//===-------- JITLink_EHFrameSupport.cpp - JITLink eh-frame utils ---------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "EHFrameSupportImpl.h" #include "llvm/BinaryFormat/Dwarf.h" #include "llvm/Config/config.h" #include "llvm/ExecutionEngine/Orc/TargetProcess/RegisterEHFrames.h" #include "llvm/Support/DynamicLibrary.h" #define DEBUG_TYPE "jitlink" namespace llvm { namespace jitlink { EHFrameSplitter::EHFrameSplitter(StringRef EHFrameSectionName) : EHFrameSectionName(EHFrameSectionName) {} Error EHFrameSplitter::operator()(LinkGraph &G) { auto *EHFrame = G.findSectionByName(EHFrameSectionName); if (!EHFrame) { LLVM_DEBUG({ dbgs() << "EHFrameSplitter: No " << EHFrameSectionName << " section. Nothing to do\n"; }); return Error::success(); } LLVM_DEBUG({ dbgs() << "EHFrameSplitter: Processing " << EHFrameSectionName << "...\n"; }); DenseMap Caches; { // Pre-build the split caches. for (auto *B : EHFrame->blocks()) Caches[B] = LinkGraph::SplitBlockCache::value_type(); for (auto *Sym : EHFrame->symbols()) Caches[&Sym->getBlock()]->push_back(Sym); for (auto *B : EHFrame->blocks()) llvm::sort(*Caches[B], [](const Symbol *LHS, const Symbol *RHS) { return LHS->getOffset() > RHS->getOffset(); }); } // Iterate over blocks (we do this by iterating over Caches entries rather // than EHFrame->blocks() as we will be inserting new blocks along the way, // which would invalidate iterators in the latter sequence. for (auto &KV : Caches) { auto &B = *KV.first; auto &BCache = KV.second; if (auto Err = processBlock(G, B, BCache)) return Err; } return Error::success(); } Error EHFrameSplitter::processBlock(LinkGraph &G, Block &B, LinkGraph::SplitBlockCache &Cache) { LLVM_DEBUG({ dbgs() << " Processing block at " << formatv("{0:x16}", B.getAddress()) << "\n"; }); // eh-frame should not contain zero-fill blocks. if (B.isZeroFill()) return make_error("Unexpected zero-fill block in " + EHFrameSectionName + " section"); if (B.getSize() == 0) { LLVM_DEBUG(dbgs() << " Block is empty. Skipping.\n"); return Error::success(); } BinaryStreamReader BlockReader(B.getContent(), G.getEndianness()); while (true) { uint64_t RecordStartOffset = BlockReader.getOffset(); LLVM_DEBUG({ dbgs() << " Processing CFI record at " << formatv("{0:x16}", B.getAddress()) << "\n"; }); uint32_t Length; if (auto Err = BlockReader.readInteger(Length)) return Err; if (Length != 0xffffffff) { if (auto Err = BlockReader.skip(Length)) return Err; } else { uint64_t ExtendedLength; if (auto Err = BlockReader.readInteger(ExtendedLength)) return Err; if (auto Err = BlockReader.skip(ExtendedLength)) return Err; } // If this was the last block then there's nothing to split if (BlockReader.empty()) { LLVM_DEBUG(dbgs() << " Extracted " << B << "\n"); return Error::success(); } uint64_t BlockSize = BlockReader.getOffset() - RecordStartOffset; auto &NewBlock = G.splitBlock(B, BlockSize); (void)NewBlock; LLVM_DEBUG(dbgs() << " Extracted " << NewBlock << "\n"); } } EHFrameEdgeFixer::EHFrameEdgeFixer(StringRef EHFrameSectionName, unsigned PointerSize, Edge::Kind Delta64, Edge::Kind Delta32, Edge::Kind NegDelta32) : EHFrameSectionName(EHFrameSectionName), PointerSize(PointerSize), Delta64(Delta64), Delta32(Delta32), NegDelta32(NegDelta32) {} Error EHFrameEdgeFixer::operator()(LinkGraph &G) { auto *EHFrame = G.findSectionByName(EHFrameSectionName); if (!EHFrame) { LLVM_DEBUG({ dbgs() << "EHFrameEdgeFixer: No " << EHFrameSectionName << " section. Nothing to do\n"; }); return Error::success(); } // Check that we support the graph's pointer size. if (G.getPointerSize() != 4 && G.getPointerSize() != 8) return make_error( "EHFrameEdgeFixer only supports 32 and 64 bit targets"); LLVM_DEBUG({ dbgs() << "EHFrameEdgeFixer: Processing " << EHFrameSectionName << "...\n"; }); ParseContext PC(G); // Build a map of all blocks and symbols in the text sections. We will use // these for finding / building edge targets when processing FDEs. for (auto &Sec : G.sections()) { PC.AddrToSyms.addSymbols(Sec.symbols()); if (auto Err = PC.AddrToBlock.addBlocks(Sec.blocks(), BlockAddressMap::includeNonNull)) return Err; } // Sort eh-frame blocks into address order to ensure we visit CIEs before // their child FDEs. std::vector EHFrameBlocks; for (auto *B : EHFrame->blocks()) EHFrameBlocks.push_back(B); llvm::sort(EHFrameBlocks, [](const Block *LHS, const Block *RHS) { return LHS->getAddress() < RHS->getAddress(); }); // Loop over the blocks in address order. for (auto *B : EHFrameBlocks) if (auto Err = processBlock(PC, *B)) return Err; return Error::success(); } Error EHFrameEdgeFixer::processBlock(ParseContext &PC, Block &B) { LLVM_DEBUG({ dbgs() << " Processing block at " << formatv("{0:x16}", B.getAddress()) << "\n"; }); // eh-frame should not contain zero-fill blocks. if (B.isZeroFill()) return make_error("Unexpected zero-fill block in " + EHFrameSectionName + " section"); if (B.getSize() == 0) { LLVM_DEBUG(dbgs() << " Block is empty. Skipping.\n"); return Error::success(); } // Find the offsets of any existing edges from this block. BlockEdgeMap BlockEdges; for (auto &E : B.edges()) if (E.isRelocation()) { if (BlockEdges.count(E.getOffset())) return make_error( "Multiple relocations at offset " + formatv("{0:x16}", E.getOffset()) + " in " + EHFrameSectionName + " block at address " + formatv("{0:x16}", B.getAddress())); BlockEdges[E.getOffset()] = EdgeTarget(E); } CIEInfosMap CIEInfos; BinaryStreamReader BlockReader(B.getContent(), PC.G.getEndianness()); while (!BlockReader.empty()) { size_t RecordStartOffset = BlockReader.getOffset(); LLVM_DEBUG({ dbgs() << " Processing CFI record at " << formatv("{0:x16}", B.getAddress() + RecordStartOffset) << "\n"; }); // Get the record length. size_t RecordRemaining; { uint32_t Length; if (auto Err = BlockReader.readInteger(Length)) return Err; // If Length < 0xffffffff then use the regular length field, otherwise // read the extended length field. if (Length != 0xffffffff) RecordRemaining = Length; else { uint64_t ExtendedLength; if (auto Err = BlockReader.readInteger(ExtendedLength)) return Err; RecordRemaining = ExtendedLength; } } if (BlockReader.bytesRemaining() < RecordRemaining) return make_error( "Incomplete CFI record at " + formatv("{0:x16}", B.getAddress() + RecordStartOffset)); // Read the CIE delta for this record. uint64_t CIEDeltaFieldOffset = BlockReader.getOffset() - RecordStartOffset; uint32_t CIEDelta; if (auto Err = BlockReader.readInteger(CIEDelta)) return Err; if (CIEDelta == 0) { if (auto Err = processCIE(PC, B, RecordStartOffset, CIEDeltaFieldOffset + RecordRemaining, CIEDeltaFieldOffset)) return Err; } else { if (auto Err = processFDE(PC, B, RecordStartOffset, CIEDeltaFieldOffset + RecordRemaining, CIEDeltaFieldOffset, CIEDelta, BlockEdges)) return Err; } // Move to the next record. BlockReader.setOffset(RecordStartOffset + CIEDeltaFieldOffset + RecordRemaining); } return Error::success(); } Error EHFrameEdgeFixer::processCIE(ParseContext &PC, Block &B, size_t RecordOffset, size_t RecordLength, size_t CIEDeltaFieldOffset) { LLVM_DEBUG(dbgs() << " Record is CIE\n"); auto RecordContent = B.getContent().substr(RecordOffset, RecordLength); BinaryStreamReader RecordReader(RecordContent, PC.G.getEndianness()); // Skip past the CIE delta field: we've already processed this far. RecordReader.setOffset(CIEDeltaFieldOffset + 4); auto &CIESymbol = PC.G.addAnonymousSymbol(B, RecordOffset, RecordLength, false, false); CIEInformation CIEInfo(CIESymbol); uint8_t Version = 0; if (auto Err = RecordReader.readInteger(Version)) return Err; if (Version != 0x01) return make_error("Bad CIE version " + Twine(Version) + " (should be 0x01) in eh-frame"); auto AugInfo = parseAugmentationString(RecordReader); if (!AugInfo) return AugInfo.takeError(); // Skip the EH Data field if present. if (AugInfo->EHDataFieldPresent) if (auto Err = RecordReader.skip(PC.G.getPointerSize())) return Err; // Read and sanity check the code alignment factor. { uint64_t CodeAlignmentFactor = 0; if (auto Err = RecordReader.readULEB128(CodeAlignmentFactor)) return Err; if (CodeAlignmentFactor != 1) return make_error("Unsupported CIE code alignment factor " + Twine(CodeAlignmentFactor) + " (expected 1)"); } // Read and sanity check the data alignment factor. { int64_t DataAlignmentFactor = 0; if (auto Err = RecordReader.readSLEB128(DataAlignmentFactor)) return Err; if (DataAlignmentFactor != -8) return make_error("Unsupported CIE data alignment factor " + Twine(DataAlignmentFactor) + " (expected -8)"); } // Skip the return address register field. if (auto Err = RecordReader.skip(1)) return Err; uint64_t AugmentationDataLength = 0; if (auto Err = RecordReader.readULEB128(AugmentationDataLength)) return Err; uint32_t AugmentationDataStartOffset = RecordReader.getOffset(); uint8_t *NextField = &AugInfo->Fields[0]; while (uint8_t Field = *NextField++) { switch (Field) { case 'L': { CIEInfo.FDEsHaveLSDAField = true; uint8_t LSDAPointerEncoding; if (auto Err = RecordReader.readInteger(LSDAPointerEncoding)) return Err; if (!isSupportedPointerEncoding(LSDAPointerEncoding)) return make_error( "Unsupported LSDA pointer encoding " + formatv("{0:x2}", LSDAPointerEncoding) + " in CIE at " + formatv("{0:x16}", CIESymbol.getAddress())); CIEInfo.LSDAPointerEncoding = LSDAPointerEncoding; break; } case 'P': { uint8_t PersonalityPointerEncoding = 0; if (auto Err = RecordReader.readInteger(PersonalityPointerEncoding)) return Err; if (PersonalityPointerEncoding != (dwarf::DW_EH_PE_indirect | dwarf::DW_EH_PE_pcrel | dwarf::DW_EH_PE_sdata4)) return make_error( "Unspported personality pointer " "encoding " + formatv("{0:x2}", PersonalityPointerEncoding) + " in CIE at " + formatv("{0:x16}", CIESymbol.getAddress())); uint32_t PersonalityPointerAddress; if (auto Err = RecordReader.readInteger(PersonalityPointerAddress)) return Err; break; } case 'R': { uint8_t FDEPointerEncoding; if (auto Err = RecordReader.readInteger(FDEPointerEncoding)) return Err; if (!isSupportedPointerEncoding(FDEPointerEncoding)) return make_error( "Unsupported FDE pointer encoding " + formatv("{0:x2}", FDEPointerEncoding) + " in CIE at " + formatv("{0:x16}", CIESymbol.getAddress())); CIEInfo.FDEPointerEncoding = FDEPointerEncoding; break; } default: llvm_unreachable("Invalid augmentation string field"); } } if (RecordReader.getOffset() - AugmentationDataStartOffset > AugmentationDataLength) return make_error("Read past the end of the augmentation " "data while parsing fields"); assert(!PC.CIEInfos.count(CIESymbol.getAddress()) && "Multiple CIEs recorded at the same address?"); PC.CIEInfos[CIESymbol.getAddress()] = std::move(CIEInfo); return Error::success(); } Error EHFrameEdgeFixer::processFDE(ParseContext &PC, Block &B, size_t RecordOffset, size_t RecordLength, size_t CIEDeltaFieldOffset, uint32_t CIEDelta, BlockEdgeMap &BlockEdges) { LLVM_DEBUG(dbgs() << " Record is FDE\n"); JITTargetAddress RecordAddress = B.getAddress() + RecordOffset; auto RecordContent = B.getContent().substr(RecordOffset, RecordLength); BinaryStreamReader RecordReader(RecordContent, PC.G.getEndianness()); // Skip past the CIE delta field: we've already read this far. RecordReader.setOffset(CIEDeltaFieldOffset + 4); auto &FDESymbol = PC.G.addAnonymousSymbol(B, RecordOffset, RecordLength, false, false); CIEInformation *CIEInfo = nullptr; { // Process the CIE pointer field. auto CIEEdgeItr = BlockEdges.find(RecordOffset + CIEDeltaFieldOffset); JITTargetAddress CIEAddress = RecordAddress + CIEDeltaFieldOffset - CIEDelta; if (CIEEdgeItr == BlockEdges.end()) { LLVM_DEBUG({ dbgs() << " Adding edge at " << formatv("{0:x16}", RecordAddress + CIEDeltaFieldOffset) << " to CIE at: " << formatv("{0:x16}", CIEAddress) << "\n"; }); if (auto CIEInfoOrErr = PC.findCIEInfo(CIEAddress)) CIEInfo = *CIEInfoOrErr; else return CIEInfoOrErr.takeError(); assert(CIEInfo->CIESymbol && "CIEInfo has no CIE symbol set"); B.addEdge(NegDelta32, RecordOffset + CIEDeltaFieldOffset, *CIEInfo->CIESymbol, 0); } else { LLVM_DEBUG({ dbgs() << " Already has edge at " << formatv("{0:x16}", RecordAddress + CIEDeltaFieldOffset) << " to CIE at " << formatv("{0:x16}", CIEAddress) << "\n"; }); auto &EI = CIEEdgeItr->second; if (EI.Addend) return make_error( "CIE edge at " + formatv("{0:x16}", RecordAddress + CIEDeltaFieldOffset) + " has non-zero addend"); if (auto CIEInfoOrErr = PC.findCIEInfo(EI.Target->getAddress())) CIEInfo = *CIEInfoOrErr; else return CIEInfoOrErr.takeError(); } } { // Process the PC-Begin field. Block *PCBeginBlock = nullptr; JITTargetAddress PCBeginFieldOffset = RecordReader.getOffset(); auto PCEdgeItr = BlockEdges.find(RecordOffset + PCBeginFieldOffset); if (PCEdgeItr == BlockEdges.end()) { auto PCBeginPtrInfo = readEncodedPointer(CIEInfo->FDEPointerEncoding, RecordAddress + PCBeginFieldOffset, RecordReader); if (!PCBeginPtrInfo) return PCBeginPtrInfo.takeError(); JITTargetAddress PCBegin = PCBeginPtrInfo->first; Edge::Kind PCBeginEdgeKind = PCBeginPtrInfo->second; LLVM_DEBUG({ dbgs() << " Adding edge at " << formatv("{0:x16}", RecordAddress + PCBeginFieldOffset) << " to PC at " << formatv("{0:x16}", PCBegin) << "\n"; }); auto PCBeginSym = getOrCreateSymbol(PC, PCBegin); if (!PCBeginSym) return PCBeginSym.takeError(); B.addEdge(PCBeginEdgeKind, RecordOffset + PCBeginFieldOffset, *PCBeginSym, 0); PCBeginBlock = &PCBeginSym->getBlock(); } else { auto &EI = PCEdgeItr->second; LLVM_DEBUG({ dbgs() << " Already has edge at " << formatv("{0:x16}", RecordAddress + PCBeginFieldOffset) << " to PC at " << formatv("{0:x16}", EI.Target->getAddress()); if (EI.Addend) dbgs() << " + " << formatv("{0:x16}", EI.Addend); dbgs() << "\n"; }); // Make sure the existing edge points at a defined block. if (!EI.Target->isDefined()) { auto EdgeAddr = RecordAddress + PCBeginFieldOffset; return make_error("FDE edge at " + formatv("{0:x16}", EdgeAddr) + " points at external block"); } PCBeginBlock = &EI.Target->getBlock(); if (auto Err = RecordReader.skip( getPointerEncodingDataSize(CIEInfo->FDEPointerEncoding))) return Err; } // Add a keep-alive edge from the FDE target to the FDE to ensure that the // FDE is kept alive if its target is. assert(PCBeginBlock && "PC-begin block not recorded"); LLVM_DEBUG({ dbgs() << " Adding keep-alive edge from target at " << formatv("{0:x16}", PCBeginBlock->getAddress()) << " to FDE at " << formatv("{0:x16}", RecordAddress) << "\n"; }); PCBeginBlock->addEdge(Edge::KeepAlive, 0, FDESymbol, 0); } // Skip over the PC range size field. if (auto Err = RecordReader.skip( getPointerEncodingDataSize(CIEInfo->FDEPointerEncoding))) return Err; if (CIEInfo->FDEsHaveLSDAField) { uint64_t AugmentationDataSize; if (auto Err = RecordReader.readULEB128(AugmentationDataSize)) return Err; JITTargetAddress LSDAFieldOffset = RecordReader.getOffset(); auto LSDAEdgeItr = BlockEdges.find(RecordOffset + LSDAFieldOffset); if (LSDAEdgeItr == BlockEdges.end()) { auto LSDAPointerInfo = readEncodedPointer(CIEInfo->LSDAPointerEncoding, RecordAddress + LSDAFieldOffset, RecordReader); if (!LSDAPointerInfo) return LSDAPointerInfo.takeError(); JITTargetAddress LSDA = LSDAPointerInfo->first; Edge::Kind LSDAEdgeKind = LSDAPointerInfo->second; auto LSDASym = getOrCreateSymbol(PC, LSDA); if (!LSDASym) return LSDASym.takeError(); LLVM_DEBUG({ dbgs() << " Adding edge at " << formatv("{0:x16}", RecordAddress + LSDAFieldOffset) << " to LSDA at " << formatv("{0:x16}", LSDA) << "\n"; }); B.addEdge(LSDAEdgeKind, RecordOffset + LSDAFieldOffset, *LSDASym, 0); } else { LLVM_DEBUG({ auto &EI = LSDAEdgeItr->second; dbgs() << " Already has edge at " << formatv("{0:x16}", RecordAddress + LSDAFieldOffset) << " to LSDA at " << formatv("{0:x16}", EI.Target->getAddress()); if (EI.Addend) dbgs() << " + " << formatv("{0:x16}", EI.Addend); dbgs() << "\n"; }); if (auto Err = RecordReader.skip(AugmentationDataSize)) return Err; } } else { LLVM_DEBUG(dbgs() << " Record does not have LSDA field.\n"); } return Error::success(); } Expected EHFrameEdgeFixer::parseAugmentationString(BinaryStreamReader &RecordReader) { AugmentationInfo AugInfo; uint8_t NextChar; uint8_t *NextField = &AugInfo.Fields[0]; if (auto Err = RecordReader.readInteger(NextChar)) return std::move(Err); while (NextChar != 0) { switch (NextChar) { case 'z': AugInfo.AugmentationDataPresent = true; break; case 'e': if (auto Err = RecordReader.readInteger(NextChar)) return std::move(Err); if (NextChar != 'h') return make_error("Unrecognized substring e" + Twine(NextChar) + " in augmentation string"); AugInfo.EHDataFieldPresent = true; break; case 'L': case 'P': case 'R': *NextField++ = NextChar; break; default: return make_error("Unrecognized character " + Twine(NextChar) + " in augmentation string"); } if (auto Err = RecordReader.readInteger(NextChar)) return std::move(Err); } return std::move(AugInfo); } bool EHFrameEdgeFixer::isSupportedPointerEncoding(uint8_t PointerEncoding) { using namespace dwarf; // We only support PC-rel for now. if ((PointerEncoding & 0x70) != DW_EH_PE_pcrel) return false; // readEncodedPointer does not handle indirect. if (PointerEncoding & DW_EH_PE_indirect) return false; // Supported datatypes. switch (PointerEncoding & 0xf) { case DW_EH_PE_absptr: case DW_EH_PE_udata4: case DW_EH_PE_udata8: case DW_EH_PE_sdata4: case DW_EH_PE_sdata8: return true; } return false; } unsigned EHFrameEdgeFixer::getPointerEncodingDataSize(uint8_t PointerEncoding) { using namespace dwarf; assert(isSupportedPointerEncoding(PointerEncoding) && "Unsupported pointer encoding"); switch (PointerEncoding & 0xf) { case DW_EH_PE_absptr: return PointerSize; case DW_EH_PE_udata4: case DW_EH_PE_sdata4: return 4; case DW_EH_PE_udata8: case DW_EH_PE_sdata8: return 8; default: llvm_unreachable("Unsupported encoding"); } } Expected> EHFrameEdgeFixer::readEncodedPointer(uint8_t PointerEncoding, JITTargetAddress PointerFieldAddress, BinaryStreamReader &RecordReader) { static_assert(sizeof(JITTargetAddress) == sizeof(uint64_t), "Result must be able to hold a uint64_t"); assert(isSupportedPointerEncoding(PointerEncoding) && "Unsupported pointer encoding"); using namespace dwarf; // Isolate data type, remap absptr to udata4 or udata8. This relies on us // having verified that the graph uses 32-bit or 64-bit pointers only at the // start of this pass. uint8_t EffectiveType = PointerEncoding & 0xf; if (EffectiveType == DW_EH_PE_absptr) EffectiveType = (PointerSize == 8) ? DW_EH_PE_udata8 : DW_EH_PE_udata4; JITTargetAddress Addr; Edge::Kind PointerEdgeKind; switch (EffectiveType) { case DW_EH_PE_udata4: { uint32_t Val; if (auto Err = RecordReader.readInteger(Val)) return std::move(Err); Addr = PointerFieldAddress + Val; PointerEdgeKind = Delta32; break; } case DW_EH_PE_udata8: { uint64_t Val; if (auto Err = RecordReader.readInteger(Val)) return std::move(Err); Addr = PointerFieldAddress + Val; PointerEdgeKind = Delta64; break; } case DW_EH_PE_sdata4: { int32_t Val; if (auto Err = RecordReader.readInteger(Val)) return std::move(Err); Addr = PointerFieldAddress + Val; PointerEdgeKind = Delta32; break; } case DW_EH_PE_sdata8: { int64_t Val; if (auto Err = RecordReader.readInteger(Val)) return std::move(Err); Addr = PointerFieldAddress + Val; PointerEdgeKind = Delta64; break; } } if (PointerEdgeKind == Edge::Invalid) return make_error( "Unspported edge kind for encoded pointer at " + formatv("{0:x}", PointerFieldAddress)); return std::make_pair(Addr, Delta64); } Expected EHFrameEdgeFixer::getOrCreateSymbol(ParseContext &PC, JITTargetAddress Addr) { Symbol *CanonicalSym = nullptr; auto UpdateCanonicalSym = [&](Symbol *Sym) { if (!CanonicalSym || Sym->getLinkage() < CanonicalSym->getLinkage() || Sym->getScope() < CanonicalSym->getScope() || (Sym->hasName() && !CanonicalSym->hasName()) || Sym->getName() < CanonicalSym->getName()) CanonicalSym = Sym; }; if (auto *SymbolsAtAddr = PC.AddrToSyms.getSymbolsAt(Addr)) for (auto *Sym : *SymbolsAtAddr) UpdateCanonicalSym(Sym); // If we found an existing symbol at the given address then use it. if (CanonicalSym) return *CanonicalSym; // Otherwise search for a block covering the address and create a new symbol. auto *B = PC.AddrToBlock.getBlockCovering(Addr); if (!B) return make_error("No symbol or block covering address " + formatv("{0:x16}", Addr)); return PC.G.addAnonymousSymbol(*B, Addr - B->getAddress(), 0, false, false); } EHFrameRegistrar::~EHFrameRegistrar() {} Error InProcessEHFrameRegistrar::registerEHFrames( JITTargetAddress EHFrameSectionAddr, size_t EHFrameSectionSize) { return orc::registerEHFrameSection( jitTargetAddressToPointer(EHFrameSectionAddr), EHFrameSectionSize); } Error InProcessEHFrameRegistrar::deregisterEHFrames( JITTargetAddress EHFrameSectionAddr, size_t EHFrameSectionSize) { return orc::deregisterEHFrameSection( jitTargetAddressToPointer(EHFrameSectionAddr), EHFrameSectionSize); } LinkGraphPassFunction createEHFrameRecorderPass(const Triple &TT, StoreFrameRangeFunction StoreRangeAddress) { const char *EHFrameSectionName = nullptr; if (TT.getObjectFormat() == Triple::MachO) EHFrameSectionName = "__eh_frame"; else EHFrameSectionName = ".eh_frame"; auto RecordEHFrame = [EHFrameSectionName, StoreFrameRange = std::move(StoreRangeAddress)](LinkGraph &G) -> Error { // Search for a non-empty eh-frame and record the address of the first // symbol in it. JITTargetAddress Addr = 0; size_t Size = 0; if (auto *S = G.findSectionByName(EHFrameSectionName)) { auto R = SectionRange(*S); Addr = R.getStart(); Size = R.getSize(); } if (Addr == 0 && Size != 0) return make_error("__eh_frame section can not have zero " "address with non-zero size"); StoreFrameRange(Addr, Size); return Error::success(); }; return RecordEHFrame; } } // end namespace jitlink } // end namespace llvm