1 //===-- WindowsResource.cpp -------------------------------------*- C++ -*-===// 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 // This file implements the .res file class. 10 // 11 //===----------------------------------------------------------------------===// 12 13 #include "llvm/Object/WindowsResource.h" 14 #include "llvm/Object/COFF.h" 15 #include "llvm/Support/FileOutputBuffer.h" 16 #include "llvm/Support/FormatVariadic.h" 17 #include "llvm/Support/MathExtras.h" 18 #include "llvm/Support/ScopedPrinter.h" 19 #include <ctime> 20 #include <queue> 21 #include <system_error> 22 23 using namespace llvm; 24 using namespace object; 25 26 namespace llvm { 27 namespace object { 28 29 #define RETURN_IF_ERROR(X) \ 30 if (auto EC = X) \ 31 return EC; 32 33 const uint32_t MIN_HEADER_SIZE = 7 * sizeof(uint32_t) + 2 * sizeof(uint16_t); 34 35 // COFF files seem to be inconsistent with alignment between sections, just use 36 // 8-byte because it makes everyone happy. 37 const uint32_t SECTION_ALIGNMENT = sizeof(uint64_t); 38 39 uint32_t WindowsResourceParser::TreeNode::StringCount = 0; 40 uint32_t WindowsResourceParser::TreeNode::DataCount = 0; 41 42 WindowsResource::WindowsResource(MemoryBufferRef Source) 43 : Binary(Binary::ID_WinRes, Source) { 44 size_t LeadingSize = WIN_RES_MAGIC_SIZE + WIN_RES_NULL_ENTRY_SIZE; 45 BBS = BinaryByteStream(Data.getBuffer().drop_front(LeadingSize), 46 support::little); 47 } 48 49 // static 50 Expected<std::unique_ptr<WindowsResource>> 51 WindowsResource::createWindowsResource(MemoryBufferRef Source) { 52 if (Source.getBufferSize() < WIN_RES_MAGIC_SIZE + WIN_RES_NULL_ENTRY_SIZE) 53 return make_error<GenericBinaryError>( 54 Source.getBufferIdentifier() + ": too small to be a resource file", 55 object_error::invalid_file_type); 56 std::unique_ptr<WindowsResource> Ret(new WindowsResource(Source)); 57 return std::move(Ret); 58 } 59 60 Expected<ResourceEntryRef> WindowsResource::getHeadEntry() { 61 if (BBS.getLength() < sizeof(WinResHeaderPrefix) + sizeof(WinResHeaderSuffix)) 62 return make_error<EmptyResError>(getFileName() + " contains no entries", 63 object_error::unexpected_eof); 64 return ResourceEntryRef::create(BinaryStreamRef(BBS), this); 65 } 66 67 ResourceEntryRef::ResourceEntryRef(BinaryStreamRef Ref, 68 const WindowsResource *Owner) 69 : Reader(Ref), Owner(Owner) {} 70 71 Expected<ResourceEntryRef> 72 ResourceEntryRef::create(BinaryStreamRef BSR, const WindowsResource *Owner) { 73 auto Ref = ResourceEntryRef(BSR, Owner); 74 if (auto E = Ref.loadNext()) 75 return std::move(E); 76 return Ref; 77 } 78 79 Error ResourceEntryRef::moveNext(bool &End) { 80 // Reached end of all the entries. 81 if (Reader.bytesRemaining() == 0) { 82 End = true; 83 return Error::success(); 84 } 85 RETURN_IF_ERROR(loadNext()); 86 87 return Error::success(); 88 } 89 90 static Error readStringOrId(BinaryStreamReader &Reader, uint16_t &ID, 91 ArrayRef<UTF16> &Str, bool &IsString) { 92 uint16_t IDFlag; 93 RETURN_IF_ERROR(Reader.readInteger(IDFlag)); 94 IsString = IDFlag != 0xffff; 95 96 if (IsString) { 97 Reader.setOffset( 98 Reader.getOffset() - 99 sizeof(uint16_t)); // Re-read the bytes which we used to check the flag. 100 RETURN_IF_ERROR(Reader.readWideString(Str)); 101 } else 102 RETURN_IF_ERROR(Reader.readInteger(ID)); 103 104 return Error::success(); 105 } 106 107 Error ResourceEntryRef::loadNext() { 108 const WinResHeaderPrefix *Prefix; 109 RETURN_IF_ERROR(Reader.readObject(Prefix)); 110 111 if (Prefix->HeaderSize < MIN_HEADER_SIZE) 112 return make_error<GenericBinaryError>(Owner->getFileName() + 113 ": header size too small", 114 object_error::parse_failed); 115 116 RETURN_IF_ERROR(readStringOrId(Reader, TypeID, Type, IsStringType)); 117 118 RETURN_IF_ERROR(readStringOrId(Reader, NameID, Name, IsStringName)); 119 120 RETURN_IF_ERROR(Reader.padToAlignment(WIN_RES_HEADER_ALIGNMENT)); 121 122 RETURN_IF_ERROR(Reader.readObject(Suffix)); 123 124 RETURN_IF_ERROR(Reader.readArray(Data, Prefix->DataSize)); 125 126 RETURN_IF_ERROR(Reader.padToAlignment(WIN_RES_DATA_ALIGNMENT)); 127 128 return Error::success(); 129 } 130 131 WindowsResourceParser::WindowsResourceParser() : Root(false) {} 132 133 void printResourceTypeName(uint16_t TypeID, raw_ostream &OS) { 134 switch (TypeID) { 135 case 1: OS << "CURSOR (ID 1)"; break; 136 case 2: OS << "BITMAP (ID 2)"; break; 137 case 3: OS << "ICON (ID 3)"; break; 138 case 4: OS << "MENU (ID 4)"; break; 139 case 5: OS << "DIALOG (ID 5)"; break; 140 case 6: OS << "STRINGTABLE (ID 6)"; break; 141 case 7: OS << "FONTDIR (ID 7)"; break; 142 case 8: OS << "FONT (ID 8)"; break; 143 case 9: OS << "ACCELERATOR (ID 9)"; break; 144 case 10: OS << "RCDATA (ID 10)"; break; 145 case 11: OS << "MESSAGETABLE (ID 11)"; break; 146 case 12: OS << "GROUP_CURSOR (ID 12)"; break; 147 case 14: OS << "GROUP_ICON (ID 14)"; break; 148 case 16: OS << "VERSIONINFO (ID 16)"; break; 149 case 17: OS << "DLGINCLUDE (ID 17)"; break; 150 case 19: OS << "PLUGPLAY (ID 19)"; break; 151 case 20: OS << "VXD (ID 20)"; break; 152 case 21: OS << "ANICURSOR (ID 21)"; break; 153 case 22: OS << "ANIICON (ID 22)"; break; 154 case 23: OS << "HTML (ID 23)"; break; 155 case 24: OS << "MANIFEST (ID 24)"; break; 156 default: OS << "ID " << TypeID; break; 157 } 158 } 159 160 static bool convertUTF16LEToUTF8String(ArrayRef<UTF16> Src, std::string &Out) { 161 if (!sys::IsBigEndianHost) 162 return convertUTF16ToUTF8String(Src, Out); 163 164 std::vector<UTF16> EndianCorrectedSrc; 165 EndianCorrectedSrc.resize(Src.size() + 1); 166 llvm::copy(Src, EndianCorrectedSrc.begin() + 1); 167 EndianCorrectedSrc[0] = UNI_UTF16_BYTE_ORDER_MARK_SWAPPED; 168 return convertUTF16ToUTF8String(makeArrayRef(EndianCorrectedSrc), Out); 169 } 170 171 static std::string makeDuplicateResourceError( 172 const ResourceEntryRef &Entry, StringRef File1, StringRef File2) { 173 std::string Ret; 174 raw_string_ostream OS(Ret); 175 176 OS << "duplicate resource:"; 177 178 OS << " type "; 179 if (Entry.checkTypeString()) { 180 std::string UTF8; 181 if (!convertUTF16LEToUTF8String(Entry.getTypeString(), UTF8)) 182 UTF8 = "(failed conversion from UTF16)"; 183 OS << '\"' << UTF8 << '\"'; 184 } else 185 printResourceTypeName(Entry.getTypeID(), OS); 186 187 OS << "/name "; 188 if (Entry.checkNameString()) { 189 std::string UTF8; 190 if (!convertUTF16LEToUTF8String(Entry.getNameString(), UTF8)) 191 UTF8 = "(failed conversion from UTF16)"; 192 OS << '\"' << UTF8 << '\"'; 193 } else { 194 OS << "ID " << Entry.getNameID(); 195 } 196 197 OS << "/language " << Entry.getLanguage() << ", in " << File1 << " and in " 198 << File2; 199 200 return OS.str(); 201 } 202 203 Error WindowsResourceParser::parse(WindowsResource *WR, 204 std::vector<std::string> &Duplicates) { 205 auto EntryOrErr = WR->getHeadEntry(); 206 if (!EntryOrErr) { 207 auto E = EntryOrErr.takeError(); 208 if (E.isA<EmptyResError>()) { 209 // Check if the .res file contains no entries. In this case we don't have 210 // to throw an error but can rather just return without parsing anything. 211 // This applies for files which have a valid PE header magic and the 212 // mandatory empty null resource entry. Files which do not fit this 213 // criteria would have already been filtered out by 214 // WindowsResource::createWindowsResource(). 215 consumeError(std::move(E)); 216 return Error::success(); 217 } 218 return E; 219 } 220 221 ResourceEntryRef Entry = EntryOrErr.get(); 222 bool End = false; 223 while (!End) { 224 Data.push_back(Entry.getData()); 225 226 bool IsNewTypeString = false; 227 bool IsNewNameString = false; 228 229 TreeNode* Node; 230 bool IsNewNode = Root.addEntry(Entry, InputFilenames.size(), 231 IsNewTypeString, IsNewNameString, Node); 232 InputFilenames.push_back(WR->getFileName()); 233 if (!IsNewNode) { 234 Duplicates.push_back(makeDuplicateResourceError( 235 Entry, InputFilenames[Node->Origin], WR->getFileName())); 236 } 237 238 if (IsNewTypeString) 239 StringTable.push_back(Entry.getTypeString()); 240 241 if (IsNewNameString) 242 StringTable.push_back(Entry.getNameString()); 243 244 RETURN_IF_ERROR(Entry.moveNext(End)); 245 } 246 247 return Error::success(); 248 } 249 250 void WindowsResourceParser::printTree(raw_ostream &OS) const { 251 ScopedPrinter Writer(OS); 252 Root.print(Writer, "Resource Tree"); 253 } 254 255 bool WindowsResourceParser::TreeNode::addEntry(const ResourceEntryRef &Entry, 256 uint32_t Origin, 257 bool &IsNewTypeString, 258 bool &IsNewNameString, 259 TreeNode *&Result) { 260 TreeNode &TypeNode = addTypeNode(Entry, IsNewTypeString); 261 TreeNode &NameNode = TypeNode.addNameNode(Entry, IsNewNameString); 262 return NameNode.addLanguageNode(Entry, Origin, Result); 263 } 264 265 WindowsResourceParser::TreeNode::TreeNode(bool IsStringNode) { 266 if (IsStringNode) 267 StringIndex = StringCount++; 268 } 269 270 WindowsResourceParser::TreeNode::TreeNode(uint16_t MajorVersion, 271 uint16_t MinorVersion, 272 uint32_t Characteristics, 273 uint32_t Origin) 274 : IsDataNode(true), MajorVersion(MajorVersion), MinorVersion(MinorVersion), 275 Characteristics(Characteristics), Origin(Origin) { 276 DataIndex = DataCount++; 277 } 278 279 std::unique_ptr<WindowsResourceParser::TreeNode> 280 WindowsResourceParser::TreeNode::createStringNode() { 281 return std::unique_ptr<TreeNode>(new TreeNode(true)); 282 } 283 284 std::unique_ptr<WindowsResourceParser::TreeNode> 285 WindowsResourceParser::TreeNode::createIDNode() { 286 return std::unique_ptr<TreeNode>(new TreeNode(false)); 287 } 288 289 std::unique_ptr<WindowsResourceParser::TreeNode> 290 WindowsResourceParser::TreeNode::createDataNode(uint16_t MajorVersion, 291 uint16_t MinorVersion, 292 uint32_t Characteristics, 293 uint32_t Origin) { 294 return std::unique_ptr<TreeNode>( 295 new TreeNode(MajorVersion, MinorVersion, Characteristics, Origin)); 296 } 297 298 WindowsResourceParser::TreeNode & 299 WindowsResourceParser::TreeNode::addTypeNode(const ResourceEntryRef &Entry, 300 bool &IsNewTypeString) { 301 if (Entry.checkTypeString()) 302 return addNameChild(Entry.getTypeString(), IsNewTypeString); 303 else 304 return addIDChild(Entry.getTypeID()); 305 } 306 307 WindowsResourceParser::TreeNode & 308 WindowsResourceParser::TreeNode::addNameNode(const ResourceEntryRef &Entry, 309 bool &IsNewNameString) { 310 if (Entry.checkNameString()) 311 return addNameChild(Entry.getNameString(), IsNewNameString); 312 else 313 return addIDChild(Entry.getNameID()); 314 } 315 316 bool WindowsResourceParser::TreeNode::addLanguageNode( 317 const ResourceEntryRef &Entry, uint32_t Origin, TreeNode *&Result) { 318 return addDataChild(Entry.getLanguage(), Entry.getMajorVersion(), 319 Entry.getMinorVersion(), Entry.getCharacteristics(), 320 Origin, Result); 321 } 322 323 bool WindowsResourceParser::TreeNode::addDataChild( 324 uint32_t ID, uint16_t MajorVersion, uint16_t MinorVersion, 325 uint32_t Characteristics, uint32_t Origin, TreeNode *&Result) { 326 auto NewChild = 327 createDataNode(MajorVersion, MinorVersion, Characteristics, Origin); 328 auto ElementInserted = IDChildren.emplace(ID, std::move(NewChild)); 329 Result = ElementInserted.first->second.get(); 330 return ElementInserted.second; 331 } 332 333 WindowsResourceParser::TreeNode &WindowsResourceParser::TreeNode::addIDChild( 334 uint32_t ID) { 335 auto Child = IDChildren.find(ID); 336 if (Child == IDChildren.end()) { 337 auto NewChild = createIDNode(); 338 WindowsResourceParser::TreeNode &Node = *NewChild; 339 IDChildren.emplace(ID, std::move(NewChild)); 340 return Node; 341 } else 342 return *(Child->second); 343 } 344 345 WindowsResourceParser::TreeNode & 346 WindowsResourceParser::TreeNode::addNameChild(ArrayRef<UTF16> NameRef, 347 bool &IsNewString) { 348 std::string NameString; 349 convertUTF16LEToUTF8String(NameRef, NameString); 350 351 auto Child = StringChildren.find(NameString); 352 if (Child == StringChildren.end()) { 353 auto NewChild = createStringNode(); 354 IsNewString = true; 355 WindowsResourceParser::TreeNode &Node = *NewChild; 356 StringChildren.emplace(NameString, std::move(NewChild)); 357 return Node; 358 } else 359 return *(Child->second); 360 } 361 362 void WindowsResourceParser::TreeNode::print(ScopedPrinter &Writer, 363 StringRef Name) const { 364 ListScope NodeScope(Writer, Name); 365 for (auto const &Child : StringChildren) { 366 Child.second->print(Writer, Child.first); 367 } 368 for (auto const &Child : IDChildren) { 369 Child.second->print(Writer, to_string(Child.first)); 370 } 371 } 372 373 // This function returns the size of the entire resource tree, including 374 // directory tables, directory entries, and data entries. It does not include 375 // the directory strings or the relocations of the .rsrc section. 376 uint32_t WindowsResourceParser::TreeNode::getTreeSize() const { 377 uint32_t Size = (IDChildren.size() + StringChildren.size()) * 378 sizeof(coff_resource_dir_entry); 379 380 // Reached a node pointing to a data entry. 381 if (IsDataNode) { 382 Size += sizeof(coff_resource_data_entry); 383 return Size; 384 } 385 386 // If the node does not point to data, it must have a directory table pointing 387 // to other nodes. 388 Size += sizeof(coff_resource_dir_table); 389 390 for (auto const &Child : StringChildren) { 391 Size += Child.second->getTreeSize(); 392 } 393 for (auto const &Child : IDChildren) { 394 Size += Child.second->getTreeSize(); 395 } 396 return Size; 397 } 398 399 class WindowsResourceCOFFWriter { 400 public: 401 WindowsResourceCOFFWriter(COFF::MachineTypes MachineType, 402 const WindowsResourceParser &Parser, Error &E); 403 std::unique_ptr<MemoryBuffer> write(uint32_t TimeDateStamp); 404 405 private: 406 void performFileLayout(); 407 void performSectionOneLayout(); 408 void performSectionTwoLayout(); 409 void writeCOFFHeader(uint32_t TimeDateStamp); 410 void writeFirstSectionHeader(); 411 void writeSecondSectionHeader(); 412 void writeFirstSection(); 413 void writeSecondSection(); 414 void writeSymbolTable(); 415 void writeStringTable(); 416 void writeDirectoryTree(); 417 void writeDirectoryStringTable(); 418 void writeFirstSectionRelocations(); 419 std::unique_ptr<WritableMemoryBuffer> OutputBuffer; 420 char *BufferStart; 421 uint64_t CurrentOffset = 0; 422 COFF::MachineTypes MachineType; 423 const WindowsResourceParser::TreeNode &Resources; 424 const ArrayRef<std::vector<uint8_t>> Data; 425 uint64_t FileSize; 426 uint32_t SymbolTableOffset; 427 uint32_t SectionOneSize; 428 uint32_t SectionOneOffset; 429 uint32_t SectionOneRelocations; 430 uint32_t SectionTwoSize; 431 uint32_t SectionTwoOffset; 432 const ArrayRef<std::vector<UTF16>> StringTable; 433 std::vector<uint32_t> StringTableOffsets; 434 std::vector<uint32_t> DataOffsets; 435 std::vector<uint32_t> RelocationAddresses; 436 }; 437 438 WindowsResourceCOFFWriter::WindowsResourceCOFFWriter( 439 COFF::MachineTypes MachineType, const WindowsResourceParser &Parser, 440 Error &E) 441 : MachineType(MachineType), Resources(Parser.getTree()), 442 Data(Parser.getData()), StringTable(Parser.getStringTable()) { 443 performFileLayout(); 444 445 OutputBuffer = WritableMemoryBuffer::getNewMemBuffer( 446 FileSize, "internal .obj file created from .res files"); 447 } 448 449 void WindowsResourceCOFFWriter::performFileLayout() { 450 // Add size of COFF header. 451 FileSize = COFF::Header16Size; 452 453 // one .rsrc section header for directory tree, another for resource data. 454 FileSize += 2 * COFF::SectionSize; 455 456 performSectionOneLayout(); 457 performSectionTwoLayout(); 458 459 // We have reached the address of the symbol table. 460 SymbolTableOffset = FileSize; 461 462 FileSize += COFF::Symbol16Size; // size of the @feat.00 symbol. 463 FileSize += 4 * COFF::Symbol16Size; // symbol + aux for each section. 464 FileSize += Data.size() * COFF::Symbol16Size; // 1 symbol per resource. 465 FileSize += 4; // four null bytes for the string table. 466 } 467 468 void WindowsResourceCOFFWriter::performSectionOneLayout() { 469 SectionOneOffset = FileSize; 470 471 SectionOneSize = Resources.getTreeSize(); 472 uint32_t CurrentStringOffset = SectionOneSize; 473 uint32_t TotalStringTableSize = 0; 474 for (auto const &String : StringTable) { 475 StringTableOffsets.push_back(CurrentStringOffset); 476 uint32_t StringSize = String.size() * sizeof(UTF16) + sizeof(uint16_t); 477 CurrentStringOffset += StringSize; 478 TotalStringTableSize += StringSize; 479 } 480 SectionOneSize += alignTo(TotalStringTableSize, sizeof(uint32_t)); 481 482 // account for the relocations of section one. 483 SectionOneRelocations = FileSize + SectionOneSize; 484 FileSize += SectionOneSize; 485 FileSize += 486 Data.size() * COFF::RelocationSize; // one relocation for each resource. 487 FileSize = alignTo(FileSize, SECTION_ALIGNMENT); 488 } 489 490 void WindowsResourceCOFFWriter::performSectionTwoLayout() { 491 // add size of .rsrc$2 section, which contains all resource data on 8-byte 492 // alignment. 493 SectionTwoOffset = FileSize; 494 SectionTwoSize = 0; 495 for (auto const &Entry : Data) { 496 DataOffsets.push_back(SectionTwoSize); 497 SectionTwoSize += alignTo(Entry.size(), sizeof(uint64_t)); 498 } 499 FileSize += SectionTwoSize; 500 FileSize = alignTo(FileSize, SECTION_ALIGNMENT); 501 } 502 503 std::unique_ptr<MemoryBuffer> 504 WindowsResourceCOFFWriter::write(uint32_t TimeDateStamp) { 505 BufferStart = OutputBuffer->getBufferStart(); 506 507 writeCOFFHeader(TimeDateStamp); 508 writeFirstSectionHeader(); 509 writeSecondSectionHeader(); 510 writeFirstSection(); 511 writeSecondSection(); 512 writeSymbolTable(); 513 writeStringTable(); 514 515 return std::move(OutputBuffer); 516 } 517 518 void WindowsResourceCOFFWriter::writeCOFFHeader(uint32_t TimeDateStamp) { 519 // Write the COFF header. 520 auto *Header = reinterpret_cast<coff_file_header *>(BufferStart); 521 Header->Machine = MachineType; 522 Header->NumberOfSections = 2; 523 Header->TimeDateStamp = TimeDateStamp; 524 Header->PointerToSymbolTable = SymbolTableOffset; 525 // One symbol for every resource plus 2 for each section and 1 for @feat.00 526 Header->NumberOfSymbols = Data.size() + 5; 527 Header->SizeOfOptionalHeader = 0; 528 // cvtres.exe sets 32BIT_MACHINE even for 64-bit machine types. Match it. 529 Header->Characteristics = COFF::IMAGE_FILE_32BIT_MACHINE; 530 } 531 532 void WindowsResourceCOFFWriter::writeFirstSectionHeader() { 533 // Write the first section header. 534 CurrentOffset += sizeof(coff_file_header); 535 auto *SectionOneHeader = 536 reinterpret_cast<coff_section *>(BufferStart + CurrentOffset); 537 strncpy(SectionOneHeader->Name, ".rsrc$01", (size_t)COFF::NameSize); 538 SectionOneHeader->VirtualSize = 0; 539 SectionOneHeader->VirtualAddress = 0; 540 SectionOneHeader->SizeOfRawData = SectionOneSize; 541 SectionOneHeader->PointerToRawData = SectionOneOffset; 542 SectionOneHeader->PointerToRelocations = SectionOneRelocations; 543 SectionOneHeader->PointerToLinenumbers = 0; 544 SectionOneHeader->NumberOfRelocations = Data.size(); 545 SectionOneHeader->NumberOfLinenumbers = 0; 546 SectionOneHeader->Characteristics += COFF::IMAGE_SCN_CNT_INITIALIZED_DATA; 547 SectionOneHeader->Characteristics += COFF::IMAGE_SCN_MEM_READ; 548 } 549 550 void WindowsResourceCOFFWriter::writeSecondSectionHeader() { 551 // Write the second section header. 552 CurrentOffset += sizeof(coff_section); 553 auto *SectionTwoHeader = 554 reinterpret_cast<coff_section *>(BufferStart + CurrentOffset); 555 strncpy(SectionTwoHeader->Name, ".rsrc$02", (size_t)COFF::NameSize); 556 SectionTwoHeader->VirtualSize = 0; 557 SectionTwoHeader->VirtualAddress = 0; 558 SectionTwoHeader->SizeOfRawData = SectionTwoSize; 559 SectionTwoHeader->PointerToRawData = SectionTwoOffset; 560 SectionTwoHeader->PointerToRelocations = 0; 561 SectionTwoHeader->PointerToLinenumbers = 0; 562 SectionTwoHeader->NumberOfRelocations = 0; 563 SectionTwoHeader->NumberOfLinenumbers = 0; 564 SectionTwoHeader->Characteristics = COFF::IMAGE_SCN_CNT_INITIALIZED_DATA; 565 SectionTwoHeader->Characteristics += COFF::IMAGE_SCN_MEM_READ; 566 } 567 568 void WindowsResourceCOFFWriter::writeFirstSection() { 569 // Write section one. 570 CurrentOffset += sizeof(coff_section); 571 572 writeDirectoryTree(); 573 writeDirectoryStringTable(); 574 writeFirstSectionRelocations(); 575 576 CurrentOffset = alignTo(CurrentOffset, SECTION_ALIGNMENT); 577 } 578 579 void WindowsResourceCOFFWriter::writeSecondSection() { 580 // Now write the .rsrc$02 section. 581 for (auto const &RawDataEntry : Data) { 582 llvm::copy(RawDataEntry, BufferStart + CurrentOffset); 583 CurrentOffset += alignTo(RawDataEntry.size(), sizeof(uint64_t)); 584 } 585 586 CurrentOffset = alignTo(CurrentOffset, SECTION_ALIGNMENT); 587 } 588 589 void WindowsResourceCOFFWriter::writeSymbolTable() { 590 // Now write the symbol table. 591 // First, the feat symbol. 592 auto *Symbol = reinterpret_cast<coff_symbol16 *>(BufferStart + CurrentOffset); 593 strncpy(Symbol->Name.ShortName, "@feat.00", (size_t)COFF::NameSize); 594 Symbol->Value = 0x11; 595 Symbol->SectionNumber = 0xffff; 596 Symbol->Type = COFF::IMAGE_SYM_DTYPE_NULL; 597 Symbol->StorageClass = COFF::IMAGE_SYM_CLASS_STATIC; 598 Symbol->NumberOfAuxSymbols = 0; 599 CurrentOffset += sizeof(coff_symbol16); 600 601 // Now write the .rsrc1 symbol + aux. 602 Symbol = reinterpret_cast<coff_symbol16 *>(BufferStart + CurrentOffset); 603 strncpy(Symbol->Name.ShortName, ".rsrc$01", (size_t)COFF::NameSize); 604 Symbol->Value = 0; 605 Symbol->SectionNumber = 1; 606 Symbol->Type = COFF::IMAGE_SYM_DTYPE_NULL; 607 Symbol->StorageClass = COFF::IMAGE_SYM_CLASS_STATIC; 608 Symbol->NumberOfAuxSymbols = 1; 609 CurrentOffset += sizeof(coff_symbol16); 610 auto *Aux = reinterpret_cast<coff_aux_section_definition *>(BufferStart + 611 CurrentOffset); 612 Aux->Length = SectionOneSize; 613 Aux->NumberOfRelocations = Data.size(); 614 Aux->NumberOfLinenumbers = 0; 615 Aux->CheckSum = 0; 616 Aux->NumberLowPart = 0; 617 Aux->Selection = 0; 618 CurrentOffset += sizeof(coff_aux_section_definition); 619 620 // Now write the .rsrc2 symbol + aux. 621 Symbol = reinterpret_cast<coff_symbol16 *>(BufferStart + CurrentOffset); 622 strncpy(Symbol->Name.ShortName, ".rsrc$02", (size_t)COFF::NameSize); 623 Symbol->Value = 0; 624 Symbol->SectionNumber = 2; 625 Symbol->Type = COFF::IMAGE_SYM_DTYPE_NULL; 626 Symbol->StorageClass = COFF::IMAGE_SYM_CLASS_STATIC; 627 Symbol->NumberOfAuxSymbols = 1; 628 CurrentOffset += sizeof(coff_symbol16); 629 Aux = reinterpret_cast<coff_aux_section_definition *>(BufferStart + 630 CurrentOffset); 631 Aux->Length = SectionTwoSize; 632 Aux->NumberOfRelocations = 0; 633 Aux->NumberOfLinenumbers = 0; 634 Aux->CheckSum = 0; 635 Aux->NumberLowPart = 0; 636 Aux->Selection = 0; 637 CurrentOffset += sizeof(coff_aux_section_definition); 638 639 // Now write a symbol for each relocation. 640 for (unsigned i = 0; i < Data.size(); i++) { 641 auto RelocationName = formatv("$R{0:X-6}", i & 0xffffff).sstr<COFF::NameSize>(); 642 Symbol = reinterpret_cast<coff_symbol16 *>(BufferStart + CurrentOffset); 643 memcpy(Symbol->Name.ShortName, RelocationName.data(), (size_t) COFF::NameSize); 644 Symbol->Value = DataOffsets[i]; 645 Symbol->SectionNumber = 2; 646 Symbol->Type = COFF::IMAGE_SYM_DTYPE_NULL; 647 Symbol->StorageClass = COFF::IMAGE_SYM_CLASS_STATIC; 648 Symbol->NumberOfAuxSymbols = 0; 649 CurrentOffset += sizeof(coff_symbol16); 650 } 651 } 652 653 void WindowsResourceCOFFWriter::writeStringTable() { 654 // Just 4 null bytes for the string table. 655 auto COFFStringTable = reinterpret_cast<void *>(BufferStart + CurrentOffset); 656 memset(COFFStringTable, 0, 4); 657 } 658 659 void WindowsResourceCOFFWriter::writeDirectoryTree() { 660 // Traverse parsed resource tree breadth-first and write the corresponding 661 // COFF objects. 662 std::queue<const WindowsResourceParser::TreeNode *> Queue; 663 Queue.push(&Resources); 664 uint32_t NextLevelOffset = 665 sizeof(coff_resource_dir_table) + (Resources.getStringChildren().size() + 666 Resources.getIDChildren().size()) * 667 sizeof(coff_resource_dir_entry); 668 std::vector<const WindowsResourceParser::TreeNode *> DataEntriesTreeOrder; 669 uint32_t CurrentRelativeOffset = 0; 670 671 while (!Queue.empty()) { 672 auto CurrentNode = Queue.front(); 673 Queue.pop(); 674 auto *Table = reinterpret_cast<coff_resource_dir_table *>(BufferStart + 675 CurrentOffset); 676 Table->Characteristics = CurrentNode->getCharacteristics(); 677 Table->TimeDateStamp = 0; 678 Table->MajorVersion = CurrentNode->getMajorVersion(); 679 Table->MinorVersion = CurrentNode->getMinorVersion(); 680 auto &IDChildren = CurrentNode->getIDChildren(); 681 auto &StringChildren = CurrentNode->getStringChildren(); 682 Table->NumberOfNameEntries = StringChildren.size(); 683 Table->NumberOfIDEntries = IDChildren.size(); 684 CurrentOffset += sizeof(coff_resource_dir_table); 685 CurrentRelativeOffset += sizeof(coff_resource_dir_table); 686 687 // Write the directory entries immediately following each directory table. 688 for (auto const &Child : StringChildren) { 689 auto *Entry = reinterpret_cast<coff_resource_dir_entry *>(BufferStart + 690 CurrentOffset); 691 Entry->Identifier.setNameOffset( 692 StringTableOffsets[Child.second->getStringIndex()]); 693 if (Child.second->checkIsDataNode()) { 694 Entry->Offset.DataEntryOffset = NextLevelOffset; 695 NextLevelOffset += sizeof(coff_resource_data_entry); 696 DataEntriesTreeOrder.push_back(Child.second.get()); 697 } else { 698 Entry->Offset.SubdirOffset = NextLevelOffset + (1 << 31); 699 NextLevelOffset += sizeof(coff_resource_dir_table) + 700 (Child.second->getStringChildren().size() + 701 Child.second->getIDChildren().size()) * 702 sizeof(coff_resource_dir_entry); 703 Queue.push(Child.second.get()); 704 } 705 CurrentOffset += sizeof(coff_resource_dir_entry); 706 CurrentRelativeOffset += sizeof(coff_resource_dir_entry); 707 } 708 for (auto const &Child : IDChildren) { 709 auto *Entry = reinterpret_cast<coff_resource_dir_entry *>(BufferStart + 710 CurrentOffset); 711 Entry->Identifier.ID = Child.first; 712 if (Child.second->checkIsDataNode()) { 713 Entry->Offset.DataEntryOffset = NextLevelOffset; 714 NextLevelOffset += sizeof(coff_resource_data_entry); 715 DataEntriesTreeOrder.push_back(Child.second.get()); 716 } else { 717 Entry->Offset.SubdirOffset = NextLevelOffset + (1 << 31); 718 NextLevelOffset += sizeof(coff_resource_dir_table) + 719 (Child.second->getStringChildren().size() + 720 Child.second->getIDChildren().size()) * 721 sizeof(coff_resource_dir_entry); 722 Queue.push(Child.second.get()); 723 } 724 CurrentOffset += sizeof(coff_resource_dir_entry); 725 CurrentRelativeOffset += sizeof(coff_resource_dir_entry); 726 } 727 } 728 729 RelocationAddresses.resize(Data.size()); 730 // Now write all the resource data entries. 731 for (auto DataNodes : DataEntriesTreeOrder) { 732 auto *Entry = reinterpret_cast<coff_resource_data_entry *>(BufferStart + 733 CurrentOffset); 734 RelocationAddresses[DataNodes->getDataIndex()] = CurrentRelativeOffset; 735 Entry->DataRVA = 0; // Set to zero because it is a relocation. 736 Entry->DataSize = Data[DataNodes->getDataIndex()].size(); 737 Entry->Codepage = 0; 738 Entry->Reserved = 0; 739 CurrentOffset += sizeof(coff_resource_data_entry); 740 CurrentRelativeOffset += sizeof(coff_resource_data_entry); 741 } 742 } 743 744 void WindowsResourceCOFFWriter::writeDirectoryStringTable() { 745 // Now write the directory string table for .rsrc$01 746 uint32_t TotalStringTableSize = 0; 747 for (auto &String : StringTable) { 748 uint16_t Length = String.size(); 749 support::endian::write16le(BufferStart + CurrentOffset, Length); 750 CurrentOffset += sizeof(uint16_t); 751 auto *Start = reinterpret_cast<UTF16 *>(BufferStart + CurrentOffset); 752 llvm::copy(String, Start); 753 CurrentOffset += Length * sizeof(UTF16); 754 TotalStringTableSize += Length * sizeof(UTF16) + sizeof(uint16_t); 755 } 756 CurrentOffset += 757 alignTo(TotalStringTableSize, sizeof(uint32_t)) - TotalStringTableSize; 758 } 759 760 void WindowsResourceCOFFWriter::writeFirstSectionRelocations() { 761 762 // Now write the relocations for .rsrc$01 763 // Five symbols already in table before we start, @feat.00 and 2 for each 764 // .rsrc section. 765 uint32_t NextSymbolIndex = 5; 766 for (unsigned i = 0; i < Data.size(); i++) { 767 auto *Reloc = 768 reinterpret_cast<coff_relocation *>(BufferStart + CurrentOffset); 769 Reloc->VirtualAddress = RelocationAddresses[i]; 770 Reloc->SymbolTableIndex = NextSymbolIndex++; 771 switch (MachineType) { 772 case COFF::IMAGE_FILE_MACHINE_ARMNT: 773 Reloc->Type = COFF::IMAGE_REL_ARM_ADDR32NB; 774 break; 775 case COFF::IMAGE_FILE_MACHINE_AMD64: 776 Reloc->Type = COFF::IMAGE_REL_AMD64_ADDR32NB; 777 break; 778 case COFF::IMAGE_FILE_MACHINE_I386: 779 Reloc->Type = COFF::IMAGE_REL_I386_DIR32NB; 780 break; 781 case COFF::IMAGE_FILE_MACHINE_ARM64: 782 Reloc->Type = COFF::IMAGE_REL_ARM64_ADDR32NB; 783 break; 784 default: 785 llvm_unreachable("unknown machine type"); 786 } 787 CurrentOffset += sizeof(coff_relocation); 788 } 789 } 790 791 Expected<std::unique_ptr<MemoryBuffer>> 792 writeWindowsResourceCOFF(COFF::MachineTypes MachineType, 793 const WindowsResourceParser &Parser, 794 uint32_t TimeDateStamp) { 795 Error E = Error::success(); 796 WindowsResourceCOFFWriter Writer(MachineType, Parser, E); 797 if (E) 798 return std::move(E); 799 return Writer.write(TimeDateStamp); 800 } 801 802 } // namespace object 803 } // namespace llvm 804