//===--------- JITLinkGeneric.cpp - Generic JIT linker utilities ----------===// // // 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 // //===----------------------------------------------------------------------===// // // Generic JITLinker utility class. // //===----------------------------------------------------------------------===// #include "JITLinkGeneric.h" #include "llvm/Support/BinaryStreamReader.h" #include "llvm/Support/MemoryBuffer.h" #define DEBUG_TYPE "jitlink" namespace llvm { namespace jitlink { JITLinkerBase::~JITLinkerBase() {} void JITLinkerBase::linkPhase1(std::unique_ptr Self) { // Build the link graph. if (auto GraphOrErr = buildGraph(Ctx->getObjectBuffer())) G = std::move(*GraphOrErr); else return Ctx->notifyFailed(GraphOrErr.takeError()); assert(G && "Graph should have been created by buildGraph above"); // Prune and optimize the graph. if (auto Err = runPasses(Passes.PrePrunePasses)) return Ctx->notifyFailed(std::move(Err)); LLVM_DEBUG({ dbgs() << "Link graph \"" << G->getName() << "\" pre-pruning:\n"; dumpGraph(dbgs()); }); prune(*G); LLVM_DEBUG({ dbgs() << "Link graph \"" << G->getName() << "\" post-pruning:\n"; dumpGraph(dbgs()); }); // Run post-pruning passes. if (auto Err = runPasses(Passes.PostPrunePasses)) return Ctx->notifyFailed(std::move(Err)); // Sort blocks into segments. auto Layout = layOutBlocks(); // Allocate memory for segments. if (auto Err = allocateSegments(Layout)) return Ctx->notifyFailed(std::move(Err)); // Notify client that the defined symbols have been assigned addresses. Ctx->notifyResolved(*G); auto ExternalSymbols = getExternalSymbolNames(); // We're about to hand off ownership of ourself to the continuation. Grab a // pointer to the context so that we can call it to initiate the lookup. // // FIXME: Once callee expressions are defined to be sequenced before argument // expressions (c++17) we can simplify all this to: // // Ctx->lookup(std::move(UnresolvedExternals), // [Self=std::move(Self)](Expected Result) { // Self->linkPhase2(std::move(Self), std::move(Result)); // }); auto *TmpCtx = Ctx.get(); TmpCtx->lookup(std::move(ExternalSymbols), createLookupContinuation( [S = std::move(Self), L = std::move(Layout)]( Expected LookupResult) mutable { auto &TmpSelf = *S; TmpSelf.linkPhase2(std::move(S), std::move(LookupResult), std::move(L)); })); } void JITLinkerBase::linkPhase2(std::unique_ptr Self, Expected LR, SegmentLayoutMap Layout) { // If the lookup failed, bail out. if (!LR) return deallocateAndBailOut(LR.takeError()); // Assign addresses to external addressables. applyLookupResult(*LR); LLVM_DEBUG({ dbgs() << "Link graph \"" << G->getName() << "\" before copy-and-fixup:\n"; dumpGraph(dbgs()); }); // Copy block content to working memory and fix up. if (auto Err = copyAndFixUpBlocks(Layout, *Alloc)) return deallocateAndBailOut(std::move(Err)); LLVM_DEBUG({ dbgs() << "Link graph \"" << G->getName() << "\" after copy-and-fixup:\n"; dumpGraph(dbgs()); }); if (auto Err = runPasses(Passes.PostFixupPasses)) return deallocateAndBailOut(std::move(Err)); // FIXME: Use move capture once we have c++14. auto *UnownedSelf = Self.release(); auto Phase3Continuation = [UnownedSelf](Error Err) { std::unique_ptr Self(UnownedSelf); UnownedSelf->linkPhase3(std::move(Self), std::move(Err)); }; Alloc->finalizeAsync(std::move(Phase3Continuation)); } void JITLinkerBase::linkPhase3(std::unique_ptr Self, Error Err) { if (Err) return deallocateAndBailOut(std::move(Err)); Ctx->notifyFinalized(std::move(Alloc)); } Error JITLinkerBase::runPasses(LinkGraphPassList &Passes) { for (auto &P : Passes) if (auto Err = P(*G)) return Err; return Error::success(); } JITLinkerBase::SegmentLayoutMap JITLinkerBase::layOutBlocks() { SegmentLayoutMap Layout; /// Partition blocks based on permissions and content vs. zero-fill. for (auto *B : G->blocks()) { auto &SegLists = Layout[B->getSection().getProtectionFlags()]; if (!B->isZeroFill()) SegLists.ContentBlocks.push_back(B); else SegLists.ZeroFillBlocks.push_back(B); } /// Sort blocks within each list. for (auto &KV : Layout) { auto CompareBlocks = [](const Block *LHS, const Block *RHS) { if (LHS->getSection().getOrdinal() != RHS->getSection().getOrdinal()) return LHS->getSection().getOrdinal() < RHS->getSection().getOrdinal(); return LHS->getOrdinal() < RHS->getOrdinal(); }; auto &SegLists = KV.second; llvm::sort(SegLists.ContentBlocks, CompareBlocks); llvm::sort(SegLists.ZeroFillBlocks, CompareBlocks); } LLVM_DEBUG({ dbgs() << "Segment ordering:\n"; for (auto &KV : Layout) { dbgs() << " Segment " << static_cast(KV.first) << ":\n"; auto &SL = KV.second; for (auto &SIEntry : {std::make_pair(&SL.ContentBlocks, "content block"), std::make_pair(&SL.ZeroFillBlocks, "zero-fill block")}) { dbgs() << " " << SIEntry.second << ":\n"; for (auto *B : *SIEntry.first) dbgs() << " " << *B << "\n"; } } }); return Layout; } Error JITLinkerBase::allocateSegments(const SegmentLayoutMap &Layout) { // Compute segment sizes and allocate memory. LLVM_DEBUG(dbgs() << "JIT linker requesting: { "); JITLinkMemoryManager::SegmentsRequestMap Segments; for (auto &KV : Layout) { auto &Prot = KV.first; auto &SegLists = KV.second; uint64_t SegAlign = 1; // Calculate segment content size. size_t SegContentSize = 0; for (auto *B : SegLists.ContentBlocks) { SegAlign = std::max(SegAlign, B->getAlignment()); SegContentSize = alignToBlock(SegContentSize, *B); SegContentSize += B->getSize(); } uint64_t SegZeroFillStart = SegContentSize; uint64_t SegZeroFillEnd = SegZeroFillStart; for (auto *B : SegLists.ZeroFillBlocks) { SegAlign = std::max(SegAlign, B->getAlignment()); SegZeroFillEnd = alignToBlock(SegZeroFillEnd, *B); SegZeroFillEnd += B->getSize(); } Segments[Prot] = {SegAlign, SegContentSize, SegZeroFillEnd - SegZeroFillStart}; LLVM_DEBUG({ dbgs() << (&KV == &*Layout.begin() ? "" : "; ") << static_cast(Prot) << ": alignment = " << SegAlign << ", content size = " << SegContentSize << ", zero-fill size = " << (SegZeroFillEnd - SegZeroFillStart); }); } LLVM_DEBUG(dbgs() << " }\n"); if (auto AllocOrErr = Ctx->getMemoryManager().allocate(Segments)) Alloc = std::move(*AllocOrErr); else return AllocOrErr.takeError(); LLVM_DEBUG({ dbgs() << "JIT linker got working memory:\n"; for (auto &KV : Layout) { auto Prot = static_cast(KV.first); dbgs() << " " << Prot << ": " << (const void *)Alloc->getWorkingMemory(Prot).data() << "\n"; } }); // Update block target addresses. for (auto &KV : Layout) { auto &Prot = KV.first; auto &SL = KV.second; JITTargetAddress NextBlockAddr = Alloc->getTargetMemory(static_cast(Prot)); for (auto *SIList : {&SL.ContentBlocks, &SL.ZeroFillBlocks}) for (auto *B : *SIList) { NextBlockAddr = alignToBlock(NextBlockAddr, *B); B->setAddress(NextBlockAddr); NextBlockAddr += B->getSize(); } } return Error::success(); } DenseSet JITLinkerBase::getExternalSymbolNames() const { // Identify unresolved external symbols. DenseSet UnresolvedExternals; for (auto *Sym : G->external_symbols()) { assert(Sym->getAddress() == 0 && "External has already been assigned an address"); assert(Sym->getName() != StringRef() && Sym->getName() != "" && "Externals must be named"); UnresolvedExternals.insert(Sym->getName()); } return UnresolvedExternals; } void JITLinkerBase::applyLookupResult(AsyncLookupResult Result) { for (auto *Sym : G->external_symbols()) { assert(Sym->getAddress() == 0 && "Symbol already resolved"); assert(!Sym->isDefined() && "Symbol being resolved is already defined"); assert(Result.count(Sym->getName()) && "Missing resolution for symbol"); Sym->getAddressable().setAddress(Result[Sym->getName()].getAddress()); } LLVM_DEBUG({ dbgs() << "Externals after applying lookup result:\n"; for (auto *Sym : G->external_symbols()) dbgs() << " " << Sym->getName() << ": " << formatv("{0:x16}", Sym->getAddress()) << "\n"; }); assert(llvm::all_of(G->external_symbols(), [](Symbol *Sym) { return Sym->getAddress() != 0; }) && "All symbols should have been resolved by this point"); } void JITLinkerBase::deallocateAndBailOut(Error Err) { assert(Err && "Should not be bailing out on success value"); assert(Alloc && "can not call deallocateAndBailOut before allocation"); Ctx->notifyFailed(joinErrors(std::move(Err), Alloc->deallocate())); } void JITLinkerBase::dumpGraph(raw_ostream &OS) { assert(G && "Graph is not set yet"); G->dump(dbgs(), [this](Edge::Kind K) { return getEdgeKindName(K); }); } void prune(LinkGraph &G) { std::vector Worklist; DenseSet VisitedBlocks; // Build the initial worklist from all symbols initially live. for (auto *Sym : G.defined_symbols()) if (Sym->isLive()) Worklist.push_back(Sym); // Propagate live flags to all symbols reachable from the initial live set. while (!Worklist.empty()) { auto *Sym = Worklist.back(); Worklist.pop_back(); auto &B = Sym->getBlock(); // Skip addressables that we've visited before. if (VisitedBlocks.count(&B)) continue; VisitedBlocks.insert(&B); for (auto &E : Sym->getBlock().edges()) { if (E.getTarget().isDefined() && !E.getTarget().isLive()) { E.getTarget().setLive(true); Worklist.push_back(&E.getTarget()); } } } // Collect all the symbols to remove, then remove them. { LLVM_DEBUG(dbgs() << "Dead-stripping symbols:\n"); std::vector SymbolsToRemove; for (auto *Sym : G.defined_symbols()) if (!Sym->isLive()) SymbolsToRemove.push_back(Sym); for (auto *Sym : SymbolsToRemove) { LLVM_DEBUG(dbgs() << " " << *Sym << "...\n"); G.removeDefinedSymbol(*Sym); } } // Delete any unused blocks. { LLVM_DEBUG(dbgs() << "Dead-stripping blocks:\n"); std::vector BlocksToRemove; for (auto *B : G.blocks()) if (!VisitedBlocks.count(B)) BlocksToRemove.push_back(B); for (auto *B : BlocksToRemove) { LLVM_DEBUG(dbgs() << " " << *B << "...\n"); G.removeBlock(*B); } } } } // end namespace jitlink } // end namespace llvm