853 // trusted location code, then do not add the inventory path as a 854 // normal FRU callout. 855 bool useInvForSymbolicFRULocCode = 856 !registryCallouts.empty() && registryCallouts[0].useInventoryLocCode && 857 !registryCallouts[0].symbolicFRUTrusted.empty(); 858 859 if (item && !useInvForSymbolicFRULocCode) 860 { 861 addInventoryCallout(*item, calloutPriority, std::nullopt, dataIface); 862 } 863 864 addDevicePathCallouts(additionalData, dataIface); 865 866 addRegistryCallouts(registryCallouts, dataIface, 867 (useInvForSymbolicFRULocCode) ? item : std::nullopt); 868 869 if (!jsonCallouts.empty()) 870 { 871 addJSONCallouts(jsonCallouts, dataIface); 872 } 873 } 874 875 void SRC::addLocationCodeOnlyCallout(const std::string& locationCode, 876 const CalloutPriority priority) 877 { 878 std::string empty; 879 std::vector<src::MRU::MRUCallout> mrus; 880 auto callout = std::make_unique<src::Callout>(priority, locationCode, empty, 881 empty, empty, mrus); 882 createCalloutsObject(); 883 _callouts->addCallout(std::move(callout)); 884 } 885 886 void SRC::addInventoryCallout(const std::string& inventoryPath, 887 const std::optional<CalloutPriority>& priority, 888 const std::optional<std::string>& locationCode, 889 const DataInterfaceBase& dataIface, 890 const std::vector<src::MRU::MRUCallout>& mrus) 891 { 892 std::string locCode; 893 std::string fn; 894 std::string ccin; 895 std::string sn; 896 std::unique_ptr<src::Callout> callout; 897 898 try 899 { 900 // Use the passed in location code if there otherwise look it up 901 if (locationCode) 902 { 903 locCode = *locationCode; 904 } 905 else 906 { 907 locCode = dataIface.getLocationCode(inventoryPath); 908 } 909 910 try 911 { 912 dataIface.getHWCalloutFields(inventoryPath, fn, ccin, sn); 913 914 CalloutPriority p = 915 priority ? priority.value() : CalloutPriority::high; 916 917 callout = 918 std::make_unique<src::Callout>(p, locCode, fn, ccin, sn, mrus); 919 } 920 catch (const sdbusplus::exception_t& e) 921 { 922 std::string msg = 923 "No VPD found for " + inventoryPath + ": " + e.what(); 924 addDebugData(msg); 925 926 // Just create the callout with empty FRU fields 927 callout = std::make_unique<src::Callout>( 928 CalloutPriority::high, locCode, fn, ccin, sn, mrus); 929 } 930 } 931 catch (const sdbusplus::exception_t& e) 932 { 933 std::string msg = "Could not get location code for " + inventoryPath + 934 ": " + e.what(); 935 addDebugData(msg); 936 937 // Don't add a callout in this case, because: 938 // 1) With how the inventory is primed, there is no case where 939 // a location code is expected to be missing. This implies 940 // the caller is passing in something invalid. 941 // 2) The addDebugData call above will put the passed in path into 942 // a user data section that can be seen by development for debug. 943 // 3) Even if we wanted to do a 'no_vpd_for_fru' sort of maint. 944 // procedure, we don't have a good way to indicate to the user 945 // anything about the intended callout (they won't see user data). 946 // 4) Creating a new standalone event log for this problem isn't 947 // possible from inside a PEL section. 948 } 949 950 if (callout) 951 { 952 createCalloutsObject(); 953 _callouts->addCallout(std::move(callout)); 954 } 955 } 956 957 std::vector<message::RegistryCallout> SRC::getRegistryCallouts( 958 const message::Entry& regEntry, const AdditionalData& additionalData, 959 const DataInterfaceBase& dataIface) 960 { 961 std::vector<message::RegistryCallout> registryCallouts; 962 963 if (regEntry.callouts) 964 { 965 std::vector<std::string> systemNames; 966 967 try 968 { 969 systemNames = dataIface.getSystemNames(); 970 } 971 catch (const std::exception& e) 972 { 973 // Compatible interface not available yet 974 } 975 976 try 977 { 978 registryCallouts = message::Registry::getCallouts( 979 regEntry.callouts.value(), systemNames, additionalData); 980 } 981 catch (const std::exception& e) 982 { 983 addDebugData(std::format( 984 "Error parsing PEL message registry callout JSON: {}", 985 e.what())); 986 } 987 } 988 989 return registryCallouts; 990 } 991 992 void SRC::addRegistryCallouts( 993 const std::vector<message::RegistryCallout>& callouts, 994 const DataInterfaceBase& dataIface, 995 std::optional<std::string> trustedSymbolicFRUInvPath) 996 { 997 try 998 { 999 for (const auto& callout : callouts) 1000 { 1001 addRegistryCallout(callout, dataIface, trustedSymbolicFRUInvPath); 1002 1003 // Only the first callout gets the inventory path 1004 if (trustedSymbolicFRUInvPath) 1005 { 1006 trustedSymbolicFRUInvPath = std::nullopt; 1007 } 1008 } 1009 } 1010 catch (const std::exception& e) 1011 { 1012 std::string msg = 1013 "Error parsing PEL message registry callout JSON: "s + e.what(); 1014 addDebugData(msg); 1015 } 1016 } 1017 1018 void SRC::addRegistryCallout( 1019 const message::RegistryCallout& regCallout, 1020 const DataInterfaceBase& dataIface, 1021 const std::optional<std::string>& trustedSymbolicFRUInvPath) 1022 { 1023 std::unique_ptr<src::Callout> callout; 1024 auto locCode = regCallout.locCode; 1025 bool locExpanded = true; 1026 1027 if (!locCode.empty()) 1028 { 1029 try 1030 { 1031 locCode = dataIface.expandLocationCode(locCode, 0); 1032 } 1033 catch (const std::exception& e) 1034 { 1035 auto msg = "Unable to expand location code " + locCode + ": " + 1036 e.what(); 1037 addDebugData(msg); 1038 locExpanded = false; 1039 } 1040 } 1041 1042 // Via the PEL values table, get the priority enum. 1043 // The schema will have validated the priority was a valid value. 1044 auto priorityIt = 1045 pv::findByName(regCallout.priority, pv::calloutPriorityValues); 1046 assert(priorityIt != pv::calloutPriorityValues.end()); 1047 auto priority = 1048 static_cast<CalloutPriority>(std::get<pv::fieldValuePos>(*priorityIt)); 1049 1050 if (!regCallout.procedure.empty()) 1051 { 1052 // Procedure callout 1053 callout = std::make_unique<src::Callout>(priority, regCallout.procedure, 1054 src::CalloutValueType::raw); 1055 } 1056 else if (!regCallout.symbolicFRU.empty()) 1057 { 1058 // Symbolic FRU callout 1059 callout = std::make_unique<src::Callout>( 1060 priority, regCallout.symbolicFRU, locCode, false); 1061 } 1062 else if (!regCallout.symbolicFRUTrusted.empty()) 1063 { 1064 // Symbolic FRU with trusted location code callout 1065 bool trusted = false; 1066 1067 // Use the location code from the inventory path if there is one. 1068 if (trustedSymbolicFRUInvPath) 1069 { 1070 try 1071 { 1072 locCode = dataIface.getLocationCode(*trustedSymbolicFRUInvPath); 1073 trusted = true; 1074 } 1075 catch (const std::exception& e) 1076 { 1077 addDebugData( 1078 std::format("Could not get location code for {}: {}", 1079 *trustedSymbolicFRUInvPath, e.what())); 1080 locCode.clear(); 1081 } 1082 } 1083 1084 // Can only trust the location code if it isn't empty and is expanded. 1085 if (!locCode.empty() && locExpanded) 1086 { 1087 trusted = true; 1088 } 1089 1090 // The registry wants it to be trusted, but that requires a valid 1091 // location code for it to actually be. 1092 callout = std::make_unique<src::Callout>( 1093 priority, regCallout.symbolicFRUTrusted, locCode, trusted); 1094 } 1095 else 1096 { 1097 // A hardware callout 1098 1099 // If couldn't expand the location code, don't bother 1100 // looking up the inventory path. 1101 if (!locExpanded && !locCode.empty()) 1102 { 1103 addLocationCodeOnlyCallout(locCode, priority); 1104 return; 1105 } 1106 1107 std::vector<std::string> inventoryPaths; 1108 1109 try 1110 { 1111 // Get the inventory item from the unexpanded location code 1112 inventoryPaths = 1113 dataIface.getInventoryFromLocCode(regCallout.locCode, 0, false); 1114 } 1115 catch (const std::exception& e) 1116 { 1117 std::string msg = 1118 "Unable to get inventory path from location code: " + locCode + 1119 ": " + e.what(); 1120 addDebugData(msg); 1121 if (!locCode.empty()) 1122 { 1123 // Still add a callout with just the location code. 1124 addLocationCodeOnlyCallout(locCode, priority); 1125 } 1126 return; 1127 } 1128 1129 // Just use first path returned since they all point to the same FRU. 1130 addInventoryCallout(inventoryPaths[0], priority, locCode, dataIface); 1131 } 1132 1133 if (callout) 1134 { 1135 createCalloutsObject(); 1136 _callouts->addCallout(std::move(callout)); 1137 } 1138 } 1139 1140 void SRC::addDevicePathCallouts(const AdditionalData& additionalData, 1141 const DataInterfaceBase& dataIface) 1142 { 1143 std::vector<device_callouts::Callout> callouts; 1144 auto i2cBus = additionalData.getValue("CALLOUT_IIC_BUS"); 1145 auto i2cAddr = additionalData.getValue("CALLOUT_IIC_ADDR"); 1146 auto devPath = additionalData.getValue("CALLOUT_DEVICE_PATH"); 1147 1148 // A device callout contains either: 1149 // * CALLOUT_ERRNO, CALLOUT_DEVICE_PATH 1150 // * CALLOUT_ERRNO, CALLOUT_IIC_BUS, CALLOUT_IIC_ADDR 1151 // We don't care about the errno. 1152 1153 if (devPath) 1154 { 1155 try 1156 { 1157 callouts = device_callouts::getCallouts(*devPath, 1158 dataIface.getSystemNames()); 1159 } 1160 catch (const std::exception& e) 1161 { 1162 addDebugData(e.what()); 1163 callouts.clear(); 1164 } 1165 } 1166 else if (i2cBus && i2cAddr) 1167 { 1168 size_t bus; 1169 uint8_t address; 1170 1171 try 1172 { 1173 // If /dev/i2c- is prepended, remove it 1174 if (i2cBus->find("/dev/i2c-") != std::string::npos) 1175 { 1176 *i2cBus = i2cBus->substr(9); 1177 } 1178 1179 bus = stoul(*i2cBus, nullptr, 0); 1180 address = stoul(*i2cAddr, nullptr, 0); 1181 } 1182 catch (const std::exception& e) 1183 { 1184 std::string msg = 1185 "Invalid CALLOUT_IIC_BUS " + *i2cBus + " or CALLOUT_IIC_ADDR " + 1186 *i2cAddr + " in AdditionalData property"; 1187 addDebugData(msg); 1188 return; 1189 } 1190 1191 try 1192 { 1193 callouts = device_callouts::getI2CCallouts( 1194 bus, address, dataIface.getSystemNames()); 1195 } 1196 catch (const std::exception& e) 1197 { 1198 addDebugData(e.what()); 1199 callouts.clear(); 1200 } 1201 } 1202 1203 for (const auto& callout : callouts) 1204 { 1205 // The priority shouldn't be invalid, but check just in case. 1206 CalloutPriority priority = CalloutPriority::high; 1207 1208 if (!callout.priority.empty()) 1209 { 1210 auto p = pel_values::findByValue( 1211 static_cast<uint32_t>(callout.priority[0]), 1212 pel_values::calloutPriorityValues); 1213 1214 if (p != pel_values::calloutPriorityValues.end()) 1215 { 1216 priority = static_cast<CalloutPriority>(callout.priority[0]); 1217 } 1218 else 1219 { 1220 auto msg = 1221 std::string{ 1222 "Invalid priority found in dev callout JSON: "} + 1223 callout.priority[0]; 1224 addDebugData(msg); 1225 } 1226 } 1227 1228 std::optional<std::string> locCode; 1229 1230 try 1231 { 1232 locCode = dataIface.expandLocationCode(callout.locationCode, 0); 1233 } 1234 catch (const std::exception& e) 1235 { 1236 auto msg = std::format("Unable to expand location code {}: {}", 1237 callout.locationCode, e.what()); 1238 addDebugData(msg); 1239 1240 // Add the callout with just the unexpanded location code. 1241 addLocationCodeOnlyCallout(callout.locationCode, priority); 1242 continue; 1243 } 1244 1245 try 1246 { 1247 auto inventoryPaths = dataIface.getInventoryFromLocCode( 1248 callout.locationCode, 0, false); 1249 1250 // Just use first path returned since they all 1251 // point to the same FRU. 1252 addInventoryCallout(inventoryPaths[0], priority, locCode, 1253 dataIface); 1254 } 1255 catch (const std::exception& e) 1256 { 1257 std::string msg = 1258 "Unable to get inventory path from location code: " + 1259 callout.locationCode + ": " + e.what(); 1260 addDebugData(msg); 1261 // Add the callout with just the location code. 1262 addLocationCodeOnlyCallout(callout.locationCode, priority); 1263 continue; 1264 } 1265 1266 // Until the code is there to convert these MRU value strings to 1267 // the official MRU values in the callout objects, just store 1268 // the MRU name in the debug UserData section. 1269 if (!callout.mru.empty()) 1270 { 1271 std::string msg = "MRU: " + callout.mru; 1272 addDebugData(msg); 1273 } 1274 1275 // getCallouts() may have generated some debug data it stored 1276 // in a callout object. Save it as well. 1277 if (!callout.debug.empty()) 1278 { 1279 addDebugData(callout.debug); 1280 } 1281 } 1282 } 1283 1284 void SRC::addJSONCallouts(const nlohmann::json& jsonCallouts, 1285 const DataInterfaceBase& dataIface) 1286 { 1287 if (jsonCallouts.empty()) 1288 { 1289 return; 1290 } 1291 1292 if (!jsonCallouts.is_array()) 1293 { 1294 addDebugData("Callout JSON isn't an array"); 1295 return; 1296 } 1297 1298 for (const auto& callout : jsonCallouts) 1299 { 1300 try 1301 { 1302 addJSONCallout(callout, dataIface); 1303 } 1304 catch (const std::exception& e) 1305 { 1306 addDebugData(std::format( 1307 "Failed extracting callout data from JSON: {}", e.what())); 1308 } 1309 } 1310 } 1311 1312 void SRC::addJSONCallout(const nlohmann::json& jsonCallout, 1313 const DataInterfaceBase& dataIface) 1314 { 1315 auto priority = getPriorityFromJSON(jsonCallout); 1316 std::string locCode; 1317 std::string unexpandedLocCode; 1318 std::unique_ptr<src::Callout> callout; 1319 1320 // Expand the location code if it's there 1321 if (jsonCallout.contains("LocationCode")) 1322 { 1323 unexpandedLocCode = jsonCallout.at("LocationCode").get<std::string>(); 1324 1325 try 1326 { 1327 locCode = dataIface.expandLocationCode(unexpandedLocCode, 0); 1328 } 1329 catch (const std::exception& e) 1330 { 1331 addDebugData(std::format("Unable to expand location code {}: {}", 1332 unexpandedLocCode, e.what())); 1333 // Use the value from the JSON so at least there's something 1334 locCode = unexpandedLocCode; 1335 } 1336 } 1337 1338 // Create either a procedure, symbolic FRU, or normal FRU callout. 1339 if (jsonCallout.contains("Procedure")) 1340 { 1341 auto procedure = jsonCallout.at("Procedure").get<std::string>(); 1342 1343 // If it's the registry name instead of the raw name, convert. 1344 if (pv::maintenanceProcedures.find(procedure) != 1345 pv::maintenanceProcedures.end()) 1346 { 1347 procedure = pv::maintenanceProcedures.at(procedure); 1348 } 1349 1350 callout = std::make_unique<src::Callout>( 1351 static_cast<CalloutPriority>(priority), procedure, 1352 src::CalloutValueType::raw); 1353 } 1354 else if (jsonCallout.contains("SymbolicFRU")) 1355 { 1356 auto fru = jsonCallout.at("SymbolicFRU").get<std::string>(); 1357 1358 // If it's the registry name instead of the raw name, convert. 1359 if (pv::symbolicFRUs.find(fru) != pv::symbolicFRUs.end()) 1360 { 1361 fru = pv::symbolicFRUs.at(fru); 1362 } 1363 1364 bool trusted = false; 1365 if (jsonCallout.contains("TrustedLocationCode") && !locCode.empty()) 1366 { 1367 trusted = jsonCallout.at("TrustedLocationCode").get<bool>(); 1368 } 1369 1370 callout = std::make_unique<src::Callout>( 1371 static_cast<CalloutPriority>(priority), fru, 1372 src::CalloutValueType::raw, locCode, trusted); 1373 } 1374 else 1375 { 1376 // A hardware FRU 1377 std::string inventoryPath; 1378 std::vector<src::MRU::MRUCallout> mrus; 1379 1380 if (jsonCallout.contains("InventoryPath")) 1381 { 1382 inventoryPath = jsonCallout.at("InventoryPath").get<std::string>(); 1383 } 1384 else 1385 { 1386 if (unexpandedLocCode.empty()) 1387 { 1388 throw std::runtime_error{"JSON callout needs either an " 1389 "inventory path or location code"}; 1390 } 1391 1392 try 1393 { 1394 auto inventoryPaths = dataIface.getInventoryFromLocCode( 1395 unexpandedLocCode, 0, false); 1396 // Just use first path returned since they all 1397 // point to the same FRU. 1398 inventoryPath = inventoryPaths[0]; 1399 } 1400 catch (const std::exception& e) 1401 { 1402 addDebugData(std::format("Unable to get inventory path from " 1403 "location code: {}: {}", 1404 unexpandedLocCode, e.what())); 1405 addLocationCodeOnlyCallout(locCode, priority); 1406 return; 1407 } 1408 } 1409 1410 if (jsonCallout.contains("MRUs")) 1411 { 1412 mrus = getMRUsFromJSON(jsonCallout.at("MRUs")); 1413 } 1414 1415 // If the location code was also passed in, use that here too 1416 // so addInventoryCallout doesn't have to look it up. 1417 std::optional<std::string> lc; 1418 if (!locCode.empty()) 1419 { 1420 lc = locCode; 1421 } 1422 1423 addInventoryCallout(inventoryPath, priority, lc, dataIface, mrus); 1424 1425 if (jsonCallout.contains("Deconfigured")) 1426 { 1427 if (jsonCallout.at("Deconfigured").get<bool>()) 1428 { 1429 setErrorStatusFlag(ErrorStatusFlags::deconfigured); 1430 } 1431 } 1432 1433 if (jsonCallout.contains("Guarded")) 1434 { 1435 if (jsonCallout.at("Guarded").get<bool>()) 1436 { 1437 setErrorStatusFlag(ErrorStatusFlags::guarded); 1438 } 1439 } 1440 } 1441 1442 if (callout) 1443 { 1444 createCalloutsObject(); 1445 _callouts->addCallout(std::move(callout)); 1446 } 1447 } 1448 1449 CalloutPriority SRC::getPriorityFromJSON(const nlohmann::json& json) 1450 { 1451 // Looks like: 1452 // { 1453 // "Priority": "H" 1454 // } 1455 auto p = json.at("Priority").get<std::string>(); 1456 if (p.empty()) 1457 { 1458 throw std::runtime_error{"Priority field in callout is empty"}; 1459 } 1460 1461 auto priority = static_cast<CalloutPriority>(p.front()); 1462 1463 // Validate it 1464 auto priorityIt = pv::findByValue(static_cast<uint32_t>(priority), 1465 pv::calloutPriorityValues); 1466 if (priorityIt == pv::calloutPriorityValues.end()) 1467 { 1468 throw std::runtime_error{ 1469 std::format("Invalid priority '{}' found in JSON callout", p)}; 1470 } 1471 1472 return priority; 1473 } 1474 1475 std::vector<src::MRU::MRUCallout> SRC::getMRUsFromJSON( 1476 const nlohmann::json& mruJSON) 1477 { 1478 std::vector<src::MRU::MRUCallout> mrus; 1479 1480 // Looks like: 1481 // [ 1482 // { 1483 // "ID": 100, 1484 // "Priority": "H" 1485 // } 1486 // ] 1487 if (!mruJSON.is_array()) 1488 { 1489 addDebugData("MRU callout JSON is not an array"); 1490 return mrus; 1491 } 1492 1493 for (const auto& mruCallout : mruJSON) 1494 { 1495 try 1496 { 1497 auto priority = getPriorityFromJSON(mruCallout); 1498 auto id = mruCallout.at("ID").get<uint32_t>(); 1499 1500 src::MRU::MRUCallout mru{static_cast<uint32_t>(priority), id}; 1501 mrus.push_back(std::move(mru)); 1502 } 1503 catch (const std::exception& e) 1504 { 1505 addDebugData(std::format("Invalid MRU entry in JSON: {}: {}", 1506 mruCallout.dump(), e.what())); 1507 } 1508 } 1509 1510 return mrus; 1511 } 1512 1513 std::vector<uint8_t> SRC::getSrcStruct() 1514 { 1515 std::vector<uint8_t> data; 1516 Stream stream{data}; 1517 1518 //------ Ref section 4.3 in PEL doc--- 1519 //------ SRC Structure 40 bytes------- 1520 // Byte-0 | Byte-1 | Byte-2 | Byte-3 | 1521 // ----------------------------------- 1522 // 02 | 08 | 00 | 09 | ==> Header 1523 // 00 | 00 | 00 | 48 | ==> Header 1524 // 00 | 00 | 00 | 00 | ==> Hex data word-2 1525 // 00 | 00 | 00 | 00 | ==> Hex data word-3 1526 // 00 | 00 | 00 | 00 | ==> Hex data word-4 1527 // 20 | 00 | 00 | 00 | ==> Hex data word-5 1528 // 00 | 00 | 00 | 00 | ==> Hex data word-6 1529 // 00 | 00 | 00 | 00 | ==> Hex data word-7 1530 // 00 | 00 | 00 | 00 | ==> Hex data word-8 1531 // 00 | 00 | 00 | 00 | ==> Hex data word-9 1532 // ----------------------------------- 1533 // ASCII string - 8 bytes | 1534 // ----------------------------------- 1535 // ASCII space NULL - 24 bytes | 1536 // ----------------------------------- 1537 //_size = Base SRC struct: 8 byte header + hex data section + ASCII string 1538 1539 uint8_t flags = (_flags | postOPPanel); 1540 1541 stream << _version << flags << _reserved1B << _wordCount << _reserved2B 1542 << _size; 1543 1544 for (auto& word : _hexData) 1545 { 1546 stream << word; 1547 } 1548 1549 _asciiString->flatten(stream); 1550 1551 return data; 1552 } 1553 1554 void SRC::setProgressCode(const DataInterfaceBase& dataIface) 1555 { 1556 std::vector<uint8_t> progressSRC; 1557 1558 try 1559 { 1560 progressSRC = dataIface.getRawProgressSRC(); 1561 } 1562 catch (const std::exception& e) 1563 { 1564 lg2::error("Error getting progress code: {ERROR}", "ERROR", e); 1565 return; 1566 } 1567 1568 _hexData[2] = getProgressCode(progressSRC); 1569 } 1570 1571 uint32_t SRC::getProgressCode(std::vector<uint8_t>& rawProgressSRC) 1572 { 1573 uint32_t progressCode = 0; 1574 1575 // A valid progress SRC is at least 72 bytes 1576 if (rawProgressSRC.size() < 72) 1577 { 1578 return progressCode; 1579 } 1580 1581 try 1582 { 1583 // The ASCII string field in progress SRCs starts at offset 40. 1584 // Take the first 8 characters to put in the uint32: 1585 // "CC009189" -> 0xCC009189 1586 Stream stream{rawProgressSRC, 40}; 1587 src::AsciiString aString{stream}; 1588 auto progressCodeString = aString.get().substr(0, 8); 1589 1590 if (std::all_of(progressCodeString.begin(), progressCodeString.end(), 1591 [](char c) { 1592 return std::isxdigit(static_cast<unsigned char>(c)); 1593 })) 1594 { 1595 progressCode = std::stoul(progressCodeString, nullptr, 16); 1596 } 1597 } 1598 catch (const std::exception& e) 1599 {} 1600 1601 return progressCode; 1602 } 1603 1604 } // namespace pels 1605 } // namespace openpower 1606