llvm/lib/ExecutionEngine/JITLink/ELF_loongarch.cpp - llvm-project.git - Git at Google

 //===--- ELF_loongarch.cpp - JIT linker implementation for ELF/loongarch --===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // ELF/loongarch jit-link implementation.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ExecutionEngine/JITLink/ELF_loongarch.h"
 #include "llvm/BinaryFormat/ELF.h"
 #include "llvm/ExecutionEngine/JITLink/DWARFRecordSectionSplitter.h"
 #include "llvm/ExecutionEngine/JITLink/JITLink.h"
 #include "llvm/ExecutionEngine/JITLink/loongarch.h"
 #include "llvm/Object/ELF.h"
 #include "llvm/Object/ELFObjectFile.h"

 #include "EHFrameSupportImpl.h"
 #include "ELFLinkGraphBuilder.h"
 #include "JITLinkGeneric.h"

 #define DEBUG_TYPE "jitlink"

 using namespace llvm;
 using namespace llvm::jitlink;
 using namespace llvm::jitlink::loongarch;

 namespace {

 class ELFJITLinker_loongarch : public JITLinker<ELFJITLinker_loongarch> {
   friend class JITLinker<ELFJITLinker_loongarch>;

 public:
   ELFJITLinker_loongarch(std::unique_ptr<JITLinkContext> Ctx,
                          std::unique_ptr<LinkGraph> G,
                          PassConfiguration PassConfig)
       : JITLinker(std::move(Ctx), std::move(G), std::move(PassConfig)) {}

 private:
   Error applyFixup(LinkGraph &G, Block &B, const Edge &E) const {
     return loongarch::applyFixup(G, B, E);
   }
 };

 namespace {

 struct SymbolAnchor {
   uint64_t Offset;
   Symbol *Sym;
   bool End; // true for the anchor of getOffset() + getSize()
 };

 struct BlockRelaxAux {
   // This records symbol start and end offsets which will be adjusted according
   // to the nearest RelocDeltas element.
   SmallVector<SymbolAnchor, 0> Anchors;
   // All edges that either 1) are R_LARCH_ALIGN or 2) have a R_LARCH_RELAX edge
   // at the same offset.
   SmallVector<Edge *, 0> RelaxEdges;
   // For RelaxEdges[I], the actual offset is RelaxEdges[I]->getOffset() - (I ?
   // RelocDeltas[I - 1] : 0).
   SmallVector<uint32_t, 0> RelocDeltas;
   // For RelaxEdges[I], the actual type is EdgeKinds[I].
   SmallVector<Edge::Kind, 0> EdgeKinds;
   // List of rewritten instructions. Contains one raw encoded instruction per
   // element in EdgeKinds that isn't Invalid or R_LARCH_ALIGN.
   SmallVector<uint32_t, 0> Writes;
 };

 struct RelaxAux {
   DenseMap<Block *, BlockRelaxAux> Blocks;
 };

 } // namespace

 static bool shouldRelax(const Section &S) {
   return (S.getMemProt() & orc::MemProt::Exec) != orc::MemProt::None;
 }

 static bool isRelaxable(const Edge &E) {
   switch (E.getKind()) {
   default:
     return false;
   case AlignRelaxable:
     return true;
   }
 }

 static RelaxAux initRelaxAux(LinkGraph &G) {
   RelaxAux Aux;
   for (auto &S : G.sections()) {
     if (!shouldRelax(S))
       continue;
     for (auto *B : S.blocks()) {
       auto BlockEmplaceResult = Aux.Blocks.try_emplace(B);
       assert(BlockEmplaceResult.second && "Block encountered twice");
       auto &BlockAux = BlockEmplaceResult.first->second;

       for (auto &E : B->edges())
         if (isRelaxable(E))
           BlockAux.RelaxEdges.push_back(&E);

       if (BlockAux.RelaxEdges.empty()) {
         Aux.Blocks.erase(BlockEmplaceResult.first);
         continue;
       }

       const auto NumEdges = BlockAux.RelaxEdges.size();
       BlockAux.RelocDeltas.resize(NumEdges, 0);
       BlockAux.EdgeKinds.resize_for_overwrite(NumEdges);

       // Store anchors (offset and offset+size) for symbols.
       for (auto *Sym : S.symbols()) {
         if (!Sym->isDefined() || &Sym->getBlock() != B)
           continue;

         BlockAux.Anchors.push_back({Sym->getOffset(), Sym, false});
         BlockAux.Anchors.push_back(
             {Sym->getOffset() + Sym->getSize(), Sym, true});
       }
     }
   }

   // Sort anchors by offset so that we can find the closest relocation
   // efficiently. For a zero size symbol, ensure that its start anchor precedes
   // its end anchor. For two symbols with anchors at the same offset, their
   // order does not matter.
   for (auto &BlockAuxIter : Aux.Blocks) {
     llvm::sort(BlockAuxIter.second.Anchors, [](auto &A, auto &B) {
       return std::make_pair(A.Offset, A.End) < std::make_pair(B.Offset, B.End);
     });
   }

   return Aux;
 }

 static void relaxAlign(orc::ExecutorAddr Loc, const Edge &E, uint32_t &Remove,
                        Edge::Kind &NewEdgeKind) {
   const uint64_t Addend =
       !E.getTarget().isDefined() ? Log2_64(E.getAddend()) + 1 : E.getAddend();
   const uint64_t AllBytes = (1ULL << (Addend & 0xff)) - 4;
   const uint64_t Align = 1ULL << (Addend & 0xff);
   const uint64_t MaxBytes = Addend >> 8;
   const uint64_t Off = Loc.getValue() & (Align - 1);
   const uint64_t CurBytes = Off == 0 ? 0 : Align - Off;
   // All bytes beyond the alignment boundary should be removed.
   // If emit bytes more than max bytes to emit, remove all.
   if (MaxBytes != 0 && CurBytes > MaxBytes)
     Remove = AllBytes;
   else
     Remove = AllBytes - CurBytes;

   assert(static_cast<int32_t>(Remove) >= 0 &&
          "R_LARCH_ALIGN needs expanding the content");
   NewEdgeKind = AlignRelaxable;
 }

 static bool relaxBlock(LinkGraph &G, Block &Block, BlockRelaxAux &Aux) {
   const auto BlockAddr = Block.getAddress();
   bool Changed = false;
   ArrayRef<SymbolAnchor> SA = ArrayRef(Aux.Anchors);
   uint32_t Delta = 0;

   Aux.EdgeKinds.assign(Aux.EdgeKinds.size(), Edge::Invalid);
   Aux.Writes.clear();

   for (auto [I, E] : llvm::enumerate(Aux.RelaxEdges)) {
     const auto Loc = BlockAddr + E->getOffset() - Delta;
     auto &Cur = Aux.RelocDeltas[I];
     uint32_t Remove = 0;
     switch (E->getKind()) {
     case AlignRelaxable:
       relaxAlign(Loc, *E, Remove, Aux.EdgeKinds[I]);
       break;
     default:
       llvm_unreachable("Unexpected relaxable edge kind");
     }

     // For all anchors whose offsets are <= E->getOffset(), they are preceded by
     // the previous relocation whose RelocDeltas value equals Delta.
     // Decrease their offset and update their size.
     for (; SA.size() && SA[0].Offset <= E->getOffset(); SA = SA.slice(1)) {
       if (SA[0].End)
         SA[0].Sym->setSize(SA[0].Offset - Delta - SA[0].Sym->getOffset());
       else
         SA[0].Sym->setOffset(SA[0].Offset - Delta);
     }

     Delta += Remove;
     if (Delta != Cur) {
       Cur = Delta;
       Changed = true;
     }
   }

   for (const SymbolAnchor &A : SA) {
     if (A.End)
       A.Sym->setSize(A.Offset - Delta - A.Sym->getOffset());
     else
       A.Sym->setOffset(A.Offset - Delta);
   }

   return Changed;
 }

 static bool relaxOnce(LinkGraph &G, RelaxAux &Aux) {
   bool Changed = false;

   for (auto &[B, BlockAux] : Aux.Blocks)
     Changed |= relaxBlock(G, *B, BlockAux);

   return Changed;
 }

 static void finalizeBlockRelax(LinkGraph &G, Block &Block, BlockRelaxAux &Aux) {
   auto Contents = Block.getAlreadyMutableContent();
   auto *Dest = Contents.data();
   uint32_t Offset = 0;
   uint32_t Delta = 0;

   // Update section content: remove NOPs for R_LARCH_ALIGN and rewrite
   // instructions for relaxed relocations.
   for (auto [I, E] : llvm::enumerate(Aux.RelaxEdges)) {
     uint32_t Remove = Aux.RelocDeltas[I] - Delta;
     Delta = Aux.RelocDeltas[I];
     if (Remove == 0 && Aux.EdgeKinds[I] == Edge::Invalid)
       continue;

     // Copy from last location to the current relocated location.
     const auto Size = E->getOffset() - Offset;
     std::memmove(Dest, Contents.data() + Offset, Size);
     Dest += Size;
     Offset = E->getOffset() + Remove;
   }

   std::memmove(Dest, Contents.data() + Offset, Contents.size() - Offset);

   // Fixup edge offsets and kinds.
   Delta = 0;
   size_t I = 0;
   for (auto &E : Block.edges()) {
     E.setOffset(E.getOffset() - Delta);

     if (I < Aux.RelaxEdges.size() && Aux.RelaxEdges[I] == &E) {
       if (Aux.EdgeKinds[I] != Edge::Invalid)
         E.setKind(Aux.EdgeKinds[I]);

       Delta = Aux.RelocDeltas[I];
       ++I;
     }
   }

   // Remove AlignRelaxable edges: all other relaxable edges got modified and
   // will be used later while linking. Alignment is entirely handled here so we
   // don't need these edges anymore.
   for (auto IE = Block.edges().begin(); IE != Block.edges().end();) {
     if (IE->getKind() == AlignRelaxable)
       IE = Block.removeEdge(IE);
     else
       ++IE;
   }
 }

 static void finalizeRelax(LinkGraph &G, RelaxAux &Aux) {
   for (auto &[B, BlockAux] : Aux.Blocks)
     finalizeBlockRelax(G, *B, BlockAux);
 }

 static Error relax(LinkGraph &G) {
   auto Aux = initRelaxAux(G);
   while (relaxOnce(G, Aux)) {
   }
   finalizeRelax(G, Aux);
   return Error::success();
 }

 template <typename ELFT>
 class ELFLinkGraphBuilder_loongarch : public ELFLinkGraphBuilder<ELFT> {
 private:
   static Expected<loongarch::EdgeKind_loongarch>
   getRelocationKind(const uint32_t Type) {
     using namespace loongarch;
     switch (Type) {
     case ELF::R_LARCH_64:
       return Pointer64;
     case ELF::R_LARCH_32:
       return Pointer32;
     case ELF::R_LARCH_32_PCREL:
       return Delta32;
     case ELF::R_LARCH_B16:
       return Branch16PCRel;
     case ELF::R_LARCH_B21:
       return Branch21PCRel;
     case ELF::R_LARCH_B26:
       return Branch26PCRel;
     case ELF::R_LARCH_PCALA_HI20:
       return Page20;
     case ELF::R_LARCH_PCALA_LO12:
       return PageOffset12;
     case ELF::R_LARCH_GOT_PC_HI20:
       return RequestGOTAndTransformToPage20;
     case ELF::R_LARCH_GOT_PC_LO12:
       return RequestGOTAndTransformToPageOffset12;
     case ELF::R_LARCH_CALL36:
       return Call36PCRel;
     case ELF::R_LARCH_ADD6:
       return Add6;
     case ELF::R_LARCH_ADD8:
       return Add8;
     case ELF::R_LARCH_ADD16:
       return Add16;
     case ELF::R_LARCH_ADD32:
       return Add32;
     case ELF::R_LARCH_ADD64:
       return Add64;
     case ELF::R_LARCH_ADD_ULEB128:
       return AddUleb128;
     case ELF::R_LARCH_SUB6:
       return Sub6;
     case ELF::R_LARCH_SUB8:
       return Sub8;
     case ELF::R_LARCH_SUB16:
       return Sub16;
     case ELF::R_LARCH_SUB32:
       return Sub32;
     case ELF::R_LARCH_SUB64:
       return Sub64;
     case ELF::R_LARCH_SUB_ULEB128:
       return SubUleb128;
     case ELF::R_LARCH_ALIGN:
       return AlignRelaxable;
     }

     return make_error<JITLinkError>(
         "Unsupported loongarch relocation:" + formatv("{0:d}: ", Type) +
         object::getELFRelocationTypeName(ELF::EM_LOONGARCH, Type));
   }

   EdgeKind_loongarch getRelaxableRelocationKind(EdgeKind_loongarch Kind) {
     // TODO: Implement more. Just ignore all relaxations now.
     return Kind;
   }

   Error addRelocations() override {
     LLVM_DEBUG(dbgs() << "Processing relocations:\n");

     using Base = ELFLinkGraphBuilder<ELFT>;
     using Self = ELFLinkGraphBuilder_loongarch<ELFT>;
     for (const auto &RelSect : Base::Sections)
       if (Error Err = Base::forEachRelaRelocation(RelSect, this,
                                                   &Self::addSingleRelocation))
         return Err;

     return Error::success();
   }

   Error addSingleRelocation(const typename ELFT::Rela &Rel,
                             const typename ELFT::Shdr &FixupSect,
                             Block &BlockToFix) {
     using Base = ELFLinkGraphBuilder<ELFT>;

     uint32_t Type = Rel.getType(false);
     int64_t Addend = Rel.r_addend;

     if (Type == ELF::R_LARCH_RELAX) {
       if (BlockToFix.edges_empty())
         return make_error<StringError>(
             "R_LARCH_RELAX without preceding relocation",
             inconvertibleErrorCode());

       auto &PrevEdge = *std::prev(BlockToFix.edges().end());
       auto Kind = static_cast<EdgeKind_loongarch>(PrevEdge.getKind());
       PrevEdge.setKind(getRelaxableRelocationKind(Kind));
       return Error::success();
     }

     Expected<loongarch::EdgeKind_loongarch> Kind = getRelocationKind(Type);
     if (!Kind)
       return Kind.takeError();

     uint32_t SymbolIndex = Rel.getSymbol(false);
     auto ObjSymbol = Base::Obj.getRelocationSymbol(Rel, Base::SymTabSec);
     if (!ObjSymbol)
       return ObjSymbol.takeError();

     Symbol *GraphSymbol = Base::getGraphSymbol(SymbolIndex);
     if (!GraphSymbol)
       return make_error<StringError>(
           formatv("Could not find symbol at given index, did you add it to "
                   "JITSymbolTable? index: {0}, shndx: {1} Size of table: {2}",
                   SymbolIndex, (*ObjSymbol)->st_shndx,
                   Base::GraphSymbols.size()),
           inconvertibleErrorCode());

     auto FixupAddress = orc::ExecutorAddr(FixupSect.sh_addr) + Rel.r_offset;
     Edge::OffsetT Offset = FixupAddress - BlockToFix.getAddress();
     Edge GE(*Kind, Offset, *GraphSymbol, Addend);
     LLVM_DEBUG({
       dbgs() << "    ";
       printEdge(dbgs(), BlockToFix, GE, loongarch::getEdgeKindName(*Kind));
       dbgs() << "\n";
     });

     BlockToFix.addEdge(std::move(GE));

     return Error::success();
   }

 public:
   ELFLinkGraphBuilder_loongarch(StringRef FileName,
                                 const object::ELFFile<ELFT> &Obj,
                                 std::shared_ptr<orc::SymbolStringPool> SSP,
                                 Triple TT, SubtargetFeatures Features)
       : ELFLinkGraphBuilder<ELFT>(Obj, std::move(SSP), std::move(TT),
                                   std::move(Features), FileName,
                                   loongarch::getEdgeKindName) {}
 };

 Error buildTables_ELF_loongarch(LinkGraph &G) {
   LLVM_DEBUG(dbgs() << "Visiting edges in graph:\n");

   GOTTableManager GOT;
   PLTTableManager PLT(GOT);
   visitExistingEdges(G, GOT, PLT);
   return Error::success();
 }

 } // namespace

 namespace llvm {
 namespace jitlink {

 Expected<std::unique_ptr<LinkGraph>> createLinkGraphFromELFObject_loongarch(
     MemoryBufferRef ObjectBuffer, std::shared_ptr<orc::SymbolStringPool> SSP) {
   LLVM_DEBUG({
     dbgs() << "Building jitlink graph for new input "
            << ObjectBuffer.getBufferIdentifier() << "...\n";
   });

   auto ELFObj = object::ObjectFile::createELFObjectFile(ObjectBuffer);
   if (!ELFObj)
     return ELFObj.takeError();

   auto Features = (*ELFObj)->getFeatures();
   if (!Features)
     return Features.takeError();

   if ((*ELFObj)->getArch() == Triple::loongarch64) {
     auto &ELFObjFile = cast<object::ELFObjectFile<object::ELF64LE>>(**ELFObj);
     return ELFLinkGraphBuilder_loongarch<object::ELF64LE>(
                (*ELFObj)->getFileName(), ELFObjFile.getELFFile(),
                std::move(SSP), (*ELFObj)->makeTriple(), std::move(*Features))
         .buildGraph();
   }

   assert((*ELFObj)->getArch() == Triple::loongarch32 &&
          "Invalid triple for LoongArch ELF object file");
   auto &ELFObjFile = cast<object::ELFObjectFile<object::ELF32LE>>(**ELFObj);
   return ELFLinkGraphBuilder_loongarch<object::ELF32LE>(
              (*ELFObj)->getFileName(), ELFObjFile.getELFFile(), std::move(SSP),
              (*ELFObj)->makeTriple(), std::move(*Features))
       .buildGraph();
 }

 void link_ELF_loongarch(std::unique_ptr<LinkGraph> G,
                         std::unique_ptr<JITLinkContext> Ctx) {
   PassConfiguration Config;
   const Triple &TT = G->getTargetTriple();
   if (Ctx->shouldAddDefaultTargetPasses(TT)) {
     // Add eh-frame passes.
     Config.PrePrunePasses.push_back(DWARFRecordSectionSplitter(".eh_frame"));
     Config.PrePrunePasses.push_back(
         EHFrameEdgeFixer(".eh_frame", G->getPointerSize(), Pointer32, Pointer64,
                          Delta32, Delta64, NegDelta32));
     Config.PrePrunePasses.push_back(EHFrameNullTerminator(".eh_frame"));

     // Add a mark-live pass.
     if (auto MarkLive = Ctx->getMarkLivePass(TT))
       Config.PrePrunePasses.push_back(std::move(MarkLive));
     else
       Config.PrePrunePasses.push_back(markAllSymbolsLive);

     // Add an in-place GOT/PLTStubs build pass.
     Config.PostPrunePasses.push_back(buildTables_ELF_loongarch);

     // Add a linker relaxation pass.
     Config.PostAllocationPasses.push_back(relax);
   }

   if (auto Err = Ctx->modifyPassConfig(*G, Config))
     return Ctx->notifyFailed(std::move(Err));

   ELFJITLinker_loongarch::link(std::move(Ctx), std::move(G), std::move(Config));
 }

 LinkGraphPassFunction createRelaxationPass_ELF_loongarch() { return relax; }

 } // namespace jitlink
 } // namespace llvm
	//===--- ELF_loongarch.cpp - JIT linker implementation for ELF/loongarch --===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// ELF/loongarch jit-link implementation.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ExecutionEngine/JITLink/ELF_loongarch.h"
	#include "llvm/BinaryFormat/ELF.h"
	#include "llvm/ExecutionEngine/JITLink/DWARFRecordSectionSplitter.h"
	#include "llvm/ExecutionEngine/JITLink/JITLink.h"
	#include "llvm/ExecutionEngine/JITLink/loongarch.h"
	#include "llvm/Object/ELF.h"
	#include "llvm/Object/ELFObjectFile.h"

	#include "EHFrameSupportImpl.h"
	#include "ELFLinkGraphBuilder.h"
	#include "JITLinkGeneric.h"

	#define DEBUG_TYPE "jitlink"

	using namespace llvm;
	using namespace llvm::jitlink;
	using namespace llvm::jitlink::loongarch;

	namespace {

	class ELFJITLinker_loongarch : public JITLinker<ELFJITLinker_loongarch> {
	friend class JITLinker<ELFJITLinker_loongarch>;

	public:
	ELFJITLinker_loongarch(std::unique_ptr<JITLinkContext> Ctx,
	std::unique_ptr<LinkGraph> G,
	PassConfiguration PassConfig)
	: JITLinker(std::move(Ctx), std::move(G), std::move(PassConfig)) {}

	private:
	Error applyFixup(LinkGraph &G, Block &B, const Edge &E) const {
	return loongarch::applyFixup(G, B, E);
	}
	};

	namespace {

	struct SymbolAnchor {
	uint64_t Offset;
	Symbol *Sym;
	bool End; // true for the anchor of getOffset() + getSize()
	};

	struct BlockRelaxAux {
	// This records symbol start and end offsets which will be adjusted according
	// to the nearest RelocDeltas element.
	SmallVector<SymbolAnchor, 0> Anchors;
	// All edges that either 1) are R_LARCH_ALIGN or 2) have a R_LARCH_RELAX edge
	// at the same offset.
	SmallVector<Edge *, 0> RelaxEdges;
	// For RelaxEdges[I], the actual offset is RelaxEdges[I]->getOffset() - (I ?
	// RelocDeltas[I - 1] : 0).
	SmallVector<uint32_t, 0> RelocDeltas;
	// For RelaxEdges[I], the actual type is EdgeKinds[I].
	SmallVector<Edge::Kind, 0> EdgeKinds;
	// List of rewritten instructions. Contains one raw encoded instruction per
	// element in EdgeKinds that isn't Invalid or R_LARCH_ALIGN.
	SmallVector<uint32_t, 0> Writes;
	};

	struct RelaxAux {
	DenseMap<Block *, BlockRelaxAux> Blocks;
	};

	} // namespace

	static bool shouldRelax(const Section &S) {
	return (S.getMemProt() & orc::MemProt::Exec) != orc::MemProt::None;
	}

	static bool isRelaxable(const Edge &E) {
	switch (E.getKind()) {
	default:
	return false;
	case AlignRelaxable:
	return true;
	}
	}

	static RelaxAux initRelaxAux(LinkGraph &G) {
	RelaxAux Aux;
	for (auto &S : G.sections()) {
	if (!shouldRelax(S))
	continue;
	for (auto *B : S.blocks()) {
	auto BlockEmplaceResult = Aux.Blocks.try_emplace(B);
	assert(BlockEmplaceResult.second && "Block encountered twice");
	auto &BlockAux = BlockEmplaceResult.first->second;

	for (auto &E : B->edges())
	if (isRelaxable(E))
	BlockAux.RelaxEdges.push_back(&E);

	if (BlockAux.RelaxEdges.empty()) {
	Aux.Blocks.erase(BlockEmplaceResult.first);
	continue;
	}

	const auto NumEdges = BlockAux.RelaxEdges.size();
	BlockAux.RelocDeltas.resize(NumEdges, 0);
	BlockAux.EdgeKinds.resize_for_overwrite(NumEdges);

	// Store anchors (offset and offset+size) for symbols.
	for (auto *Sym : S.symbols()) {
	if (!Sym->isDefined() \|\| &Sym->getBlock() != B)
	continue;

	BlockAux.Anchors.push_back({Sym->getOffset(), Sym, false});
	BlockAux.Anchors.push_back(
	{Sym->getOffset() + Sym->getSize(), Sym, true});
	}
	}
	}

	// Sort anchors by offset so that we can find the closest relocation
	// efficiently. For a zero size symbol, ensure that its start anchor precedes
	// its end anchor. For two symbols with anchors at the same offset, their
	// order does not matter.
	for (auto &BlockAuxIter : Aux.Blocks) {
	llvm::sort(BlockAuxIter.second.Anchors, [](auto &A, auto &B) {
	return std::make_pair(A.Offset, A.End) < std::make_pair(B.Offset, B.End);
	});
	}

	return Aux;
	}

	static void relaxAlign(orc::ExecutorAddr Loc, const Edge &E, uint32_t &Remove,
	Edge::Kind &NewEdgeKind) {
	const uint64_t Addend =
	!E.getTarget().isDefined() ? Log2_64(E.getAddend()) + 1 : E.getAddend();
	const uint64_t AllBytes = (1ULL << (Addend & 0xff)) - 4;
	const uint64_t Align = 1ULL << (Addend & 0xff);
	const uint64_t MaxBytes = Addend >> 8;
	const uint64_t Off = Loc.getValue() & (Align - 1);
	const uint64_t CurBytes = Off == 0 ? 0 : Align - Off;
	// All bytes beyond the alignment boundary should be removed.
	// If emit bytes more than max bytes to emit, remove all.
	if (MaxBytes != 0 && CurBytes > MaxBytes)
	Remove = AllBytes;
	else
	Remove = AllBytes - CurBytes;

	assert(static_cast<int32_t>(Remove) >= 0 &&
	"R_LARCH_ALIGN needs expanding the content");
	NewEdgeKind = AlignRelaxable;
	}

	static bool relaxBlock(LinkGraph &G, Block &Block, BlockRelaxAux &Aux) {
	const auto BlockAddr = Block.getAddress();
	bool Changed = false;
	ArrayRef<SymbolAnchor> SA = ArrayRef(Aux.Anchors);
	uint32_t Delta = 0;

	Aux.EdgeKinds.assign(Aux.EdgeKinds.size(), Edge::Invalid);
	Aux.Writes.clear();

	for (auto [I, E] : llvm::enumerate(Aux.RelaxEdges)) {
	const auto Loc = BlockAddr + E->getOffset() - Delta;
	auto &Cur = Aux.RelocDeltas[I];
	uint32_t Remove = 0;
	switch (E->getKind()) {
	case AlignRelaxable:
	relaxAlign(Loc, *E, Remove, Aux.EdgeKinds[I]);
	break;
	default:
	llvm_unreachable("Unexpected relaxable edge kind");
	}

	// For all anchors whose offsets are <= E->getOffset(), they are preceded by
	// the previous relocation whose RelocDeltas value equals Delta.
	// Decrease their offset and update their size.
	for (; SA.size() && SA[0].Offset <= E->getOffset(); SA = SA.slice(1)) {
	if (SA[0].End)
	SA[0].Sym->setSize(SA[0].Offset - Delta - SA[0].Sym->getOffset());
	else
	SA[0].Sym->setOffset(SA[0].Offset - Delta);
	}

	Delta += Remove;
	if (Delta != Cur) {
	Cur = Delta;
	Changed = true;
	}
	}

	for (const SymbolAnchor &A : SA) {
	if (A.End)
	A.Sym->setSize(A.Offset - Delta - A.Sym->getOffset());
	else
	A.Sym->setOffset(A.Offset - Delta);
	}

	return Changed;
	}

	static bool relaxOnce(LinkGraph &G, RelaxAux &Aux) {
	bool Changed = false;

	for (auto &[B, BlockAux] : Aux.Blocks)
	Changed \|= relaxBlock(G, *B, BlockAux);

	return Changed;
	}

	static void finalizeBlockRelax(LinkGraph &G, Block &Block, BlockRelaxAux &Aux) {
	auto Contents = Block.getAlreadyMutableContent();
	auto *Dest = Contents.data();
	uint32_t Offset = 0;
	uint32_t Delta = 0;

	// Update section content: remove NOPs for R_LARCH_ALIGN and rewrite
	// instructions for relaxed relocations.
	for (auto [I, E] : llvm::enumerate(Aux.RelaxEdges)) {
	uint32_t Remove = Aux.RelocDeltas[I] - Delta;
	Delta = Aux.RelocDeltas[I];
	if (Remove == 0 && Aux.EdgeKinds[I] == Edge::Invalid)
	continue;

	// Copy from last location to the current relocated location.
	const auto Size = E->getOffset() - Offset;
	std::memmove(Dest, Contents.data() + Offset, Size);
	Dest += Size;
	Offset = E->getOffset() + Remove;
	}

	std::memmove(Dest, Contents.data() + Offset, Contents.size() - Offset);

	// Fixup edge offsets and kinds.
	Delta = 0;
	size_t I = 0;
	for (auto &E : Block.edges()) {
	E.setOffset(E.getOffset() - Delta);

	if (I < Aux.RelaxEdges.size() && Aux.RelaxEdges[I] == &E) {
	if (Aux.EdgeKinds[I] != Edge::Invalid)
	E.setKind(Aux.EdgeKinds[I]);

	Delta = Aux.RelocDeltas[I];
	++I;
	}
	}

	// Remove AlignRelaxable edges: all other relaxable edges got modified and
	// will be used later while linking. Alignment is entirely handled here so we
	// don't need these edges anymore.
	for (auto IE = Block.edges().begin(); IE != Block.edges().end();) {
	if (IE->getKind() == AlignRelaxable)
	IE = Block.removeEdge(IE);
	else
	++IE;
	}
	}

	static void finalizeRelax(LinkGraph &G, RelaxAux &Aux) {
	for (auto &[B, BlockAux] : Aux.Blocks)
	finalizeBlockRelax(G, *B, BlockAux);
	}

	static Error relax(LinkGraph &G) {
	auto Aux = initRelaxAux(G);
	while (relaxOnce(G, Aux)) {
	}
	finalizeRelax(G, Aux);
	return Error::success();
	}

	template <typename ELFT>
	class ELFLinkGraphBuilder_loongarch : public ELFLinkGraphBuilder<ELFT> {
	private:
	static Expected<loongarch::EdgeKind_loongarch>
	getRelocationKind(const uint32_t Type) {
	using namespace loongarch;
	switch (Type) {
	case ELF::R_LARCH_64:
	return Pointer64;
	case ELF::R_LARCH_32:
	return Pointer32;
	case ELF::R_LARCH_32_PCREL:
	return Delta32;
	case ELF::R_LARCH_B16:
	return Branch16PCRel;
	case ELF::R_LARCH_B21:
	return Branch21PCRel;
	case ELF::R_LARCH_B26:
	return Branch26PCRel;
	case ELF::R_LARCH_PCALA_HI20:
	return Page20;
	case ELF::R_LARCH_PCALA_LO12:
	return PageOffset12;
	case ELF::R_LARCH_GOT_PC_HI20:
	return RequestGOTAndTransformToPage20;
	case ELF::R_LARCH_GOT_PC_LO12:
	return RequestGOTAndTransformToPageOffset12;
	case ELF::R_LARCH_CALL36:
	return Call36PCRel;
	case ELF::R_LARCH_ADD6:
	return Add6;
	case ELF::R_LARCH_ADD8:
	return Add8;
	case ELF::R_LARCH_ADD16:
	return Add16;
	case ELF::R_LARCH_ADD32:
	return Add32;
	case ELF::R_LARCH_ADD64:
	return Add64;
	case ELF::R_LARCH_ADD_ULEB128:
	return AddUleb128;
	case ELF::R_LARCH_SUB6:
	return Sub6;
	case ELF::R_LARCH_SUB8:
	return Sub8;
	case ELF::R_LARCH_SUB16:
	return Sub16;
	case ELF::R_LARCH_SUB32:
	return Sub32;
	case ELF::R_LARCH_SUB64:
	return Sub64;
	case ELF::R_LARCH_SUB_ULEB128:
	return SubUleb128;
	case ELF::R_LARCH_ALIGN:
	return AlignRelaxable;
	}

	return make_error<JITLinkError>(
	"Unsupported loongarch relocation:" + formatv("{0:d}: ", Type) +
	object::getELFRelocationTypeName(ELF::EM_LOONGARCH, Type));
	}

	EdgeKind_loongarch getRelaxableRelocationKind(EdgeKind_loongarch Kind) {
	// TODO: Implement more. Just ignore all relaxations now.
	return Kind;
	}

	Error addRelocations() override {
	LLVM_DEBUG(dbgs() << "Processing relocations:\n");

	using Base = ELFLinkGraphBuilder<ELFT>;
	using Self = ELFLinkGraphBuilder_loongarch<ELFT>;
	for (const auto &RelSect : Base::Sections)
	if (Error Err = Base::forEachRelaRelocation(RelSect, this,
	&Self::addSingleRelocation))
	return Err;

	return Error::success();
	}

	Error addSingleRelocation(const typename ELFT::Rela &Rel,
	const typename ELFT::Shdr &FixupSect,
	Block &BlockToFix) {
	using Base = ELFLinkGraphBuilder<ELFT>;

	uint32_t Type = Rel.getType(false);
	int64_t Addend = Rel.r_addend;

	if (Type == ELF::R_LARCH_RELAX) {
	if (BlockToFix.edges_empty())
	return make_error<StringError>(
	"R_LARCH_RELAX without preceding relocation",
	inconvertibleErrorCode());

	auto &PrevEdge = *std::prev(BlockToFix.edges().end());
	auto Kind = static_cast<EdgeKind_loongarch>(PrevEdge.getKind());
	PrevEdge.setKind(getRelaxableRelocationKind(Kind));
	return Error::success();
	}

	Expected<loongarch::EdgeKind_loongarch> Kind = getRelocationKind(Type);
	if (!Kind)
	return Kind.takeError();

	uint32_t SymbolIndex = Rel.getSymbol(false);
	auto ObjSymbol = Base::Obj.getRelocationSymbol(Rel, Base::SymTabSec);
	if (!ObjSymbol)
	return ObjSymbol.takeError();

	Symbol *GraphSymbol = Base::getGraphSymbol(SymbolIndex);
	if (!GraphSymbol)
	return make_error<StringError>(
	formatv("Could not find symbol at given index, did you add it to "
	"JITSymbolTable? index: {0}, shndx: {1} Size of table: {2}",
	SymbolIndex, (*ObjSymbol)->st_shndx,
	Base::GraphSymbols.size()),
	inconvertibleErrorCode());

	auto FixupAddress = orc::ExecutorAddr(FixupSect.sh_addr) + Rel.r_offset;
	Edge::OffsetT Offset = FixupAddress - BlockToFix.getAddress();
	Edge GE(Kind, Offset, GraphSymbol, Addend);
	LLVM_DEBUG({
	dbgs() << " ";
	printEdge(dbgs(), BlockToFix, GE, loongarch::getEdgeKindName(*Kind));
	dbgs() << "\n";
	});

	BlockToFix.addEdge(std::move(GE));

	return Error::success();
	}

	public:
	ELFLinkGraphBuilder_loongarch(StringRef FileName,
	const object::ELFFile<ELFT> &Obj,
	std::shared_ptr<orc::SymbolStringPool> SSP,
	Triple TT, SubtargetFeatures Features)
	: ELFLinkGraphBuilder<ELFT>(Obj, std::move(SSP), std::move(TT),
	std::move(Features), FileName,
	loongarch::getEdgeKindName) {}
	};

	Error buildTables_ELF_loongarch(LinkGraph &G) {
	LLVM_DEBUG(dbgs() << "Visiting edges in graph:\n");

	GOTTableManager GOT;
	PLTTableManager PLT(GOT);
	visitExistingEdges(G, GOT, PLT);
	return Error::success();
	}

	} // namespace

	namespace llvm {
	namespace jitlink {

	Expected<std::unique_ptr<LinkGraph>> createLinkGraphFromELFObject_loongarch(
	MemoryBufferRef ObjectBuffer, std::shared_ptr<orc::SymbolStringPool> SSP) {
	LLVM_DEBUG({
	dbgs() << "Building jitlink graph for new input "
	<< ObjectBuffer.getBufferIdentifier() << "...\n";
	});

	auto ELFObj = object::ObjectFile::createELFObjectFile(ObjectBuffer);
	if (!ELFObj)
	return ELFObj.takeError();

	auto Features = (*ELFObj)->getFeatures();
	if (!Features)
	return Features.takeError();

	if ((*ELFObj)->getArch() == Triple::loongarch64) {
	auto &ELFObjFile = cast<object::ELFObjectFile<object::ELF64LE>>(**ELFObj);
	return ELFLinkGraphBuilder_loongarch<object::ELF64LE>(
	(*ELFObj)->getFileName(), ELFObjFile.getELFFile(),
	std::move(SSP), (ELFObj)->makeTriple(), std::move(Features))
	.buildGraph();
	}

	assert((*ELFObj)->getArch() == Triple::loongarch32 &&
	"Invalid triple for LoongArch ELF object file");
	auto &ELFObjFile = cast<object::ELFObjectFile<object::ELF32LE>>(**ELFObj);
	return ELFLinkGraphBuilder_loongarch<object::ELF32LE>(
	(*ELFObj)->getFileName(), ELFObjFile.getELFFile(), std::move(SSP),
	(ELFObj)->makeTriple(), std::move(Features))
	.buildGraph();
	}

	void link_ELF_loongarch(std::unique_ptr<LinkGraph> G,
	std::unique_ptr<JITLinkContext> Ctx) {
	PassConfiguration Config;
	const Triple &TT = G->getTargetTriple();
	if (Ctx->shouldAddDefaultTargetPasses(TT)) {
	// Add eh-frame passes.
	Config.PrePrunePasses.push_back(DWARFRecordSectionSplitter(".eh_frame"));
	Config.PrePrunePasses.push_back(
	EHFrameEdgeFixer(".eh_frame", G->getPointerSize(), Pointer32, Pointer64,
	Delta32, Delta64, NegDelta32));
	Config.PrePrunePasses.push_back(EHFrameNullTerminator(".eh_frame"));

	// Add a mark-live pass.
	if (auto MarkLive = Ctx->getMarkLivePass(TT))
	Config.PrePrunePasses.push_back(std::move(MarkLive));
	else
	Config.PrePrunePasses.push_back(markAllSymbolsLive);

	// Add an in-place GOT/PLTStubs build pass.
	Config.PostPrunePasses.push_back(buildTables_ELF_loongarch);

	// Add a linker relaxation pass.
	Config.PostAllocationPasses.push_back(relax);
	}

	if (auto Err = Ctx->modifyPassConfig(*G, Config))
	return Ctx->notifyFailed(std::move(Err));

	ELFJITLinker_loongarch::link(std::move(Ctx), std::move(G), std::move(Config));
	}

	LinkGraphPassFunction createRelaxationPass_ELF_loongarch() { return relax; }

	} // namespace jitlink
	} // namespace llvm