//===- SymbolRewriter.cpp - Symbol Rewriter -------------------------------===// // // 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 // //===----------------------------------------------------------------------===// // // SymbolRewriter is a LLVM pass which can rewrite symbols transparently within // existing code. It is implemented as a compiler pass and is configured via a // YAML configuration file. // // The YAML configuration file format is as follows: // // RewriteMapFile := RewriteDescriptors // RewriteDescriptors := RewriteDescriptor | RewriteDescriptors // RewriteDescriptor := RewriteDescriptorType ':' '{' RewriteDescriptorFields '}' // RewriteDescriptorFields := RewriteDescriptorField | RewriteDescriptorFields // RewriteDescriptorField := FieldIdentifier ':' FieldValue ',' // RewriteDescriptorType := Identifier // FieldIdentifier := Identifier // FieldValue := Identifier // Identifier := [0-9a-zA-Z]+ // // Currently, the following descriptor types are supported: // // - function: (function rewriting) // + Source (original name of the function) // + Target (explicit transformation) // + Transform (pattern transformation) // + Naked (boolean, whether the function is undecorated) // - global variable: (external linkage global variable rewriting) // + Source (original name of externally visible variable) // + Target (explicit transformation) // + Transform (pattern transformation) // - global alias: (global alias rewriting) // + Source (original name of the aliased name) // + Target (explicit transformation) // + Transform (pattern transformation) // // Note that source and exactly one of [Target, Transform] must be provided // // New rewrite descriptors can be created. Addding a new rewrite descriptor // involves: // // a) extended the rewrite descriptor kind enumeration // (::RewriteDescriptor::RewriteDescriptorType) // b) implementing the new descriptor // (c.f. ::ExplicitRewriteFunctionDescriptor) // c) extending the rewrite map parser // (::RewriteMapParser::parseEntry) // // Specify to rewrite the symbols using the `-rewrite-symbols` option, and // specify the map file to use for the rewriting via the `-rewrite-map-file` // option. // //===----------------------------------------------------------------------===// #include "llvm/Transforms/Utils/SymbolRewriter.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/ilist.h" #include "llvm/ADT/iterator_range.h" #include "llvm/IR/Comdat.h" #include "llvm/IR/Function.h" #include "llvm/IR/GlobalAlias.h" #include "llvm/IR/GlobalObject.h" #include "llvm/IR/GlobalVariable.h" #include "llvm/IR/Module.h" #include "llvm/IR/Value.h" #include "llvm/InitializePasses.h" #include "llvm/Pass.h" #include "llvm/Support/Casting.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/ErrorOr.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Regex.h" #include "llvm/Support/SourceMgr.h" #include "llvm/Support/YAMLParser.h" #include #include #include using namespace llvm; using namespace SymbolRewriter; #define DEBUG_TYPE "symbol-rewriter" static cl::list RewriteMapFiles("rewrite-map-file", cl::desc("Symbol Rewrite Map"), cl::value_desc("filename"), cl::Hidden); static void rewriteComdat(Module &M, GlobalObject *GO, const std::string &Source, const std::string &Target) { if (Comdat *CD = GO->getComdat()) { auto &Comdats = M.getComdatSymbolTable(); Comdat *C = M.getOrInsertComdat(Target); C->setSelectionKind(CD->getSelectionKind()); GO->setComdat(C); Comdats.erase(Comdats.find(Source)); } } namespace { template class ExplicitRewriteDescriptor : public RewriteDescriptor { public: const std::string Source; const std::string Target; ExplicitRewriteDescriptor(StringRef S, StringRef T, const bool Naked) : RewriteDescriptor(DT), Source(std::string(Naked ? StringRef("\01" + S.str()) : S)), Target(std::string(T)) {} bool performOnModule(Module &M) override; static bool classof(const RewriteDescriptor *RD) { return RD->getType() == DT; } }; } // end anonymous namespace template bool ExplicitRewriteDescriptor::performOnModule(Module &M) { bool Changed = false; if (ValueType *S = (M.*Get)(Source)) { if (GlobalObject *GO = dyn_cast(S)) rewriteComdat(M, GO, Source, Target); if (Value *T = (M.*Get)(Target)) S->setValueName(T->getValueName()); else S->setName(Target); Changed = true; } return Changed; } namespace { template ::iterator> (Module::*Iterator)()> class PatternRewriteDescriptor : public RewriteDescriptor { public: const std::string Pattern; const std::string Transform; PatternRewriteDescriptor(StringRef P, StringRef T) : RewriteDescriptor(DT), Pattern(std::string(P)), Transform(std::string(T)) {} bool performOnModule(Module &M) override; static bool classof(const RewriteDescriptor *RD) { return RD->getType() == DT; } }; } // end anonymous namespace template ::iterator> (Module::*Iterator)()> bool PatternRewriteDescriptor:: performOnModule(Module &M) { bool Changed = false; for (auto &C : (M.*Iterator)()) { std::string Error; std::string Name = Regex(Pattern).sub(Transform, C.getName(), &Error); if (!Error.empty()) report_fatal_error(Twine("unable to transforn ") + C.getName() + " in " + M.getModuleIdentifier() + ": " + Error); if (C.getName() == Name) continue; if (GlobalObject *GO = dyn_cast(&C)) rewriteComdat(M, GO, std::string(C.getName()), Name); if (Value *V = (M.*Get)(Name)) C.setValueName(V->getValueName()); else C.setName(Name); Changed = true; } return Changed; } namespace { /// Represents a rewrite for an explicitly named (function) symbol. Both the /// source function name and target function name of the transformation are /// explicitly spelt out. using ExplicitRewriteFunctionDescriptor = ExplicitRewriteDescriptor; /// Represents a rewrite for an explicitly named (global variable) symbol. Both /// the source variable name and target variable name are spelt out. This /// applies only to module level variables. using ExplicitRewriteGlobalVariableDescriptor = ExplicitRewriteDescriptor; /// Represents a rewrite for an explicitly named global alias. Both the source /// and target name are explicitly spelt out. using ExplicitRewriteNamedAliasDescriptor = ExplicitRewriteDescriptor; /// Represents a rewrite for a regular expression based pattern for functions. /// A pattern for the function name is provided and a transformation for that /// pattern to determine the target function name create the rewrite rule. using PatternRewriteFunctionDescriptor = PatternRewriteDescriptor; /// Represents a rewrite for a global variable based upon a matching pattern. /// Each global variable matching the provided pattern will be transformed as /// described in the transformation pattern for the target. Applies only to /// module level variables. using PatternRewriteGlobalVariableDescriptor = PatternRewriteDescriptor; /// PatternRewriteNamedAliasDescriptor - represents a rewrite for global /// aliases which match a given pattern. The provided transformation will be /// applied to each of the matching names. using PatternRewriteNamedAliasDescriptor = PatternRewriteDescriptor; } // end anonymous namespace bool RewriteMapParser::parse(const std::string &MapFile, RewriteDescriptorList *DL) { ErrorOr> Mapping = MemoryBuffer::getFile(MapFile); if (!Mapping) report_fatal_error(Twine("unable to read rewrite map '") + MapFile + "': " + Mapping.getError().message()); if (!parse(*Mapping, DL)) report_fatal_error(Twine("unable to parse rewrite map '") + MapFile + "'"); return true; } bool RewriteMapParser::parse(std::unique_ptr &MapFile, RewriteDescriptorList *DL) { SourceMgr SM; yaml::Stream YS(MapFile->getBuffer(), SM); for (auto &Document : YS) { yaml::MappingNode *DescriptorList; // ignore empty documents if (isa(Document.getRoot())) continue; DescriptorList = dyn_cast(Document.getRoot()); if (!DescriptorList) { YS.printError(Document.getRoot(), "DescriptorList node must be a map"); return false; } for (auto &Descriptor : *DescriptorList) if (!parseEntry(YS, Descriptor, DL)) return false; } return true; } bool RewriteMapParser::parseEntry(yaml::Stream &YS, yaml::KeyValueNode &Entry, RewriteDescriptorList *DL) { yaml::ScalarNode *Key; yaml::MappingNode *Value; SmallString<32> KeyStorage; StringRef RewriteType; Key = dyn_cast(Entry.getKey()); if (!Key) { YS.printError(Entry.getKey(), "rewrite type must be a scalar"); return false; } Value = dyn_cast(Entry.getValue()); if (!Value) { YS.printError(Entry.getValue(), "rewrite descriptor must be a map"); return false; } RewriteType = Key->getValue(KeyStorage); if (RewriteType.equals("function")) return parseRewriteFunctionDescriptor(YS, Key, Value, DL); else if (RewriteType.equals("global variable")) return parseRewriteGlobalVariableDescriptor(YS, Key, Value, DL); else if (RewriteType.equals("global alias")) return parseRewriteGlobalAliasDescriptor(YS, Key, Value, DL); YS.printError(Entry.getKey(), "unknown rewrite type"); return false; } bool RewriteMapParser:: parseRewriteFunctionDescriptor(yaml::Stream &YS, yaml::ScalarNode *K, yaml::MappingNode *Descriptor, RewriteDescriptorList *DL) { bool Naked = false; std::string Source; std::string Target; std::string Transform; for (auto &Field : *Descriptor) { yaml::ScalarNode *Key; yaml::ScalarNode *Value; SmallString<32> KeyStorage; SmallString<32> ValueStorage; StringRef KeyValue; Key = dyn_cast(Field.getKey()); if (!Key) { YS.printError(Field.getKey(), "descriptor key must be a scalar"); return false; } Value = dyn_cast(Field.getValue()); if (!Value) { YS.printError(Field.getValue(), "descriptor value must be a scalar"); return false; } KeyValue = Key->getValue(KeyStorage); if (KeyValue.equals("source")) { std::string Error; Source = std::string(Value->getValue(ValueStorage)); if (!Regex(Source).isValid(Error)) { YS.printError(Field.getKey(), "invalid regex: " + Error); return false; } } else if (KeyValue.equals("target")) { Target = std::string(Value->getValue(ValueStorage)); } else if (KeyValue.equals("transform")) { Transform = std::string(Value->getValue(ValueStorage)); } else if (KeyValue.equals("naked")) { std::string Undecorated; Undecorated = std::string(Value->getValue(ValueStorage)); Naked = StringRef(Undecorated).lower() == "true" || Undecorated == "1"; } else { YS.printError(Field.getKey(), "unknown key for function"); return false; } } if (Transform.empty() == Target.empty()) { YS.printError(Descriptor, "exactly one of transform or target must be specified"); return false; } // TODO see if there is a more elegant solution to selecting the rewrite // descriptor type if (!Target.empty()) DL->push_back(std::make_unique( Source, Target, Naked)); else DL->push_back( std::make_unique(Source, Transform)); return true; } bool RewriteMapParser:: parseRewriteGlobalVariableDescriptor(yaml::Stream &YS, yaml::ScalarNode *K, yaml::MappingNode *Descriptor, RewriteDescriptorList *DL) { std::string Source; std::string Target; std::string Transform; for (auto &Field : *Descriptor) { yaml::ScalarNode *Key; yaml::ScalarNode *Value; SmallString<32> KeyStorage; SmallString<32> ValueStorage; StringRef KeyValue; Key = dyn_cast(Field.getKey()); if (!Key) { YS.printError(Field.getKey(), "descriptor Key must be a scalar"); return false; } Value = dyn_cast(Field.getValue()); if (!Value) { YS.printError(Field.getValue(), "descriptor value must be a scalar"); return false; } KeyValue = Key->getValue(KeyStorage); if (KeyValue.equals("source")) { std::string Error; Source = std::string(Value->getValue(ValueStorage)); if (!Regex(Source).isValid(Error)) { YS.printError(Field.getKey(), "invalid regex: " + Error); return false; } } else if (KeyValue.equals("target")) { Target = std::string(Value->getValue(ValueStorage)); } else if (KeyValue.equals("transform")) { Transform = std::string(Value->getValue(ValueStorage)); } else { YS.printError(Field.getKey(), "unknown Key for Global Variable"); return false; } } if (Transform.empty() == Target.empty()) { YS.printError(Descriptor, "exactly one of transform or target must be specified"); return false; } if (!Target.empty()) DL->push_back(std::make_unique( Source, Target, /*Naked*/ false)); else DL->push_back(std::make_unique( Source, Transform)); return true; } bool RewriteMapParser:: parseRewriteGlobalAliasDescriptor(yaml::Stream &YS, yaml::ScalarNode *K, yaml::MappingNode *Descriptor, RewriteDescriptorList *DL) { std::string Source; std::string Target; std::string Transform; for (auto &Field : *Descriptor) { yaml::ScalarNode *Key; yaml::ScalarNode *Value; SmallString<32> KeyStorage; SmallString<32> ValueStorage; StringRef KeyValue; Key = dyn_cast(Field.getKey()); if (!Key) { YS.printError(Field.getKey(), "descriptor key must be a scalar"); return false; } Value = dyn_cast(Field.getValue()); if (!Value) { YS.printError(Field.getValue(), "descriptor value must be a scalar"); return false; } KeyValue = Key->getValue(KeyStorage); if (KeyValue.equals("source")) { std::string Error; Source = std::string(Value->getValue(ValueStorage)); if (!Regex(Source).isValid(Error)) { YS.printError(Field.getKey(), "invalid regex: " + Error); return false; } } else if (KeyValue.equals("target")) { Target = std::string(Value->getValue(ValueStorage)); } else if (KeyValue.equals("transform")) { Transform = std::string(Value->getValue(ValueStorage)); } else { YS.printError(Field.getKey(), "unknown key for Global Alias"); return false; } } if (Transform.empty() == Target.empty()) { YS.printError(Descriptor, "exactly one of transform or target must be specified"); return false; } if (!Target.empty()) DL->push_back(std::make_unique( Source, Target, /*Naked*/ false)); else DL->push_back(std::make_unique( Source, Transform)); return true; } namespace { class RewriteSymbolsLegacyPass : public ModulePass { public: static char ID; // Pass identification, replacement for typeid RewriteSymbolsLegacyPass(); RewriteSymbolsLegacyPass(SymbolRewriter::RewriteDescriptorList &DL); bool runOnModule(Module &M) override; private: RewriteSymbolPass Impl; }; } // end anonymous namespace char RewriteSymbolsLegacyPass::ID = 0; RewriteSymbolsLegacyPass::RewriteSymbolsLegacyPass() : ModulePass(ID) { initializeRewriteSymbolsLegacyPassPass(*PassRegistry::getPassRegistry()); } RewriteSymbolsLegacyPass::RewriteSymbolsLegacyPass( SymbolRewriter::RewriteDescriptorList &DL) : ModulePass(ID), Impl(DL) {} bool RewriteSymbolsLegacyPass::runOnModule(Module &M) { return Impl.runImpl(M); } PreservedAnalyses RewriteSymbolPass::run(Module &M, ModuleAnalysisManager &AM) { if (!runImpl(M)) return PreservedAnalyses::all(); return PreservedAnalyses::none(); } bool RewriteSymbolPass::runImpl(Module &M) { bool Changed; Changed = false; for (auto &Descriptor : Descriptors) Changed |= Descriptor->performOnModule(M); return Changed; } void RewriteSymbolPass::loadAndParseMapFiles() { const std::vector MapFiles(RewriteMapFiles); SymbolRewriter::RewriteMapParser Parser; for (const auto &MapFile : MapFiles) Parser.parse(MapFile, &Descriptors); } INITIALIZE_PASS(RewriteSymbolsLegacyPass, "rewrite-symbols", "Rewrite Symbols", false, false) ModulePass *llvm::createRewriteSymbolsPass() { return new RewriteSymbolsLegacyPass(); } ModulePass * llvm::createRewriteSymbolsPass(SymbolRewriter::RewriteDescriptorList &DL) { return new RewriteSymbolsLegacyPass(DL); }