1 #include "pldm_fw_update_cmd.hpp" 2 3 #include "common/utils.hpp" 4 #include "pldm_cmd_helper.hpp" 5 6 #include <libpldm/firmware_update.h> 7 8 namespace pldmtool 9 { 10 11 namespace fw_update 12 { 13 14 namespace 15 { 16 17 using namespace pldmtool::helper; 18 using namespace pldm::fw_update; 19 20 std::vector<std::unique_ptr<CommandInterface>> commands; 21 22 } // namespace 23 24 const std::map<uint8_t, std::string> fdStateMachine{ 25 {PLDM_FD_STATE_IDLE, "IDLE"}, 26 {PLDM_FD_STATE_LEARN_COMPONENTS, "LEARN COMPONENTS"}, 27 {PLDM_FD_STATE_READY_XFER, "READY XFER"}, 28 {PLDM_FD_STATE_DOWNLOAD, "DOWNLOAD"}, 29 {PLDM_FD_STATE_VERIFY, "VERIFY"}, 30 {PLDM_FD_STATE_APPLY, "APPLY"}, 31 {PLDM_FD_STATE_ACTIVATE, "ACTIVATE"}}; 32 33 const std::map<uint8_t, const char*> fdAuxState{ 34 {PLDM_FD_OPERATION_IN_PROGRESS, "Operation in progress"}, 35 {PLDM_FD_OPERATION_SUCCESSFUL, "Operation successful"}, 36 {PLDM_FD_OPERATION_FAILED, "Operation Failed"}, 37 {PLDM_FD_IDLE_LEARN_COMPONENTS_READ_XFER, 38 "Not applicable in current state"}}; 39 40 const std::map<uint8_t, const char*> fdAuxStateStatus{ 41 {PLDM_FD_AUX_STATE_IN_PROGRESS_OR_SUCCESS, 42 "AuxState is In Progress or Success"}, 43 {PLDM_FD_TIMEOUT, "Timeout occurred while performing action"}, 44 {PLDM_FD_GENERIC_ERROR, "Generic Error has occurred"}}; 45 46 const std::map<uint8_t, const char*> fdReasonCode{ 47 {PLDM_FD_INITIALIZATION, "Initialization of firmware device has occurred"}, 48 {PLDM_FD_ACTIVATE_FW, "ActivateFirmware command was received"}, 49 {PLDM_FD_CANCEL_UPDATE, "CancelUpdate command was received"}, 50 {PLDM_FD_TIMEOUT_LEARN_COMPONENT, 51 "Timeout occurred when in LEARN COMPONENT state"}, 52 {PLDM_FD_TIMEOUT_READY_XFER, "Timeout occurred when in READY XFER state"}, 53 {PLDM_FD_TIMEOUT_DOWNLOAD, "Timeout occurred when in DOWNLOAD state"}, 54 {PLDM_FD_TIMEOUT_VERIFY, "Timeout occurred when in VERIFY state"}, 55 {PLDM_FD_TIMEOUT_APPLY, "Timeout occurred when in APPLY state"}}; 56 57 /** 58 * @brief descriptor type to name mapping 59 * 60 */ 61 const std::map<DescriptorType, const char*> descriptorName{ 62 {PLDM_FWUP_PCI_VENDOR_ID, "PCI Vendor ID"}, 63 {PLDM_FWUP_IANA_ENTERPRISE_ID, "IANA Enterprise ID"}, 64 {PLDM_FWUP_UUID, "UUID"}, 65 {PLDM_FWUP_PNP_VENDOR_ID, "PnP Vendor ID"}, 66 {PLDM_FWUP_ACPI_VENDOR_ID, "ACPI Vendor ID"}, 67 {PLDM_FWUP_PCI_DEVICE_ID, "PCI Device ID"}, 68 {PLDM_FWUP_PCI_SUBSYSTEM_VENDOR_ID, "PCI Subsystem Vendor ID"}, 69 {PLDM_FWUP_PCI_SUBSYSTEM_ID, "PCI Subsystem ID"}, 70 {PLDM_FWUP_PCI_REVISION_ID, "PCI Revision ID"}, 71 {PLDM_FWUP_PNP_PRODUCT_IDENTIFIER, "PnP Product Identifier"}, 72 {PLDM_FWUP_ACPI_PRODUCT_IDENTIFIER, "ACPI Product Identifier"}, 73 {PLDM_FWUP_VENDOR_DEFINED, "Vendor Defined"}}; 74 75 class GetStatus : public CommandInterface 76 { 77 public: 78 ~GetStatus() = default; 79 GetStatus() = delete; 80 GetStatus(const GetStatus&) = delete; 81 GetStatus(GetStatus&&) = default; 82 GetStatus& operator=(const GetStatus&) = delete; 83 GetStatus& operator=(GetStatus&&) = delete; 84 85 using CommandInterface::CommandInterface; 86 87 std::pair<int, std::vector<uint8_t>> createRequestMsg() override 88 { 89 std::vector<uint8_t> requestMsg(sizeof(pldm_msg_hdr) + 90 PLDM_GET_STATUS_REQ_BYTES); 91 auto request = reinterpret_cast<pldm_msg*>(requestMsg.data()); 92 auto rc = encode_get_status_req(instanceId, request, 93 PLDM_GET_STATUS_REQ_BYTES); 94 return {rc, requestMsg}; 95 } 96 97 void parseResponseMsg(pldm_msg* responsePtr, size_t payloadLength) override 98 { 99 uint8_t completionCode = 0; 100 uint8_t currentState = 0; 101 uint8_t previousState = 0; 102 uint8_t auxState = 0; 103 uint8_t auxStateStatus = 0; 104 uint8_t progressPercent = 0; 105 uint8_t reasonCode = 0; 106 bitfield32_t updateOptionFlagsEnabled{0}; 107 108 auto rc = decode_get_status_resp( 109 responsePtr, payloadLength, &completionCode, ¤tState, 110 &previousState, &auxState, &auxStateStatus, &progressPercent, 111 &reasonCode, &updateOptionFlagsEnabled); 112 if (rc != PLDM_SUCCESS || completionCode != PLDM_SUCCESS) 113 { 114 std::cerr << "Response Message Error: " 115 << "rc=" << rc << ",cc=" << (int)completionCode << "\n"; 116 return; 117 } 118 119 ordered_json data; 120 data["CurrentState"] = fdStateMachine.at(currentState); 121 data["PreviousState"] = fdStateMachine.at(previousState); 122 data["AuxState"] = fdAuxState.at(auxState); 123 if (auxStateStatus >= PLDM_FD_VENDOR_DEFINED_STATUS_CODE_START && 124 auxStateStatus <= PLDM_FD_VENDOR_DEFINED_STATUS_CODE_END) 125 { 126 data["AuxStateStatus"] = auxStateStatus; 127 } 128 else 129 { 130 data["AuxStateStatus"] = fdAuxStateStatus.at(auxStateStatus); 131 } 132 data["ProgressPercent"] = progressPercent; 133 if (reasonCode >= PLDM_FD_STATUS_VENDOR_DEFINED_MIN && 134 reasonCode <= PLDM_FD_STATUS_VENDOR_DEFINED_MAX) 135 { 136 data["ReasonCode"] = reasonCode; 137 } 138 else 139 { 140 data["ReasonCode"] = fdReasonCode.at(reasonCode); 141 } 142 data["UpdateOptionFlagsEnabled"] = updateOptionFlagsEnabled.value; 143 144 pldmtool::helper::DisplayInJson(data); 145 } 146 }; 147 148 const std::map<uint16_t, std::string> componentClassification{ 149 {PLDM_COMP_UNKNOWN, "Unknown"}, 150 {PLDM_COMP_OTHER, "Other"}, 151 {PLDM_COMP_DRIVER, "Driver"}, 152 {PLDM_COMP_CONFIGURATION_SOFTWARE, "Configuration Software"}, 153 {PLDM_COMP_APPLICATION_SOFTWARE, "Application Software"}, 154 {PLDM_COMP_INSTRUMENTATION, "Instrumentation"}, 155 {PLDM_COMP_FIRMWARE_OR_BIOS, "Firmware/BIOS"}, 156 {PLDM_COMP_DIAGNOSTIC_SOFTWARE, "Diagnostic Software"}, 157 {PLDM_COMP_OPERATING_SYSTEM, "Operating System"}, 158 {PLDM_COMP_MIDDLEWARE, "Middleware"}, 159 {PLDM_COMP_FIRMWARE, "Firmware"}, 160 {PLDM_COMP_BIOS_OR_FCODE, "BIOS/FCode"}, 161 {PLDM_COMP_SUPPORT_OR_SERVICEPACK, "Support/Service Pack"}, 162 {PLDM_COMP_SOFTWARE_BUNDLE, "Software Bundle"}, 163 {PLDM_COMP_DOWNSTREAM_DEVICE, "Downstream Device"}}; 164 165 class GetFwParams : public CommandInterface 166 { 167 public: 168 ~GetFwParams() = default; 169 GetFwParams() = delete; 170 GetFwParams(const GetFwParams&) = delete; 171 GetFwParams(GetFwParams&&) = default; 172 GetFwParams& operator=(const GetFwParams&) = delete; 173 GetFwParams& operator=(GetFwParams&&) = delete; 174 175 using CommandInterface::CommandInterface; 176 177 std::pair<int, std::vector<uint8_t>> createRequestMsg() override 178 { 179 std::vector<uint8_t> requestMsg(sizeof(pldm_msg_hdr) + 180 PLDM_GET_FIRMWARE_PARAMETERS_REQ_BYTES); 181 auto request = reinterpret_cast<pldm_msg*>(requestMsg.data()); 182 auto rc = encode_get_firmware_parameters_req( 183 instanceId, PLDM_GET_FIRMWARE_PARAMETERS_REQ_BYTES, request); 184 return {rc, requestMsg}; 185 } 186 187 void parseResponseMsg(pldm_msg* responsePtr, size_t payloadLength) override 188 { 189 pldm_get_firmware_parameters_resp fwParams{}; 190 variable_field activeCompImageSetVersion{}; 191 variable_field pendingCompImageSetVersion{}; 192 variable_field compParameterTable{}; 193 194 auto rc = decode_get_firmware_parameters_resp( 195 responsePtr, payloadLength, &fwParams, &activeCompImageSetVersion, 196 &pendingCompImageSetVersion, &compParameterTable); 197 if (rc != PLDM_SUCCESS || fwParams.completion_code != PLDM_SUCCESS) 198 { 199 std::cerr << "Response Message Error: " 200 << "rc=" << rc << ",cc=" << (int)fwParams.completion_code 201 << "\n"; 202 return; 203 } 204 205 ordered_json capabilitiesDuringUpdate; 206 if (fwParams.capabilities_during_update.bits.bit0) 207 { 208 capabilitiesDuringUpdate 209 ["Component Update Failure Recovery Capability"] = 210 "Device will not revert to previous component image upon failure, timeout or cancellation of the transfer."; 211 } 212 else 213 { 214 capabilitiesDuringUpdate 215 ["Component Update Failure Recovery Capability"] = 216 "Device will revert to previous component image upon failure, timeout or cancellation of the transfer."; 217 } 218 219 if (fwParams.capabilities_during_update.bits.bit1) 220 { 221 capabilitiesDuringUpdate["Component Update Failure Retry Capability"] = 222 "Device will not be able to update component again unless it exits update mode and the UA sends a new Request Update command."; 223 } 224 else 225 { 226 capabilitiesDuringUpdate["Component Update Failure Retry Capability"] = 227 " Device can have component updated again without exiting update mode and restarting transfer via RequestUpdate command."; 228 } 229 230 if (fwParams.capabilities_during_update.bits.bit2) 231 { 232 capabilitiesDuringUpdate["Firmware Device Partial Updates"] = 233 "Firmware Device can support a partial update, whereby a package which contains a component image set that is a subset of all components currently residing on the FD, can be transferred."; 234 } 235 else 236 { 237 capabilitiesDuringUpdate["Firmware Device Partial Updates"] = 238 "Firmware Device cannot accept a partial update and all components present on the FD shall be updated."; 239 } 240 241 if (fwParams.capabilities_during_update.bits.bit3) 242 { 243 capabilitiesDuringUpdate 244 ["Firmware Device Host Functionality during Firmware Update"] = 245 "Device will not revert to previous component image upon failure, timeout or cancellation of the transfer"; 246 } 247 else 248 { 249 capabilitiesDuringUpdate 250 ["Firmware Device Host Functionality during Firmware Update"] = 251 "Device will revert to previous component image upon failure, timeout or cancellation of the transfer"; 252 } 253 254 if (fwParams.capabilities_during_update.bits.bit4) 255 { 256 capabilitiesDuringUpdate["Firmware Device Update Mode Restrictions"] = 257 "Firmware device unable to enter update mode if host OS environment is active."; 258 } 259 else 260 { 261 capabilitiesDuringUpdate 262 ["Firmware Device Update Mode Restrictions"] = 263 "No host OS environment restriction for update mode"; 264 } 265 266 ordered_json data; 267 data["CapabilitiesDuringUpdate"] = capabilitiesDuringUpdate; 268 data["ComponentCount"] = static_cast<uint16_t>(fwParams.comp_count); 269 data["ActiveComponentImageSetVersionString"] = 270 pldm::utils::toString(activeCompImageSetVersion); 271 data["PendingComponentImageSetVersionString"] = 272 pldm::utils::toString(pendingCompImageSetVersion); 273 274 auto compParamPtr = compParameterTable.ptr; 275 auto compParamTableLen = compParameterTable.length; 276 pldm_component_parameter_entry compEntry{}; 277 variable_field activeCompVerStr{}; 278 variable_field pendingCompVerStr{}; 279 ordered_json compDataEntries; 280 281 while (fwParams.comp_count-- && (compParamTableLen > 0)) 282 { 283 ordered_json compData; 284 auto rc = decode_get_firmware_parameters_resp_comp_entry( 285 compParamPtr, compParamTableLen, &compEntry, &activeCompVerStr, 286 &pendingCompVerStr); 287 if (rc) 288 { 289 std::cerr 290 << "Decoding component parameter table entry failed, RC=" 291 << rc << "\n"; 292 return; 293 } 294 295 if (componentClassification.contains(compEntry.comp_classification)) 296 { 297 compData["ComponentClassification"] = 298 componentClassification.at(compEntry.comp_classification); 299 } 300 else 301 { 302 compData["ComponentClassification"] = 303 static_cast<uint16_t>(compEntry.comp_classification); 304 } 305 compData["ComponentIdentifier"] = 306 static_cast<uint16_t>(compEntry.comp_identifier); 307 compData["ComponentClassificationIndex"] = 308 static_cast<uint8_t>(compEntry.comp_classification_index); 309 compData["ActiveComponentComparisonStamp"] = 310 static_cast<uint32_t>(compEntry.active_comp_comparison_stamp); 311 312 // ActiveComponentReleaseData 313 std::array<uint8_t, 8> noReleaseData{0x00, 0x00, 0x00, 0x00, 314 0x00, 0x00, 0x00, 0x00}; 315 if (std::equal(noReleaseData.begin(), noReleaseData.end(), 316 compEntry.active_comp_release_date)) 317 { 318 compData["ActiveComponentReleaseDate"] = ""; 319 } 320 else 321 { 322 std::string activeComponentReleaseDate( 323 reinterpret_cast<const char*>( 324 compEntry.active_comp_release_date), 325 sizeof(compEntry.active_comp_release_date)); 326 compData["ActiveComponentReleaseDate"] = 327 activeComponentReleaseDate; 328 } 329 330 compData["PendingComponentComparisonStamp"] = 331 static_cast<uint32_t>(compEntry.pending_comp_comparison_stamp); 332 333 // PendingComponentReleaseData 334 if (std::equal(noReleaseData.begin(), noReleaseData.end(), 335 compEntry.pending_comp_release_date)) 336 { 337 compData["PendingComponentReleaseDate"] = ""; 338 } 339 else 340 { 341 std::string pendingComponentReleaseDate( 342 reinterpret_cast<const char*>( 343 compEntry.pending_comp_release_date), 344 sizeof(compEntry.pending_comp_release_date)); 345 compData["PendingComponentReleaseDate"] = 346 pendingComponentReleaseDate; 347 } 348 349 // ComponentActivationMethods 350 ordered_json componentActivationMethods; 351 if (compEntry.comp_activation_methods.bits.bit0) 352 { 353 componentActivationMethods.push_back("Automatic"); 354 } 355 else if (compEntry.comp_activation_methods.bits.bit1) 356 { 357 componentActivationMethods.push_back("Self-Contained"); 358 } 359 else if (compEntry.comp_activation_methods.bits.bit2) 360 { 361 componentActivationMethods.push_back("Medium-specific reset"); 362 } 363 else if (compEntry.comp_activation_methods.bits.bit3) 364 { 365 componentActivationMethods.push_back("System reboot"); 366 } 367 else if (compEntry.comp_activation_methods.bits.bit4) 368 { 369 componentActivationMethods.push_back("DC power cycel"); 370 } 371 else if (compEntry.comp_activation_methods.bits.bit5) 372 { 373 componentActivationMethods.push_back("AC power cycle"); 374 } 375 compData["ComponentActivationMethods"] = componentActivationMethods; 376 377 // CapabilitiesDuringUpdate 378 ordered_json compCapabilitiesDuringUpdate; 379 if (compEntry.capabilities_during_update.bits.bit0) 380 { 381 compCapabilitiesDuringUpdate 382 ["Firmware Device apply state functionality"] = 383 "Firmware Device performs an auto-apply during transfer phase and apply step will be completed immediately."; 384 } 385 else 386 { 387 compCapabilitiesDuringUpdate 388 ["Firmware Device apply state functionality"] = 389 " Firmware Device will execute an operation during the APPLY state which will include migrating the new component image to its final non-volatile storage destination."; 390 } 391 compData["CapabilitiesDuringUpdate"] = compCapabilitiesDuringUpdate; 392 393 compData["ActiveComponentVersionString"] = 394 pldm::utils::toString(activeCompVerStr); 395 compData["PendingComponentVersionString"] = 396 pldm::utils::toString(pendingCompVerStr); 397 398 compParamPtr += sizeof(pldm_component_parameter_entry) + 399 activeCompVerStr.length + pendingCompVerStr.length; 400 compParamTableLen -= sizeof(pldm_component_parameter_entry) + 401 activeCompVerStr.length + 402 pendingCompVerStr.length; 403 compDataEntries.push_back(compData); 404 } 405 data["ComponentParameterEntries"] = compDataEntries; 406 407 pldmtool::helper::DisplayInJson(data); 408 } 409 }; 410 411 class QueryDeviceIdentifiers : public CommandInterface 412 { 413 public: 414 ~QueryDeviceIdentifiers() = default; 415 QueryDeviceIdentifiers() = delete; 416 QueryDeviceIdentifiers(const QueryDeviceIdentifiers&) = delete; 417 QueryDeviceIdentifiers(QueryDeviceIdentifiers&&) = default; 418 QueryDeviceIdentifiers& operator=(const QueryDeviceIdentifiers&) = delete; 419 QueryDeviceIdentifiers& operator=(QueryDeviceIdentifiers&&) = delete; 420 421 /** 422 * @brief Implementation of createRequestMsg for QueryDeviceIdentifiers 423 * 424 * @return std::pair<int, std::vector<uint8_t>> 425 */ 426 std::pair<int, std::vector<uint8_t>> createRequestMsg() override; 427 428 /** 429 * @brief Implementation of parseResponseMsg for QueryDeviceIdentifiers 430 * 431 * @param[in] responsePtr 432 * @param[in] payloadLength 433 */ 434 void parseResponseMsg(pldm_msg* responsePtr, size_t payloadLength) override; 435 using CommandInterface::CommandInterface; 436 437 private: 438 /** 439 * @brief Method to update QueryDeviceIdentifiers json response in a user 440 * friendly format 441 * 442 * @param[in] descriptors - descriptor json response 443 * @param[in] descriptorType - descriptor type 444 * @param[in] descriptorVal - descriptor value 445 */ 446 void updateDescriptor( 447 ordered_json& descriptors, const DescriptorType& descriptorType, 448 const std::variant<DescriptorData, VendorDefinedDescriptorInfo>& 449 descriptorVal); 450 }; 451 452 void QueryDeviceIdentifiers::updateDescriptor( 453 ordered_json& descriptors, const DescriptorType& descriptorType, 454 const std::variant<DescriptorData, VendorDefinedDescriptorInfo>& 455 descriptorVal) 456 { 457 std::ostringstream descDataStream; 458 DescriptorData descData; 459 if (descriptorType != PLDM_FWUP_VENDOR_DEFINED) 460 { 461 descData = std::get<DescriptorData>(descriptorVal); 462 } 463 else 464 { 465 descData = std::get<VendorDefinedDescriptorData>( 466 std::get<VendorDefinedDescriptorInfo>(descriptorVal)); 467 } 468 for (int byte : descData) 469 { 470 descDataStream << std::setfill('0') << std::setw(2) << std::hex << byte; 471 } 472 473 if (descriptorName.contains(descriptorType)) 474 { 475 // Update the existing json response if entry is already present 476 for (auto& descriptor : descriptors) 477 { 478 if (descriptor["Type"] == descriptorName.at(descriptorType)) 479 { 480 if (descriptorType != PLDM_FWUP_VENDOR_DEFINED) 481 { 482 descriptor["Value"].emplace_back(descDataStream.str()); 483 } 484 else 485 { 486 ordered_json vendorDefinedVal; 487 vendorDefinedVal[std::get<VendorDefinedDescriptorTitle>( 488 std::get<VendorDefinedDescriptorInfo>(descriptorVal))] = 489 descDataStream.str(); 490 descriptor["Value"].emplace_back(vendorDefinedVal); 491 } 492 return; 493 } 494 } 495 // Entry is not present, add type and value to json response 496 ordered_json descriptor = 497 ordered_json::object({{"Type", descriptorName.at(descriptorType)}, 498 {"Value", ordered_json::array()}}); 499 if (descriptorType != PLDM_FWUP_VENDOR_DEFINED) 500 { 501 descriptor["Value"].emplace_back(descDataStream.str()); 502 } 503 else 504 { 505 ordered_json vendorDefinedVal; 506 vendorDefinedVal[std::get<VendorDefinedDescriptorTitle>( 507 std::get<VendorDefinedDescriptorInfo>(descriptorVal))] = 508 descDataStream.str(); 509 descriptor["Value"].emplace_back(vendorDefinedVal); 510 } 511 descriptors.emplace_back(descriptor); 512 } 513 else 514 { 515 std::cerr << "Unknown descriptor type, type=" << descriptorType << "\n"; 516 } 517 } 518 std::pair<int, std::vector<uint8_t>> QueryDeviceIdentifiers::createRequestMsg() 519 { 520 std::vector<uint8_t> requestMsg(sizeof(pldm_msg_hdr) + 521 PLDM_QUERY_DEVICE_IDENTIFIERS_REQ_BYTES); 522 auto request = reinterpret_cast<pldm_msg*>(requestMsg.data()); 523 auto rc = encode_query_device_identifiers_req( 524 instanceId, PLDM_QUERY_DEVICE_IDENTIFIERS_REQ_BYTES, request); 525 return {rc, requestMsg}; 526 } 527 528 void QueryDeviceIdentifiers::parseResponseMsg(pldm_msg* responsePtr, 529 size_t payloadLength) 530 { 531 uint8_t completionCode = PLDM_SUCCESS; 532 uint32_t deviceIdentifiersLen = 0; 533 uint8_t descriptorCount = 0; 534 uint8_t* descriptorPtr = nullptr; 535 uint8_t eid = getMCTPEID(); 536 auto rc = decode_query_device_identifiers_resp( 537 responsePtr, payloadLength, &completionCode, &deviceIdentifiersLen, 538 &descriptorCount, &descriptorPtr); 539 if (rc) 540 { 541 std::cerr << "Decoding QueryDeviceIdentifiers response failed,EID=" 542 << unsigned(eid) << ", RC=" << rc << "\n"; 543 return; 544 } 545 if (completionCode) 546 { 547 std::cerr << "QueryDeviceIdentifiers response failed with error " 548 "completion code, EID=" 549 << unsigned(eid) << ", CC=" << unsigned(completionCode) 550 << "\n"; 551 return; 552 } 553 ordered_json data; 554 data["EID"] = eid; 555 ordered_json descriptors; 556 while (descriptorCount-- && (deviceIdentifiersLen > 0)) 557 { 558 DescriptorType descriptorType = 0; 559 variable_field descriptorData{}; 560 561 rc = decode_descriptor_type_length_value( 562 descriptorPtr, deviceIdentifiersLen, &descriptorType, 563 &descriptorData); 564 if (rc) 565 { 566 std::cerr << "Decoding descriptor type, length and value failed," 567 << "EID=" << unsigned(eid) << ",RC=" << rc << "\n "; 568 return; 569 } 570 571 if (descriptorType != PLDM_FWUP_VENDOR_DEFINED) 572 { 573 std::vector<uint8_t> descData( 574 descriptorData.ptr, descriptorData.ptr + descriptorData.length); 575 updateDescriptor(descriptors, descriptorType, descData); 576 } 577 else 578 { 579 uint8_t descriptorTitleStrType = 0; 580 variable_field descriptorTitleStr{}; 581 variable_field vendorDefinedDescriptorData{}; 582 583 rc = decode_vendor_defined_descriptor_value( 584 descriptorData.ptr, descriptorData.length, 585 &descriptorTitleStrType, &descriptorTitleStr, 586 &vendorDefinedDescriptorData); 587 if (rc) 588 { 589 std::cerr << "Decoding Vendor-defined descriptor value" 590 << "failed EID=" << unsigned(eid) << ", RC=" << rc 591 << "\n "; 592 return; 593 } 594 595 auto vendorDescTitle = pldm::utils::toString(descriptorTitleStr); 596 std::vector<uint8_t> vendorDescData( 597 vendorDefinedDescriptorData.ptr, 598 vendorDefinedDescriptorData.ptr + 599 vendorDefinedDescriptorData.length); 600 updateDescriptor(descriptors, descriptorType, 601 std::make_tuple(vendorDescTitle, vendorDescData)); 602 } 603 auto nextDescriptorOffset = 604 sizeof(pldm_descriptor_tlv().descriptor_type) + 605 sizeof(pldm_descriptor_tlv().descriptor_length) + 606 descriptorData.length; 607 descriptorPtr += nextDescriptorOffset; 608 deviceIdentifiersLen -= nextDescriptorOffset; 609 } 610 data["Descriptors"] = descriptors; 611 pldmtool::helper::DisplayInJson(data); 612 } 613 614 void registerCommand(CLI::App& app) 615 { 616 auto fwUpdate = app.add_subcommand("fw_update", 617 "firmware update type commands"); 618 fwUpdate->require_subcommand(1); 619 620 auto getStatus = fwUpdate->add_subcommand("GetStatus", "Status of the FD"); 621 commands.push_back( 622 std::make_unique<GetStatus>("fw_update", "GetStatus", getStatus)); 623 624 auto getFwParams = fwUpdate->add_subcommand( 625 "GetFwParams", "To get the component details of the FD"); 626 commands.push_back( 627 std::make_unique<GetFwParams>("fw_update", "GetFwParams", getFwParams)); 628 629 auto queryDeviceIdentifiers = fwUpdate->add_subcommand( 630 "QueryDeviceIdentifiers", "To query device identifiers of the FD"); 631 commands.push_back(std::make_unique<QueryDeviceIdentifiers>( 632 "fw_update", "QueryDeviceIdentifiers", queryDeviceIdentifiers)); 633 } 634 635 } // namespace fw_update 636 637 } // namespace pldmtool 638