Mercurial > hg > CbC > CbC_llvm
view lld/wasm/Writer.cpp @ 240:ca573705d418
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| author | matac |
|---|---|
| date | Fri, 28 Jul 2023 20:50:09 +0900 |
| parents | c4bab56944e8 |
| children | 1f2b6ac9f198 |
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//===- Writer.cpp ---------------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "Writer.h" #include "Config.h" #include "InputChunks.h" #include "InputElement.h" #include "MapFile.h" #include "OutputSections.h" #include "OutputSegment.h" #include "Relocations.h" #include "SymbolTable.h" #include "SyntheticSections.h" #include "WriterUtils.h" #include "lld/Common/CommonLinkerContext.h" #include "lld/Common/Strings.h" #include "llvm/ADT/DenseSet.h" #include "llvm/ADT/SmallSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/StringMap.h" #include "llvm/BinaryFormat/Wasm.h" #include "llvm/BinaryFormat/WasmTraits.h" #include "llvm/Support/FileOutputBuffer.h" #include "llvm/Support/Format.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/LEB128.h" #include "llvm/Support/Parallel.h" #include <cstdarg> #include <map> #define DEBUG_TYPE "lld" using namespace llvm; using namespace llvm::wasm; namespace lld { namespace wasm { static constexpr int stackAlignment = 16; static constexpr int heapAlignment = 16; namespace { // The writer writes a SymbolTable result to a file. class Writer { public: void run(); private: void openFile(); bool needsPassiveInitialization(const OutputSegment *segment); bool hasPassiveInitializedSegments(); void createSyntheticInitFunctions(); void createInitMemoryFunction(); void createStartFunction(); void createApplyDataRelocationsFunction(); void createApplyGlobalRelocationsFunction(); void createApplyGlobalTLSRelocationsFunction(); void createCallCtorsFunction(); void createInitTLSFunction(); void createCommandExportWrappers(); void createCommandExportWrapper(uint32_t functionIndex, DefinedFunction *f); void assignIndexes(); void populateSymtab(); void populateProducers(); void populateTargetFeatures(); // populateTargetFeatures happens early on so some checks are delayed // until imports and exports are finalized. There are run unstead // in checkImportExportTargetFeatures void checkImportExportTargetFeatures(); void calculateInitFunctions(); void calculateImports(); void calculateExports(); void calculateCustomSections(); void calculateTypes(); void createOutputSegments(); OutputSegment *createOutputSegment(StringRef name); void combineOutputSegments(); void layoutMemory(); void createHeader(); void addSection(OutputSection *sec); void addSections(); void createCustomSections(); void createSyntheticSections(); void createSyntheticSectionsPostLayout(); void finalizeSections(); // Custom sections void createRelocSections(); void writeHeader(); void writeSections(); uint64_t fileSize = 0; std::vector<WasmInitEntry> initFunctions; llvm::StringMap<std::vector<InputChunk *>> customSectionMapping; // Stable storage for command export wrapper function name strings. std::list<std::string> commandExportWrapperNames; // Elements that are used to construct the final output std::string header; std::vector<OutputSection *> outputSections; std::unique_ptr<FileOutputBuffer> buffer; std::vector<OutputSegment *> segments; llvm::SmallDenseMap<StringRef, OutputSegment *> segmentMap; }; } // anonymous namespace void Writer::calculateCustomSections() { log("calculateCustomSections"); bool stripDebug = config->stripDebug || config->stripAll; for (ObjFile *file : symtab->objectFiles) { for (InputChunk *section : file->customSections) { // Exclude COMDAT sections that are not selected for inclusion if (section->discarded) continue; StringRef name = section->name; // These custom sections are known the linker and synthesized rather than // blindly copied. if (name == "linking" || name == "name" || name == "producers" || name == "target_features" || name.startswith("reloc.")) continue; // These custom sections are generated by `clang -fembed-bitcode`. // These are used by the rust toolchain to ship LTO data along with // compiled object code, but they don't want this included in the linker // output. if (name == ".llvmbc" || name == ".llvmcmd") continue; // Strip debug section in that option was specified. if (stripDebug && name.startswith(".debug_")) continue; // Otherwise include custom sections by default and concatenate their // contents. customSectionMapping[name].push_back(section); } } } void Writer::createCustomSections() { log("createCustomSections"); for (auto &pair : customSectionMapping) { StringRef name = pair.first(); LLVM_DEBUG(dbgs() << "createCustomSection: " << name << "\n"); OutputSection *sec = make<CustomSection>(std::string(name), pair.second); if (config->relocatable || config->emitRelocs) { auto *sym = make<OutputSectionSymbol>(sec); out.linkingSec->addToSymtab(sym); sec->sectionSym = sym; } addSection(sec); } } // Create relocations sections in the final output. // These are only created when relocatable output is requested. void Writer::createRelocSections() { log("createRelocSections"); // Don't use iterator here since we are adding to OutputSection size_t origSize = outputSections.size(); for (size_t i = 0; i < origSize; i++) { LLVM_DEBUG(dbgs() << "check section " << i << "\n"); OutputSection *sec = outputSections[i]; // Count the number of needed sections. uint32_t count = sec->getNumRelocations(); if (!count) continue; StringRef name; if (sec->type == WASM_SEC_DATA) name = "reloc.DATA"; else if (sec->type == WASM_SEC_CODE) name = "reloc.CODE"; else if (sec->type == WASM_SEC_CUSTOM) name = saver().save("reloc." + sec->name); else llvm_unreachable( "relocations only supported for code, data, or custom sections"); addSection(make<RelocSection>(name, sec)); } } void Writer::populateProducers() { for (ObjFile *file : symtab->objectFiles) { const WasmProducerInfo &info = file->getWasmObj()->getProducerInfo(); out.producersSec->addInfo(info); } } void Writer::writeHeader() { memcpy(buffer->getBufferStart(), header.data(), header.size()); } void Writer::writeSections() { uint8_t *buf = buffer->getBufferStart(); parallelForEach(outputSections, [buf](OutputSection *s) { assert(s->isNeeded()); s->writeTo(buf); }); } static void setGlobalPtr(DefinedGlobal *g, uint64_t memoryPtr) { LLVM_DEBUG(dbgs() << "setGlobalPtr " << g->getName() << " -> " << memoryPtr << "\n"); g->global->setPointerValue(memoryPtr); } // Fix the memory layout of the output binary. This assigns memory offsets // to each of the input data sections as well as the explicit stack region. // The default memory layout is as follows, from low to high. // // - initialized data (starting at config->globalBase) // - BSS data (not currently implemented in llvm) // - explicit stack (config->ZStackSize) // - heap start / unallocated // // The --stack-first option means that stack is placed before any static data. // This can be useful since it means that stack overflow traps immediately // rather than overwriting global data, but also increases code size since all // static data loads and stores requires larger offsets. void Writer::layoutMemory() { uint64_t memoryPtr = 0; auto placeStack = [&]() { if (config->relocatable || config->isPic) return; memoryPtr = alignTo(memoryPtr, stackAlignment); if (WasmSym::stackLow) WasmSym::stackLow->setVA(memoryPtr); if (config->zStackSize != alignTo(config->zStackSize, stackAlignment)) error("stack size must be " + Twine(stackAlignment) + "-byte aligned"); log("mem: stack size = " + Twine(config->zStackSize)); log("mem: stack base = " + Twine(memoryPtr)); memoryPtr += config->zStackSize; setGlobalPtr(cast<DefinedGlobal>(WasmSym::stackPointer), memoryPtr); if (WasmSym::stackHigh) WasmSym::stackHigh->setVA(memoryPtr); log("mem: stack top = " + Twine(memoryPtr)); }; if (config->stackFirst) { placeStack(); if (config->globalBase) { if (config->globalBase < memoryPtr) { error("--global-base cannot be less than stack size when --stack-first is used"); return; } memoryPtr = config->globalBase; } } else { if (!config->globalBase && !config->relocatable && !config->isPic) { // The default offset for static/global data, for when --global-base is // not specified on the command line. The precise value of 1024 is // somewhat arbitrary, and pre-dates wasm-ld (Its the value that // emscripten used prior to wasm-ld). config->globalBase = 1024; } memoryPtr = config->globalBase; } log("mem: global base = " + Twine(memoryPtr)); if (WasmSym::globalBase) WasmSym::globalBase->setVA(memoryPtr); uint64_t dataStart = memoryPtr; // Arbitrarily set __dso_handle handle to point to the start of the data // segments. if (WasmSym::dsoHandle) WasmSym::dsoHandle->setVA(dataStart); out.dylinkSec->memAlign = 0; for (OutputSegment *seg : segments) { out.dylinkSec->memAlign = std::max(out.dylinkSec->memAlign, seg->alignment); memoryPtr = alignTo(memoryPtr, 1ULL << seg->alignment); seg->startVA = memoryPtr; log(formatv("mem: {0,-15} offset={1,-8} size={2,-8} align={3}", seg->name, memoryPtr, seg->size, seg->alignment)); if (!config->relocatable && seg->isTLS()) { if (WasmSym::tlsSize) { auto *tlsSize = cast<DefinedGlobal>(WasmSym::tlsSize); setGlobalPtr(tlsSize, seg->size); } if (WasmSym::tlsAlign) { auto *tlsAlign = cast<DefinedGlobal>(WasmSym::tlsAlign); setGlobalPtr(tlsAlign, int64_t{1} << seg->alignment); } if (!config->sharedMemory && WasmSym::tlsBase) { auto *tlsBase = cast<DefinedGlobal>(WasmSym::tlsBase); setGlobalPtr(tlsBase, memoryPtr); } } memoryPtr += seg->size; } // Make space for the memory initialization flag if (config->sharedMemory && hasPassiveInitializedSegments()) { memoryPtr = alignTo(memoryPtr, 4); WasmSym::initMemoryFlag = symtab->addSyntheticDataSymbol( "__wasm_init_memory_flag", WASM_SYMBOL_VISIBILITY_HIDDEN); WasmSym::initMemoryFlag->markLive(); WasmSym::initMemoryFlag->setVA(memoryPtr); log(formatv("mem: {0,-15} offset={1,-8} size={2,-8} align={3}", "__wasm_init_memory_flag", memoryPtr, 4, 4)); memoryPtr += 4; } if (WasmSym::dataEnd) WasmSym::dataEnd->setVA(memoryPtr); uint64_t staticDataSize = memoryPtr - dataStart; log("mem: static data = " + Twine(staticDataSize)); if (config->isPic) out.dylinkSec->memSize = staticDataSize; if (!config->stackFirst) placeStack(); if (WasmSym::heapBase) { // Set `__heap_base` to follow the end of the stack or global data. The // fact that this comes last means that a malloc/brk implementation can // grow the heap at runtime. // We'll align the heap base here because memory allocators might expect // __heap_base to be aligned already. memoryPtr = alignTo(memoryPtr, heapAlignment); log("mem: heap base = " + Twine(memoryPtr)); WasmSym::heapBase->setVA(memoryPtr); } uint64_t maxMemorySetting = 1ULL << (config->is64.value_or(false) ? 48 : 32); if (config->initialMemory != 0) { if (config->initialMemory != alignTo(config->initialMemory, WasmPageSize)) error("initial memory must be " + Twine(WasmPageSize) + "-byte aligned"); if (memoryPtr > config->initialMemory) error("initial memory too small, " + Twine(memoryPtr) + " bytes needed"); if (config->initialMemory > maxMemorySetting) error("initial memory too large, cannot be greater than " + Twine(maxMemorySetting)); memoryPtr = config->initialMemory; } memoryPtr = alignTo(memoryPtr, WasmPageSize); out.memorySec->numMemoryPages = memoryPtr / WasmPageSize; log("mem: total pages = " + Twine(out.memorySec->numMemoryPages)); if (WasmSym::heapEnd) { // Set `__heap_end` to follow the end of the statically allocated linear // memory. The fact that this comes last means that a malloc/brk // implementation can grow the heap at runtime. log("mem: heap end = " + Twine(memoryPtr)); WasmSym::heapEnd->setVA(memoryPtr); } if (config->maxMemory != 0) { if (config->maxMemory != alignTo(config->maxMemory, WasmPageSize)) error("maximum memory must be " + Twine(WasmPageSize) + "-byte aligned"); if (memoryPtr > config->maxMemory) error("maximum memory too small, " + Twine(memoryPtr) + " bytes needed"); if (config->maxMemory > maxMemorySetting) error("maximum memory too large, cannot be greater than " + Twine(maxMemorySetting)); } // Check max if explicitly supplied or required by shared memory if (config->maxMemory != 0 || config->sharedMemory) { uint64_t max = config->maxMemory; if (max == 0) { // If no maxMemory config was supplied but we are building with // shared memory, we need to pick a sensible upper limit. if (config->isPic) max = maxMemorySetting; else max = memoryPtr; } out.memorySec->maxMemoryPages = max / WasmPageSize; log("mem: max pages = " + Twine(out.memorySec->maxMemoryPages)); } } void Writer::addSection(OutputSection *sec) { if (!sec->isNeeded()) return; log("addSection: " + toString(*sec)); sec->sectionIndex = outputSections.size(); outputSections.push_back(sec); } // If a section name is valid as a C identifier (which is rare because of // the leading '.'), linkers are expected to define __start_<secname> and // __stop_<secname> symbols. They are at beginning and end of the section, // respectively. This is not requested by the ELF standard, but GNU ld and // gold provide the feature, and used by many programs. static void addStartStopSymbols(const OutputSegment *seg) { StringRef name = seg->name; if (!isValidCIdentifier(name)) return; LLVM_DEBUG(dbgs() << "addStartStopSymbols: " << name << "\n"); uint64_t start = seg->startVA; uint64_t stop = start + seg->size; symtab->addOptionalDataSymbol(saver().save("__start_" + name), start); symtab->addOptionalDataSymbol(saver().save("__stop_" + name), stop); } void Writer::addSections() { addSection(out.dylinkSec); addSection(out.typeSec); addSection(out.importSec); addSection(out.functionSec); addSection(out.tableSec); addSection(out.memorySec); addSection(out.tagSec); addSection(out.globalSec); addSection(out.exportSec); addSection(out.startSec); addSection(out.elemSec); addSection(out.dataCountSec); addSection(make<CodeSection>(out.functionSec->inputFunctions)); addSection(make<DataSection>(segments)); createCustomSections(); addSection(out.linkingSec); if (config->emitRelocs || config->relocatable) { createRelocSections(); } addSection(out.nameSec); addSection(out.producersSec); addSection(out.targetFeaturesSec); } void Writer::finalizeSections() { for (OutputSection *s : outputSections) { s->setOffset(fileSize); s->finalizeContents(); fileSize += s->getSize(); } } void Writer::populateTargetFeatures() { StringMap<std::string> used; StringMap<std::string> required; StringMap<std::string> disallowed; SmallSet<std::string, 8> &allowed = out.targetFeaturesSec->features; bool tlsUsed = false; if (config->isPic) { // This should not be necessary because all PIC objects should // contain the mutable-globals feature. // TODO(https://bugs.llvm.org/show_bug.cgi?id=52339) allowed.insert("mutable-globals"); } if (config->extraFeatures.has_value()) { auto &extraFeatures = config->extraFeatures.value(); allowed.insert(extraFeatures.begin(), extraFeatures.end()); } // Only infer used features if user did not specify features bool inferFeatures = !config->features.has_value(); if (!inferFeatures) { auto &explicitFeatures = config->features.value(); allowed.insert(explicitFeatures.begin(), explicitFeatures.end()); if (!config->checkFeatures) goto done; } // Find the sets of used, required, and disallowed features for (ObjFile *file : symtab->objectFiles) { StringRef fileName(file->getName()); for (auto &feature : file->getWasmObj()->getTargetFeatures()) { switch (feature.Prefix) { case WASM_FEATURE_PREFIX_USED: used.insert({feature.Name, std::string(fileName)}); break; case WASM_FEATURE_PREFIX_REQUIRED: used.insert({feature.Name, std::string(fileName)}); required.insert({feature.Name, std::string(fileName)}); break; case WASM_FEATURE_PREFIX_DISALLOWED: disallowed.insert({feature.Name, std::string(fileName)}); break; default: error("Unrecognized feature policy prefix " + std::to_string(feature.Prefix)); } } // Find TLS data segments auto isTLS = [](InputChunk *segment) { return segment->live && segment->isTLS(); }; tlsUsed = tlsUsed || llvm::any_of(file->segments, isTLS); } if (inferFeatures) for (const auto &key : used.keys()) allowed.insert(std::string(key)); if (!config->checkFeatures) goto done; if (config->sharedMemory) { if (disallowed.count("shared-mem")) error("--shared-memory is disallowed by " + disallowed["shared-mem"] + " because it was not compiled with 'atomics' or 'bulk-memory' " "features."); for (auto feature : {"atomics", "bulk-memory"}) if (!allowed.count(feature)) error(StringRef("'") + feature + "' feature must be used in order to use shared memory"); } if (tlsUsed) { for (auto feature : {"atomics", "bulk-memory"}) if (!allowed.count(feature)) error(StringRef("'") + feature + "' feature must be used in order to use thread-local storage"); } // Validate that used features are allowed in output if (!inferFeatures) { for (const auto &feature : used.keys()) { if (!allowed.count(std::string(feature))) error(Twine("Target feature '") + feature + "' used by " + used[feature] + " is not allowed."); } } // Validate the required and disallowed constraints for each file for (ObjFile *file : symtab->objectFiles) { StringRef fileName(file->getName()); SmallSet<std::string, 8> objectFeatures; for (const auto &feature : file->getWasmObj()->getTargetFeatures()) { if (feature.Prefix == WASM_FEATURE_PREFIX_DISALLOWED) continue; objectFeatures.insert(feature.Name); if (disallowed.count(feature.Name)) error(Twine("Target feature '") + feature.Name + "' used in " + fileName + " is disallowed by " + disallowed[feature.Name] + ". Use --no-check-features to suppress."); } for (const auto &feature : required.keys()) { if (!objectFeatures.count(std::string(feature))) error(Twine("Missing target feature '") + feature + "' in " + fileName + ", required by " + required[feature] + ". Use --no-check-features to suppress."); } } done: // Normally we don't include bss segments in the binary. In particular if // memory is not being imported then we can assume its zero initialized. // In the case the memory is imported, and we can use the memory.fill // instruction, then we can also avoid including the segments. if (config->memoryImport.has_value() && !allowed.count("bulk-memory")) config->emitBssSegments = true; if (allowed.count("extended-const")) config->extendedConst = true; for (auto &feature : allowed) log("Allowed feature: " + feature); } void Writer::checkImportExportTargetFeatures() { if (config->relocatable || !config->checkFeatures) return; if (out.targetFeaturesSec->features.count("mutable-globals") == 0) { for (const Symbol *sym : out.importSec->importedSymbols) { if (auto *global = dyn_cast<GlobalSymbol>(sym)) { if (global->getGlobalType()->Mutable) { error(Twine("mutable global imported but 'mutable-globals' feature " "not present in inputs: `") + toString(*sym) + "`. Use --no-check-features to suppress."); } } } for (const Symbol *sym : out.exportSec->exportedSymbols) { if (isa<GlobalSymbol>(sym)) { error(Twine("mutable global exported but 'mutable-globals' feature " "not present in inputs: `") + toString(*sym) + "`. Use --no-check-features to suppress."); } } } } static bool shouldImport(Symbol *sym) { // We don't generate imports for data symbols. They however can be imported // as GOT entries. if (isa<DataSymbol>(sym)) return false; if (!sym->isLive()) return false; if (!sym->isUsedInRegularObj) return false; // When a symbol is weakly defined in a shared library we need to allow // it to be overridden by another module so need to both import // and export the symbol. if (config->shared && sym->isWeak() && !sym->isUndefined() && !sym->isHidden()) return true; if (!sym->isUndefined()) return false; if (sym->isWeak() && !config->relocatable && !config->isPic) return false; // In PIC mode we only need to import functions when they are called directly. // Indirect usage all goes via GOT imports. if (config->isPic) { if (auto *f = dyn_cast<UndefinedFunction>(sym)) if (!f->isCalledDirectly) return false; } if (config->isPic || config->relocatable || config->importUndefined || config->unresolvedSymbols == UnresolvedPolicy::ImportDynamic) return true; if (config->allowUndefinedSymbols.count(sym->getName()) != 0) return true; return sym->importName.has_value(); } void Writer::calculateImports() { // Some inputs require that the indirect function table be assigned to table // number 0, so if it is present and is an import, allocate it before any // other tables. if (WasmSym::indirectFunctionTable && shouldImport(WasmSym::indirectFunctionTable)) out.importSec->addImport(WasmSym::indirectFunctionTable); for (Symbol *sym : symtab->symbols()) { if (!shouldImport(sym)) continue; if (sym == WasmSym::indirectFunctionTable) continue; LLVM_DEBUG(dbgs() << "import: " << sym->getName() << "\n"); out.importSec->addImport(sym); } } void Writer::calculateExports() { if (config->relocatable) return; if (!config->relocatable && config->memoryExport.has_value()) { out.exportSec->exports.push_back( WasmExport{*config->memoryExport, WASM_EXTERNAL_MEMORY, 0}); } unsigned globalIndex = out.importSec->getNumImportedGlobals() + out.globalSec->numGlobals(); for (Symbol *sym : symtab->symbols()) { if (!sym->isExported()) continue; if (!sym->isLive()) continue; StringRef name = sym->getName(); WasmExport export_; if (auto *f = dyn_cast<DefinedFunction>(sym)) { if (Optional<StringRef> exportName = f->function->getExportName()) { name = *exportName; } export_ = {name, WASM_EXTERNAL_FUNCTION, f->getExportedFunctionIndex()}; } else if (auto *g = dyn_cast<DefinedGlobal>(sym)) { if (g->getGlobalType()->Mutable && !g->getFile() && !g->forceExport) { // Avoid exporting mutable globals are linker synthesized (e.g. // __stack_pointer or __tls_base) unless they are explicitly exported // from the command line. // Without this check `--export-all` would cause any program using the // stack pointer to export a mutable global even if none of the input // files were built with the `mutable-globals` feature. continue; } export_ = {name, WASM_EXTERNAL_GLOBAL, g->getGlobalIndex()}; } else if (auto *t = dyn_cast<DefinedTag>(sym)) { export_ = {name, WASM_EXTERNAL_TAG, t->getTagIndex()}; } else if (auto *d = dyn_cast<DefinedData>(sym)) { out.globalSec->dataAddressGlobals.push_back(d); export_ = {name, WASM_EXTERNAL_GLOBAL, globalIndex++}; } else { auto *t = cast<DefinedTable>(sym); export_ = {name, WASM_EXTERNAL_TABLE, t->getTableNumber()}; } LLVM_DEBUG(dbgs() << "Export: " << name << "\n"); out.exportSec->exports.push_back(export_); out.exportSec->exportedSymbols.push_back(sym); } } void Writer::populateSymtab() { if (!config->relocatable && !config->emitRelocs) return; for (Symbol *sym : symtab->symbols()) if (sym->isUsedInRegularObj && sym->isLive()) out.linkingSec->addToSymtab(sym); for (ObjFile *file : symtab->objectFiles) { LLVM_DEBUG(dbgs() << "Local symtab entries: " << file->getName() << "\n"); for (Symbol *sym : file->getSymbols()) if (sym->isLocal() && !isa<SectionSymbol>(sym) && sym->isLive()) out.linkingSec->addToSymtab(sym); } } void Writer::calculateTypes() { // The output type section is the union of the following sets: // 1. Any signature used in the TYPE relocation // 2. The signatures of all imported functions // 3. The signatures of all defined functions // 4. The signatures of all imported tags // 5. The signatures of all defined tags for (ObjFile *file : symtab->objectFiles) { ArrayRef<WasmSignature> types = file->getWasmObj()->types(); for (uint32_t i = 0; i < types.size(); i++) if (file->typeIsUsed[i]) file->typeMap[i] = out.typeSec->registerType(types[i]); } for (const Symbol *sym : out.importSec->importedSymbols) { if (auto *f = dyn_cast<FunctionSymbol>(sym)) out.typeSec->registerType(*f->signature); else if (auto *t = dyn_cast<TagSymbol>(sym)) out.typeSec->registerType(*t->signature); } for (const InputFunction *f : out.functionSec->inputFunctions) out.typeSec->registerType(f->signature); for (const InputTag *t : out.tagSec->inputTags) out.typeSec->registerType(t->signature); } // In a command-style link, create a wrapper for each exported symbol // which calls the constructors and destructors. void Writer::createCommandExportWrappers() { // This logic doesn't currently support Emscripten-style PIC mode. assert(!config->isPic); // If there are no ctors and there's no libc `__wasm_call_dtors` to // call, don't wrap the exports. if (initFunctions.empty() && WasmSym::callDtors == nullptr) return; std::vector<DefinedFunction *> toWrap; for (Symbol *sym : symtab->symbols()) if (sym->isExported()) if (auto *f = dyn_cast<DefinedFunction>(sym)) toWrap.push_back(f); for (auto *f : toWrap) { auto funcNameStr = (f->getName() + ".command_export").str(); commandExportWrapperNames.push_back(funcNameStr); const std::string &funcName = commandExportWrapperNames.back(); auto func = make<SyntheticFunction>(*f->getSignature(), funcName); if (f->function->getExportName()) func->setExportName(f->function->getExportName()->str()); else func->setExportName(f->getName().str()); DefinedFunction *def = symtab->addSyntheticFunction(funcName, f->flags, func); def->markLive(); def->flags |= WASM_SYMBOL_EXPORTED; def->flags &= ~WASM_SYMBOL_VISIBILITY_HIDDEN; def->forceExport = f->forceExport; f->flags |= WASM_SYMBOL_VISIBILITY_HIDDEN; f->flags &= ~WASM_SYMBOL_EXPORTED; f->forceExport = false; out.functionSec->addFunction(func); createCommandExportWrapper(f->getFunctionIndex(), def); } } static void finalizeIndirectFunctionTable() { if (!WasmSym::indirectFunctionTable) return; if (shouldImport(WasmSym::indirectFunctionTable) && !WasmSym::indirectFunctionTable->hasTableNumber()) { // Processing -Bsymbolic relocations resulted in a late requirement that the // indirect function table be present, and we are running in --import-table // mode. Add the table now to the imports section. Otherwise it will be // added to the tables section later in assignIndexes. out.importSec->addImport(WasmSym::indirectFunctionTable); } uint32_t tableSize = config->tableBase + out.elemSec->numEntries(); WasmLimits limits = {0, tableSize, 0}; if (WasmSym::indirectFunctionTable->isDefined() && !config->growableTable) { limits.Flags |= WASM_LIMITS_FLAG_HAS_MAX; limits.Maximum = limits.Minimum; } WasmSym::indirectFunctionTable->setLimits(limits); } static void scanRelocations() { for (ObjFile *file : symtab->objectFiles) { LLVM_DEBUG(dbgs() << "scanRelocations: " << file->getName() << "\n"); for (InputChunk *chunk : file->functions) scanRelocations(chunk); for (InputChunk *chunk : file->segments) scanRelocations(chunk); for (auto &p : file->customSections) scanRelocations(p); } } void Writer::assignIndexes() { // Seal the import section, since other index spaces such as function and // global are effected by the number of imports. out.importSec->seal(); for (InputFunction *func : symtab->syntheticFunctions) out.functionSec->addFunction(func); for (ObjFile *file : symtab->objectFiles) { LLVM_DEBUG(dbgs() << "Functions: " << file->getName() << "\n"); for (InputFunction *func : file->functions) out.functionSec->addFunction(func); } for (InputGlobal *global : symtab->syntheticGlobals) out.globalSec->addGlobal(global); for (ObjFile *file : symtab->objectFiles) { LLVM_DEBUG(dbgs() << "Globals: " << file->getName() << "\n"); for (InputGlobal *global : file->globals) out.globalSec->addGlobal(global); } for (ObjFile *file : symtab->objectFiles) { LLVM_DEBUG(dbgs() << "Tags: " << file->getName() << "\n"); for (InputTag *tag : file->tags) out.tagSec->addTag(tag); } for (ObjFile *file : symtab->objectFiles) { LLVM_DEBUG(dbgs() << "Tables: " << file->getName() << "\n"); for (InputTable *table : file->tables) out.tableSec->addTable(table); } for (InputTable *table : symtab->syntheticTables) out.tableSec->addTable(table); out.globalSec->assignIndexes(); out.tableSec->assignIndexes(); } static StringRef getOutputDataSegmentName(const InputChunk &seg) { // We always merge .tbss and .tdata into a single TLS segment so all TLS // symbols are be relative to single __tls_base. if (seg.isTLS()) return ".tdata"; if (!config->mergeDataSegments) return seg.name; if (seg.name.startswith(".text.")) return ".text"; if (seg.name.startswith(".data.")) return ".data"; if (seg.name.startswith(".bss.")) return ".bss"; if (seg.name.startswith(".rodata.")) return ".rodata"; return seg.name; } OutputSegment *Writer::createOutputSegment(StringRef name) { LLVM_DEBUG(dbgs() << "new segment: " << name << "\n"); OutputSegment *s = make<OutputSegment>(name); if (config->sharedMemory) s->initFlags = WASM_DATA_SEGMENT_IS_PASSIVE; if (!config->relocatable && name.startswith(".bss")) s->isBss = true; segments.push_back(s); return s; } void Writer::createOutputSegments() { for (ObjFile *file : symtab->objectFiles) { for (InputChunk *segment : file->segments) { if (!segment->live) continue; StringRef name = getOutputDataSegmentName(*segment); OutputSegment *s = nullptr; // When running in relocatable mode we can't merge segments that are part // of comdat groups since the ultimate linker needs to be able exclude or // include them individually. if (config->relocatable && !segment->getComdatName().empty()) { s = createOutputSegment(name); } else { if (segmentMap.count(name) == 0) segmentMap[name] = createOutputSegment(name); s = segmentMap[name]; } s->addInputSegment(segment); } } // Sort segments by type, placing .bss last std::stable_sort(segments.begin(), segments.end(), [](const OutputSegment *a, const OutputSegment *b) { auto order = [](StringRef name) { return StringSwitch<int>(name) .StartsWith(".tdata", 0) .StartsWith(".rodata", 1) .StartsWith(".data", 2) .StartsWith(".bss", 4) .Default(3); }; return order(a->name) < order(b->name); }); for (size_t i = 0; i < segments.size(); ++i) segments[i]->index = i; // Merge MergeInputSections into a single MergeSyntheticSection. LLVM_DEBUG(dbgs() << "-- finalize input semgments\n"); for (OutputSegment *seg : segments) seg->finalizeInputSegments(); } void Writer::combineOutputSegments() { // With PIC code we currently only support a single active data segment since // we only have a single __memory_base to use as our base address. This pass // combines all data segments into a single .data segment. // This restriction does not apply when the extended const extension is // available: https://github.com/WebAssembly/extended-const assert(!config->extendedConst); assert(config->isPic && !config->sharedMemory); if (segments.size() <= 1) return; OutputSegment *combined = make<OutputSegment>(".data"); combined->startVA = segments[0]->startVA; for (OutputSegment *s : segments) { bool first = true; for (InputChunk *inSeg : s->inputSegments) { if (first) inSeg->alignment = std::max(inSeg->alignment, s->alignment); first = false; #ifndef NDEBUG uint64_t oldVA = inSeg->getVA(); #endif combined->addInputSegment(inSeg); #ifndef NDEBUG uint64_t newVA = inSeg->getVA(); LLVM_DEBUG(dbgs() << "added input segment. name=" << inSeg->name << " oldVA=" << oldVA << " newVA=" << newVA << "\n"); assert(oldVA == newVA); #endif } } segments = {combined}; } static void createFunction(DefinedFunction *func, StringRef bodyContent) { std::string functionBody; { raw_string_ostream os(functionBody); writeUleb128(os, bodyContent.size(), "function size"); os << bodyContent; } ArrayRef<uint8_t> body = arrayRefFromStringRef(saver().save(functionBody)); cast<SyntheticFunction>(func->function)->setBody(body); } bool Writer::needsPassiveInitialization(const OutputSegment *segment) { // If bulk memory features is supported then we can perform bss initialization // (via memory.fill) during `__wasm_init_memory`. if (config->memoryImport.has_value() && !segment->requiredInBinary()) return true; return segment->initFlags & WASM_DATA_SEGMENT_IS_PASSIVE; } bool Writer::hasPassiveInitializedSegments() { return llvm::any_of(segments, [this](const OutputSegment *s) { return this->needsPassiveInitialization(s); }); } void Writer::createSyntheticInitFunctions() { if (config->relocatable) return; static WasmSignature nullSignature = {{}, {}}; // Passive segments are used to avoid memory being reinitialized on each // thread's instantiation. These passive segments are initialized and // dropped in __wasm_init_memory, which is registered as the start function // We also initialize bss segments (using memory.fill) as part of this // function. if (hasPassiveInitializedSegments()) { WasmSym::initMemory = symtab->addSyntheticFunction( "__wasm_init_memory", WASM_SYMBOL_VISIBILITY_HIDDEN, make<SyntheticFunction>(nullSignature, "__wasm_init_memory")); WasmSym::initMemory->markLive(); if (config->sharedMemory) { // This global is assigned during __wasm_init_memory in the shared memory // case. WasmSym::tlsBase->markLive(); } } if (config->sharedMemory && out.globalSec->needsTLSRelocations()) { WasmSym::applyGlobalTLSRelocs = symtab->addSyntheticFunction( "__wasm_apply_global_tls_relocs", WASM_SYMBOL_VISIBILITY_HIDDEN, make<SyntheticFunction>(nullSignature, "__wasm_apply_global_tls_relocs")); WasmSym::applyGlobalTLSRelocs->markLive(); // TLS relocations depend on the __tls_base symbols WasmSym::tlsBase->markLive(); } if (config->isPic && out.globalSec->needsRelocations()) { WasmSym::applyGlobalRelocs = symtab->addSyntheticFunction( "__wasm_apply_global_relocs", WASM_SYMBOL_VISIBILITY_HIDDEN, make<SyntheticFunction>(nullSignature, "__wasm_apply_global_relocs")); WasmSym::applyGlobalRelocs->markLive(); } // If there is only one start function we can just use that function // itself as the Wasm start function, otherwise we need to synthesize // a new function to call them in sequence. if (WasmSym::applyGlobalRelocs && WasmSym::initMemory) { WasmSym::startFunction = symtab->addSyntheticFunction( "__wasm_start", WASM_SYMBOL_VISIBILITY_HIDDEN, make<SyntheticFunction>(nullSignature, "__wasm_start")); WasmSym::startFunction->markLive(); } } void Writer::createInitMemoryFunction() { LLVM_DEBUG(dbgs() << "createInitMemoryFunction\n"); assert(WasmSym::initMemory); assert(hasPassiveInitializedSegments()); uint64_t flagAddress; if (config->sharedMemory) { assert(WasmSym::initMemoryFlag); flagAddress = WasmSym::initMemoryFlag->getVA(); } bool is64 = config->is64.value_or(false); std::string bodyContent; { raw_string_ostream os(bodyContent); // Initialize memory in a thread-safe manner. The thread that successfully // increments the flag from 0 to 1 is is responsible for performing the // memory initialization. Other threads go sleep on the flag until the // first thread finishing initializing memory, increments the flag to 2, // and wakes all the other threads. Once the flag has been set to 2, // subsequently started threads will skip the sleep. All threads // unconditionally drop their passive data segments once memory has been // initialized. The generated code is as follows: // // (func $__wasm_init_memory // (block $drop // (block $wait // (block $init // (br_table $init $wait $drop // (i32.atomic.rmw.cmpxchg align=2 offset=0 // (i32.const $__init_memory_flag) // (i32.const 0) // (i32.const 1) // ) // ) // ) ;; $init // ( ... initialize data segments ... ) // (i32.atomic.store align=2 offset=0 // (i32.const $__init_memory_flag) // (i32.const 2) // ) // (drop // (i32.atomic.notify align=2 offset=0 // (i32.const $__init_memory_flag) // (i32.const -1u) // ) // ) // (br $drop) // ) ;; $wait // (drop // (i32.atomic.wait align=2 offset=0 // (i32.const $__init_memory_flag) // (i32.const 1) // (i32.const -1) // ) // ) // ) ;; $drop // ( ... drop data segments ... ) // ) // // When we are building with PIC, calculate the flag location using: // // (global.get $__memory_base) // (i32.const $__init_memory_flag) // (i32.const 1) auto writeGetFlagAddress = [&]() { if (config->isPic) { writeU8(os, WASM_OPCODE_LOCAL_GET, "local.get"); writeUleb128(os, 0, "local 0"); } else { writePtrConst(os, flagAddress, is64, "flag address"); } }; if (config->sharedMemory) { // With PIC code we cache the flag address in local 0 if (config->isPic) { writeUleb128(os, 1, "num local decls"); writeUleb128(os, 2, "local count"); writeU8(os, is64 ? WASM_TYPE_I64 : WASM_TYPE_I32, "address type"); writeU8(os, WASM_OPCODE_GLOBAL_GET, "GLOBAL_GET"); writeUleb128(os, WasmSym::memoryBase->getGlobalIndex(), "memory_base"); writePtrConst(os, flagAddress, is64, "flag address"); writeU8(os, is64 ? WASM_OPCODE_I64_ADD : WASM_OPCODE_I32_ADD, "add"); writeU8(os, WASM_OPCODE_LOCAL_SET, "local.set"); writeUleb128(os, 0, "local 0"); } else { writeUleb128(os, 0, "num locals"); } // Set up destination blocks writeU8(os, WASM_OPCODE_BLOCK, "block $drop"); writeU8(os, WASM_TYPE_NORESULT, "block type"); writeU8(os, WASM_OPCODE_BLOCK, "block $wait"); writeU8(os, WASM_TYPE_NORESULT, "block type"); writeU8(os, WASM_OPCODE_BLOCK, "block $init"); writeU8(os, WASM_TYPE_NORESULT, "block type"); // Atomically check whether we win the race. writeGetFlagAddress(); writeI32Const(os, 0, "expected flag value"); writeI32Const(os, 1, "new flag value"); writeU8(os, WASM_OPCODE_ATOMICS_PREFIX, "atomics prefix"); writeUleb128(os, WASM_OPCODE_I32_RMW_CMPXCHG, "i32.atomic.rmw.cmpxchg"); writeMemArg(os, 2, 0); // Based on the value, decide what to do next. writeU8(os, WASM_OPCODE_BR_TABLE, "br_table"); writeUleb128(os, 2, "label vector length"); writeUleb128(os, 0, "label $init"); writeUleb128(os, 1, "label $wait"); writeUleb128(os, 2, "default label $drop"); // Initialize passive data segments writeU8(os, WASM_OPCODE_END, "end $init"); } else { writeUleb128(os, 0, "num local decls"); } for (const OutputSegment *s : segments) { if (needsPassiveInitialization(s)) { // For passive BSS segments we can simple issue a memory.fill(0). // For non-BSS segments we do a memory.init. Both these // instructions take as their first argument the destination // address. writePtrConst(os, s->startVA, is64, "destination address"); if (config->isPic) { writeU8(os, WASM_OPCODE_GLOBAL_GET, "GLOBAL_GET"); writeUleb128(os, WasmSym::memoryBase->getGlobalIndex(), "__memory_base"); writeU8(os, is64 ? WASM_OPCODE_I64_ADD : WASM_OPCODE_I32_ADD, "i32.add"); } // When we initialize the TLS segment we also set the `__tls_base` // global. This allows the runtime to use this static copy of the // TLS data for the first/main thread. if (config->sharedMemory && s->isTLS()) { if (config->isPic) { // Cache the result of the addionion in local 0 writeU8(os, WASM_OPCODE_LOCAL_TEE, "local.tee"); writeUleb128(os, 1, "local 1"); } else { writePtrConst(os, s->startVA, is64, "destination address"); } writeU8(os, WASM_OPCODE_GLOBAL_SET, "GLOBAL_SET"); writeUleb128(os, WasmSym::tlsBase->getGlobalIndex(), "__tls_base"); if (config->isPic) { writeU8(os, WASM_OPCODE_LOCAL_GET, "local.tee"); writeUleb128(os, 1, "local 1"); } } if (s->isBss) { writeI32Const(os, 0, "fill value"); writeI32Const(os, s->size, "memory region size"); writeU8(os, WASM_OPCODE_MISC_PREFIX, "bulk-memory prefix"); writeUleb128(os, WASM_OPCODE_MEMORY_FILL, "memory.fill"); writeU8(os, 0, "memory index immediate"); } else { writeI32Const(os, 0, "source segment offset"); writeI32Const(os, s->size, "memory region size"); writeU8(os, WASM_OPCODE_MISC_PREFIX, "bulk-memory prefix"); writeUleb128(os, WASM_OPCODE_MEMORY_INIT, "memory.init"); writeUleb128(os, s->index, "segment index immediate"); writeU8(os, 0, "memory index immediate"); } } } if (config->sharedMemory) { // Set flag to 2 to mark end of initialization writeGetFlagAddress(); writeI32Const(os, 2, "flag value"); writeU8(os, WASM_OPCODE_ATOMICS_PREFIX, "atomics prefix"); writeUleb128(os, WASM_OPCODE_I32_ATOMIC_STORE, "i32.atomic.store"); writeMemArg(os, 2, 0); // Notify any waiters that memory initialization is complete writeGetFlagAddress(); writeI32Const(os, -1, "number of waiters"); writeU8(os, WASM_OPCODE_ATOMICS_PREFIX, "atomics prefix"); writeUleb128(os, WASM_OPCODE_ATOMIC_NOTIFY, "atomic.notify"); writeMemArg(os, 2, 0); writeU8(os, WASM_OPCODE_DROP, "drop"); // Branch to drop the segments writeU8(os, WASM_OPCODE_BR, "br"); writeUleb128(os, 1, "label $drop"); // Wait for the winning thread to initialize memory writeU8(os, WASM_OPCODE_END, "end $wait"); writeGetFlagAddress(); writeI32Const(os, 1, "expected flag value"); writeI64Const(os, -1, "timeout"); writeU8(os, WASM_OPCODE_ATOMICS_PREFIX, "atomics prefix"); writeUleb128(os, WASM_OPCODE_I32_ATOMIC_WAIT, "i32.atomic.wait"); writeMemArg(os, 2, 0); writeU8(os, WASM_OPCODE_DROP, "drop"); // Unconditionally drop passive data segments writeU8(os, WASM_OPCODE_END, "end $drop"); } for (const OutputSegment *s : segments) { if (needsPassiveInitialization(s) && !s->isBss) { // The TLS region should not be dropped since its is needed // during the initialization of each thread (__wasm_init_tls). if (config->sharedMemory && s->isTLS()) continue; // data.drop instruction writeU8(os, WASM_OPCODE_MISC_PREFIX, "bulk-memory prefix"); writeUleb128(os, WASM_OPCODE_DATA_DROP, "data.drop"); writeUleb128(os, s->index, "segment index immediate"); } } // End the function writeU8(os, WASM_OPCODE_END, "END"); } createFunction(WasmSym::initMemory, bodyContent); } void Writer::createStartFunction() { // If the start function exists when we have more than one function to call. if (WasmSym::initMemory && WasmSym::applyGlobalRelocs) { assert(WasmSym::startFunction); std::string bodyContent; { raw_string_ostream os(bodyContent); writeUleb128(os, 0, "num locals"); writeU8(os, WASM_OPCODE_CALL, "CALL"); writeUleb128(os, WasmSym::applyGlobalRelocs->getFunctionIndex(), "function index"); writeU8(os, WASM_OPCODE_CALL, "CALL"); writeUleb128(os, WasmSym::initMemory->getFunctionIndex(), "function index"); writeU8(os, WASM_OPCODE_END, "END"); } createFunction(WasmSym::startFunction, bodyContent); } else if (WasmSym::initMemory) { WasmSym::startFunction = WasmSym::initMemory; } else if (WasmSym::applyGlobalRelocs) { WasmSym::startFunction = WasmSym::applyGlobalRelocs; } } // For -shared (PIC) output, we create create a synthetic function which will // apply any relocations to the data segments on startup. This function is // called `__wasm_apply_data_relocs` and is expected to be called before // any user code (i.e. before `__wasm_call_ctors`). void Writer::createApplyDataRelocationsFunction() { LLVM_DEBUG(dbgs() << "createApplyDataRelocationsFunction\n"); // First write the body's contents to a string. std::string bodyContent; { raw_string_ostream os(bodyContent); writeUleb128(os, 0, "num locals"); for (const OutputSegment *seg : segments) for (const InputChunk *inSeg : seg->inputSegments) inSeg->generateRelocationCode(os); writeU8(os, WASM_OPCODE_END, "END"); } createFunction(WasmSym::applyDataRelocs, bodyContent); } // Similar to createApplyDataRelocationsFunction but generates relocation code // for WebAssembly globals. Because these globals are not shared between threads // these relocation need to run on every thread. void Writer::createApplyGlobalRelocationsFunction() { // First write the body's contents to a string. std::string bodyContent; { raw_string_ostream os(bodyContent); writeUleb128(os, 0, "num locals"); out.globalSec->generateRelocationCode(os, false); writeU8(os, WASM_OPCODE_END, "END"); } createFunction(WasmSym::applyGlobalRelocs, bodyContent); } // Similar to createApplyGlobalRelocationsFunction but for // TLS symbols. This cannot be run during the start function // but must be delayed until __wasm_init_tls is called. void Writer::createApplyGlobalTLSRelocationsFunction() { // First write the body's contents to a string. std::string bodyContent; { raw_string_ostream os(bodyContent); writeUleb128(os, 0, "num locals"); out.globalSec->generateRelocationCode(os, true); writeU8(os, WASM_OPCODE_END, "END"); } createFunction(WasmSym::applyGlobalTLSRelocs, bodyContent); } // Create synthetic "__wasm_call_ctors" function based on ctor functions // in input object. void Writer::createCallCtorsFunction() { // If __wasm_call_ctors isn't referenced, there aren't any ctors, don't // define the `__wasm_call_ctors` function. if (!WasmSym::callCtors->isLive() && initFunctions.empty()) return; // First write the body's contents to a string. std::string bodyContent; { raw_string_ostream os(bodyContent); writeUleb128(os, 0, "num locals"); // Call constructors for (const WasmInitEntry &f : initFunctions) { writeU8(os, WASM_OPCODE_CALL, "CALL"); writeUleb128(os, f.sym->getFunctionIndex(), "function index"); for (size_t i = 0; i < f.sym->signature->Returns.size(); i++) { writeU8(os, WASM_OPCODE_DROP, "DROP"); } } writeU8(os, WASM_OPCODE_END, "END"); } createFunction(WasmSym::callCtors, bodyContent); } // Create a wrapper around a function export which calls the // static constructors and destructors. void Writer::createCommandExportWrapper(uint32_t functionIndex, DefinedFunction *f) { // First write the body's contents to a string. std::string bodyContent; { raw_string_ostream os(bodyContent); writeUleb128(os, 0, "num locals"); // Call `__wasm_call_ctors` which call static constructors (and // applies any runtime relocations in Emscripten-style PIC mode) if (WasmSym::callCtors->isLive()) { writeU8(os, WASM_OPCODE_CALL, "CALL"); writeUleb128(os, WasmSym::callCtors->getFunctionIndex(), "function index"); } // Call the user's code, leaving any return values on the operand stack. for (size_t i = 0; i < f->signature->Params.size(); ++i) { writeU8(os, WASM_OPCODE_LOCAL_GET, "local.get"); writeUleb128(os, i, "local index"); } writeU8(os, WASM_OPCODE_CALL, "CALL"); writeUleb128(os, functionIndex, "function index"); // Call the function that calls the destructors. if (DefinedFunction *callDtors = WasmSym::callDtors) { writeU8(os, WASM_OPCODE_CALL, "CALL"); writeUleb128(os, callDtors->getFunctionIndex(), "function index"); } // End the function, returning the return values from the user's code. writeU8(os, WASM_OPCODE_END, "END"); } createFunction(f, bodyContent); } void Writer::createInitTLSFunction() { std::string bodyContent; { raw_string_ostream os(bodyContent); OutputSegment *tlsSeg = nullptr; for (auto *seg : segments) { if (seg->name == ".tdata") { tlsSeg = seg; break; } } writeUleb128(os, 0, "num locals"); if (tlsSeg) { writeU8(os, WASM_OPCODE_LOCAL_GET, "local.get"); writeUleb128(os, 0, "local index"); writeU8(os, WASM_OPCODE_GLOBAL_SET, "global.set"); writeUleb128(os, WasmSym::tlsBase->getGlobalIndex(), "global index"); // FIXME(wvo): this local needs to be I64 in wasm64, or we need an extend op. writeU8(os, WASM_OPCODE_LOCAL_GET, "local.get"); writeUleb128(os, 0, "local index"); writeI32Const(os, 0, "segment offset"); writeI32Const(os, tlsSeg->size, "memory region size"); writeU8(os, WASM_OPCODE_MISC_PREFIX, "bulk-memory prefix"); writeUleb128(os, WASM_OPCODE_MEMORY_INIT, "MEMORY.INIT"); writeUleb128(os, tlsSeg->index, "segment index immediate"); writeU8(os, 0, "memory index immediate"); } if (WasmSym::applyGlobalTLSRelocs) { writeU8(os, WASM_OPCODE_CALL, "CALL"); writeUleb128(os, WasmSym::applyGlobalTLSRelocs->getFunctionIndex(), "function index"); } writeU8(os, WASM_OPCODE_END, "end function"); } createFunction(WasmSym::initTLS, bodyContent); } // Populate InitFunctions vector with init functions from all input objects. // This is then used either when creating the output linking section or to // synthesize the "__wasm_call_ctors" function. void Writer::calculateInitFunctions() { if (!config->relocatable && !WasmSym::callCtors->isLive()) return; for (ObjFile *file : symtab->objectFiles) { const WasmLinkingData &l = file->getWasmObj()->linkingData(); for (const WasmInitFunc &f : l.InitFunctions) { FunctionSymbol *sym = file->getFunctionSymbol(f.Symbol); // comdat exclusions can cause init functions be discarded. if (sym->isDiscarded() || !sym->isLive()) continue; if (sym->signature->Params.size() != 0) error("constructor functions cannot take arguments: " + toString(*sym)); LLVM_DEBUG(dbgs() << "initFunctions: " << toString(*sym) << "\n"); initFunctions.emplace_back(WasmInitEntry{sym, f.Priority}); } } // Sort in order of priority (lowest first) so that they are called // in the correct order. llvm::stable_sort(initFunctions, [](const WasmInitEntry &l, const WasmInitEntry &r) { return l.priority < r.priority; }); } void Writer::createSyntheticSections() { out.dylinkSec = make<DylinkSection>(); out.typeSec = make<TypeSection>(); out.importSec = make<ImportSection>(); out.functionSec = make<FunctionSection>(); out.tableSec = make<TableSection>(); out.memorySec = make<MemorySection>(); out.tagSec = make<TagSection>(); out.globalSec = make<GlobalSection>(); out.exportSec = make<ExportSection>(); out.startSec = make<StartSection>(); out.elemSec = make<ElemSection>(); out.producersSec = make<ProducersSection>(); out.targetFeaturesSec = make<TargetFeaturesSection>(); } void Writer::createSyntheticSectionsPostLayout() { out.dataCountSec = make<DataCountSection>(segments); out.linkingSec = make<LinkingSection>(initFunctions, segments); out.nameSec = make<NameSection>(segments); } void Writer::run() { // For PIC code the table base is assigned dynamically by the loader. // For non-PIC, we start at 1 so that accessing table index 0 always traps. if (!config->isPic) { config->tableBase = 1; if (WasmSym::definedTableBase) WasmSym::definedTableBase->setVA(config->tableBase); if (WasmSym::definedTableBase32) WasmSym::definedTableBase32->setVA(config->tableBase); } log("-- createOutputSegments"); createOutputSegments(); log("-- createSyntheticSections"); createSyntheticSections(); log("-- layoutMemory"); layoutMemory(); if (!config->relocatable) { // Create linker synthesized __start_SECNAME/__stop_SECNAME symbols // This has to be done after memory layout is performed. for (const OutputSegment *seg : segments) { addStartStopSymbols(seg); } } for (auto &pair : config->exportedSymbols) { Symbol *sym = symtab->find(pair.first()); if (sym && sym->isDefined()) sym->forceExport = true; } // Delay reporting error about explicit exports until after // addStartStopSymbols which can create optional symbols. for (auto &name : config->requiredExports) { Symbol *sym = symtab->find(name); if (!sym || !sym->isDefined()) { if (config->unresolvedSymbols == UnresolvedPolicy::ReportError) error(Twine("symbol exported via --export not found: ") + name); if (config->unresolvedSymbols == UnresolvedPolicy::Warn) warn(Twine("symbol exported via --export not found: ") + name); } } log("-- populateTargetFeatures"); populateTargetFeatures(); // When outputting PIC code each segment lives at at fixes offset from the // `__memory_base` import. Unless we support the extended const expression we // can't do addition inside the constant expression, so we much combine the // segments into a single one that can live at `__memory_base`. if (config->isPic && !config->extendedConst && !config->sharedMemory) { // In shared memory mode all data segments are passive and initialized // via __wasm_init_memory. log("-- combineOutputSegments"); combineOutputSegments(); } log("-- createSyntheticSectionsPostLayout"); createSyntheticSectionsPostLayout(); log("-- populateProducers"); populateProducers(); log("-- calculateImports"); calculateImports(); log("-- scanRelocations"); scanRelocations(); log("-- finalizeIndirectFunctionTable"); finalizeIndirectFunctionTable(); log("-- createSyntheticInitFunctions"); createSyntheticInitFunctions(); log("-- assignIndexes"); assignIndexes(); log("-- calculateInitFunctions"); calculateInitFunctions(); if (!config->relocatable) { // Create linker synthesized functions if (WasmSym::applyDataRelocs) createApplyDataRelocationsFunction(); if (WasmSym::applyGlobalRelocs) createApplyGlobalRelocationsFunction(); if (WasmSym::applyGlobalTLSRelocs) createApplyGlobalTLSRelocationsFunction(); if (WasmSym::initMemory) createInitMemoryFunction(); createStartFunction(); createCallCtorsFunction(); // Create export wrappers for commands if needed. // // If the input contains a call to `__wasm_call_ctors`, either in one of // the input objects or an explicit export from the command-line, we // assume ctors and dtors are taken care of already. if (!config->relocatable && !config->isPic && !WasmSym::callCtors->isUsedInRegularObj && !WasmSym::callCtors->isExported()) { log("-- createCommandExportWrappers"); createCommandExportWrappers(); } } if (WasmSym::initTLS && WasmSym::initTLS->isLive()) { log("-- createInitTLSFunction"); createInitTLSFunction(); } if (errorCount()) return; log("-- calculateTypes"); calculateTypes(); log("-- calculateExports"); calculateExports(); log("-- calculateCustomSections"); calculateCustomSections(); log("-- populateSymtab"); populateSymtab(); log("-- checkImportExportTargetFeatures"); checkImportExportTargetFeatures(); log("-- addSections"); addSections(); if (errorHandler().verbose) { log("Defined Functions: " + Twine(out.functionSec->inputFunctions.size())); log("Defined Globals : " + Twine(out.globalSec->numGlobals())); log("Defined Tags : " + Twine(out.tagSec->inputTags.size())); log("Defined Tables : " + Twine(out.tableSec->inputTables.size())); log("Function Imports : " + Twine(out.importSec->getNumImportedFunctions())); log("Global Imports : " + Twine(out.importSec->getNumImportedGlobals())); log("Tag Imports : " + Twine(out.importSec->getNumImportedTags())); log("Table Imports : " + Twine(out.importSec->getNumImportedTables())); } createHeader(); log("-- finalizeSections"); finalizeSections(); log("-- writeMapFile"); writeMapFile(outputSections); log("-- openFile"); openFile(); if (errorCount()) return; writeHeader(); log("-- writeSections"); writeSections(); if (errorCount()) return; if (Error e = buffer->commit()) fatal("failed to write output '" + buffer->getPath() + "': " + toString(std::move(e))); } // Open a result file. void Writer::openFile() { log("writing: " + config->outputFile); Expected<std::unique_ptr<FileOutputBuffer>> bufferOrErr = FileOutputBuffer::create(config->outputFile, fileSize, FileOutputBuffer::F_executable); if (!bufferOrErr) error("failed to open " + config->outputFile + ": " + toString(bufferOrErr.takeError())); else buffer = std::move(*bufferOrErr); } void Writer::createHeader() { raw_string_ostream os(header); writeBytes(os, WasmMagic, sizeof(WasmMagic), "wasm magic"); writeU32(os, WasmVersion, "wasm version"); os.flush(); fileSize += header.size(); } void writeResult() { Writer().run(); } } // namespace wasm } // namespace lld