8 #include "llvm/Analysis/TargetLibraryInfo.h"
9 #include "llvm/Analysis/TargetTransformInfo.h"
10 #include "llvm/CodeGen/TargetSubtargetInfo.h"
11 #include "llvm/IR/AutoUpgrade.h"
12 #include "llvm/IR/AssemblyAnnotationWriter.h"
13 #include "llvm/IR/IntrinsicInst.h"
14 #include "llvm/Support/CBindingWrapping.h"
15 #include "llvm/Support/FileSystem.h"
16 #include "llvm/Support/Host.h"
17 #include "llvm/Target/TargetMachine.h"
18 #include "llvm/Transforms/IPO/PassManagerBuilder.h"
19 #include "llvm/Transforms/IPO/AlwaysInliner.h"
20 #include "llvm/Transforms/IPO/FunctionImport.h"
21 #include "llvm/Transforms/Utils/FunctionImportUtils.h"
22 #include "llvm/LTO/LTO.h"
23 #include "llvm-c/Transforms/PassManagerBuilder.h"
25 #include "llvm/Transforms/Instrumentation.h"
26 #if LLVM_VERSION_GE(9, 0)
27 #include "llvm/Transforms/Instrumentation/AddressSanitizer.h"
29 #if LLVM_VERSION_GE(8, 0)
30 #include "llvm/Transforms/Instrumentation/ThreadSanitizer.h"
31 #include "llvm/Transforms/Instrumentation/MemorySanitizer.h"
35 using namespace llvm::legacy;
37 typedef struct LLVMOpaquePass *LLVMPassRef;
38 typedef struct LLVMOpaqueTargetMachine *LLVMTargetMachineRef;
40 DEFINE_STDCXX_CONVERSION_FUNCTIONS(Pass, LLVMPassRef)
41 DEFINE_STDCXX_CONVERSION_FUNCTIONS(TargetMachine, LLVMTargetMachineRef)
42 DEFINE_STDCXX_CONVERSION_FUNCTIONS(PassManagerBuilder,
43 LLVMPassManagerBuilderRef)
45 extern "C" void LLVMInitializePasses() {
46 PassRegistry &Registry = *PassRegistry::getPassRegistry();
47 initializeCore(Registry);
48 initializeCodeGen(Registry);
49 initializeScalarOpts(Registry);
50 initializeVectorization(Registry);
51 initializeIPO(Registry);
52 initializeAnalysis(Registry);
53 initializeTransformUtils(Registry);
54 initializeInstCombine(Registry);
55 initializeInstrumentation(Registry);
56 initializeTarget(Registry);
59 enum class LLVMRustPassKind {
65 static LLVMRustPassKind toRust(PassKind Kind) {
68 return LLVMRustPassKind::Function;
70 return LLVMRustPassKind::Module;
72 return LLVMRustPassKind::Other;
76 extern "C" LLVMPassRef LLVMRustFindAndCreatePass(const char *PassName) {
77 StringRef SR(PassName);
78 PassRegistry *PR = PassRegistry::getPassRegistry();
80 const PassInfo *PI = PR->getPassInfo(SR);
82 return wrap(PI->createPass());
87 extern "C" LLVMPassRef LLVMRustCreateAddressSanitizerFunctionPass(bool Recover) {
88 const bool CompileKernel = false;
90 return wrap(createAddressSanitizerFunctionPass(CompileKernel, Recover));
93 extern "C" LLVMPassRef LLVMRustCreateModuleAddressSanitizerPass(bool Recover) {
94 const bool CompileKernel = false;
96 #if LLVM_VERSION_GE(9, 0)
97 return wrap(createModuleAddressSanitizerLegacyPassPass(CompileKernel, Recover));
99 return wrap(createAddressSanitizerModulePass(CompileKernel, Recover));
103 extern "C" LLVMPassRef LLVMRustCreateMemorySanitizerPass(int TrackOrigins, bool Recover) {
104 #if LLVM_VERSION_GE(8, 0)
105 const bool CompileKernel = false;
107 return wrap(createMemorySanitizerLegacyPassPass(
108 MemorySanitizerOptions{TrackOrigins, Recover, CompileKernel}));
110 return wrap(createMemorySanitizerPass(TrackOrigins, Recover));
114 extern "C" LLVMPassRef LLVMRustCreateThreadSanitizerPass() {
115 #if LLVM_VERSION_GE(8, 0)
116 return wrap(createThreadSanitizerLegacyPassPass());
118 return wrap(createThreadSanitizerPass());
122 extern "C" LLVMRustPassKind LLVMRustPassKind(LLVMPassRef RustPass) {
124 Pass *Pass = unwrap(RustPass);
125 return toRust(Pass->getPassKind());
128 extern "C" void LLVMRustAddPass(LLVMPassManagerRef PMR, LLVMPassRef RustPass) {
130 Pass *Pass = unwrap(RustPass);
131 PassManagerBase *PMB = unwrap(PMR);
136 void LLVMRustPassManagerBuilderPopulateThinLTOPassManager(
137 LLVMPassManagerBuilderRef PMBR,
138 LLVMPassManagerRef PMR
140 unwrap(PMBR)->populateThinLTOPassManager(*unwrap(PMR));
144 void LLVMRustAddLastExtensionPasses(
145 LLVMPassManagerBuilderRef PMBR, LLVMPassRef *Passes, size_t NumPasses) {
146 auto AddExtensionPasses = [Passes, NumPasses](
147 const PassManagerBuilder &Builder, PassManagerBase &PM) {
148 for (size_t I = 0; I < NumPasses; I++) {
149 PM.add(unwrap(Passes[I]));
152 // Add the passes to both of the pre-finalization extension points,
153 // so they are run for optimized and non-optimized builds.
154 unwrap(PMBR)->addExtension(PassManagerBuilder::EP_OptimizerLast,
156 unwrap(PMBR)->addExtension(PassManagerBuilder::EP_EnabledOnOptLevel0,
160 #ifdef LLVM_COMPONENT_X86
161 #define SUBTARGET_X86 SUBTARGET(X86)
163 #define SUBTARGET_X86
166 #ifdef LLVM_COMPONENT_ARM
167 #define SUBTARGET_ARM SUBTARGET(ARM)
169 #define SUBTARGET_ARM
172 #ifdef LLVM_COMPONENT_AARCH64
173 #define SUBTARGET_AARCH64 SUBTARGET(AArch64)
175 #define SUBTARGET_AARCH64
178 #ifdef LLVM_COMPONENT_MIPS
179 #define SUBTARGET_MIPS SUBTARGET(Mips)
181 #define SUBTARGET_MIPS
184 #ifdef LLVM_COMPONENT_POWERPC
185 #define SUBTARGET_PPC SUBTARGET(PPC)
187 #define SUBTARGET_PPC
190 #ifdef LLVM_COMPONENT_SYSTEMZ
191 #define SUBTARGET_SYSTEMZ SUBTARGET(SystemZ)
193 #define SUBTARGET_SYSTEMZ
196 #ifdef LLVM_COMPONENT_MSP430
197 #define SUBTARGET_MSP430 SUBTARGET(MSP430)
199 #define SUBTARGET_MSP430
202 #ifdef LLVM_COMPONENT_RISCV
203 #define SUBTARGET_RISCV SUBTARGET(RISCV)
205 #define SUBTARGET_RISCV
208 #ifdef LLVM_COMPONENT_SPARC
209 #define SUBTARGET_SPARC SUBTARGET(Sparc)
211 #define SUBTARGET_SPARC
214 #ifdef LLVM_COMPONENT_HEXAGON
215 #define SUBTARGET_HEXAGON SUBTARGET(Hexagon)
217 #define SUBTARGET_HEXAGON
220 #define GEN_SUBTARGETS \
232 #define SUBTARGET(x) \
234 extern const SubtargetFeatureKV x##FeatureKV[]; \
235 extern const SubtargetFeatureKV x##SubTypeKV[]; \
241 extern "C" bool LLVMRustHasFeature(LLVMTargetMachineRef TM,
242 const char *Feature) {
243 TargetMachine *Target = unwrap(TM);
244 const MCSubtargetInfo *MCInfo = Target->getMCSubtargetInfo();
245 return MCInfo->checkFeatures(std::string("+") + Feature);
248 enum class LLVMRustCodeModel {
257 static CodeModel::Model fromRust(LLVMRustCodeModel Model) {
259 case LLVMRustCodeModel::Small:
260 return CodeModel::Small;
261 case LLVMRustCodeModel::Kernel:
262 return CodeModel::Kernel;
263 case LLVMRustCodeModel::Medium:
264 return CodeModel::Medium;
265 case LLVMRustCodeModel::Large:
266 return CodeModel::Large;
268 report_fatal_error("Bad CodeModel.");
272 enum class LLVMRustCodeGenOptLevel {
280 static CodeGenOpt::Level fromRust(LLVMRustCodeGenOptLevel Level) {
282 case LLVMRustCodeGenOptLevel::None:
283 return CodeGenOpt::None;
284 case LLVMRustCodeGenOptLevel::Less:
285 return CodeGenOpt::Less;
286 case LLVMRustCodeGenOptLevel::Default:
287 return CodeGenOpt::Default;
288 case LLVMRustCodeGenOptLevel::Aggressive:
289 return CodeGenOpt::Aggressive;
291 report_fatal_error("Bad CodeGenOptLevel.");
295 enum class LLVMRustRelocMode {
305 static Optional<Reloc::Model> fromRust(LLVMRustRelocMode RustReloc) {
307 case LLVMRustRelocMode::Default:
309 case LLVMRustRelocMode::Static:
310 return Reloc::Static;
311 case LLVMRustRelocMode::PIC:
313 case LLVMRustRelocMode::DynamicNoPic:
314 return Reloc::DynamicNoPIC;
315 case LLVMRustRelocMode::ROPI:
317 case LLVMRustRelocMode::RWPI:
319 case LLVMRustRelocMode::ROPIRWPI:
320 return Reloc::ROPI_RWPI;
322 report_fatal_error("Bad RelocModel.");
326 /// getLongestEntryLength - Return the length of the longest entry in the table.
327 template<typename KV>
328 static size_t getLongestEntryLength(ArrayRef<KV> Table) {
330 for (auto &I : Table)
331 MaxLen = std::max(MaxLen, std::strlen(I.Key));
335 extern "C" void LLVMRustPrintTargetCPUs(LLVMTargetMachineRef TM) {
336 const TargetMachine *Target = unwrap(TM);
337 const MCSubtargetInfo *MCInfo = Target->getMCSubtargetInfo();
338 const Triple::ArchType HostArch = Triple(sys::getProcessTriple()).getArch();
339 const Triple::ArchType TargetArch = Target->getTargetTriple().getArch();
340 const ArrayRef<SubtargetSubTypeKV> CPUTable = MCInfo->getCPUTable();
341 unsigned MaxCPULen = getLongestEntryLength(CPUTable);
343 printf("Available CPUs for this target:\n");
344 if (HostArch == TargetArch) {
345 const StringRef HostCPU = sys::getHostCPUName();
346 printf(" %-*s - Select the CPU of the current host (currently %.*s).\n",
347 MaxCPULen, "native", (int)HostCPU.size(), HostCPU.data());
349 for (auto &CPU : CPUTable)
350 printf(" %-*s\n", MaxCPULen, CPU.Key);
354 extern "C" void LLVMRustPrintTargetFeatures(LLVMTargetMachineRef TM) {
355 const TargetMachine *Target = unwrap(TM);
356 const MCSubtargetInfo *MCInfo = Target->getMCSubtargetInfo();
357 const ArrayRef<SubtargetFeatureKV> FeatTable = MCInfo->getFeatureTable();
358 unsigned MaxFeatLen = getLongestEntryLength(FeatTable);
360 printf("Available features for this target:\n");
361 for (auto &Feature : FeatTable)
362 printf(" %-*s - %s.\n", MaxFeatLen, Feature.Key, Feature.Desc);
365 printf("Use +feature to enable a feature, or -feature to disable it.\n"
366 "For example, rustc -C -target-cpu=mycpu -C "
367 "target-feature=+feature1,-feature2\n\n");
372 extern "C" void LLVMRustPrintTargetCPUs(LLVMTargetMachineRef) {
373 printf("Target CPU help is not supported by this LLVM version.\n\n");
376 extern "C" void LLVMRustPrintTargetFeatures(LLVMTargetMachineRef) {
377 printf("Target features help is not supported by this LLVM version.\n\n");
381 extern "C" const char* LLVMRustGetHostCPUName(size_t *len) {
382 StringRef Name = sys::getHostCPUName();
387 extern "C" LLVMTargetMachineRef LLVMRustCreateTargetMachine(
388 const char *TripleStr, const char *CPU, const char *Feature,
389 const char *ABIStr, LLVMRustCodeModel RustCM, LLVMRustRelocMode RustReloc,
390 LLVMRustCodeGenOptLevel RustOptLevel, bool UseSoftFloat,
391 bool PositionIndependentExecutable, bool FunctionSections,
393 bool TrapUnreachable,
396 bool EmitStackSizeSection) {
398 auto OptLevel = fromRust(RustOptLevel);
399 auto RM = fromRust(RustReloc);
402 Triple Trip(Triple::normalize(TripleStr));
403 const llvm::Target *TheTarget =
404 TargetRegistry::lookupTarget(Trip.getTriple(), Error);
405 if (TheTarget == nullptr) {
406 LLVMRustSetLastError(Error.c_str());
410 TargetOptions Options;
412 Options.FloatABIType = FloatABI::Default;
414 Options.FloatABIType = FloatABI::Soft;
416 Options.DataSections = DataSections;
417 Options.FunctionSections = FunctionSections;
418 Options.MCOptions.AsmVerbose = AsmComments;
419 Options.MCOptions.PreserveAsmComments = AsmComments;
420 Options.MCOptions.ABIName = ABIStr;
422 if (TrapUnreachable) {
423 // Tell LLVM to codegen `unreachable` into an explicit trap instruction.
424 // This limits the extent of possible undefined behavior in some cases, as
425 // it prevents control flow from "falling through" into whatever code
426 // happens to be laid out next in memory.
427 Options.TrapUnreachable = true;
431 Options.ThreadModel = ThreadModel::Single;
434 Options.EmitStackSizeSection = EmitStackSizeSection;
436 Optional<CodeModel::Model> CM;
437 if (RustCM != LLVMRustCodeModel::None)
438 CM = fromRust(RustCM);
439 TargetMachine *TM = TheTarget->createTargetMachine(
440 Trip.getTriple(), CPU, Feature, Options, RM, CM, OptLevel);
444 extern "C" void LLVMRustDisposeTargetMachine(LLVMTargetMachineRef TM) {
448 // Unfortunately, LLVM doesn't expose a C API to add the corresponding analysis
449 // passes for a target to a pass manager. We export that functionality through
451 extern "C" void LLVMRustAddAnalysisPasses(LLVMTargetMachineRef TM,
452 LLVMPassManagerRef PMR,
454 PassManagerBase *PM = unwrap(PMR);
456 createTargetTransformInfoWrapperPass(unwrap(TM)->getTargetIRAnalysis()));
459 extern "C" void LLVMRustConfigurePassManagerBuilder(
460 LLVMPassManagerBuilderRef PMBR, LLVMRustCodeGenOptLevel OptLevel,
461 bool MergeFunctions, bool SLPVectorize, bool LoopVectorize, bool PrepareForThinLTO,
462 const char* PGOGenPath, const char* PGOUsePath) {
463 #if LLVM_VERSION_GE(7, 0)
464 unwrap(PMBR)->MergeFunctions = MergeFunctions;
466 unwrap(PMBR)->SLPVectorize = SLPVectorize;
467 unwrap(PMBR)->OptLevel = fromRust(OptLevel);
468 unwrap(PMBR)->LoopVectorize = LoopVectorize;
469 unwrap(PMBR)->PrepareForThinLTO = PrepareForThinLTO;
473 unwrap(PMBR)->EnablePGOInstrGen = true;
474 unwrap(PMBR)->PGOInstrGen = PGOGenPath;
478 unwrap(PMBR)->PGOInstrUse = PGOUsePath;
482 // Unfortunately, the LLVM C API doesn't provide a way to set the `LibraryInfo`
483 // field of a PassManagerBuilder, we expose our own method of doing so.
484 extern "C" void LLVMRustAddBuilderLibraryInfo(LLVMPassManagerBuilderRef PMBR,
486 bool DisableSimplifyLibCalls) {
487 Triple TargetTriple(unwrap(M)->getTargetTriple());
488 TargetLibraryInfoImpl *TLI = new TargetLibraryInfoImpl(TargetTriple);
489 if (DisableSimplifyLibCalls)
490 TLI->disableAllFunctions();
491 unwrap(PMBR)->LibraryInfo = TLI;
494 // Unfortunately, the LLVM C API doesn't provide a way to create the
495 // TargetLibraryInfo pass, so we use this method to do so.
496 extern "C" void LLVMRustAddLibraryInfo(LLVMPassManagerRef PMR, LLVMModuleRef M,
497 bool DisableSimplifyLibCalls) {
498 Triple TargetTriple(unwrap(M)->getTargetTriple());
499 TargetLibraryInfoImpl TLII(TargetTriple);
500 if (DisableSimplifyLibCalls)
501 TLII.disableAllFunctions();
502 unwrap(PMR)->add(new TargetLibraryInfoWrapperPass(TLII));
505 // Unfortunately, the LLVM C API doesn't provide an easy way of iterating over
506 // all the functions in a module, so we do that manually here. You'll find
507 // similar code in clang's BackendUtil.cpp file.
508 extern "C" void LLVMRustRunFunctionPassManager(LLVMPassManagerRef PMR,
510 llvm::legacy::FunctionPassManager *P =
511 unwrap<llvm::legacy::FunctionPassManager>(PMR);
512 P->doInitialization();
514 // Upgrade all calls to old intrinsics first.
515 for (Module::iterator I = unwrap(M)->begin(), E = unwrap(M)->end(); I != E;)
516 UpgradeCallsToIntrinsic(&*I++); // must be post-increment, as we remove
518 for (Module::iterator I = unwrap(M)->begin(), E = unwrap(M)->end(); I != E;
520 if (!I->isDeclaration())
526 extern "C" void LLVMRustSetLLVMOptions(int Argc, char **Argv) {
527 // Initializing the command-line options more than once is not allowed. So,
528 // check if they've already been initialized. (This could happen if we're
529 // being called from rustpkg, for example). If the arguments change, then
530 // that's just kinda unfortunate.
531 static bool Initialized = false;
535 cl::ParseCommandLineOptions(Argc, Argv);
538 enum class LLVMRustFileType {
544 static TargetMachine::CodeGenFileType fromRust(LLVMRustFileType Type) {
546 case LLVMRustFileType::AssemblyFile:
547 return TargetMachine::CGFT_AssemblyFile;
548 case LLVMRustFileType::ObjectFile:
549 return TargetMachine::CGFT_ObjectFile;
551 report_fatal_error("Bad FileType.");
555 extern "C" LLVMRustResult
556 LLVMRustWriteOutputFile(LLVMTargetMachineRef Target, LLVMPassManagerRef PMR,
557 LLVMModuleRef M, const char *Path,
558 LLVMRustFileType RustFileType) {
559 llvm::legacy::PassManager *PM = unwrap<llvm::legacy::PassManager>(PMR);
560 auto FileType = fromRust(RustFileType);
562 std::string ErrorInfo;
564 raw_fd_ostream OS(Path, EC, sys::fs::F_None);
566 ErrorInfo = EC.message();
567 if (ErrorInfo != "") {
568 LLVMRustSetLastError(ErrorInfo.c_str());
569 return LLVMRustResult::Failure;
572 #if LLVM_VERSION_GE(7, 0)
573 buffer_ostream BOS(OS);
574 unwrap(Target)->addPassesToEmitFile(*PM, BOS, nullptr, FileType, false);
576 unwrap(Target)->addPassesToEmitFile(*PM, OS, FileType, false);
580 // Apparently `addPassesToEmitFile` adds a pointer to our on-the-stack output
581 // stream (OS), so the only real safe place to delete this is here? Don't we
582 // wish this was written in Rust?
583 LLVMDisposePassManager(PMR);
584 return LLVMRustResult::Success;
588 // Callback to demangle function name
590 // * name to be demangled
593 // * output buffer len
594 // Returns len of demangled string, or 0 if demangle failed.
595 typedef size_t (*DemangleFn)(const char*, size_t, char*, size_t);
600 class RustAssemblyAnnotationWriter : public AssemblyAnnotationWriter {
602 std::vector<char> Buf;
605 RustAssemblyAnnotationWriter(DemangleFn Demangle) : Demangle(Demangle) {}
607 // Return empty string if demangle failed
608 // or if name does not need to be demangled
609 StringRef CallDemangle(StringRef name) {
614 if (Buf.size() < name.size() * 2) {
615 // Semangled name usually shorter than mangled,
616 // but allocate twice as much memory just in case
617 Buf.resize(name.size() * 2);
620 auto R = Demangle(name.data(), name.size(), Buf.data(), Buf.size());
626 auto Demangled = StringRef(Buf.data(), R);
627 if (Demangled == name) {
628 // Do not print anything if demangled name is equal to mangled.
635 void emitFunctionAnnot(const Function *F,
636 formatted_raw_ostream &OS) override {
637 StringRef Demangled = CallDemangle(F->getName());
638 if (Demangled.empty()) {
642 OS << "; " << Demangled << "\n";
645 void emitInstructionAnnot(const Instruction *I,
646 formatted_raw_ostream &OS) override {
649 if (const CallInst *CI = dyn_cast<CallInst>(I)) {
651 Value = CI->getCalledValue();
652 } else if (const InvokeInst* II = dyn_cast<InvokeInst>(I)) {
654 Value = II->getCalledValue();
656 // Could demangle more operations, e. g.
657 // `store %place, @function`.
661 if (!Value->hasName()) {
665 StringRef Demangled = CallDemangle(Value->getName());
666 if (Demangled.empty()) {
670 OS << "; " << Name << " " << Demangled << "\n";
674 class RustPrintModulePass : public ModulePass {
679 RustPrintModulePass() : ModulePass(ID), OS(nullptr), Demangle(nullptr) {}
680 RustPrintModulePass(raw_ostream &OS, DemangleFn Demangle)
681 : ModulePass(ID), OS(&OS), Demangle(Demangle) {}
683 bool runOnModule(Module &M) override {
684 RustAssemblyAnnotationWriter AW(Demangle);
686 M.print(*OS, &AW, false);
691 void getAnalysisUsage(AnalysisUsage &AU) const override {
692 AU.setPreservesAll();
695 static StringRef name() { return "RustPrintModulePass"; }
701 void initializeRustPrintModulePassPass(PassRegistry&);
704 char RustPrintModulePass::ID = 0;
705 INITIALIZE_PASS(RustPrintModulePass, "print-rust-module",
706 "Print rust module to stderr", false, false)
708 extern "C" LLVMRustResult
709 LLVMRustPrintModule(LLVMPassManagerRef PMR, LLVMModuleRef M,
710 const char *Path, DemangleFn Demangle) {
711 llvm::legacy::PassManager *PM = unwrap<llvm::legacy::PassManager>(PMR);
712 std::string ErrorInfo;
715 raw_fd_ostream OS(Path, EC, sys::fs::F_None);
717 ErrorInfo = EC.message();
718 if (ErrorInfo != "") {
719 LLVMRustSetLastError(ErrorInfo.c_str());
720 return LLVMRustResult::Failure;
723 formatted_raw_ostream FOS(OS);
725 PM->add(new RustPrintModulePass(FOS, Demangle));
729 return LLVMRustResult::Success;
732 extern "C" void LLVMRustPrintPasses() {
733 LLVMInitializePasses();
734 struct MyListener : PassRegistrationListener {
735 void passEnumerate(const PassInfo *Info) {
736 StringRef PassArg = Info->getPassArgument();
737 StringRef PassName = Info->getPassName();
738 if (!PassArg.empty()) {
739 // These unsigned->signed casts could theoretically overflow, but
740 // realistically never will (and even if, the result is implementation
741 // defined rather plain UB).
742 printf("%15.*s - %.*s\n", (int)PassArg.size(), PassArg.data(),
743 (int)PassName.size(), PassName.data());
748 PassRegistry *PR = PassRegistry::getPassRegistry();
749 PR->enumerateWith(&Listener);
752 extern "C" void LLVMRustAddAlwaysInlinePass(LLVMPassManagerBuilderRef PMBR,
754 unwrap(PMBR)->Inliner = llvm::createAlwaysInlinerLegacyPass(AddLifetimes);
757 extern "C" void LLVMRustRunRestrictionPass(LLVMModuleRef M, char **Symbols,
759 llvm::legacy::PassManager passes;
761 auto PreserveFunctions = [=](const GlobalValue &GV) {
762 for (size_t I = 0; I < Len; I++) {
763 if (GV.getName() == Symbols[I]) {
770 passes.add(llvm::createInternalizePass(PreserveFunctions));
772 passes.run(*unwrap(M));
775 extern "C" void LLVMRustMarkAllFunctionsNounwind(LLVMModuleRef M) {
776 for (Module::iterator GV = unwrap(M)->begin(), E = unwrap(M)->end(); GV != E;
778 GV->setDoesNotThrow();
779 Function *F = dyn_cast<Function>(GV);
783 for (Function::iterator B = F->begin(), BE = F->end(); B != BE; ++B) {
784 for (BasicBlock::iterator I = B->begin(), IE = B->end(); I != IE; ++I) {
785 if (isa<InvokeInst>(I)) {
786 InvokeInst *CI = cast<InvokeInst>(I);
787 CI->setDoesNotThrow();
795 LLVMRustSetDataLayoutFromTargetMachine(LLVMModuleRef Module,
796 LLVMTargetMachineRef TMR) {
797 TargetMachine *Target = unwrap(TMR);
798 unwrap(Module)->setDataLayout(Target->createDataLayout());
801 extern "C" void LLVMRustSetModulePICLevel(LLVMModuleRef M) {
802 unwrap(M)->setPICLevel(PICLevel::Level::BigPIC);
805 extern "C" void LLVMRustSetModulePIELevel(LLVMModuleRef M) {
806 unwrap(M)->setPIELevel(PIELevel::Level::Large);
809 // Here you'll find an implementation of ThinLTO as used by the Rust compiler
810 // right now. This ThinLTO support is only enabled on "recent ish" versions of
811 // LLVM, and otherwise it's just blanket rejected from other compilers.
813 // Most of this implementation is straight copied from LLVM. At the time of
814 // this writing it wasn't *quite* suitable to reuse more code from upstream
815 // for our purposes, but we should strive to upstream this support once it's
816 // ready to go! I figure we may want a bit of testing locally first before
817 // sending this upstream to LLVM. I hear though they're quite eager to receive
818 // feedback like this!
820 // If you're reading this code and wondering "what in the world" or you're
821 // working "good lord by LLVM upgrade is *still* failing due to these bindings"
822 // then fear not! (ok maybe fear a little). All code here is mostly based
823 // on `lib/LTO/ThinLTOCodeGenerator.cpp` in LLVM.
825 // You'll find that the general layout here roughly corresponds to the `run`
826 // method in that file as well as `ProcessThinLTOModule`. Functions are
827 // specifically commented below as well, but if you're updating this code
828 // or otherwise trying to understand it, the LLVM source will be useful in
829 // interpreting the mysteries within.
831 // Otherwise I'll apologize in advance, it probably requires a relatively
832 // significant investment on your part to "truly understand" what's going on
833 // here. Not saying I do myself, but it took me awhile staring at LLVM's source
834 // and various online resources about ThinLTO to make heads or tails of all
837 // This is a shared data structure which *must* be threadsafe to share
838 // read-only amongst threads. This also corresponds basically to the arguments
839 // of the `ProcessThinLTOModule` function in the LLVM source.
840 struct LLVMRustThinLTOData {
841 // The combined index that is the global analysis over all modules we're
842 // performing ThinLTO for. This is mostly managed by LLVM.
843 ModuleSummaryIndex Index;
845 // All modules we may look at, stored as in-memory serialized versions. This
846 // is later used when inlining to ensure we can extract any module to inline
848 StringMap<MemoryBufferRef> ModuleMap;
850 // A set that we manage of everything we *don't* want internalized. Note that
851 // this includes all transitive references right now as well, but it may not
853 DenseSet<GlobalValue::GUID> GUIDPreservedSymbols;
855 // Not 100% sure what these are, but they impact what's internalized and
856 // what's inlined across modules, I believe.
857 StringMap<FunctionImporter::ImportMapTy> ImportLists;
858 StringMap<FunctionImporter::ExportSetTy> ExportLists;
859 StringMap<GVSummaryMapTy> ModuleToDefinedGVSummaries;
861 #if LLVM_VERSION_GE(7, 0)
862 LLVMRustThinLTOData() : Index(/* HaveGVs = */ false) {}
866 // Just an argument to the `LLVMRustCreateThinLTOData` function below.
867 struct LLVMRustThinLTOModule {
868 const char *identifier;
873 // This is copied from `lib/LTO/ThinLTOCodeGenerator.cpp`, not sure what it
875 static const GlobalValueSummary *
876 getFirstDefinitionForLinker(const GlobalValueSummaryList &GVSummaryList) {
877 auto StrongDefForLinker = llvm::find_if(
878 GVSummaryList, [](const std::unique_ptr<GlobalValueSummary> &Summary) {
879 auto Linkage = Summary->linkage();
880 return !GlobalValue::isAvailableExternallyLinkage(Linkage) &&
881 !GlobalValue::isWeakForLinker(Linkage);
883 if (StrongDefForLinker != GVSummaryList.end())
884 return StrongDefForLinker->get();
886 auto FirstDefForLinker = llvm::find_if(
887 GVSummaryList, [](const std::unique_ptr<GlobalValueSummary> &Summary) {
888 auto Linkage = Summary->linkage();
889 return !GlobalValue::isAvailableExternallyLinkage(Linkage);
891 if (FirstDefForLinker == GVSummaryList.end())
893 return FirstDefForLinker->get();
896 // The main entry point for creating the global ThinLTO analysis. The structure
897 // here is basically the same as before threads are spawned in the `run`
898 // function of `lib/LTO/ThinLTOCodeGenerator.cpp`.
899 extern "C" LLVMRustThinLTOData*
900 LLVMRustCreateThinLTOData(LLVMRustThinLTOModule *modules,
902 const char **preserved_symbols,
904 auto Ret = llvm::make_unique<LLVMRustThinLTOData>();
906 // Load each module's summary and merge it into one combined index
907 for (int i = 0; i < num_modules; i++) {
908 auto module = &modules[i];
909 StringRef buffer(module->data, module->len);
910 MemoryBufferRef mem_buffer(buffer, module->identifier);
912 Ret->ModuleMap[module->identifier] = mem_buffer;
914 if (Error Err = readModuleSummaryIndex(mem_buffer, Ret->Index, i)) {
915 LLVMRustSetLastError(toString(std::move(Err)).c_str());
920 // Collect for each module the list of function it defines (GUID -> Summary)
921 Ret->Index.collectDefinedGVSummariesPerModule(Ret->ModuleToDefinedGVSummaries);
923 // Convert the preserved symbols set from string to GUID, this is then needed
924 // for internalization.
925 for (int i = 0; i < num_symbols; i++) {
926 auto GUID = GlobalValue::getGUID(preserved_symbols[i]);
927 Ret->GUIDPreservedSymbols.insert(GUID);
930 // Collect the import/export lists for all modules from the call-graph in the
933 // This is copied from `lib/LTO/ThinLTOCodeGenerator.cpp`
934 #if LLVM_VERSION_GE(7, 0)
935 auto deadIsPrevailing = [&](GlobalValue::GUID G) {
936 return PrevailingType::Unknown;
938 #if LLVM_VERSION_GE(8, 0)
939 // We don't have a complete picture in our use of ThinLTO, just our immediate
940 // crate, so we need `ImportEnabled = false` to limit internalization.
941 // Otherwise, we sometimes lose `static` values -- see #60184.
942 computeDeadSymbolsWithConstProp(Ret->Index, Ret->GUIDPreservedSymbols,
943 deadIsPrevailing, /* ImportEnabled = */ false);
945 computeDeadSymbols(Ret->Index, Ret->GUIDPreservedSymbols, deadIsPrevailing);
948 computeDeadSymbols(Ret->Index, Ret->GUIDPreservedSymbols);
950 ComputeCrossModuleImport(
952 Ret->ModuleToDefinedGVSummaries,
957 // Resolve LinkOnce/Weak symbols, this has to be computed early be cause it
958 // impacts the caching.
960 // This is copied from `lib/LTO/ThinLTOCodeGenerator.cpp` with some of this
961 // being lifted from `lib/LTO/LTO.cpp` as well
962 StringMap<std::map<GlobalValue::GUID, GlobalValue::LinkageTypes>> ResolvedODR;
963 DenseMap<GlobalValue::GUID, const GlobalValueSummary *> PrevailingCopy;
964 for (auto &I : Ret->Index) {
965 if (I.second.SummaryList.size() > 1)
966 PrevailingCopy[I.first] = getFirstDefinitionForLinker(I.second.SummaryList);
968 auto isPrevailing = [&](GlobalValue::GUID GUID, const GlobalValueSummary *S) {
969 const auto &Prevailing = PrevailingCopy.find(GUID);
970 if (Prevailing == PrevailingCopy.end())
972 return Prevailing->second == S;
974 auto recordNewLinkage = [&](StringRef ModuleIdentifier,
975 GlobalValue::GUID GUID,
976 GlobalValue::LinkageTypes NewLinkage) {
977 ResolvedODR[ModuleIdentifier][GUID] = NewLinkage;
979 #if LLVM_VERSION_GE(9, 0)
980 thinLTOResolvePrevailingInIndex(Ret->Index, isPrevailing, recordNewLinkage,
981 Ret->GUIDPreservedSymbols);
982 #elif LLVM_VERSION_GE(8, 0)
983 thinLTOResolvePrevailingInIndex(Ret->Index, isPrevailing, recordNewLinkage);
985 thinLTOResolveWeakForLinkerInIndex(Ret->Index, isPrevailing, recordNewLinkage);
988 // Here we calculate an `ExportedGUIDs` set for use in the `isExported`
989 // callback below. This callback below will dictate the linkage for all
990 // summaries in the index, and we basically just only want to ensure that dead
991 // symbols are internalized. Otherwise everything that's already external
992 // linkage will stay as external, and internal will stay as internal.
993 std::set<GlobalValue::GUID> ExportedGUIDs;
994 for (auto &List : Ret->Index) {
995 for (auto &GVS: List.second.SummaryList) {
996 if (GlobalValue::isLocalLinkage(GVS->linkage()))
998 auto GUID = GVS->getOriginalName();
999 if (GVS->flags().Live)
1000 ExportedGUIDs.insert(GUID);
1003 auto isExported = [&](StringRef ModuleIdentifier, GlobalValue::GUID GUID) {
1004 const auto &ExportList = Ret->ExportLists.find(ModuleIdentifier);
1005 return (ExportList != Ret->ExportLists.end() &&
1006 ExportList->second.count(GUID)) ||
1007 ExportedGUIDs.count(GUID);
1009 thinLTOInternalizeAndPromoteInIndex(Ret->Index, isExported);
1011 return Ret.release();
1015 LLVMRustFreeThinLTOData(LLVMRustThinLTOData *Data) {
1019 // Below are the various passes that happen *per module* when doing ThinLTO.
1021 // In other words, these are the functions that are all run concurrently
1022 // with one another, one per module. The passes here correspond to the analysis
1023 // passes in `lib/LTO/ThinLTOCodeGenerator.cpp`, currently found in the
1024 // `ProcessThinLTOModule` function. Here they're split up into separate steps
1025 // so rustc can save off the intermediate bytecode between each step.
1028 LLVMRustPrepareThinLTORename(const LLVMRustThinLTOData *Data, LLVMModuleRef M) {
1029 Module &Mod = *unwrap(M);
1030 if (renameModuleForThinLTO(Mod, Data->Index)) {
1031 LLVMRustSetLastError("renameModuleForThinLTO failed");
1038 LLVMRustPrepareThinLTOResolveWeak(const LLVMRustThinLTOData *Data, LLVMModuleRef M) {
1039 Module &Mod = *unwrap(M);
1040 const auto &DefinedGlobals = Data->ModuleToDefinedGVSummaries.lookup(Mod.getModuleIdentifier());
1041 #if LLVM_VERSION_GE(8, 0)
1042 thinLTOResolvePrevailingInModule(Mod, DefinedGlobals);
1044 thinLTOResolveWeakForLinkerModule(Mod, DefinedGlobals);
1050 LLVMRustPrepareThinLTOInternalize(const LLVMRustThinLTOData *Data, LLVMModuleRef M) {
1051 Module &Mod = *unwrap(M);
1052 const auto &DefinedGlobals = Data->ModuleToDefinedGVSummaries.lookup(Mod.getModuleIdentifier());
1053 thinLTOInternalizeModule(Mod, DefinedGlobals);
1058 LLVMRustPrepareThinLTOImport(const LLVMRustThinLTOData *Data, LLVMModuleRef M) {
1059 Module &Mod = *unwrap(M);
1061 const auto &ImportList = Data->ImportLists.lookup(Mod.getModuleIdentifier());
1062 auto Loader = [&](StringRef Identifier) {
1063 const auto &Memory = Data->ModuleMap.lookup(Identifier);
1064 auto &Context = Mod.getContext();
1065 auto MOrErr = getLazyBitcodeModule(Memory, Context, true, true);
1070 // The rest of this closure is a workaround for
1071 // https://bugs.llvm.org/show_bug.cgi?id=38184 where during ThinLTO imports
1072 // we accidentally import wasm custom sections into different modules,
1073 // duplicating them by in the final output artifact.
1075 // The issue is worked around here by manually removing the
1076 // `wasm.custom_sections` named metadata node from any imported module. This
1077 // we know isn't used by any optimization pass so there's no need for it to
1080 // Note that the metadata is currently lazily loaded, so we materialize it
1081 // here before looking up if there's metadata inside. The `FunctionImporter`
1082 // will immediately materialize metadata anyway after an import, so this
1083 // shouldn't be a perf hit.
1084 if (Error Err = (*MOrErr)->materializeMetadata()) {
1085 Expected<std::unique_ptr<Module>> Ret(std::move(Err));
1089 auto *WasmCustomSections = (*MOrErr)->getNamedMetadata("wasm.custom_sections");
1090 if (WasmCustomSections)
1091 WasmCustomSections->eraseFromParent();
1095 FunctionImporter Importer(Data->Index, Loader);
1096 Expected<bool> Result = Importer.importFunctions(Mod, ImportList);
1098 LLVMRustSetLastError(toString(Result.takeError()).c_str());
1104 extern "C" typedef void (*LLVMRustModuleNameCallback)(void*, // payload
1105 const char*, // importing module name
1106 const char*); // imported module name
1108 // Calls `module_name_callback` for each module import done by ThinLTO.
1109 // The callback is provided with regular null-terminated C strings.
1111 LLVMRustGetThinLTOModuleImports(const LLVMRustThinLTOData *data,
1112 LLVMRustModuleNameCallback module_name_callback,
1113 void* callback_payload) {
1114 for (const auto& importing_module : data->ImportLists) {
1115 const std::string importing_module_id = importing_module.getKey().str();
1116 const auto& imports = importing_module.getValue();
1117 for (const auto& imported_module : imports) {
1118 const std::string imported_module_id = imported_module.getKey().str();
1119 module_name_callback(callback_payload,
1120 importing_module_id.c_str(),
1121 imported_module_id.c_str());
1126 // This struct and various functions are sort of a hack right now, but the
1127 // problem is that we've got in-memory LLVM modules after we generate and
1128 // optimize all codegen-units for one compilation in rustc. To be compatible
1129 // with the LTO support above we need to serialize the modules plus their
1130 // ThinLTO summary into memory.
1132 // This structure is basically an owned version of a serialize module, with
1133 // a ThinLTO summary attached.
1134 struct LLVMRustThinLTOBuffer {
1138 extern "C" LLVMRustThinLTOBuffer*
1139 LLVMRustThinLTOBufferCreate(LLVMModuleRef M) {
1140 auto Ret = llvm::make_unique<LLVMRustThinLTOBuffer>();
1142 raw_string_ostream OS(Ret->data);
1144 legacy::PassManager PM;
1145 PM.add(createWriteThinLTOBitcodePass(OS));
1149 return Ret.release();
1153 LLVMRustThinLTOBufferFree(LLVMRustThinLTOBuffer *Buffer) {
1157 extern "C" const void*
1158 LLVMRustThinLTOBufferPtr(const LLVMRustThinLTOBuffer *Buffer) {
1159 return Buffer->data.data();
1163 LLVMRustThinLTOBufferLen(const LLVMRustThinLTOBuffer *Buffer) {
1164 return Buffer->data.length();
1167 // This is what we used to parse upstream bitcode for actual ThinLTO
1168 // processing. We'll call this once per module optimized through ThinLTO, and
1169 // it'll be called concurrently on many threads.
1170 extern "C" LLVMModuleRef
1171 LLVMRustParseBitcodeForLTO(LLVMContextRef Context,
1174 const char *identifier) {
1175 StringRef Data(data, len);
1176 MemoryBufferRef Buffer(Data, identifier);
1177 unwrap(Context)->enableDebugTypeODRUniquing();
1178 Expected<std::unique_ptr<Module>> SrcOrError =
1179 parseBitcodeFile(Buffer, *unwrap(Context));
1181 LLVMRustSetLastError(toString(SrcOrError.takeError()).c_str());
1184 return wrap(std::move(*SrcOrError).release());
1187 // Rewrite all `DICompileUnit` pointers to the `DICompileUnit` specified. See
1188 // the comment in `back/lto.rs` for why this exists.
1190 LLVMRustThinLTOGetDICompileUnit(LLVMModuleRef Mod,
1192 DICompileUnit **B) {
1193 Module *M = unwrap(Mod);
1194 DICompileUnit **Cur = A;
1195 DICompileUnit **Next = B;
1196 for (DICompileUnit *CU : M->debug_compile_units()) {
1205 // Rewrite all `DICompileUnit` pointers to the `DICompileUnit` specified. See
1206 // the comment in `back/lto.rs` for why this exists.
1208 LLVMRustThinLTOPatchDICompileUnit(LLVMModuleRef Mod, DICompileUnit *Unit) {
1209 Module *M = unwrap(Mod);
1211 // If the original source module didn't have a `DICompileUnit` then try to
1212 // merge all the existing compile units. If there aren't actually any though
1213 // then there's not much for us to do so return.
1214 if (Unit == nullptr) {
1215 for (DICompileUnit *CU : M->debug_compile_units()) {
1219 if (Unit == nullptr)
1223 // Use LLVM's built-in `DebugInfoFinder` to find a bunch of debuginfo and
1224 // process it recursively. Note that we specifically iterate over instructions
1225 // to ensure we feed everything into it.
1226 DebugInfoFinder Finder;
1227 Finder.processModule(*M);
1228 for (Function &F : M->functions()) {
1229 for (auto &FI : F) {
1230 for (Instruction &BI : FI) {
1231 if (auto Loc = BI.getDebugLoc())
1232 Finder.processLocation(*M, Loc);
1233 if (auto DVI = dyn_cast<DbgValueInst>(&BI))
1234 Finder.processValue(*M, DVI);
1235 if (auto DDI = dyn_cast<DbgDeclareInst>(&BI))
1236 Finder.processDeclare(*M, DDI);
1241 // After we've found all our debuginfo, rewrite all subprograms to point to
1242 // the same `DICompileUnit`.
1243 for (auto &F : Finder.subprograms()) {
1244 F->replaceUnit(Unit);
1247 // Erase any other references to other `DICompileUnit` instances, the verifier
1248 // will later ensure that we don't actually have any other stale references to
1250 auto *MD = M->getNamedMetadata("llvm.dbg.cu");
1251 MD->clearOperands();
1252 MD->addOperand(Unit);