//===- FunctionImport.cpp - ThinLTO Summary-based Function Import ---------===// // // 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 // //===----------------------------------------------------------------------===// // // This file implements Function import based on summaries. // //===----------------------------------------------------------------------===// #include "llvm/Transforms/IPO/FunctionImport.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SetVector.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/Statistic.h" #include "llvm/ADT/StringMap.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/StringSet.h" #include "llvm/Bitcode/BitcodeReader.h" #include "llvm/IR/AutoUpgrade.h" #include "llvm/IR/Constants.h" #include "llvm/IR/Function.h" #include "llvm/IR/GlobalAlias.h" #include "llvm/IR/GlobalObject.h" #include "llvm/IR/GlobalValue.h" #include "llvm/IR/GlobalVariable.h" #include "llvm/IR/Metadata.h" #include "llvm/IR/Module.h" #include "llvm/IR/ModuleSummaryIndex.h" #include "llvm/IRReader/IRReader.h" #include "llvm/InitializePasses.h" #include "llvm/Linker/IRMover.h" #include "llvm/Object/ModuleSymbolTable.h" #include "llvm/Object/SymbolicFile.h" #include "llvm/Pass.h" #include "llvm/Support/Casting.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/Error.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/SourceMgr.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Transforms/IPO/Internalize.h" #include "llvm/Transforms/Utils/Cloning.h" #include "llvm/Transforms/Utils/FunctionImportUtils.h" #include "llvm/Transforms/Utils/ValueMapper.h" #include #include #include #include #include #include #include using namespace llvm; #define DEBUG_TYPE "function-import" STATISTIC(NumImportedFunctionsThinLink, "Number of functions thin link decided to import"); STATISTIC(NumImportedHotFunctionsThinLink, "Number of hot functions thin link decided to import"); STATISTIC(NumImportedCriticalFunctionsThinLink, "Number of critical functions thin link decided to import"); STATISTIC(NumImportedGlobalVarsThinLink, "Number of global variables thin link decided to import"); STATISTIC(NumImportedFunctions, "Number of functions imported in backend"); STATISTIC(NumImportedGlobalVars, "Number of global variables imported in backend"); STATISTIC(NumImportedModules, "Number of modules imported from"); STATISTIC(NumDeadSymbols, "Number of dead stripped symbols in index"); STATISTIC(NumLiveSymbols, "Number of live symbols in index"); /// Limit on instruction count of imported functions. static cl::opt ImportInstrLimit( "import-instr-limit", cl::init(100), cl::Hidden, cl::value_desc("N"), cl::desc("Only import functions with less than N instructions")); static cl::opt ImportCutoff( "import-cutoff", cl::init(-1), cl::Hidden, cl::value_desc("N"), cl::desc("Only import first N functions if N>=0 (default -1)")); static cl::opt ImportInstrFactor("import-instr-evolution-factor", cl::init(0.7), cl::Hidden, cl::value_desc("x"), cl::desc("As we import functions, multiply the " "`import-instr-limit` threshold by this factor " "before processing newly imported functions")); static cl::opt ImportHotInstrFactor( "import-hot-evolution-factor", cl::init(1.0), cl::Hidden, cl::value_desc("x"), cl::desc("As we import functions called from hot callsite, multiply the " "`import-instr-limit` threshold by this factor " "before processing newly imported functions")); static cl::opt ImportHotMultiplier( "import-hot-multiplier", cl::init(10.0), cl::Hidden, cl::value_desc("x"), cl::desc("Multiply the `import-instr-limit` threshold for hot callsites")); static cl::opt ImportCriticalMultiplier( "import-critical-multiplier", cl::init(100.0), cl::Hidden, cl::value_desc("x"), cl::desc( "Multiply the `import-instr-limit` threshold for critical callsites")); // FIXME: This multiplier was not really tuned up. static cl::opt ImportColdMultiplier( "import-cold-multiplier", cl::init(0), cl::Hidden, cl::value_desc("N"), cl::desc("Multiply the `import-instr-limit` threshold for cold callsites")); static cl::opt PrintImports("print-imports", cl::init(false), cl::Hidden, cl::desc("Print imported functions")); static cl::opt PrintImportFailures( "print-import-failures", cl::init(false), cl::Hidden, cl::desc("Print information for functions rejected for importing")); static cl::opt ComputeDead("compute-dead", cl::init(true), cl::Hidden, cl::desc("Compute dead symbols")); static cl::opt EnableImportMetadata( "enable-import-metadata", cl::init(false), cl::Hidden, cl::desc("Enable import metadata like 'thinlto_src_module'")); /// Summary file to use for function importing when using -function-import from /// the command line. static cl::opt SummaryFile("summary-file", cl::desc("The summary file to use for function importing.")); /// Used when testing importing from distributed indexes via opt // -function-import. static cl::opt ImportAllIndex("import-all-index", cl::desc("Import all external functions in index.")); // Load lazily a module from \p FileName in \p Context. static std::unique_ptr loadFile(const std::string &FileName, LLVMContext &Context) { SMDiagnostic Err; LLVM_DEBUG(dbgs() << "Loading '" << FileName << "'\n"); // Metadata isn't loaded until functions are imported, to minimize // the memory overhead. std::unique_ptr Result = getLazyIRFileModule(FileName, Err, Context, /* ShouldLazyLoadMetadata = */ true); if (!Result) { Err.print("function-import", errs()); report_fatal_error("Abort"); } return Result; } /// Given a list of possible callee implementation for a call site, select one /// that fits the \p Threshold. /// /// FIXME: select "best" instead of first that fits. But what is "best"? /// - The smallest: more likely to be inlined. /// - The one with the least outgoing edges (already well optimized). /// - One from a module already being imported from in order to reduce the /// number of source modules parsed/linked. /// - One that has PGO data attached. /// - [insert you fancy metric here] static const GlobalValueSummary * selectCallee(const ModuleSummaryIndex &Index, ArrayRef> CalleeSummaryList, unsigned Threshold, StringRef CallerModulePath, FunctionImporter::ImportFailureReason &Reason, GlobalValue::GUID GUID) { Reason = FunctionImporter::ImportFailureReason::None; auto It = llvm::find_if( CalleeSummaryList, [&](const std::unique_ptr &SummaryPtr) { auto *GVSummary = SummaryPtr.get(); if (!Index.isGlobalValueLive(GVSummary)) { Reason = FunctionImporter::ImportFailureReason::NotLive; return false; } // For SamplePGO, in computeImportForFunction the OriginalId // may have been used to locate the callee summary list (See // comment there). // The mapping from OriginalId to GUID may return a GUID // that corresponds to a static variable. Filter it out here. // This can happen when // 1) There is a call to a library function which is not defined // in the index. // 2) There is a static variable with the OriginalGUID identical // to the GUID of the library function in 1); // When this happens, the logic for SamplePGO kicks in and // the static variable in 2) will be found, which needs to be // filtered out. if (GVSummary->getSummaryKind() == GlobalValueSummary::GlobalVarKind) { Reason = FunctionImporter::ImportFailureReason::GlobalVar; return false; } if (GlobalValue::isInterposableLinkage(GVSummary->linkage())) { Reason = FunctionImporter::ImportFailureReason::InterposableLinkage; // There is no point in importing these, we can't inline them return false; } auto *Summary = cast(GVSummary->getBaseObject()); // If this is a local function, make sure we import the copy // in the caller's module. The only time a local function can // share an entry in the index is if there is a local with the same name // in another module that had the same source file name (in a different // directory), where each was compiled in their own directory so there // was not distinguishing path. // However, do the import from another module if there is only one // entry in the list - in that case this must be a reference due // to indirect call profile data, since a function pointer can point to // a local in another module. if (GlobalValue::isLocalLinkage(Summary->linkage()) && CalleeSummaryList.size() > 1 && Summary->modulePath() != CallerModulePath) { Reason = FunctionImporter::ImportFailureReason::LocalLinkageNotInModule; return false; } if ((Summary->instCount() > Threshold) && !Summary->fflags().AlwaysInline) { Reason = FunctionImporter::ImportFailureReason::TooLarge; return false; } // Skip if it isn't legal to import (e.g. may reference unpromotable // locals). if (Summary->notEligibleToImport()) { Reason = FunctionImporter::ImportFailureReason::NotEligible; return false; } // Don't bother importing if we can't inline it anyway. if (Summary->fflags().NoInline) { Reason = FunctionImporter::ImportFailureReason::NoInline; return false; } return true; }); if (It == CalleeSummaryList.end()) return nullptr; return cast(It->get()); } namespace { using EdgeInfo = std::tuple; } // anonymous namespace static ValueInfo updateValueInfoForIndirectCalls(const ModuleSummaryIndex &Index, ValueInfo VI) { if (!VI.getSummaryList().empty()) return VI; // For SamplePGO, the indirect call targets for local functions will // have its original name annotated in profile. We try to find the // corresponding PGOFuncName as the GUID. // FIXME: Consider updating the edges in the graph after building // it, rather than needing to perform this mapping on each walk. auto GUID = Index.getGUIDFromOriginalID(VI.getGUID()); if (GUID == 0) return ValueInfo(); return Index.getValueInfo(GUID); } static void computeImportForReferencedGlobals( const GlobalValueSummary &Summary, const ModuleSummaryIndex &Index, const GVSummaryMapTy &DefinedGVSummaries, SmallVectorImpl &Worklist, FunctionImporter::ImportMapTy &ImportList, StringMap *ExportLists) { for (auto &VI : Summary.refs()) { if (DefinedGVSummaries.count(VI.getGUID())) { LLVM_DEBUG( dbgs() << "Ref ignored! Target already in destination module.\n"); continue; } LLVM_DEBUG(dbgs() << " ref -> " << VI << "\n"); // If this is a local variable, make sure we import the copy // in the caller's module. The only time a local variable can // share an entry in the index is if there is a local with the same name // in another module that had the same source file name (in a different // directory), where each was compiled in their own directory so there // was not distinguishing path. auto LocalNotInModule = [&](const GlobalValueSummary *RefSummary) -> bool { return GlobalValue::isLocalLinkage(RefSummary->linkage()) && RefSummary->modulePath() != Summary.modulePath(); }; for (auto &RefSummary : VI.getSummaryList()) if (isa(RefSummary.get()) && Index.canImportGlobalVar(RefSummary.get(), /* AnalyzeRefs */ true) && !LocalNotInModule(RefSummary.get())) { auto ILI = ImportList[RefSummary->modulePath()].insert(VI.getGUID()); // Only update stat and exports if we haven't already imported this // variable. if (!ILI.second) break; NumImportedGlobalVarsThinLink++; // Any references made by this variable will be marked exported later, // in ComputeCrossModuleImport, after import decisions are complete, // which is more efficient than adding them here. if (ExportLists) (*ExportLists)[RefSummary->modulePath()].insert(VI); // If variable is not writeonly we attempt to recursively analyze // its references in order to import referenced constants. if (!Index.isWriteOnly(cast(RefSummary.get()))) Worklist.emplace_back(RefSummary.get(), 0); break; } } } static const char * getFailureName(FunctionImporter::ImportFailureReason Reason) { switch (Reason) { case FunctionImporter::ImportFailureReason::None: return "None"; case FunctionImporter::ImportFailureReason::GlobalVar: return "GlobalVar"; case FunctionImporter::ImportFailureReason::NotLive: return "NotLive"; case FunctionImporter::ImportFailureReason::TooLarge: return "TooLarge"; case FunctionImporter::ImportFailureReason::InterposableLinkage: return "InterposableLinkage"; case FunctionImporter::ImportFailureReason::LocalLinkageNotInModule: return "LocalLinkageNotInModule"; case FunctionImporter::ImportFailureReason::NotEligible: return "NotEligible"; case FunctionImporter::ImportFailureReason::NoInline: return "NoInline"; } llvm_unreachable("invalid reason"); } /// Compute the list of functions to import for a given caller. Mark these /// imported functions and the symbols they reference in their source module as /// exported from their source module. static void computeImportForFunction( const FunctionSummary &Summary, const ModuleSummaryIndex &Index, const unsigned Threshold, const GVSummaryMapTy &DefinedGVSummaries, SmallVectorImpl &Worklist, FunctionImporter::ImportMapTy &ImportList, StringMap *ExportLists, FunctionImporter::ImportThresholdsTy &ImportThresholds) { computeImportForReferencedGlobals(Summary, Index, DefinedGVSummaries, Worklist, ImportList, ExportLists); static int ImportCount = 0; for (auto &Edge : Summary.calls()) { ValueInfo VI = Edge.first; LLVM_DEBUG(dbgs() << " edge -> " << VI << " Threshold:" << Threshold << "\n"); if (ImportCutoff >= 0 && ImportCount >= ImportCutoff) { LLVM_DEBUG(dbgs() << "ignored! import-cutoff value of " << ImportCutoff << " reached.\n"); continue; } VI = updateValueInfoForIndirectCalls(Index, VI); if (!VI) continue; if (DefinedGVSummaries.count(VI.getGUID())) { LLVM_DEBUG(dbgs() << "ignored! Target already in destination module.\n"); continue; } auto GetBonusMultiplier = [](CalleeInfo::HotnessType Hotness) -> float { if (Hotness == CalleeInfo::HotnessType::Hot) return ImportHotMultiplier; if (Hotness == CalleeInfo::HotnessType::Cold) return ImportColdMultiplier; if (Hotness == CalleeInfo::HotnessType::Critical) return ImportCriticalMultiplier; return 1.0; }; const auto NewThreshold = Threshold * GetBonusMultiplier(Edge.second.getHotness()); auto IT = ImportThresholds.insert(std::make_pair( VI.getGUID(), std::make_tuple(NewThreshold, nullptr, nullptr))); bool PreviouslyVisited = !IT.second; auto &ProcessedThreshold = std::get<0>(IT.first->second); auto &CalleeSummary = std::get<1>(IT.first->second); auto &FailureInfo = std::get<2>(IT.first->second); bool IsHotCallsite = Edge.second.getHotness() == CalleeInfo::HotnessType::Hot; bool IsCriticalCallsite = Edge.second.getHotness() == CalleeInfo::HotnessType::Critical; const FunctionSummary *ResolvedCalleeSummary = nullptr; if (CalleeSummary) { assert(PreviouslyVisited); // Since the traversal of the call graph is DFS, we can revisit a function // a second time with a higher threshold. In this case, it is added back // to the worklist with the new threshold (so that its own callee chains // can be considered with the higher threshold). if (NewThreshold <= ProcessedThreshold) { LLVM_DEBUG( dbgs() << "ignored! Target was already imported with Threshold " << ProcessedThreshold << "\n"); continue; } // Update with new larger threshold. ProcessedThreshold = NewThreshold; ResolvedCalleeSummary = cast(CalleeSummary); } else { // If we already rejected importing a callee at the same or higher // threshold, don't waste time calling selectCallee. if (PreviouslyVisited && NewThreshold <= ProcessedThreshold) { LLVM_DEBUG( dbgs() << "ignored! Target was already rejected with Threshold " << ProcessedThreshold << "\n"); if (PrintImportFailures) { assert(FailureInfo && "Expected FailureInfo for previously rejected candidate"); FailureInfo->Attempts++; } continue; } FunctionImporter::ImportFailureReason Reason; CalleeSummary = selectCallee(Index, VI.getSummaryList(), NewThreshold, Summary.modulePath(), Reason, VI.getGUID()); if (!CalleeSummary) { // Update with new larger threshold if this was a retry (otherwise // we would have already inserted with NewThreshold above). Also // update failure info if requested. if (PreviouslyVisited) { ProcessedThreshold = NewThreshold; if (PrintImportFailures) { assert(FailureInfo && "Expected FailureInfo for previously rejected candidate"); FailureInfo->Reason = Reason; FailureInfo->Attempts++; FailureInfo->MaxHotness = std::max(FailureInfo->MaxHotness, Edge.second.getHotness()); } } else if (PrintImportFailures) { assert(!FailureInfo && "Expected no FailureInfo for newly rejected candidate"); FailureInfo = std::make_unique( VI, Edge.second.getHotness(), Reason, 1); } LLVM_DEBUG( dbgs() << "ignored! No qualifying callee with summary found.\n"); continue; } // "Resolve" the summary CalleeSummary = CalleeSummary->getBaseObject(); ResolvedCalleeSummary = cast(CalleeSummary); assert((ResolvedCalleeSummary->fflags().AlwaysInline || (ResolvedCalleeSummary->instCount() <= NewThreshold)) && "selectCallee() didn't honor the threshold"); auto ExportModulePath = ResolvedCalleeSummary->modulePath(); auto ILI = ImportList[ExportModulePath].insert(VI.getGUID()); // We previously decided to import this GUID definition if it was already // inserted in the set of imports from the exporting module. bool PreviouslyImported = !ILI.second; if (!PreviouslyImported) { NumImportedFunctionsThinLink++; if (IsHotCallsite) NumImportedHotFunctionsThinLink++; if (IsCriticalCallsite) NumImportedCriticalFunctionsThinLink++; } // Any calls/references made by this function will be marked exported // later, in ComputeCrossModuleImport, after import decisions are // complete, which is more efficient than adding them here. if (ExportLists) (*ExportLists)[ExportModulePath].insert(VI); } auto GetAdjustedThreshold = [](unsigned Threshold, bool IsHotCallsite) { // Adjust the threshold for next level of imported functions. // The threshold is different for hot callsites because we can then // inline chains of hot calls. if (IsHotCallsite) return Threshold * ImportHotInstrFactor; return Threshold * ImportInstrFactor; }; const auto AdjThreshold = GetAdjustedThreshold(Threshold, IsHotCallsite); ImportCount++; // Insert the newly imported function to the worklist. Worklist.emplace_back(ResolvedCalleeSummary, AdjThreshold); } } /// Given the list of globals defined in a module, compute the list of imports /// as well as the list of "exports", i.e. the list of symbols referenced from /// another module (that may require promotion). static void ComputeImportForModule( const GVSummaryMapTy &DefinedGVSummaries, const ModuleSummaryIndex &Index, StringRef ModName, FunctionImporter::ImportMapTy &ImportList, StringMap *ExportLists = nullptr) { // Worklist contains the list of function imported in this module, for which // we will analyse the callees and may import further down the callgraph. SmallVector Worklist; FunctionImporter::ImportThresholdsTy ImportThresholds; // Populate the worklist with the import for the functions in the current // module for (auto &GVSummary : DefinedGVSummaries) { #ifndef NDEBUG // FIXME: Change the GVSummaryMapTy to hold ValueInfo instead of GUID // so this map look up (and possibly others) can be avoided. auto VI = Index.getValueInfo(GVSummary.first); #endif if (!Index.isGlobalValueLive(GVSummary.second)) { LLVM_DEBUG(dbgs() << "Ignores Dead GUID: " << VI << "\n"); continue; } auto *FuncSummary = dyn_cast(GVSummary.second->getBaseObject()); if (!FuncSummary) // Skip import for global variables continue; LLVM_DEBUG(dbgs() << "Initialize import for " << VI << "\n"); computeImportForFunction(*FuncSummary, Index, ImportInstrLimit, DefinedGVSummaries, Worklist, ImportList, ExportLists, ImportThresholds); } // Process the newly imported functions and add callees to the worklist. while (!Worklist.empty()) { auto GVInfo = Worklist.pop_back_val(); auto *Summary = std::get<0>(GVInfo); auto Threshold = std::get<1>(GVInfo); if (auto *FS = dyn_cast(Summary)) computeImportForFunction(*FS, Index, Threshold, DefinedGVSummaries, Worklist, ImportList, ExportLists, ImportThresholds); else computeImportForReferencedGlobals(*Summary, Index, DefinedGVSummaries, Worklist, ImportList, ExportLists); } // Print stats about functions considered but rejected for importing // when requested. if (PrintImportFailures) { dbgs() << "Missed imports into module " << ModName << "\n"; for (auto &I : ImportThresholds) { auto &ProcessedThreshold = std::get<0>(I.second); auto &CalleeSummary = std::get<1>(I.second); auto &FailureInfo = std::get<2>(I.second); if (CalleeSummary) continue; // We are going to import. assert(FailureInfo); FunctionSummary *FS = nullptr; if (!FailureInfo->VI.getSummaryList().empty()) FS = dyn_cast( FailureInfo->VI.getSummaryList()[0]->getBaseObject()); dbgs() << FailureInfo->VI << ": Reason = " << getFailureName(FailureInfo->Reason) << ", Threshold = " << ProcessedThreshold << ", Size = " << (FS ? (int)FS->instCount() : -1) << ", MaxHotness = " << getHotnessName(FailureInfo->MaxHotness) << ", Attempts = " << FailureInfo->Attempts << "\n"; } } } #ifndef NDEBUG static bool isGlobalVarSummary(const ModuleSummaryIndex &Index, ValueInfo VI) { auto SL = VI.getSummaryList(); return SL.empty() ? false : SL[0]->getSummaryKind() == GlobalValueSummary::GlobalVarKind; } static bool isGlobalVarSummary(const ModuleSummaryIndex &Index, GlobalValue::GUID G) { if (const auto &VI = Index.getValueInfo(G)) return isGlobalVarSummary(Index, VI); return false; } template static unsigned numGlobalVarSummaries(const ModuleSummaryIndex &Index, T &Cont) { unsigned NumGVS = 0; for (auto &V : Cont) if (isGlobalVarSummary(Index, V)) ++NumGVS; return NumGVS; } #endif #ifndef NDEBUG static bool checkVariableImport(const ModuleSummaryIndex &Index, StringMap &ImportLists, StringMap &ExportLists) { DenseSet FlattenedImports; for (auto &ImportPerModule : ImportLists) for (auto &ExportPerModule : ImportPerModule.second) FlattenedImports.insert(ExportPerModule.second.begin(), ExportPerModule.second.end()); // Checks that all GUIDs of read/writeonly vars we see in export lists // are also in the import lists. Otherwise we my face linker undefs, // because readonly and writeonly vars are internalized in their // source modules. auto IsReadOrWriteOnlyVar = [&](StringRef ModulePath, const ValueInfo &VI) { auto *GVS = dyn_cast_or_null( Index.findSummaryInModule(VI, ModulePath)); return GVS && (Index.isReadOnly(GVS) || Index.isWriteOnly(GVS)); }; for (auto &ExportPerModule : ExportLists) for (auto &VI : ExportPerModule.second) if (!FlattenedImports.count(VI.getGUID()) && IsReadOrWriteOnlyVar(ExportPerModule.first(), VI)) return false; return true; } #endif /// Compute all the import and export for every module using the Index. void llvm::ComputeCrossModuleImport( const ModuleSummaryIndex &Index, const StringMap &ModuleToDefinedGVSummaries, StringMap &ImportLists, StringMap &ExportLists) { // For each module that has function defined, compute the import/export lists. for (auto &DefinedGVSummaries : ModuleToDefinedGVSummaries) { auto &ImportList = ImportLists[DefinedGVSummaries.first()]; LLVM_DEBUG(dbgs() << "Computing import for Module '" << DefinedGVSummaries.first() << "'\n"); ComputeImportForModule(DefinedGVSummaries.second, Index, DefinedGVSummaries.first(), ImportList, &ExportLists); } // When computing imports we only added the variables and functions being // imported to the export list. We also need to mark any references and calls // they make as exported as well. We do this here, as it is more efficient // since we may import the same values multiple times into different modules // during the import computation. for (auto &ELI : ExportLists) { FunctionImporter::ExportSetTy NewExports; const auto &DefinedGVSummaries = ModuleToDefinedGVSummaries.lookup(ELI.first()); for (auto &EI : ELI.second) { // Find the copy defined in the exporting module so that we can mark the // values it references in that specific definition as exported. // Below we will add all references and called values, without regard to // whether they are also defined in this module. We subsequently prune the // list to only include those defined in the exporting module, see comment // there as to why. auto DS = DefinedGVSummaries.find(EI.getGUID()); // Anything marked exported during the import computation must have been // defined in the exporting module. assert(DS != DefinedGVSummaries.end()); auto *S = DS->getSecond(); S = S->getBaseObject(); if (auto *GVS = dyn_cast(S)) { // Export referenced functions and variables. We don't export/promote // objects referenced by writeonly variable initializer, because // we convert such variables initializers to "zeroinitializer". // See processGlobalForThinLTO. if (!Index.isWriteOnly(GVS)) for (const auto &VI : GVS->refs()) NewExports.insert(VI); } else { auto *FS = cast(S); for (auto &Edge : FS->calls()) NewExports.insert(Edge.first); for (auto &Ref : FS->refs()) NewExports.insert(Ref); } } // Prune list computed above to only include values defined in the exporting // module. We do this after the above insertion since we may hit the same // ref/call target multiple times in above loop, and it is more efficient to // avoid a set lookup each time. for (auto EI = NewExports.begin(); EI != NewExports.end();) { if (!DefinedGVSummaries.count(EI->getGUID())) NewExports.erase(EI++); else ++EI; } ELI.second.insert(NewExports.begin(), NewExports.end()); } assert(checkVariableImport(Index, ImportLists, ExportLists)); #ifndef NDEBUG LLVM_DEBUG(dbgs() << "Import/Export lists for " << ImportLists.size() << " modules:\n"); for (auto &ModuleImports : ImportLists) { auto ModName = ModuleImports.first(); auto &Exports = ExportLists[ModName]; unsigned NumGVS = numGlobalVarSummaries(Index, Exports); LLVM_DEBUG(dbgs() << "* Module " << ModName << " exports " << Exports.size() - NumGVS << " functions and " << NumGVS << " vars. Imports from " << ModuleImports.second.size() << " modules.\n"); for (auto &Src : ModuleImports.second) { auto SrcModName = Src.first(); unsigned NumGVSPerMod = numGlobalVarSummaries(Index, Src.second); LLVM_DEBUG(dbgs() << " - " << Src.second.size() - NumGVSPerMod << " functions imported from " << SrcModName << "\n"); LLVM_DEBUG(dbgs() << " - " << NumGVSPerMod << " global vars imported from " << SrcModName << "\n"); } } #endif } #ifndef NDEBUG static void dumpImportListForModule(const ModuleSummaryIndex &Index, StringRef ModulePath, FunctionImporter::ImportMapTy &ImportList) { LLVM_DEBUG(dbgs() << "* Module " << ModulePath << " imports from " << ImportList.size() << " modules.\n"); for (auto &Src : ImportList) { auto SrcModName = Src.first(); unsigned NumGVSPerMod = numGlobalVarSummaries(Index, Src.second); LLVM_DEBUG(dbgs() << " - " << Src.second.size() - NumGVSPerMod << " functions imported from " << SrcModName << "\n"); LLVM_DEBUG(dbgs() << " - " << NumGVSPerMod << " vars imported from " << SrcModName << "\n"); } } #endif /// Compute all the imports for the given module in the Index. void llvm::ComputeCrossModuleImportForModule( StringRef ModulePath, const ModuleSummaryIndex &Index, FunctionImporter::ImportMapTy &ImportList) { // Collect the list of functions this module defines. // GUID -> Summary GVSummaryMapTy FunctionSummaryMap; Index.collectDefinedFunctionsForModule(ModulePath, FunctionSummaryMap); // Compute the import list for this module. LLVM_DEBUG(dbgs() << "Computing import for Module '" << ModulePath << "'\n"); ComputeImportForModule(FunctionSummaryMap, Index, ModulePath, ImportList); #ifndef NDEBUG dumpImportListForModule(Index, ModulePath, ImportList); #endif } // Mark all external summaries in Index for import into the given module. // Used for distributed builds using a distributed index. void llvm::ComputeCrossModuleImportForModuleFromIndex( StringRef ModulePath, const ModuleSummaryIndex &Index, FunctionImporter::ImportMapTy &ImportList) { for (auto &GlobalList : Index) { // Ignore entries for undefined references. if (GlobalList.second.SummaryList.empty()) continue; auto GUID = GlobalList.first; assert(GlobalList.second.SummaryList.size() == 1 && "Expected individual combined index to have one summary per GUID"); auto &Summary = GlobalList.second.SummaryList[0]; // Skip the summaries for the importing module. These are included to // e.g. record required linkage changes. if (Summary->modulePath() == ModulePath) continue; // Add an entry to provoke importing by thinBackend. ImportList[Summary->modulePath()].insert(GUID); } #ifndef NDEBUG dumpImportListForModule(Index, ModulePath, ImportList); #endif } void llvm::computeDeadSymbols( ModuleSummaryIndex &Index, const DenseSet &GUIDPreservedSymbols, function_ref isPrevailing) { assert(!Index.withGlobalValueDeadStripping()); if (!ComputeDead) return; if (GUIDPreservedSymbols.empty()) // Don't do anything when nothing is live, this is friendly with tests. return; unsigned LiveSymbols = 0; SmallVector Worklist; Worklist.reserve(GUIDPreservedSymbols.size() * 2); for (auto GUID : GUIDPreservedSymbols) { ValueInfo VI = Index.getValueInfo(GUID); if (!VI) continue; for (auto &S : VI.getSummaryList()) S->setLive(true); } // Add values flagged in the index as live roots to the worklist. for (const auto &Entry : Index) { auto VI = Index.getValueInfo(Entry); for (auto &S : Entry.second.SummaryList) if (S->isLive()) { LLVM_DEBUG(dbgs() << "Live root: " << VI << "\n"); Worklist.push_back(VI); ++LiveSymbols; break; } } // Make value live and add it to the worklist if it was not live before. auto visit = [&](ValueInfo VI, bool IsAliasee) { // FIXME: If we knew which edges were created for indirect call profiles, // we could skip them here. Any that are live should be reached via // other edges, e.g. reference edges. Otherwise, using a profile collected // on a slightly different binary might provoke preserving, importing // and ultimately promoting calls to functions not linked into this // binary, which increases the binary size unnecessarily. Note that // if this code changes, the importer needs to change so that edges // to functions marked dead are skipped. VI = updateValueInfoForIndirectCalls(Index, VI); if (!VI) return; if (llvm::any_of(VI.getSummaryList(), [](const std::unique_ptr &S) { return S->isLive(); })) return; // We only keep live symbols that are known to be non-prevailing if any are // available_externally, linkonceodr, weakodr. Those symbols are discarded // later in the EliminateAvailableExternally pass and setting them to // not-live could break downstreams users of liveness information (PR36483) // or limit optimization opportunities. if (isPrevailing(VI.getGUID()) == PrevailingType::No) { bool KeepAliveLinkage = false; bool Interposable = false; for (auto &S : VI.getSummaryList()) { if (S->linkage() == GlobalValue::AvailableExternallyLinkage || S->linkage() == GlobalValue::WeakODRLinkage || S->linkage() == GlobalValue::LinkOnceODRLinkage) KeepAliveLinkage = true; else if (GlobalValue::isInterposableLinkage(S->linkage())) Interposable = true; } if (!IsAliasee) { if (!KeepAliveLinkage) return; if (Interposable) report_fatal_error( "Interposable and available_externally/linkonce_odr/weak_odr " "symbol"); } } for (auto &S : VI.getSummaryList()) S->setLive(true); ++LiveSymbols; Worklist.push_back(VI); }; while (!Worklist.empty()) { auto VI = Worklist.pop_back_val(); for (auto &Summary : VI.getSummaryList()) { Summary->setLive(true); if (auto *AS = dyn_cast(Summary.get())) { // If this is an alias, visit the aliasee VI to ensure that all copies // are marked live and it is added to the worklist for further // processing of its references. visit(AS->getAliaseeVI(), true); continue; } for (auto Ref : Summary->refs()) visit(Ref, false); if (auto *FS = dyn_cast(Summary.get())) for (auto Call : FS->calls()) visit(Call.first, false); } } Index.setWithGlobalValueDeadStripping(); unsigned DeadSymbols = Index.size() - LiveSymbols; LLVM_DEBUG(dbgs() << LiveSymbols << " symbols Live, and " << DeadSymbols << " symbols Dead \n"); NumDeadSymbols += DeadSymbols; NumLiveSymbols += LiveSymbols; } // Compute dead symbols and propagate constants in combined index. void llvm::computeDeadSymbolsWithConstProp( ModuleSummaryIndex &Index, const DenseSet &GUIDPreservedSymbols, function_ref isPrevailing, bool ImportEnabled) { computeDeadSymbols(Index, GUIDPreservedSymbols, isPrevailing); if (ImportEnabled) Index.propagateAttributes(GUIDPreservedSymbols); } /// Compute the set of summaries needed for a ThinLTO backend compilation of /// \p ModulePath. void llvm::gatherImportedSummariesForModule( StringRef ModulePath, const StringMap &ModuleToDefinedGVSummaries, const FunctionImporter::ImportMapTy &ImportList, std::map &ModuleToSummariesForIndex) { // Include all summaries from the importing module. ModuleToSummariesForIndex[std::string(ModulePath)] = ModuleToDefinedGVSummaries.lookup(ModulePath); // Include summaries for imports. for (auto &ILI : ImportList) { auto &SummariesForIndex = ModuleToSummariesForIndex[std::string(ILI.first())]; const auto &DefinedGVSummaries = ModuleToDefinedGVSummaries.lookup(ILI.first()); for (auto &GI : ILI.second) { const auto &DS = DefinedGVSummaries.find(GI); assert(DS != DefinedGVSummaries.end() && "Expected a defined summary for imported global value"); SummariesForIndex[GI] = DS->second; } } } /// Emit the files \p ModulePath will import from into \p OutputFilename. std::error_code llvm::EmitImportsFiles( StringRef ModulePath, StringRef OutputFilename, const std::map &ModuleToSummariesForIndex) { std::error_code EC; raw_fd_ostream ImportsOS(OutputFilename, EC, sys::fs::OpenFlags::OF_None); if (EC) return EC; for (auto &ILI : ModuleToSummariesForIndex) // The ModuleToSummariesForIndex map includes an entry for the current // Module (needed for writing out the index files). We don't want to // include it in the imports file, however, so filter it out. if (ILI.first != ModulePath) ImportsOS << ILI.first << "\n"; return std::error_code(); } bool llvm::convertToDeclaration(GlobalValue &GV) { LLVM_DEBUG(dbgs() << "Converting to a declaration: `" << GV.getName() << "\n"); if (Function *F = dyn_cast(&GV)) { F->deleteBody(); F->clearMetadata(); F->setComdat(nullptr); } else if (GlobalVariable *V = dyn_cast(&GV)) { V->setInitializer(nullptr); V->setLinkage(GlobalValue::ExternalLinkage); V->clearMetadata(); V->setComdat(nullptr); } else { GlobalValue *NewGV; if (GV.getValueType()->isFunctionTy()) NewGV = Function::Create(cast(GV.getValueType()), GlobalValue::ExternalLinkage, GV.getAddressSpace(), "", GV.getParent()); else NewGV = new GlobalVariable(*GV.getParent(), GV.getValueType(), /*isConstant*/ false, GlobalValue::ExternalLinkage, /*init*/ nullptr, "", /*insertbefore*/ nullptr, GV.getThreadLocalMode(), GV.getType()->getAddressSpace()); NewGV->takeName(&GV); GV.replaceAllUsesWith(NewGV); return false; } if (!GV.isImplicitDSOLocal()) GV.setDSOLocal(false); return true; } /// Fixup prevailing symbol linkages in \p TheModule based on summary analysis. void llvm::thinLTOResolvePrevailingInModule( Module &TheModule, const GVSummaryMapTy &DefinedGlobals) { auto updateLinkage = [&](GlobalValue &GV) { // See if the global summary analysis computed a new resolved linkage. const auto &GS = DefinedGlobals.find(GV.getGUID()); if (GS == DefinedGlobals.end()) return; auto NewLinkage = GS->second->linkage(); if (NewLinkage == GV.getLinkage()) return; if (GlobalValue::isLocalLinkage(GV.getLinkage()) || // Don't internalize anything here, because the code below // lacks necessary correctness checks. Leave this job to // LLVM 'internalize' pass. GlobalValue::isLocalLinkage(NewLinkage) || // In case it was dead and already converted to declaration. GV.isDeclaration()) return; // Check for a non-prevailing def that has interposable linkage // (e.g. non-odr weak or linkonce). In that case we can't simply // convert to available_externally, since it would lose the // interposable property and possibly get inlined. Simply drop // the definition in that case. if (GlobalValue::isAvailableExternallyLinkage(NewLinkage) && GlobalValue::isInterposableLinkage(GV.getLinkage())) { if (!convertToDeclaration(GV)) // FIXME: Change this to collect replaced GVs and later erase // them from the parent module once thinLTOResolvePrevailingGUID is // changed to enable this for aliases. llvm_unreachable("Expected GV to be converted"); } else { // If all copies of the original symbol had global unnamed addr and // linkonce_odr linkage, it should be an auto hide symbol. In that case // the thin link would have marked it as CanAutoHide. Add hidden visibility // to the symbol to preserve the property. if (NewLinkage == GlobalValue::WeakODRLinkage && GS->second->canAutoHide()) { assert(GV.hasLinkOnceODRLinkage() && GV.hasGlobalUnnamedAddr()); GV.setVisibility(GlobalValue::HiddenVisibility); } LLVM_DEBUG(dbgs() << "ODR fixing up linkage for `" << GV.getName() << "` from " << GV.getLinkage() << " to " << NewLinkage << "\n"); GV.setLinkage(NewLinkage); } // Remove declarations from comdats, including available_externally // as this is a declaration for the linker, and will be dropped eventually. // It is illegal for comdats to contain declarations. auto *GO = dyn_cast_or_null(&GV); if (GO && GO->isDeclarationForLinker() && GO->hasComdat()) GO->setComdat(nullptr); }; // Process functions and global now for (auto &GV : TheModule) updateLinkage(GV); for (auto &GV : TheModule.globals()) updateLinkage(GV); for (auto &GV : TheModule.aliases()) updateLinkage(GV); } /// Run internalization on \p TheModule based on symmary analysis. void llvm::thinLTOInternalizeModule(Module &TheModule, const GVSummaryMapTy &DefinedGlobals) { // Declare a callback for the internalize pass that will ask for every // candidate GlobalValue if it can be internalized or not. auto MustPreserveGV = [&](const GlobalValue &GV) -> bool { // Lookup the linkage recorded in the summaries during global analysis. auto GS = DefinedGlobals.find(GV.getGUID()); if (GS == DefinedGlobals.end()) { // Must have been promoted (possibly conservatively). Find original // name so that we can access the correct summary and see if it can // be internalized again. // FIXME: Eventually we should control promotion instead of promoting // and internalizing again. StringRef OrigName = ModuleSummaryIndex::getOriginalNameBeforePromote(GV.getName()); std::string OrigId = GlobalValue::getGlobalIdentifier( OrigName, GlobalValue::InternalLinkage, TheModule.getSourceFileName()); GS = DefinedGlobals.find(GlobalValue::getGUID(OrigId)); if (GS == DefinedGlobals.end()) { // Also check the original non-promoted non-globalized name. In some // cases a preempted weak value is linked in as a local copy because // it is referenced by an alias (IRLinker::linkGlobalValueProto). // In that case, since it was originally not a local value, it was // recorded in the index using the original name. // FIXME: This may not be needed once PR27866 is fixed. GS = DefinedGlobals.find(GlobalValue::getGUID(OrigName)); assert(GS != DefinedGlobals.end()); } } return !GlobalValue::isLocalLinkage(GS->second->linkage()); }; // FIXME: See if we can just internalize directly here via linkage changes // based on the index, rather than invoking internalizeModule. internalizeModule(TheModule, MustPreserveGV); } /// Make alias a clone of its aliasee. static Function *replaceAliasWithAliasee(Module *SrcModule, GlobalAlias *GA) { Function *Fn = cast(GA->getBaseObject()); ValueToValueMapTy VMap; Function *NewFn = CloneFunction(Fn, VMap); // Clone should use the original alias's linkage, visibility and name, and we // ensure all uses of alias instead use the new clone (casted if necessary). NewFn->setLinkage(GA->getLinkage()); NewFn->setVisibility(GA->getVisibility()); GA->replaceAllUsesWith(ConstantExpr::getBitCast(NewFn, GA->getType())); NewFn->takeName(GA); return NewFn; } // Internalize values that we marked with specific attribute // in processGlobalForThinLTO. static void internalizeGVsAfterImport(Module &M) { for (auto &GV : M.globals()) // Skip GVs which have been converted to declarations // by dropDeadSymbols. if (!GV.isDeclaration() && GV.hasAttribute("thinlto-internalize")) { GV.setLinkage(GlobalValue::InternalLinkage); GV.setVisibility(GlobalValue::DefaultVisibility); } } // Automatically import functions in Module \p DestModule based on the summaries // index. Expected FunctionImporter::importFunctions( Module &DestModule, const FunctionImporter::ImportMapTy &ImportList) { LLVM_DEBUG(dbgs() << "Starting import for Module " << DestModule.getModuleIdentifier() << "\n"); unsigned ImportedCount = 0, ImportedGVCount = 0; IRMover Mover(DestModule); // Do the actual import of functions now, one Module at a time std::set ModuleNameOrderedList; for (auto &FunctionsToImportPerModule : ImportList) { ModuleNameOrderedList.insert(FunctionsToImportPerModule.first()); } for (auto &Name : ModuleNameOrderedList) { // Get the module for the import const auto &FunctionsToImportPerModule = ImportList.find(Name); assert(FunctionsToImportPerModule != ImportList.end()); Expected> SrcModuleOrErr = ModuleLoader(Name); if (!SrcModuleOrErr) return SrcModuleOrErr.takeError(); std::unique_ptr SrcModule = std::move(*SrcModuleOrErr); assert(&DestModule.getContext() == &SrcModule->getContext() && "Context mismatch"); // If modules were created with lazy metadata loading, materialize it // now, before linking it (otherwise this will be a noop). if (Error Err = SrcModule->materializeMetadata()) return std::move(Err); auto &ImportGUIDs = FunctionsToImportPerModule->second; // Find the globals to import SetVector GlobalsToImport; for (Function &F : *SrcModule) { if (!F.hasName()) continue; auto GUID = F.getGUID(); auto Import = ImportGUIDs.count(GUID); LLVM_DEBUG(dbgs() << (Import ? "Is" : "Not") << " importing function " << GUID << " " << F.getName() << " from " << SrcModule->getSourceFileName() << "\n"); if (Import) { if (Error Err = F.materialize()) return std::move(Err); if (EnableImportMetadata) { // Add 'thinlto_src_module' metadata for statistics and debugging. F.setMetadata( "thinlto_src_module", MDNode::get(DestModule.getContext(), {MDString::get(DestModule.getContext(), SrcModule->getSourceFileName())})); } GlobalsToImport.insert(&F); } } for (GlobalVariable &GV : SrcModule->globals()) { if (!GV.hasName()) continue; auto GUID = GV.getGUID(); auto Import = ImportGUIDs.count(GUID); LLVM_DEBUG(dbgs() << (Import ? "Is" : "Not") << " importing global " << GUID << " " << GV.getName() << " from " << SrcModule->getSourceFileName() << "\n"); if (Import) { if (Error Err = GV.materialize()) return std::move(Err); ImportedGVCount += GlobalsToImport.insert(&GV); } } for (GlobalAlias &GA : SrcModule->aliases()) { if (!GA.hasName()) continue; auto GUID = GA.getGUID(); auto Import = ImportGUIDs.count(GUID); LLVM_DEBUG(dbgs() << (Import ? "Is" : "Not") << " importing alias " << GUID << " " << GA.getName() << " from " << SrcModule->getSourceFileName() << "\n"); if (Import) { if (Error Err = GA.materialize()) return std::move(Err); // Import alias as a copy of its aliasee. GlobalObject *Base = GA.getBaseObject(); if (Error Err = Base->materialize()) return std::move(Err); auto *Fn = replaceAliasWithAliasee(SrcModule.get(), &GA); LLVM_DEBUG(dbgs() << "Is importing aliasee fn " << Base->getGUID() << " " << Base->getName() << " from " << SrcModule->getSourceFileName() << "\n"); if (EnableImportMetadata) { // Add 'thinlto_src_module' metadata for statistics and debugging. Fn->setMetadata( "thinlto_src_module", MDNode::get(DestModule.getContext(), {MDString::get(DestModule.getContext(), SrcModule->getSourceFileName())})); } GlobalsToImport.insert(Fn); } } // Upgrade debug info after we're done materializing all the globals and we // have loaded all the required metadata! UpgradeDebugInfo(*SrcModule); // Set the partial sample profile ratio in the profile summary module flag // of the imported source module, if applicable, so that the profile summary // module flag will match with that of the destination module when it's // imported. SrcModule->setPartialSampleProfileRatio(Index); // Link in the specified functions. if (renameModuleForThinLTO(*SrcModule, Index, ClearDSOLocalOnDeclarations, &GlobalsToImport)) return true; if (PrintImports) { for (const auto *GV : GlobalsToImport) dbgs() << DestModule.getSourceFileName() << ": Import " << GV->getName() << " from " << SrcModule->getSourceFileName() << "\n"; } if (Error Err = Mover.move( std::move(SrcModule), GlobalsToImport.getArrayRef(), [](GlobalValue &, IRMover::ValueAdder) {}, /*IsPerformingImport=*/true)) report_fatal_error("Function Import: link error: " + toString(std::move(Err))); ImportedCount += GlobalsToImport.size(); NumImportedModules++; } internalizeGVsAfterImport(DestModule); NumImportedFunctions += (ImportedCount - ImportedGVCount); NumImportedGlobalVars += ImportedGVCount; LLVM_DEBUG(dbgs() << "Imported " << ImportedCount - ImportedGVCount << " functions for Module " << DestModule.getModuleIdentifier() << "\n"); LLVM_DEBUG(dbgs() << "Imported " << ImportedGVCount << " global variables for Module " << DestModule.getModuleIdentifier() << "\n"); return ImportedCount; } static bool doImportingForModule(Module &M) { if (SummaryFile.empty()) report_fatal_error("error: -function-import requires -summary-file\n"); Expected> IndexPtrOrErr = getModuleSummaryIndexForFile(SummaryFile); if (!IndexPtrOrErr) { logAllUnhandledErrors(IndexPtrOrErr.takeError(), errs(), "Error loading file '" + SummaryFile + "': "); return false; } std::unique_ptr Index = std::move(*IndexPtrOrErr); // First step is collecting the import list. FunctionImporter::ImportMapTy ImportList; // If requested, simply import all functions in the index. This is used // when testing distributed backend handling via the opt tool, when // we have distributed indexes containing exactly the summaries to import. if (ImportAllIndex) ComputeCrossModuleImportForModuleFromIndex(M.getModuleIdentifier(), *Index, ImportList); else ComputeCrossModuleImportForModule(M.getModuleIdentifier(), *Index, ImportList); // Conservatively mark all internal values as promoted. This interface is // only used when doing importing via the function importing pass. The pass // is only enabled when testing importing via the 'opt' tool, which does // not do the ThinLink that would normally determine what values to promote. for (auto &I : *Index) { for (auto &S : I.second.SummaryList) { if (GlobalValue::isLocalLinkage(S->linkage())) S->setLinkage(GlobalValue::ExternalLinkage); } } // Next we need to promote to global scope and rename any local values that // are potentially exported to other modules. if (renameModuleForThinLTO(M, *Index, /*ClearDSOLocalOnDeclarations=*/false, /*GlobalsToImport=*/nullptr)) { errs() << "Error renaming module\n"; return false; } // Perform the import now. auto ModuleLoader = [&M](StringRef Identifier) { return loadFile(std::string(Identifier), M.getContext()); }; FunctionImporter Importer(*Index, ModuleLoader, /*ClearDSOLocalOnDeclarations=*/false); Expected Result = Importer.importFunctions(M, ImportList); // FIXME: Probably need to propagate Errors through the pass manager. if (!Result) { logAllUnhandledErrors(Result.takeError(), errs(), "Error importing module: "); return false; } return *Result; } namespace { /// Pass that performs cross-module function import provided a summary file. class FunctionImportLegacyPass : public ModulePass { public: /// Pass identification, replacement for typeid static char ID; explicit FunctionImportLegacyPass() : ModulePass(ID) {} /// Specify pass name for debug output StringRef getPassName() const override { return "Function Importing"; } bool runOnModule(Module &M) override { if (skipModule(M)) return false; return doImportingForModule(M); } }; } // end anonymous namespace PreservedAnalyses FunctionImportPass::run(Module &M, ModuleAnalysisManager &AM) { if (!doImportingForModule(M)) return PreservedAnalyses::all(); return PreservedAnalyses::none(); } char FunctionImportLegacyPass::ID = 0; INITIALIZE_PASS(FunctionImportLegacyPass, "function-import", "Summary Based Function Import", false, false) namespace llvm { Pass *createFunctionImportPass() { return new FunctionImportLegacyPass(); } } // end namespace llvm