1 //===- MinidumpYAML.cpp - Minidump YAMLIO implementation ------------------===// 2 // 3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4 // See https://llvm.org/LICENSE.txt for license information. 5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6 // 7 //===----------------------------------------------------------------------===// 8 9 #include "llvm/ObjectYAML/MinidumpYAML.h" 10 #include "llvm/Support/Allocator.h" 11 12 using namespace llvm; 13 using namespace llvm::MinidumpYAML; 14 using namespace llvm::minidump; 15 16 /// Perform an optional yaml-mapping of an endian-aware type EndianType. The 17 /// only purpose of this function is to avoid casting the Default value to the 18 /// endian type; 19 template <typename EndianType> 20 static inline void mapOptional(yaml::IO &IO, const char *Key, EndianType &Val, 21 typename EndianType::value_type Default) { 22 IO.mapOptional(Key, Val, EndianType(Default)); 23 } 24 25 /// Yaml-map an endian-aware type EndianType as some other type MapType. 26 template <typename MapType, typename EndianType> 27 static inline void mapRequiredAs(yaml::IO &IO, const char *Key, 28 EndianType &Val) { 29 MapType Mapped = static_cast<typename EndianType::value_type>(Val); 30 IO.mapRequired(Key, Mapped); 31 Val = static_cast<typename EndianType::value_type>(Mapped); 32 } 33 34 /// Perform an optional yaml-mapping of an endian-aware type EndianType as some 35 /// other type MapType. 36 template <typename MapType, typename EndianType> 37 static inline void mapOptionalAs(yaml::IO &IO, const char *Key, EndianType &Val, 38 MapType Default) { 39 MapType Mapped = static_cast<typename EndianType::value_type>(Val); 40 IO.mapOptional(Key, Mapped, Default); 41 Val = static_cast<typename EndianType::value_type>(Mapped); 42 } 43 44 namespace { 45 /// Return the appropriate yaml Hex type for a given endian-aware type. 46 template <typename EndianType> struct HexType; 47 template <> struct HexType<support::ulittle16_t> { using type = yaml::Hex16; }; 48 template <> struct HexType<support::ulittle32_t> { using type = yaml::Hex32; }; 49 template <> struct HexType<support::ulittle64_t> { using type = yaml::Hex64; }; 50 } // namespace 51 52 /// Yaml-map an endian-aware type as an appropriately-sized hex value. 53 template <typename EndianType> 54 static inline void mapRequiredHex(yaml::IO &IO, const char *Key, 55 EndianType &Val) { 56 mapRequiredAs<typename HexType<EndianType>::type>(IO, Key, Val); 57 } 58 59 /// Perform an optional yaml-mapping of an endian-aware type as an 60 /// appropriately-sized hex value. 61 template <typename EndianType> 62 static inline void mapOptionalHex(yaml::IO &IO, const char *Key, 63 EndianType &Val, 64 typename EndianType::value_type Default) { 65 mapOptionalAs<typename HexType<EndianType>::type>(IO, Key, Val, Default); 66 } 67 68 Stream::~Stream() = default; 69 70 Stream::StreamKind Stream::getKind(StreamType Type) { 71 switch (Type) { 72 case StreamType::Exception: 73 return StreamKind::Exception; 74 case StreamType::MemoryInfoList: 75 return StreamKind::MemoryInfoList; 76 case StreamType::MemoryList: 77 return StreamKind::MemoryList; 78 case StreamType::ModuleList: 79 return StreamKind::ModuleList; 80 case StreamType::SystemInfo: 81 return StreamKind::SystemInfo; 82 case StreamType::LinuxCPUInfo: 83 case StreamType::LinuxProcStatus: 84 case StreamType::LinuxLSBRelease: 85 case StreamType::LinuxCMDLine: 86 case StreamType::LinuxMaps: 87 case StreamType::LinuxProcStat: 88 case StreamType::LinuxProcUptime: 89 return StreamKind::TextContent; 90 case StreamType::ThreadList: 91 return StreamKind::ThreadList; 92 default: 93 return StreamKind::RawContent; 94 } 95 } 96 97 std::unique_ptr<Stream> Stream::create(StreamType Type) { 98 StreamKind Kind = getKind(Type); 99 switch (Kind) { 100 case StreamKind::Exception: 101 return std::make_unique<ExceptionStream>(); 102 case StreamKind::MemoryInfoList: 103 return std::make_unique<MemoryInfoListStream>(); 104 case StreamKind::MemoryList: 105 return std::make_unique<MemoryListStream>(); 106 case StreamKind::ModuleList: 107 return std::make_unique<ModuleListStream>(); 108 case StreamKind::RawContent: 109 return std::make_unique<RawContentStream>(Type); 110 case StreamKind::SystemInfo: 111 return std::make_unique<SystemInfoStream>(); 112 case StreamKind::TextContent: 113 return std::make_unique<TextContentStream>(Type); 114 case StreamKind::ThreadList: 115 return std::make_unique<ThreadListStream>(); 116 } 117 llvm_unreachable("Unhandled stream kind!"); 118 } 119 120 void yaml::ScalarBitSetTraits<MemoryProtection>::bitset( 121 IO &IO, MemoryProtection &Protect) { 122 #define HANDLE_MDMP_PROTECT(CODE, NAME, NATIVENAME) \ 123 IO.bitSetCase(Protect, #NATIVENAME, MemoryProtection::NAME); 124 #include "llvm/BinaryFormat/MinidumpConstants.def" 125 } 126 127 void yaml::ScalarBitSetTraits<MemoryState>::bitset(IO &IO, MemoryState &State) { 128 #define HANDLE_MDMP_MEMSTATE(CODE, NAME, NATIVENAME) \ 129 IO.bitSetCase(State, #NATIVENAME, MemoryState::NAME); 130 #include "llvm/BinaryFormat/MinidumpConstants.def" 131 } 132 133 void yaml::ScalarBitSetTraits<MemoryType>::bitset(IO &IO, MemoryType &Type) { 134 #define HANDLE_MDMP_MEMTYPE(CODE, NAME, NATIVENAME) \ 135 IO.bitSetCase(Type, #NATIVENAME, MemoryType::NAME); 136 #include "llvm/BinaryFormat/MinidumpConstants.def" 137 } 138 139 void yaml::ScalarEnumerationTraits<ProcessorArchitecture>::enumeration( 140 IO &IO, ProcessorArchitecture &Arch) { 141 #define HANDLE_MDMP_ARCH(CODE, NAME) \ 142 IO.enumCase(Arch, #NAME, ProcessorArchitecture::NAME); 143 #include "llvm/BinaryFormat/MinidumpConstants.def" 144 IO.enumFallback<Hex16>(Arch); 145 } 146 147 void yaml::ScalarEnumerationTraits<OSPlatform>::enumeration(IO &IO, 148 OSPlatform &Plat) { 149 #define HANDLE_MDMP_PLATFORM(CODE, NAME) \ 150 IO.enumCase(Plat, #NAME, OSPlatform::NAME); 151 #include "llvm/BinaryFormat/MinidumpConstants.def" 152 IO.enumFallback<Hex32>(Plat); 153 } 154 155 void yaml::ScalarEnumerationTraits<StreamType>::enumeration(IO &IO, 156 StreamType &Type) { 157 #define HANDLE_MDMP_STREAM_TYPE(CODE, NAME) \ 158 IO.enumCase(Type, #NAME, StreamType::NAME); 159 #include "llvm/BinaryFormat/MinidumpConstants.def" 160 IO.enumFallback<Hex32>(Type); 161 } 162 163 void yaml::MappingTraits<CPUInfo::ArmInfo>::mapping(IO &IO, 164 CPUInfo::ArmInfo &Info) { 165 mapRequiredHex(IO, "CPUID", Info.CPUID); 166 mapOptionalHex(IO, "ELF hwcaps", Info.ElfHWCaps, 0); 167 } 168 169 namespace { 170 template <std::size_t N> struct FixedSizeHex { 171 FixedSizeHex(uint8_t (&Storage)[N]) : Storage(Storage) {} 172 173 uint8_t (&Storage)[N]; 174 }; 175 } // namespace 176 177 namespace llvm { 178 namespace yaml { 179 template <std::size_t N> struct ScalarTraits<FixedSizeHex<N>> { 180 static void output(const FixedSizeHex<N> &Fixed, void *, raw_ostream &OS) { 181 OS << toHex(makeArrayRef(Fixed.Storage)); 182 } 183 184 static StringRef input(StringRef Scalar, void *, FixedSizeHex<N> &Fixed) { 185 if (!all_of(Scalar, isHexDigit)) 186 return "Invalid hex digit in input"; 187 if (Scalar.size() < 2 * N) 188 return "String too short"; 189 if (Scalar.size() > 2 * N) 190 return "String too long"; 191 copy(fromHex(Scalar), Fixed.Storage); 192 return ""; 193 } 194 195 static QuotingType mustQuote(StringRef S) { return QuotingType::None; } 196 }; 197 } // namespace yaml 198 } // namespace llvm 199 void yaml::MappingTraits<CPUInfo::OtherInfo>::mapping( 200 IO &IO, CPUInfo::OtherInfo &Info) { 201 FixedSizeHex<sizeof(Info.ProcessorFeatures)> Features(Info.ProcessorFeatures); 202 IO.mapRequired("Features", Features); 203 } 204 205 namespace { 206 /// A type which only accepts strings of a fixed size for yaml conversion. 207 template <std::size_t N> struct FixedSizeString { 208 FixedSizeString(char (&Storage)[N]) : Storage(Storage) {} 209 210 char (&Storage)[N]; 211 }; 212 } // namespace 213 214 namespace llvm { 215 namespace yaml { 216 template <std::size_t N> struct ScalarTraits<FixedSizeString<N>> { 217 static void output(const FixedSizeString<N> &Fixed, void *, raw_ostream &OS) { 218 OS << StringRef(Fixed.Storage, N); 219 } 220 221 static StringRef input(StringRef Scalar, void *, FixedSizeString<N> &Fixed) { 222 if (Scalar.size() < N) 223 return "String too short"; 224 if (Scalar.size() > N) 225 return "String too long"; 226 copy(Scalar, Fixed.Storage); 227 return ""; 228 } 229 230 static QuotingType mustQuote(StringRef S) { return needsQuotes(S); } 231 }; 232 } // namespace yaml 233 } // namespace llvm 234 235 void yaml::MappingTraits<CPUInfo::X86Info>::mapping(IO &IO, 236 CPUInfo::X86Info &Info) { 237 FixedSizeString<sizeof(Info.VendorID)> VendorID(Info.VendorID); 238 IO.mapRequired("Vendor ID", VendorID); 239 240 mapRequiredHex(IO, "Version Info", Info.VersionInfo); 241 mapRequiredHex(IO, "Feature Info", Info.FeatureInfo); 242 mapOptionalHex(IO, "AMD Extended Features", Info.AMDExtendedFeatures, 0); 243 } 244 245 void yaml::MappingTraits<MemoryInfo>::mapping(IO &IO, MemoryInfo &Info) { 246 mapRequiredHex(IO, "Base Address", Info.BaseAddress); 247 mapOptionalHex(IO, "Allocation Base", Info.AllocationBase, Info.BaseAddress); 248 mapRequiredAs<MemoryProtection>(IO, "Allocation Protect", 249 Info.AllocationProtect); 250 mapOptionalHex(IO, "Reserved0", Info.Reserved0, 0); 251 mapRequiredHex(IO, "Region Size", Info.RegionSize); 252 mapRequiredAs<MemoryState>(IO, "State", Info.State); 253 mapOptionalAs<MemoryProtection>(IO, "Protect", Info.Protect, 254 Info.AllocationProtect); 255 mapRequiredAs<MemoryType>(IO, "Type", Info.Type); 256 mapOptionalHex(IO, "Reserved1", Info.Reserved1, 0); 257 } 258 259 void yaml::MappingTraits<VSFixedFileInfo>::mapping(IO &IO, 260 VSFixedFileInfo &Info) { 261 mapOptionalHex(IO, "Signature", Info.Signature, 0); 262 mapOptionalHex(IO, "Struct Version", Info.StructVersion, 0); 263 mapOptionalHex(IO, "File Version High", Info.FileVersionHigh, 0); 264 mapOptionalHex(IO, "File Version Low", Info.FileVersionLow, 0); 265 mapOptionalHex(IO, "Product Version High", Info.ProductVersionHigh, 0); 266 mapOptionalHex(IO, "Product Version Low", Info.ProductVersionLow, 0); 267 mapOptionalHex(IO, "File Flags Mask", Info.FileFlagsMask, 0); 268 mapOptionalHex(IO, "File Flags", Info.FileFlags, 0); 269 mapOptionalHex(IO, "File OS", Info.FileOS, 0); 270 mapOptionalHex(IO, "File Type", Info.FileType, 0); 271 mapOptionalHex(IO, "File Subtype", Info.FileSubtype, 0); 272 mapOptionalHex(IO, "File Date High", Info.FileDateHigh, 0); 273 mapOptionalHex(IO, "File Date Low", Info.FileDateLow, 0); 274 } 275 276 void yaml::MappingTraits<ModuleListStream::entry_type>::mapping( 277 IO &IO, ModuleListStream::entry_type &M) { 278 mapRequiredHex(IO, "Base of Image", M.Entry.BaseOfImage); 279 mapRequiredHex(IO, "Size of Image", M.Entry.SizeOfImage); 280 mapOptionalHex(IO, "Checksum", M.Entry.Checksum, 0); 281 mapOptional(IO, "Time Date Stamp", M.Entry.TimeDateStamp, 0); 282 IO.mapRequired("Module Name", M.Name); 283 IO.mapOptional("Version Info", M.Entry.VersionInfo, VSFixedFileInfo()); 284 IO.mapRequired("CodeView Record", M.CvRecord); 285 IO.mapOptional("Misc Record", M.MiscRecord, yaml::BinaryRef()); 286 mapOptionalHex(IO, "Reserved0", M.Entry.Reserved0, 0); 287 mapOptionalHex(IO, "Reserved1", M.Entry.Reserved1, 0); 288 } 289 290 static void streamMapping(yaml::IO &IO, RawContentStream &Stream) { 291 IO.mapOptional("Content", Stream.Content); 292 IO.mapOptional("Size", Stream.Size, Stream.Content.binary_size()); 293 } 294 295 static StringRef streamValidate(RawContentStream &Stream) { 296 if (Stream.Size.value < Stream.Content.binary_size()) 297 return "Stream size must be greater or equal to the content size"; 298 return ""; 299 } 300 301 void yaml::MappingTraits<MemoryListStream::entry_type>::mapping( 302 IO &IO, MemoryListStream::entry_type &Range) { 303 MappingContextTraits<MemoryDescriptor, yaml::BinaryRef>::mapping( 304 IO, Range.Entry, Range.Content); 305 } 306 307 static void streamMapping(yaml::IO &IO, MemoryInfoListStream &Stream) { 308 IO.mapRequired("Memory Ranges", Stream.Infos); 309 } 310 311 static void streamMapping(yaml::IO &IO, MemoryListStream &Stream) { 312 IO.mapRequired("Memory Ranges", Stream.Entries); 313 } 314 315 static void streamMapping(yaml::IO &IO, ModuleListStream &Stream) { 316 IO.mapRequired("Modules", Stream.Entries); 317 } 318 319 static void streamMapping(yaml::IO &IO, SystemInfoStream &Stream) { 320 SystemInfo &Info = Stream.Info; 321 IO.mapRequired("Processor Arch", Info.ProcessorArch); 322 mapOptional(IO, "Processor Level", Info.ProcessorLevel, 0); 323 mapOptional(IO, "Processor Revision", Info.ProcessorRevision, 0); 324 IO.mapOptional("Number of Processors", Info.NumberOfProcessors, 0); 325 IO.mapOptional("Product type", Info.ProductType, 0); 326 mapOptional(IO, "Major Version", Info.MajorVersion, 0); 327 mapOptional(IO, "Minor Version", Info.MinorVersion, 0); 328 mapOptional(IO, "Build Number", Info.BuildNumber, 0); 329 IO.mapRequired("Platform ID", Info.PlatformId); 330 IO.mapOptional("CSD Version", Stream.CSDVersion, ""); 331 mapOptionalHex(IO, "Suite Mask", Info.SuiteMask, 0); 332 mapOptionalHex(IO, "Reserved", Info.Reserved, 0); 333 switch (static_cast<ProcessorArchitecture>(Info.ProcessorArch)) { 334 case ProcessorArchitecture::X86: 335 case ProcessorArchitecture::AMD64: 336 IO.mapOptional("CPU", Info.CPU.X86); 337 break; 338 case ProcessorArchitecture::ARM: 339 case ProcessorArchitecture::ARM64: 340 case ProcessorArchitecture::BP_ARM64: 341 IO.mapOptional("CPU", Info.CPU.Arm); 342 break; 343 default: 344 IO.mapOptional("CPU", Info.CPU.Other); 345 break; 346 } 347 } 348 349 static void streamMapping(yaml::IO &IO, TextContentStream &Stream) { 350 IO.mapOptional("Text", Stream.Text); 351 } 352 353 void yaml::MappingContextTraits<MemoryDescriptor, yaml::BinaryRef>::mapping( 354 IO &IO, MemoryDescriptor &Memory, BinaryRef &Content) { 355 mapRequiredHex(IO, "Start of Memory Range", Memory.StartOfMemoryRange); 356 IO.mapRequired("Content", Content); 357 } 358 359 void yaml::MappingTraits<ThreadListStream::entry_type>::mapping( 360 IO &IO, ThreadListStream::entry_type &T) { 361 mapRequiredHex(IO, "Thread Id", T.Entry.ThreadId); 362 mapOptionalHex(IO, "Suspend Count", T.Entry.SuspendCount, 0); 363 mapOptionalHex(IO, "Priority Class", T.Entry.PriorityClass, 0); 364 mapOptionalHex(IO, "Priority", T.Entry.Priority, 0); 365 mapOptionalHex(IO, "Environment Block", T.Entry.EnvironmentBlock, 0); 366 IO.mapRequired("Context", T.Context); 367 IO.mapRequired("Stack", T.Entry.Stack, T.Stack); 368 } 369 370 static void streamMapping(yaml::IO &IO, ThreadListStream &Stream) { 371 IO.mapRequired("Threads", Stream.Entries); 372 } 373 374 static void streamMapping(yaml::IO &IO, MinidumpYAML::ExceptionStream &Stream) { 375 mapRequiredHex(IO, "Thread ID", Stream.MDExceptionStream.ThreadId); 376 IO.mapRequired("Exception Record", Stream.MDExceptionStream.ExceptionRecord); 377 IO.mapRequired("Thread Context", Stream.ThreadContext); 378 } 379 380 void yaml::MappingTraits<minidump::Exception>::mapping( 381 yaml::IO &IO, minidump::Exception &Exception) { 382 mapRequiredHex(IO, "Exception Code", Exception.ExceptionCode); 383 mapOptionalHex(IO, "Exception Flags", Exception.ExceptionFlags, 0); 384 mapOptionalHex(IO, "Exception Record", Exception.ExceptionRecord, 0); 385 mapOptionalHex(IO, "Exception Address", Exception.ExceptionAddress, 0); 386 mapOptional(IO, "Number of Parameters", Exception.NumberParameters, 0); 387 388 for (size_t Index = 0; Index < Exception.MaxParameters; ++Index) { 389 SmallString<16> Name("Parameter "); 390 Twine(Index).toVector(Name); 391 support::ulittle64_t &Field = Exception.ExceptionInformation[Index]; 392 393 if (Index < Exception.NumberParameters) 394 mapRequiredHex(IO, Name.c_str(), Field); 395 else 396 mapOptionalHex(IO, Name.c_str(), Field, 0); 397 } 398 } 399 400 void yaml::MappingTraits<std::unique_ptr<Stream>>::mapping( 401 yaml::IO &IO, std::unique_ptr<MinidumpYAML::Stream> &S) { 402 StreamType Type; 403 if (IO.outputting()) 404 Type = S->Type; 405 IO.mapRequired("Type", Type); 406 407 if (!IO.outputting()) 408 S = MinidumpYAML::Stream::create(Type); 409 switch (S->Kind) { 410 case MinidumpYAML::Stream::StreamKind::Exception: 411 streamMapping(IO, llvm::cast<MinidumpYAML::ExceptionStream>(*S)); 412 break; 413 case MinidumpYAML::Stream::StreamKind::MemoryInfoList: 414 streamMapping(IO, llvm::cast<MemoryInfoListStream>(*S)); 415 break; 416 case MinidumpYAML::Stream::StreamKind::MemoryList: 417 streamMapping(IO, llvm::cast<MemoryListStream>(*S)); 418 break; 419 case MinidumpYAML::Stream::StreamKind::ModuleList: 420 streamMapping(IO, llvm::cast<ModuleListStream>(*S)); 421 break; 422 case MinidumpYAML::Stream::StreamKind::RawContent: 423 streamMapping(IO, llvm::cast<RawContentStream>(*S)); 424 break; 425 case MinidumpYAML::Stream::StreamKind::SystemInfo: 426 streamMapping(IO, llvm::cast<SystemInfoStream>(*S)); 427 break; 428 case MinidumpYAML::Stream::StreamKind::TextContent: 429 streamMapping(IO, llvm::cast<TextContentStream>(*S)); 430 break; 431 case MinidumpYAML::Stream::StreamKind::ThreadList: 432 streamMapping(IO, llvm::cast<ThreadListStream>(*S)); 433 break; 434 } 435 } 436 437 StringRef yaml::MappingTraits<std::unique_ptr<Stream>>::validate( 438 yaml::IO &IO, std::unique_ptr<MinidumpYAML::Stream> &S) { 439 switch (S->Kind) { 440 case MinidumpYAML::Stream::StreamKind::RawContent: 441 return streamValidate(cast<RawContentStream>(*S)); 442 case MinidumpYAML::Stream::StreamKind::Exception: 443 case MinidumpYAML::Stream::StreamKind::MemoryInfoList: 444 case MinidumpYAML::Stream::StreamKind::MemoryList: 445 case MinidumpYAML::Stream::StreamKind::ModuleList: 446 case MinidumpYAML::Stream::StreamKind::SystemInfo: 447 case MinidumpYAML::Stream::StreamKind::TextContent: 448 case MinidumpYAML::Stream::StreamKind::ThreadList: 449 return ""; 450 } 451 llvm_unreachable("Fully covered switch above!"); 452 } 453 454 void yaml::MappingTraits<Object>::mapping(IO &IO, Object &O) { 455 IO.mapTag("!minidump", true); 456 mapOptionalHex(IO, "Signature", O.Header.Signature, Header::MagicSignature); 457 mapOptionalHex(IO, "Version", O.Header.Version, Header::MagicVersion); 458 mapOptionalHex(IO, "Flags", O.Header.Flags, 0); 459 IO.mapRequired("Streams", O.Streams); 460 } 461 462 Expected<std::unique_ptr<Stream>> 463 Stream::create(const Directory &StreamDesc, const object::MinidumpFile &File) { 464 StreamKind Kind = getKind(StreamDesc.Type); 465 switch (Kind) { 466 case StreamKind::Exception: { 467 Expected<const minidump::ExceptionStream &> ExpectedExceptionStream = 468 File.getExceptionStream(); 469 if (!ExpectedExceptionStream) 470 return ExpectedExceptionStream.takeError(); 471 Expected<ArrayRef<uint8_t>> ExpectedThreadContext = 472 File.getRawData(ExpectedExceptionStream->ThreadContext); 473 if (!ExpectedThreadContext) 474 return ExpectedThreadContext.takeError(); 475 return std::make_unique<ExceptionStream>(*ExpectedExceptionStream, 476 *ExpectedThreadContext); 477 } 478 case StreamKind::MemoryInfoList: { 479 if (auto ExpectedList = File.getMemoryInfoList()) 480 return std::make_unique<MemoryInfoListStream>(*ExpectedList); 481 else 482 return ExpectedList.takeError(); 483 } 484 case StreamKind::MemoryList: { 485 auto ExpectedList = File.getMemoryList(); 486 if (!ExpectedList) 487 return ExpectedList.takeError(); 488 std::vector<MemoryListStream::entry_type> Ranges; 489 for (const MemoryDescriptor &MD : *ExpectedList) { 490 auto ExpectedContent = File.getRawData(MD.Memory); 491 if (!ExpectedContent) 492 return ExpectedContent.takeError(); 493 Ranges.push_back({MD, *ExpectedContent}); 494 } 495 return std::make_unique<MemoryListStream>(std::move(Ranges)); 496 } 497 case StreamKind::ModuleList: { 498 auto ExpectedList = File.getModuleList(); 499 if (!ExpectedList) 500 return ExpectedList.takeError(); 501 std::vector<ModuleListStream::entry_type> Modules; 502 for (const Module &M : *ExpectedList) { 503 auto ExpectedName = File.getString(M.ModuleNameRVA); 504 if (!ExpectedName) 505 return ExpectedName.takeError(); 506 auto ExpectedCv = File.getRawData(M.CvRecord); 507 if (!ExpectedCv) 508 return ExpectedCv.takeError(); 509 auto ExpectedMisc = File.getRawData(M.MiscRecord); 510 if (!ExpectedMisc) 511 return ExpectedMisc.takeError(); 512 Modules.push_back( 513 {M, std::move(*ExpectedName), *ExpectedCv, *ExpectedMisc}); 514 } 515 return std::make_unique<ModuleListStream>(std::move(Modules)); 516 } 517 case StreamKind::RawContent: 518 return std::make_unique<RawContentStream>(StreamDesc.Type, 519 File.getRawStream(StreamDesc)); 520 case StreamKind::SystemInfo: { 521 auto ExpectedInfo = File.getSystemInfo(); 522 if (!ExpectedInfo) 523 return ExpectedInfo.takeError(); 524 auto ExpectedCSDVersion = File.getString(ExpectedInfo->CSDVersionRVA); 525 if (!ExpectedCSDVersion) 526 return ExpectedInfo.takeError(); 527 return std::make_unique<SystemInfoStream>(*ExpectedInfo, 528 std::move(*ExpectedCSDVersion)); 529 } 530 case StreamKind::TextContent: 531 return std::make_unique<TextContentStream>( 532 StreamDesc.Type, toStringRef(File.getRawStream(StreamDesc))); 533 case StreamKind::ThreadList: { 534 auto ExpectedList = File.getThreadList(); 535 if (!ExpectedList) 536 return ExpectedList.takeError(); 537 std::vector<ThreadListStream::entry_type> Threads; 538 for (const Thread &T : *ExpectedList) { 539 auto ExpectedStack = File.getRawData(T.Stack.Memory); 540 if (!ExpectedStack) 541 return ExpectedStack.takeError(); 542 auto ExpectedContext = File.getRawData(T.Context); 543 if (!ExpectedContext) 544 return ExpectedContext.takeError(); 545 Threads.push_back({T, *ExpectedStack, *ExpectedContext}); 546 } 547 return std::make_unique<ThreadListStream>(std::move(Threads)); 548 } 549 } 550 llvm_unreachable("Unhandled stream kind!"); 551 } 552 553 Expected<Object> Object::create(const object::MinidumpFile &File) { 554 std::vector<std::unique_ptr<Stream>> Streams; 555 Streams.reserve(File.streams().size()); 556 for (const Directory &StreamDesc : File.streams()) { 557 auto ExpectedStream = Stream::create(StreamDesc, File); 558 if (!ExpectedStream) 559 return ExpectedStream.takeError(); 560 Streams.push_back(std::move(*ExpectedStream)); 561 } 562 return Object(File.header(), std::move(Streams)); 563 } 564