/* * Copyright 2010, The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "slang_rs_metadata_spec.h" #include #include #include #include #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/StringRef.h" #include "llvm/Metadata.h" #include "llvm/Module.h" #include "slang_assert.h" #include "slang_rs_type_spec.h" #define RS_METADATA_STRTAB_MN "#rs_metadata_strtab" #define RS_TYPE_INFO_MN "#rs_type_info" #define RS_EXPORT_VAR_MN "#rs_export_var" #define RS_EXPORT_FUNC_MN "#rs_export_func" #define RS_EXPORT_RECORD_TYPE_NAME_MN_PREFIX "%" /////////////////////////////////////////////////////////////////////////////// // Useful utility functions /////////////////////////////////////////////////////////////////////////////// static bool EncodeInteger(llvm::LLVMContext &C, unsigned I, llvm::SmallVectorImpl &Op) { llvm::StringRef S(reinterpret_cast(&I), sizeof(I)); llvm::MDString *MDS = llvm::MDString::get(C, S); if (MDS == NULL) return false; Op.push_back(MDS); return true; } /////////////////////////////////////////////////////////////////////////////// // class RSMetadataEncoderInternal /////////////////////////////////////////////////////////////////////////////// namespace { class RSMetadataEncoderInternal { private: llvm::Module *mModule; typedef std::map TypesMapTy; TypesMapTy mTypes; std::list mEncodedRSTypeInfo; // simply a sequece of integers unsigned mCurTypeIndex; // A special type for lookup created record type. It uses record name as key. typedef std::map RecordTypesMapTy; RecordTypesMapTy mRecordTypes; typedef std::map StringsMapTy; StringsMapTy mStrings; std::list mEncodedStrings; unsigned mCurStringIndex; llvm::NamedMDNode *mVarInfoMetadata; llvm::NamedMDNode *mFuncInfoMetadata; // This function check the return value of function: // joinString, encodeTypeBase, encode*Type(), encodeRSType, encodeRSVar, // and encodeRSFunc. Return false if the value of Index indicates failure. inline bool checkReturnIndex(unsigned *Index) { if (*Index == 0) return false; else (*Index)--; return true; } unsigned joinString(const std::string &S); unsigned encodeTypeBase(const struct RSTypeBase *Base); unsigned encodeTypeBaseAsKey(const struct RSTypeBase *Base); #define ENUM_RS_DATA_TYPE_CLASS(x) \ unsigned encode ## x ## Type(const union RSType *T); RS_DATA_TYPE_CLASS_ENUMS #undef ENUM_RS_DATA_TYPE_CLASS unsigned encodeRSType(const union RSType *T); int flushStringTable(); int flushTypeInfo(); public: explicit RSMetadataEncoderInternal(llvm::Module *M); int encodeRSVar(const RSVar *V); int encodeRSFunc(const RSFunction *F); int finalize(); }; } RSMetadataEncoderInternal::RSMetadataEncoderInternal(llvm::Module *M) : mModule(M), mCurTypeIndex(0), mCurStringIndex(0), mVarInfoMetadata(NULL), mFuncInfoMetadata(NULL) { mTypes.clear(); mEncodedRSTypeInfo.clear(); mRecordTypes.clear(); mStrings.clear(); return; } // Return (StringIndex + 1) when successfully join the string and 0 if there's // any error. unsigned RSMetadataEncoderInternal::joinString(const std::string &S) { StringsMapTy::const_iterator I = mStrings.find(S); if (I != mStrings.end()) return (I->second + 1); // Add S into mStrings std::pair Res = mStrings.insert(std::make_pair(S, mCurStringIndex)); // Insertion failed if (!Res.second) return 0; // Add S into mEncodedStrings mEncodedStrings.push_back(Res.first->first.c_str()); mCurStringIndex++; // Return (StringIndex + 1) return (Res.first->second + 1); } unsigned RSMetadataEncoderInternal::encodeTypeBase(const struct RSTypeBase *Base) { mEncodedRSTypeInfo.push_back(Base->bits); return ++mCurTypeIndex; } unsigned RSMetadataEncoderInternal::encodeTypeBaseAsKey( const struct RSTypeBase *Base) { TypesMapTy::const_iterator I = mTypes.find(Base->bits); if (I != mTypes.end()) return (I->second + 1); // Add Base into mTypes std::pair Res = mTypes.insert(std::make_pair(Base->bits, mCurTypeIndex)); // Insertion failed if (!Res.second) return 0; // Push to mEncodedRSTypeInfo. This will also update mCurTypeIndex. return encodeTypeBase(Base); } unsigned RSMetadataEncoderInternal::encodePrimitiveType(const union RSType *T) { return encodeTypeBaseAsKey(RS_GET_TYPE_BASE(T)); } unsigned RSMetadataEncoderInternal::encodePointerType(const union RSType *T) { // Encode pointee type first unsigned PointeeType = encodeRSType(RS_POINTER_TYPE_GET_POINTEE_TYPE(T)); if (!checkReturnIndex(&PointeeType)) return 0; unsigned Res = encodeTypeBaseAsKey(RS_GET_TYPE_BASE(T)); // Push PointeeType after the base type mEncodedRSTypeInfo.push_back(PointeeType); return Res; } unsigned RSMetadataEncoderInternal::encodeVectorType(const union RSType *T) { return encodeTypeBaseAsKey(RS_GET_TYPE_BASE(T)); } unsigned RSMetadataEncoderInternal::encodeMatrixType(const union RSType *T) { return encodeTypeBaseAsKey(RS_GET_TYPE_BASE(T)); } unsigned RSMetadataEncoderInternal::encodeConstantArrayType(const union RSType *T) { // Encode element type unsigned ElementType = encodeRSType(RS_CONSTANT_ARRAY_TYPE_GET_ELEMENT_TYPE(T)); if (!checkReturnIndex(&ElementType)) return 0; unsigned Res = encodeTypeBase(RS_GET_TYPE_BASE(T)); // Push the ElementType after the type base mEncodedRSTypeInfo.push_back(ElementType); return Res; } unsigned RSMetadataEncoderInternal::encodeRecordType(const union RSType *T) { // Construct record name std::string RecordInfoMetadataName(RS_EXPORT_RECORD_TYPE_NAME_MN_PREFIX); RecordInfoMetadataName.append(RS_RECORD_TYPE_GET_NAME(T)); // Try to find it in mRecordTypes RecordTypesMapTy::const_iterator I = mRecordTypes.find(RecordInfoMetadataName); // This record type has been encoded before. Fast return its index here. if (I != mRecordTypes.end()) return (I->second + 1); // Encode this record type into mTypes. Encode record name string first. unsigned RecordName = joinString(RecordInfoMetadataName); if (!checkReturnIndex(&RecordName)) return 0; unsigned Base = encodeTypeBase(RS_GET_TYPE_BASE(T)); if (!checkReturnIndex(&Base)) return 0; // Push record name after encoding the type base mEncodedRSTypeInfo.push_back(RecordName); // Add this record type into the map std::pair Res = mRecordTypes.insert(std::make_pair(RecordInfoMetadataName, Base)); // Insertion failed if (!Res.second) return 0; // Create a named MDNode for this record type. We cannot create this before // encoding type base into Types and updating mRecordTypes. This is because // we may have structure like: // // struct foo { // ... // struct foo *bar; // self type reference // ... // } llvm::NamedMDNode *RecordInfoMetadata = mModule->getOrInsertNamedMetadata(RecordInfoMetadataName); slangAssert((RecordInfoMetadata->getNumOperands() == 0) && "Record created before!"); // Encode field info into this named MDNode llvm::SmallVector FieldInfo; for (unsigned i = 0; i < RS_RECORD_TYPE_GET_NUM_FIELDS(T); i++) { // 1. field name unsigned FieldName = joinString(RS_RECORD_TYPE_GET_FIELD_NAME(T, i)); if (!checkReturnIndex(&FieldName)) return 0; if (!EncodeInteger(mModule->getContext(), FieldName, FieldInfo)) { return 0; } // 2. field type unsigned FieldType = encodeRSType(RS_RECORD_TYPE_GET_FIELD_TYPE(T, i)); if (!checkReturnIndex(&FieldType)) return 0; if (!EncodeInteger(mModule->getContext(), FieldType, FieldInfo)) { return 0; } // 3. field data kind if (!EncodeInteger(mModule->getContext(), RS_RECORD_TYPE_GET_FIELD_DATA_KIND(T, i), FieldInfo)) { return 0; } RecordInfoMetadata->addOperand(llvm::MDNode::get(mModule->getContext(), FieldInfo)); FieldInfo.clear(); } return (Res.first->second + 1); } unsigned RSMetadataEncoderInternal::encodeRSType(const union RSType *T) { switch (static_cast(RS_TYPE_GET_CLASS(T))) { #define ENUM_RS_DATA_TYPE_CLASS(x) \ case RS_TC_ ## x: return encode ## x ## Type(T); RS_DATA_TYPE_CLASS_ENUMS #undef ENUM_RS_DATA_TYPE_CLASS default: return 0; } return 0; } int RSMetadataEncoderInternal::encodeRSVar(const RSVar *V) { // check parameter if ((V == NULL) || (V->name == NULL) || (V->type == NULL)) return -1; // 1. var name unsigned VarName = joinString(V->name); if (!checkReturnIndex(&VarName)) { return -2; } // 2. type unsigned Type = encodeRSType(V->type); llvm::SmallVector VarInfo; if (!EncodeInteger(mModule->getContext(), VarName, VarInfo)) { return -3; } if (!EncodeInteger(mModule->getContext(), Type, VarInfo)) { return -4; } if (mVarInfoMetadata == NULL) mVarInfoMetadata = mModule->getOrInsertNamedMetadata(RS_EXPORT_VAR_MN); mVarInfoMetadata->addOperand(llvm::MDNode::get(mModule->getContext(), VarInfo)); return 0; } int RSMetadataEncoderInternal::encodeRSFunc(const RSFunction *F) { // check parameter if ((F == NULL) || (F->name == NULL)) { return -1; } // 1. var name unsigned FuncName = joinString(F->name); if (!checkReturnIndex(&FuncName)) { return -2; } llvm::SmallVector FuncInfo; if (!EncodeInteger(mModule->getContext(), FuncName, FuncInfo)) { return -3; } if (mFuncInfoMetadata == NULL) mFuncInfoMetadata = mModule->getOrInsertNamedMetadata(RS_EXPORT_FUNC_MN); mFuncInfoMetadata->addOperand(llvm::MDNode::get(mModule->getContext(), FuncInfo)); return 0; } // Write string table and string index table int RSMetadataEncoderInternal::flushStringTable() { slangAssert((mCurStringIndex == mEncodedStrings.size())); slangAssert((mCurStringIndex == mStrings.size())); if (mCurStringIndex == 0) return 0; // Prepare named MDNode for string table and string index table. llvm::NamedMDNode *RSMetadataStrTab = mModule->getOrInsertNamedMetadata(RS_METADATA_STRTAB_MN); RSMetadataStrTab->dropAllReferences(); unsigned StrTabSize = 0; unsigned *StrIdx = reinterpret_cast( ::malloc((mStrings.size() + 1) * sizeof(unsigned))); if (StrIdx == NULL) return -1; unsigned StrIdxI = 0; // iterator for array StrIdx // count StrTabSize and fill StrIdx by the way for (std::list::const_iterator I = mEncodedStrings.begin(), E = mEncodedStrings.end(); I != E; I++) { StrIdx[StrIdxI++] = StrTabSize; StrTabSize += ::strlen(*I) + 1 /* for '\0' */; } StrIdx[StrIdxI] = StrTabSize; // Allocate char *StrTab = reinterpret_cast(::malloc(StrTabSize)); if (StrTab == NULL) { free(StrIdx); return -1; } llvm::StringRef StrTabData(StrTab, StrTabSize); llvm::StringRef StrIdxData(reinterpret_cast(StrIdx), mStrings.size() * sizeof(unsigned)); // Copy StrIdxI = 1; for (std::list::const_iterator I = mEncodedStrings.begin(), E = mEncodedStrings.end(); I != E; I++) { // Get string length from StrIdx (O(1)) instead of call strlen again (O(n)). unsigned CurStrLength = StrIdx[StrIdxI] - StrIdx[StrIdxI - 1]; ::memcpy(StrTab, *I, CurStrLength); // Move forward the pointer StrTab += CurStrLength; StrIdxI++; } // Flush to metadata llvm::Value *StrTabMDS = llvm::MDString::get(mModule->getContext(), StrTabData); llvm::Value *StrIdxMDS = llvm::MDString::get(mModule->getContext(), StrIdxData); if ((StrTabMDS == NULL) || (StrIdxMDS == NULL)) { free(StrIdx); free(StrTab); return -1; } llvm::SmallVector StrTabVal; StrTabVal.push_back(StrTabMDS); StrTabVal.push_back(StrIdxMDS); RSMetadataStrTab->addOperand(llvm::MDNode::get(mModule->getContext(), StrTabVal)); return 0; } // Write RS type stream int RSMetadataEncoderInternal::flushTypeInfo() { unsigned TypeInfoCount = mEncodedRSTypeInfo.size(); if (TypeInfoCount <= 0) { return 0; } llvm::NamedMDNode *RSTypeInfo = mModule->getOrInsertNamedMetadata(RS_TYPE_INFO_MN); RSTypeInfo->dropAllReferences(); unsigned *TypeInfos = reinterpret_cast(::malloc(TypeInfoCount * sizeof(unsigned))); unsigned TypeInfosIdx = 0; // iterator for array TypeInfos if (TypeInfos == NULL) return -1; for (std::list::const_iterator I = mEncodedRSTypeInfo.begin(), E = mEncodedRSTypeInfo.end(); I != E; I++) TypeInfos[TypeInfosIdx++] = *I; llvm::StringRef TypeInfoData(reinterpret_cast(TypeInfos), TypeInfoCount * sizeof(unsigned)); llvm::Value *TypeInfoMDS = llvm::MDString::get(mModule->getContext(), TypeInfoData); if (TypeInfoMDS == NULL) { free(TypeInfos); return -1; } llvm::SmallVector TypeInfo; TypeInfo.push_back(TypeInfoMDS); RSTypeInfo->addOperand(llvm::MDNode::get(mModule->getContext(), TypeInfo)); free(TypeInfos); return 0; } int RSMetadataEncoderInternal::finalize() { int Res = flushStringTable(); if (Res != 0) return Res; Res = flushTypeInfo(); if (Res != 0) return Res; return 0; } /////////////////////////////////////////////////////////////////////////////// // APIs /////////////////////////////////////////////////////////////////////////////// RSMetadataEncoder *CreateRSMetadataEncoder(llvm::Module *M) { return reinterpret_cast(new RSMetadataEncoderInternal(M)); } int RSEncodeVarMetadata(RSMetadataEncoder *E, const RSVar *V) { return reinterpret_cast(E)->encodeRSVar(V); } int RSEncodeFunctionMetadata(RSMetadataEncoder *E, const RSFunction *F) { return reinterpret_cast(E)->encodeRSFunc(F); } void DestroyRSMetadataEncoder(RSMetadataEncoder *E) { RSMetadataEncoderInternal *C = reinterpret_cast(E); delete C; return; } int FinalizeRSMetadataEncoder(RSMetadataEncoder *E) { RSMetadataEncoderInternal *C = reinterpret_cast(E); int Res = C->finalize(); DestroyRSMetadataEncoder(E); return Res; }