//===- subzero/src/WasmTranslator.cpp - WASM to Subzero Translation -------===// // // The Subzero Code Generator // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// /// \file /// \brief Defines a driver for translating Wasm bitcode into PNaCl bitcode. /// /// The translator uses V8's WebAssembly decoder to handle the binary Wasm /// format but replaces the usual TurboFan builder with a new PNaCl builder. /// //===----------------------------------------------------------------------===// #if ALLOW_WASM #include "WasmTranslator.h" #ifdef __clang__ #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wunused-parameter" #pragma clang diagnostic ignored "-Wcovered-switch-default" #endif // __clang__ #if defined(__GNUC__) && !defined(__clang__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-but-set-variable" #endif // defined(__GNUC__) && !defined(__clang__) #include "src/wasm/module-decoder.h" #include "src/wasm/wasm-opcodes.h" #include "src/zone.h" #include "src/bit-vector.h" #include "src/wasm/ast-decoder-impl.h" #ifdef __clang__ #pragma clang diagnostic pop #endif // __clang__ #if defined(__GNUC__) && !defined(__clang__) #pragma GCC diagnostic pop #endif // defined(__GNUC__) && !defined(__clang__) #include "IceCfgNode.h" #include "IceGlobalInits.h" using namespace std; using namespace Ice; using namespace v8::internal; using namespace v8::internal::wasm; using v8::internal::wasm::DecodeWasmModule; #undef LOG #define LOG(Expr) log([&](Ostream & out) { Expr; }) namespace { // 64KB const uint32_t WASM_PAGE_SIZE = 64 << 10; std::string toStdString(WasmName Name) { return std::string(Name.name, Name.length); } Ice::Type toIceType(wasm::LocalType Type) { switch (Type) { case MachineRepresentation::kNone: llvm::report_fatal_error("kNone type not supported"); case MachineRepresentation::kBit: return IceType_i1; case MachineRepresentation::kWord8: return IceType_i8; case MachineRepresentation::kWord16: return IceType_i16; case MachineRepresentation::kWord32: return IceType_i32; case MachineRepresentation::kWord64: return IceType_i64; case MachineRepresentation::kFloat32: return IceType_f32; case MachineRepresentation::kFloat64: return IceType_f64; case MachineRepresentation::kSimd128: llvm::report_fatal_error("ambiguous SIMD type"); case MachineRepresentation::kTagged: llvm::report_fatal_error("kTagged type not supported"); } llvm::report_fatal_error("unexpected type"); } Ice::Type toIceType(v8::internal::MachineType Type) { // TODO (eholk): reorder these based on expected call frequency. if (Type == MachineType::Int32()) { return IceType_i32; } if (Type == MachineType::Uint32()) { return IceType_i32; } if (Type == MachineType::Int8()) { return IceType_i8; } if (Type == MachineType::Uint8()) { return IceType_i8; } if (Type == MachineType::Int16()) { return IceType_i16; } if (Type == MachineType::Uint16()) { return IceType_i16; } if (Type == MachineType::Int64()) { return IceType_i64; } if (Type == MachineType::Uint64()) { return IceType_i64; } if (Type == MachineType::Float32()) { return IceType_f32; } if (Type == MachineType::Float64()) { return IceType_f64; } llvm::report_fatal_error("Unsupported MachineType"); } std::string fnNameFromId(uint32_t Id) { return std::string("fn") + to_string(Id); } std::string getFunctionName(const WasmModule *Module, uint32_t func_index) { // Try to find the function name in the export table for (const auto Export : Module->export_table) { if (Export.func_index == func_index) { return "__szwasm_" + toStdString(Module->GetName(Export.name_offset, Export.name_length)); } } return fnNameFromId(func_index); } } // end of anonymous namespace /// This class wraps either an Operand or a CfgNode. /// /// Turbofan's sea of nodes representation only has nodes for values, control /// flow, etc. In Subzero these concepts are all separate. This class lets V8's /// Wasm decoder treat Subzero objects as though they are all the same. class OperandNode { static constexpr uintptr_t NODE_FLAG = 1; static constexpr uintptr_t UNDEF_PTR = (uintptr_t)-1; uintptr_t Data = UNDEF_PTR; public: OperandNode() = default; explicit OperandNode(Operand *Operand) : Data(reinterpret_cast(Operand)) {} explicit OperandNode(CfgNode *Node) : Data(reinterpret_cast(Node) | NODE_FLAG) {} explicit OperandNode(nullptr_t) : Data(UNDEF_PTR) {} operator Operand *() const { if (UNDEF_PTR == Data) { return nullptr; } if (!isOperand()) { llvm::report_fatal_error("This OperandNode is not an Operand"); } return reinterpret_cast(Data); } operator CfgNode *() const { if (UNDEF_PTR == Data) { return nullptr; } if (!isCfgNode()) { llvm::report_fatal_error("This OperandNode is not a CfgNode"); } return reinterpret_cast(Data & ~NODE_FLAG); } explicit operator bool() const { return (Data != UNDEF_PTR) && Data; } bool operator==(const OperandNode &Rhs) const { return (Data == Rhs.Data) || (UNDEF_PTR == Data && (Rhs.Data == 0 || Rhs.Data == NODE_FLAG)) || (UNDEF_PTR == Rhs.Data && (Data == 0 || Data == NODE_FLAG)); } bool operator!=(const OperandNode &Rhs) const { return !(*this == Rhs); } bool isOperand() const { return (Data != UNDEF_PTR) && !(Data & NODE_FLAG); } bool isCfgNode() const { return (Data != UNDEF_PTR) && (Data & NODE_FLAG); } Operand *toOperand() const { return static_cast(*this); } CfgNode *toCfgNode() const { return static_cast(*this); } }; Ostream &operator<<(Ostream &Out, const OperandNode &Op) { if (Op.isOperand()) { const auto *Oper = Op.toOperand(); Out << "(Operand*)" << Oper; if (Oper) { Out << "::" << Oper->getType(); } } else if (Op.isCfgNode()) { Out << "(CfgNode*)" << Op.toCfgNode(); } else { Out << "nullptr"; } return Out; } bool isComparison(wasm::WasmOpcode Opcode) { switch (Opcode) { case kExprI32Ne: case kExprI64Ne: case kExprI32Eq: case kExprI64Eq: case kExprI32LtS: case kExprI64LtS: case kExprI32LtU: case kExprI64LtU: case kExprI32GeS: case kExprI64GeS: case kExprI32GtS: case kExprI64GtS: case kExprI32GtU: case kExprI64GtU: case kExprF32Eq: case kExprF64Eq: case kExprF32Ne: case kExprF64Ne: case kExprF32Le: case kExprF64Le: case kExprF32Lt: case kExprF64Lt: case kExprF32Ge: case kExprF64Ge: case kExprF32Gt: case kExprF64Gt: case kExprI32LeS: case kExprI64LeS: case kExprI32GeU: case kExprI64GeU: case kExprI32LeU: case kExprI64LeU: return true; default: return false; } } class IceBuilder { using Node = OperandNode; using Variable = Ice::Variable; IceBuilder() = delete; IceBuilder(const IceBuilder &) = delete; IceBuilder &operator=(const IceBuilder &) = delete; public: explicit IceBuilder(class Cfg *Func) : ControlPtr(nullptr), Func(Func), Ctx(Func->getContext()) {} /// Allocates a buffer of Nodes for use by V8. Node *Buffer(size_t Count) { LOG(out << "Buffer(" << Count << ")\n"); return Func->allocateArrayOf(Count); } Node Error() { llvm::report_fatal_error("Error"); } Node Start(uint32_t Params) { LOG(out << "Start(" << Params << ") = "); auto *Entry = Func->getEntryNode(); assert(Entry); LOG(out << Node(Entry) << "\n"); // Load the WasmMemory address to make it available everywhere else in the // function. auto *WasmMemoryPtr = Ctx->getConstantExternSym(Ctx->getGlobalString("WASM_MEMORY")); assert(WasmMemory == nullptr); auto *WasmMemoryV = makeVariable(getPointerType()); Entry->appendInst(InstLoad::create(Func, WasmMemoryV, WasmMemoryPtr)); WasmMemory = WasmMemoryV; return OperandNode(Entry); } Node Param(uint32_t Index, wasm::LocalType Type) { LOG(out << "Param(" << Index << ") = "); auto *Arg = makeVariable(toIceType(Type)); assert(Index == NextArg); Func->addArg(Arg); ++NextArg; LOG(out << Node(Arg) << "\n"); return OperandNode(Arg); } Node Loop(CfgNode *Entry) { auto *Loop = Func->makeNode(); LOG(out << "Loop(" << Entry << ") = " << Loop << "\n"); Entry->appendInst(InstBr::create(Func, Loop)); return OperandNode(Loop); } void Terminate(Node Effect, Node Control) { // TODO(eholk): this is almost certainly wrong LOG(out << "Terminate(" << Effect << ", " << Control << ")" << "\n"); } Node Merge(uint32_t Count, Node *Controls) { LOG(out << "Merge(" << Count); for (uint32_t i = 0; i < Count; ++i) { LOG(out << ", " << Controls[i]); } LOG(out << ") = "); auto *MergedNode = Func->makeNode(); for (uint32_t i = 0; i < Count; ++i) { CfgNode *Control = Controls[i]; Control->appendInst(InstBr::create(Func, MergedNode)); } LOG(out << (OperandNode)MergedNode << "\n"); return OperandNode(MergedNode); } Node Phi(wasm::LocalType, uint32_t Count, Node *Vals, Node Control) { LOG(out << "Phi(" << Count << ", " << Control); for (uint32_t i = 0; i < Count; ++i) { LOG(out << ", " << Vals[i]); } LOG(out << ") = "); const auto &InEdges = Control.toCfgNode()->getInEdges(); assert(Count == InEdges.size()); assert(Count > 0); auto *Dest = makeVariable(Vals[0].toOperand()->getType(), Control); // Multiply by 200 in case more things get added later. // TODO(eholk): find a better way besides multiplying by some arbitrary // constant. auto *Phi = InstPhi::create(Func, Count * 200, Dest); for (uint32_t i = 0; i < Count; ++i) { auto *Op = Vals[i].toOperand(); assert(Op); Phi->addArgument(Op, InEdges[i]); } setDefiningInst(Dest, Phi); Control.toCfgNode()->appendInst(Phi); LOG(out << Node(Dest) << "\n"); return OperandNode(Dest); } Node EffectPhi(uint32_t Count, Node *Effects, Node Control) { // TODO(eholk): this function is almost certainly wrong. LOG(out << "EffectPhi(" << Count << ", " << Control << "):\n"); for (uint32_t i = 0; i < Count; ++i) { LOG(out << " " << Effects[i] << "\n"); } return OperandNode(nullptr); } Node Int32Constant(int32_t Value) { LOG(out << "Int32Constant(" << Value << ") = "); auto *Const = Ctx->getConstantInt32(Value); assert(Const); assert(Control()); LOG(out << Node(Const) << "\n"); return OperandNode(Const); } Node Int64Constant(int64_t Value) { LOG(out << "Int64Constant(" << Value << ") = "); auto *Const = Ctx->getConstantInt64(Value); assert(Const); LOG(out << Node(Const) << "\n"); return OperandNode(Const); } Node Float32Constant(float Value) { LOG(out << "Float32Constant(" << Value << ") = "); auto *Const = Ctx->getConstantFloat(Value); assert(Const); LOG(out << Node(Const) << "\n"); return OperandNode(Const); } Node Float64Constant(double Value) { LOG(out << "Float64Constant(" << Value << ") = "); auto *Const = Ctx->getConstantDouble(Value); assert(Const); LOG(out << Node(Const) << "\n"); return OperandNode(Const); } Node Binop(wasm::WasmOpcode Opcode, Node Left, Node Right) { LOG(out << "Binop(" << WasmOpcodes::OpcodeName(Opcode) << ", " << Left << ", " << Right << ") = "); BooleanVariable *BoolDest = nullptr; Variable *Dest = nullptr; if (isComparison(Opcode)) { BoolDest = makeVariable(IceType_i32); Dest = BoolDest; } else { Dest = makeVariable(Left.toOperand()->getType()); } switch (Opcode) { case kExprI32Add: case kExprI64Add: Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Add, Dest, Left, Right)); break; case kExprF32Add: case kExprF64Add: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Fadd, Dest, Left, Right)); break; case kExprI32Sub: case kExprI64Sub: Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Sub, Dest, Left, Right)); break; case kExprF32Sub: case kExprF64Sub: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Fsub, Dest, Left, Right)); break; case kExprI32Mul: case kExprI64Mul: Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Mul, Dest, Left, Right)); break; case kExprF32Mul: case kExprF64Mul: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Fmul, Dest, Left, Right)); break; case kExprI32DivS: case kExprI64DivS: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Sdiv, Dest, Left, Right)); break; case kExprI32DivU: case kExprI64DivU: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Udiv, Dest, Left, Right)); break; case kExprF32Div: case kExprF64Div: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Fdiv, Dest, Left, Right)); break; case kExprI32RemU: case kExprI64RemU: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Urem, Dest, Left, Right)); break; case kExprI32RemS: case kExprI64RemS: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Srem, Dest, Left, Right)); break; case kExprI32Ior: case kExprI64Ior: Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Or, Dest, Left, Right)); break; case kExprI32Xor: case kExprI64Xor: Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Xor, Dest, Left, Right)); break; case kExprI32Shl: case kExprI64Shl: Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Shl, Dest, Left, Right)); break; case kExprI32Rol: case kExprI64Rol: { // TODO(eholk): add rotate as an ICE instruction to make it easier to take // advantage of hardware support. const auto DestTy = Left.toOperand()->getType(); const SizeT BitCount = typeWidthInBytes(DestTy) * CHAR_BIT; auto *Masked = makeVariable(DestTy); auto *Bottom = makeVariable(DestTy); auto *Top = makeVariable(DestTy); Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::And, Masked, Right, Ctx->getConstantInt(DestTy, BitCount - 1))); Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Shl, Top, Left, Masked)); auto *RotShift = makeVariable(DestTy); Control()->appendInst(InstArithmetic::create( Func, InstArithmetic::Sub, RotShift, Ctx->getConstantInt(DestTy, BitCount), Masked)); Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Lshr, Bottom, Left, RotShift)); Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Or, Dest, Top, Bottom)); break; } case kExprI32Ror: case kExprI64Ror: { // TODO(eholk): add rotate as an ICE instruction to make it easier to take // advantage of hardware support. const auto DestTy = Left.toOperand()->getType(); const SizeT BitCount = typeWidthInBytes(DestTy) * CHAR_BIT; auto *Masked = makeVariable(DestTy); auto *Bottom = makeVariable(DestTy); auto *Top = makeVariable(DestTy); Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::And, Masked, Right, Ctx->getConstantInt(DestTy, BitCount - 1))); Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Lshr, Top, Left, Masked)); auto *RotShift = makeVariable(DestTy); Control()->appendInst(InstArithmetic::create( Func, InstArithmetic::Sub, RotShift, Ctx->getConstantInt(DestTy, BitCount), Masked)); Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Shl, Bottom, Left, RotShift)); Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::Or, Dest, Top, Bottom)); break; } case kExprI32ShrU: case kExprI64ShrU: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Lshr, Dest, Left, Right)); break; case kExprI32ShrS: case kExprI64ShrS: Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Ashr, Dest, Left, Right)); break; case kExprI32And: case kExprI64And: Control()->appendInst( InstArithmetic::create(Func, InstArithmetic::And, Dest, Left, Right)); break; case kExprI32Ne: case kExprI64Ne: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Ne, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32Eq: case kExprI64Eq: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Eq, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32LtS: case kExprI64LtS: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Slt, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32LeS: case kExprI64LeS: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Sle, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32GeU: case kExprI64GeU: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Uge, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32LeU: case kExprI64LeU: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Ule, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32LtU: case kExprI64LtU: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Ult, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32GeS: case kExprI64GeS: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Sge, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32GtS: case kExprI64GtS: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Sgt, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprI32GtU: case kExprI64GtU: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstIcmp::create(Func, InstIcmp::Ugt, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprF32Eq: case kExprF64Eq: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstFcmp::create(Func, InstFcmp::Ueq, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprF32Ne: case kExprF64Ne: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstFcmp::create(Func, InstFcmp::Une, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprF32Le: case kExprF64Le: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstFcmp::create(Func, InstFcmp::Ule, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprF32Lt: case kExprF64Lt: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstFcmp::create(Func, InstFcmp::Ult, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprF32Ge: case kExprF64Ge: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstFcmp::create(Func, InstFcmp::Uge, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } case kExprF32Gt: case kExprF64Gt: { auto *TmpDest = makeVariable(IceType_i1); Control()->appendInst( InstFcmp::create(Func, InstFcmp::Ugt, TmpDest, Left, Right)); BoolDest->setBoolSource(TmpDest); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, TmpDest)); break; } default: LOG(out << "Unknown binop: " << WasmOpcodes::OpcodeName(Opcode) << "\n"); llvm::report_fatal_error("Uncovered or invalid binop."); return OperandNode(nullptr); } LOG(out << Dest << "\n"); return OperandNode(Dest); } Node Unop(wasm::WasmOpcode Opcode, Node Input) { LOG(out << "Unop(" << WasmOpcodes::OpcodeName(Opcode) << ", " << Input << ") = "); Variable *Dest = nullptr; switch (Opcode) { // TODO (eholk): merge these next two cases using getConstantInteger case kExprI32Eqz: { auto *BoolDest = makeVariable(IceType_i32); Dest = BoolDest; auto *Tmp = makeVariable(IceType_i1); Control()->appendInst(InstIcmp::create(Func, InstIcmp::Eq, Tmp, Input, Ctx->getConstantInt32(0))); BoolDest->setBoolSource(Tmp); Control()->appendInst(InstCast::create(Func, InstCast::Zext, Dest, Tmp)); break; } case kExprI64Eqz: { auto *BoolDest = makeVariable(IceType_i32); Dest = BoolDest; auto *Tmp = makeVariable(IceType_i1); Control()->appendInst(InstIcmp::create(Func, InstIcmp::Eq, Tmp, Input, Ctx->getConstantInt64(0))); BoolDest->setBoolSource(Tmp); Control()->appendInst(InstCast::create(Func, InstCast::Zext, Dest, Tmp)); break; } case kExprI32Ctz: { Dest = makeVariable(IceType_i32); const auto FnName = Ctx->getGlobalString("llvm.cttz.i32"); bool BadInstrinsic = false; const auto *Info = Ctx->getIntrinsicsInfo().find(FnName, BadInstrinsic); assert(!BadInstrinsic); assert(Info); auto *Call = InstIntrinsicCall::create( Func, 1, Dest, Ctx->getConstantExternSym(FnName), Info->Info); Call->addArg(Input); Control()->appendInst(Call); break; } case kExprF32Neg: { Dest = makeVariable(IceType_f32); Control()->appendInst(InstArithmetic::create( Func, InstArithmetic::Fsub, Dest, Ctx->getConstantFloat(0), Input)); break; } case kExprF64Neg: { Dest = makeVariable(IceType_f64); Control()->appendInst(InstArithmetic::create( Func, InstArithmetic::Fsub, Dest, Ctx->getConstantDouble(0), Input)); break; } case kExprF32Abs: { Dest = makeVariable(IceType_f32); const auto FnName = Ctx->getGlobalString("llvm.fabs.f32"); bool BadInstrinsic = false; const auto *Info = Ctx->getIntrinsicsInfo().find(FnName, BadInstrinsic); assert(!BadInstrinsic); assert(Info); auto *Call = InstIntrinsicCall::create( Func, 1, Dest, Ctx->getConstantExternSym(FnName), Info->Info); Call->addArg(Input); Control()->appendInst(Call); break; } case kExprF64Abs: { Dest = makeVariable(IceType_f64); const auto FnName = Ctx->getGlobalString("llvm.fabs.f64"); bool BadInstrinsic = false; const auto *Info = Ctx->getIntrinsicsInfo().find(FnName, BadInstrinsic); assert(!BadInstrinsic); assert(Info); auto *Call = InstIntrinsicCall::create( Func, 1, Dest, Ctx->getConstantExternSym(FnName), Info->Info); Call->addArg(Input); Control()->appendInst(Call); break; } case kExprF32Floor: { Dest = makeVariable(IceType_f64); const auto FnName = Ctx->getGlobalString("env$$floor_f"); constexpr bool HasTailCall = false; auto *Call = InstCall::create( Func, 1, Dest, Ctx->getConstantExternSym(FnName), HasTailCall); Call->addArg(Input); Control()->appendInst(Call); break; } case kExprF64Floor: { Dest = makeVariable(IceType_f64); const auto FnName = Ctx->getGlobalString("env$$floor_d"); constexpr bool HasTailCall = false; auto *Call = InstCall::create( Func, 1, Dest, Ctx->getConstantExternSym(FnName), HasTailCall); Call->addArg(Input); Control()->appendInst(Call); break; } case kExprF32Sqrt: { Dest = makeVariable(IceType_f32); const auto FnName = Ctx->getGlobalString("llvm.sqrt.f32"); bool BadInstrinsic = false; const auto *Info = Ctx->getIntrinsicsInfo().find(FnName, BadInstrinsic); assert(!BadInstrinsic); assert(Info); auto *Call = InstIntrinsicCall::create( Func, 1, Dest, Ctx->getConstantExternSym(FnName), Info->Info); Call->addArg(Input); Control()->appendInst(Call); break; } case kExprF64Sqrt: { Dest = makeVariable(IceType_f64); const auto FnName = Ctx->getGlobalString("llvm.sqrt.f64"); bool BadInstrinsic = false; const auto *Info = Ctx->getIntrinsicsInfo().find(FnName, BadInstrinsic); assert(!BadInstrinsic); assert(Info); auto *Call = InstIntrinsicCall::create( Func, 1, Dest, Ctx->getConstantExternSym(FnName), Info->Info); Call->addArg(Input); Control()->appendInst(Call); break; } case kExprI64UConvertI32: Dest = makeVariable(IceType_i64); Control()->appendInst( InstCast::create(Func, InstCast::Zext, Dest, Input)); break; case kExprI64SConvertI32: Dest = makeVariable(IceType_i64); Control()->appendInst( InstCast::create(Func, InstCast::Sext, Dest, Input)); break; case kExprI32SConvertF32: Dest = makeVariable(IceType_i32); Control()->appendInst( InstCast::create(Func, InstCast::Fptosi, Dest, Input)); break; case kExprI32UConvertF32: Dest = makeVariable(IceType_i32); Control()->appendInst( InstCast::create(Func, InstCast::Fptoui, Dest, Input)); break; case kExprI32SConvertF64: Dest = makeVariable(IceType_i32); Control()->appendInst( InstCast::create(Func, InstCast::Fptosi, Dest, Input)); break; case kExprI32UConvertF64: Dest = makeVariable(IceType_i32); Control()->appendInst( InstCast::create(Func, InstCast::Fptoui, Dest, Input)); break; case kExprI32ReinterpretF32: Dest = makeVariable(IceType_i32); Control()->appendInst( InstCast::create(Func, InstCast::Bitcast, Dest, Input)); break; case kExprI64ReinterpretF64: Dest = makeVariable(IceType_i64); Control()->appendInst( InstCast::create(Func, InstCast::Bitcast, Dest, Input)); break; case kExprF64ReinterpretI64: Dest = makeVariable(IceType_f64); Control()->appendInst( InstCast::create(Func, InstCast::Bitcast, Dest, Input)); break; case kExprI32ConvertI64: Dest = makeVariable(IceType_i32); Control()->appendInst( InstCast::create(Func, InstCast::Trunc, Dest, Input)); break; case kExprF64SConvertI32: Dest = makeVariable(IceType_f64); Control()->appendInst( InstCast::create(Func, InstCast::Sitofp, Dest, Input)); break; case kExprF64UConvertI32: Dest = makeVariable(IceType_f64); Control()->appendInst( InstCast::create(Func, InstCast::Uitofp, Dest, Input)); break; case kExprF64ConvertF32: Dest = makeVariable(IceType_f64); Control()->appendInst( InstCast::create(Func, InstCast::Fpext, Dest, Input)); break; case kExprF32SConvertI32: Dest = makeVariable(IceType_f32); Control()->appendInst( InstCast::create(Func, InstCast::Sitofp, Dest, Input)); break; case kExprF32UConvertI32: Dest = makeVariable(IceType_f32); Control()->appendInst( InstCast::create(Func, InstCast::Uitofp, Dest, Input)); break; case kExprF32ReinterpretI32: Dest = makeVariable(IceType_f32); Control()->appendInst( InstCast::create(Func, InstCast::Bitcast, Dest, Input)); break; case kExprF32ConvertF64: Dest = makeVariable(IceType_f32); Control()->appendInst( InstCast::create(Func, InstCast::Fptrunc, Dest, Input)); break; default: LOG(out << "Unknown unop: " << WasmOpcodes::OpcodeName(Opcode) << "\n"); llvm::report_fatal_error("Uncovered or invalid unop."); return OperandNode(nullptr); } LOG(out << Dest << "\n"); return OperandNode(Dest); } uint32_t InputCount(CfgNode *Node) const { return Node->getInEdges().size(); } bool IsPhiWithMerge(Node Phi, Node Merge) const { LOG(out << "IsPhiWithMerge(" << Phi << ", " << Merge << ")" << "\n"); if (Phi && Phi.isOperand()) { LOG(out << " ...is operand" << "\n"); if (getDefiningInst(Phi)) { LOG(out << " ...has defining instruction" << "\n"); LOG(out << getDefNode(Phi) << "\n"); LOG(out << " ..." << (getDefNode(Phi) == Merge) << "\n"); return getDefNode(Phi) == Merge; } } return false; } void AppendToMerge(CfgNode *Merge, CfgNode *From) const { From->appendInst(InstBr::create(Func, Merge)); } void AppendToPhi(Node Merge, Node Phi, Node From) { LOG(out << "AppendToPhi(" << Merge << ", " << Phi << ", " << From << ")" << "\n"); auto *Inst = getDefiningInst(Phi); assert(Inst->getDest()->getType() == From.toOperand()->getType()); Inst->addArgument(From, getDefNode(From)); } //----------------------------------------------------------------------- // Operations that read and/or write {control} and {effect}. //----------------------------------------------------------------------- Node Branch(Node Cond, Node *TrueNode, Node *FalseNode) { // true_node and false_node appear to be out parameters. LOG(out << "Branch(" << Cond << ", "); // save control here because true_node appears to alias control. auto *Ctrl = Control(); *TrueNode = OperandNode(Func->makeNode()); *FalseNode = OperandNode(Func->makeNode()); LOG(out << *TrueNode << ", " << *FalseNode << ")" << "\n"); auto *CondBool = Cond.toOperand()->asBoolean(); if (CondBool == nullptr) { CondBool = makeVariable(IceType_i1); Ctrl->appendInst(InstIcmp::create(Func, InstIcmp::Ne, CondBool, Cond, Ctx->getConstantInt32(0))); } Ctrl->appendInst(InstBr::create(Func, CondBool, *TrueNode, *FalseNode)); return OperandNode(nullptr); } InstSwitch *CurrentSwitch = nullptr; CfgNode *SwitchNode = nullptr; SizeT SwitchIndex = 0; Node Switch(uint32_t Count, Node Key) { LOG(out << "Switch(" << Count << ", " << Key << ")\n"); assert(!CurrentSwitch); auto *Default = Func->makeNode(); // Count - 1 because the decoder counts the default label but Subzero does // not. CurrentSwitch = InstSwitch::create(Func, Count - 1, Key, Default); SwitchIndex = 0; SwitchNode = Control(); // We don't actually append the switch to the CfgNode here because not all // the branches are ready. return Node(nullptr); } Node IfValue(int32_t Value, Node) { LOG(out << "IfValue(" << Value << ") [Index = " << SwitchIndex << "]\n"); assert(CurrentSwitch); auto *Target = Func->makeNode(); CurrentSwitch->addBranch(SwitchIndex++, Value, Target); return Node(Target); } Node IfDefault(Node) { LOG(out << "IfDefault(...) [Index = " << SwitchIndex << "]\n"); assert(CurrentSwitch); assert(CurrentSwitch->getLabelDefault()); // Now we append the switch, since this should be the last edge. assert(SwitchIndex == CurrentSwitch->getNumCases()); SwitchNode->appendInst(CurrentSwitch); SwitchNode = nullptr; auto Default = Node(CurrentSwitch->getLabelDefault()); CurrentSwitch = nullptr; return Default; } Node Return(uint32_t Count, Node *Vals) { assert(1 >= Count); LOG(out << "Return("); if (Count > 0) LOG(out << Vals[0]); LOG(out << ")" << "\n"); auto *Instr = 1 == Count ? InstRet::create(Func, Vals[0]) : InstRet::create(Func); Control()->appendInst(Instr); Control()->setHasReturn(); LOG(out << Node(nullptr) << "\n"); return OperandNode(nullptr); } Node ReturnVoid() { LOG(out << "ReturnVoid() = "); auto *Instr = InstRet::create(Func); Control()->appendInst(Instr); Control()->setHasReturn(); LOG(out << Node(nullptr) << "\n"); return OperandNode(nullptr); } Node Unreachable() { LOG(out << "Unreachable() = "); auto *Instr = InstUnreachable::create(Func); Control()->appendInst(Instr); LOG(out << Node(nullptr) << "\n"); return OperandNode(nullptr); } Node CallDirect(uint32_t Index, Node *Args) { LOG(out << "CallDirect(" << Index << ")" << "\n"); assert(Module->IsValidFunction(Index)); const auto *Module = this->Module->module; assert(Module); const auto &Target = Module->functions[Index]; const auto *Sig = Target.sig; assert(Sig); const auto NumArgs = Sig->parameter_count(); LOG(out << " number of args: " << NumArgs << "\n"); const auto TargetName = getFunctionName(Module, Index); LOG(out << " target name: " << TargetName << "\n"); assert(Sig->return_count() <= 1); auto TargetOperand = Ctx->getConstantSym(0, Ctx->getGlobalString(TargetName)); auto *Dest = Sig->return_count() > 0 ? makeVariable(toIceType(Sig->GetReturn())) : nullptr; auto *Call = InstCall::create(Func, NumArgs, Dest, TargetOperand, false /* HasTailCall */); for (uint32_t i = 0; i < NumArgs; ++i) { // The builder reserves the first argument for the code object. LOG(out << " args[" << i << "] = " << Args[i + 1] << "\n"); Call->addArg(Args[i + 1]); } Control()->appendInst(Call); LOG(out << "Call Result = " << Node(Dest) << "\n"); return OperandNode(Dest); } Node CallImport(uint32_t Index, Node *Args) { LOG(out << "CallImport(" << Index << ")" << "\n"); const auto *Module = this->Module->module; assert(Module); const auto *Sig = this->Module->GetImportSignature(Index); assert(Sig); const auto NumArgs = Sig->parameter_count(); LOG(out << " number of args: " << NumArgs << "\n"); const auto &Target = Module->import_table[Index]; const auto ModuleName = toStdString( Module->GetName(Target.module_name_offset, Target.module_name_length)); const auto FnName = toStdString(Module->GetName( Target.function_name_offset, Target.function_name_length)); const auto TargetName = Ctx->getGlobalString(ModuleName + "$$" + FnName); LOG(out << " target name: " << TargetName << "\n"); assert(Sig->return_count() <= 1); auto TargetOperand = Ctx->getConstantExternSym(TargetName); auto *Dest = Sig->return_count() > 0 ? makeVariable(toIceType(Sig->GetReturn())) : nullptr; constexpr bool NoTailCall = false; auto *Call = InstCall::create(Func, NumArgs, Dest, TargetOperand, NoTailCall); for (uint32_t i = 0; i < NumArgs; ++i) { // The builder reserves the first argument for the code object. LOG(out << " args[" << i << "] = " << Args[i + 1] << "\n"); assert(Args[i + 1].toOperand()->getType() == toIceType(Sig->GetParam(i))); Call->addArg(Args[i + 1]); } Control()->appendInst(Call); LOG(out << "Call Result = " << Node(Dest) << "\n"); return OperandNode(Dest); } Node CallIndirect(uint32_t SigIndex, Node *Args) { LOG(out << "CallIndirect(" << SigIndex << ")\n"); // TODO(eholk): Compile to something better than a switch. const auto *Module = this->Module->module; assert(Module); const auto &IndirectTable = Module->function_table; auto *Abort = getIndirectFailTarget(); assert(Args[0].toOperand()); auto *Switch = InstSwitch::create(Func, IndirectTable.size(), Args[0].toOperand(), Abort); assert(Abort); const bool HasReturn = Module->signatures[SigIndex]->return_count() != 0; const Ice::Type DestTy = HasReturn ? toIceType(Module->signatures[SigIndex]->GetReturn()) : IceType_void; auto *Dest = HasReturn ? makeVariable(DestTy) : nullptr; auto *ExitNode = Func->makeNode(); auto *PhiInst = HasReturn ? InstPhi::create(Func, IndirectTable.size(), Dest) : nullptr; for (uint32_t Index = 0; Index < IndirectTable.size(); ++Index) { const auto &Target = Module->functions[IndirectTable[Index]]; if (SigIndex == Target.sig_index) { auto *CallNode = Func->makeNode(); auto *SavedControl = Control(); *ControlPtr = OperandNode(CallNode); auto *Tmp = CallDirect(Target.func_index, Args).toOperand(); *ControlPtr = OperandNode(SavedControl); if (PhiInst) { PhiInst->addArgument(Tmp, CallNode); } CallNode->appendInst(InstBr::create(Func, ExitNode)); Switch->addBranch(Index, Index, CallNode); } else { Switch->addBranch(Index, Index, Abort); } } if (PhiInst) { ExitNode->appendInst(PhiInst); } Control()->appendInst(Switch); *ControlPtr = OperandNode(ExitNode); return OperandNode(Dest); } Node Invert(Node Node) { (void)Node; llvm::report_fatal_error("Invert"); } //----------------------------------------------------------------------- // Operations that concern the linear memory. //----------------------------------------------------------------------- Node MemSize(uint32_t Offset) { (void)Offset; llvm::report_fatal_error("MemSize"); } Node LoadGlobal(uint32_t Index) { (void)Index; llvm::report_fatal_error("LoadGlobal"); } Node StoreGlobal(uint32_t Index, Node Val) { (void)Index; (void)Val; llvm::report_fatal_error("StoreGlobal"); } Node LoadMem(wasm::LocalType Type, MachineType MemType, Node Index, uint32_t Offset) { LOG(out << "LoadMem." << toIceType(MemType) << "(" << Index << "[" << Offset << "]) = "); auto *RealAddr = sanitizeAddress(Index, Offset); auto *LoadResult = makeVariable(toIceType(MemType)); Control()->appendInst(InstLoad::create(Func, LoadResult, RealAddr)); // and cast, if needed Variable *Result = nullptr; if (toIceType(Type) != toIceType(MemType)) { auto DestType = toIceType(Type); Result = makeVariable(DestType); // TODO(eholk): handle signs correctly. if (isScalarIntegerType(DestType)) { if (MemType.IsSigned()) { Control()->appendInst( InstCast::create(Func, InstCast::Sext, Result, LoadResult)); } else { Control()->appendInst( InstCast::create(Func, InstCast::Zext, Result, LoadResult)); } } else if (isScalarFloatingType(DestType)) { Control()->appendInst( InstCast::create(Func, InstCast::Sitofp, Result, LoadResult)); } else { llvm::report_fatal_error("Unsupported type for memory load"); } } else { Result = LoadResult; } LOG(out << Result << "\n"); return OperandNode(Result); } void StoreMem(MachineType Type, Node Index, uint32_t Offset, Node Val) { LOG(out << "StoreMem." << toIceType(Type) << "(" << Index << "[" << Offset << "] = " << Val << ")" << "\n"); auto *RealAddr = sanitizeAddress(Index, Offset); // cast the value to the right type, if needed Operand *StoreVal = nullptr; if (toIceType(Type) != Val.toOperand()->getType()) { auto *LocalStoreVal = makeVariable(toIceType(Type)); Control()->appendInst( InstCast::create(Func, InstCast::Trunc, LocalStoreVal, Val)); StoreVal = LocalStoreVal; } else { StoreVal = Val; } // then store the memory Control()->appendInst(InstStore::create(Func, StoreVal, RealAddr)); } static void PrintDebugName(OperandNode Node) { (void)Node; llvm::report_fatal_error("PrintDebugName"); } CfgNode *Control() { return ControlPtr ? ControlPtr->toCfgNode() : Func->getEntryNode(); } Node Effect() { return *EffectPtr; } void set_module(wasm::ModuleEnv *Module) { this->Module = Module; } void set_control_ptr(Node *Control) { this->ControlPtr = Control; } void set_effect_ptr(Node *Effect) { this->EffectPtr = Effect; } private: wasm::ModuleEnv *Module; Node *ControlPtr; Node *EffectPtr; class Cfg *Func; GlobalContext *Ctx; CfgNode *BoundsFailTarget = nullptr; CfgNode *IndirectFailTarget = nullptr; SizeT NextArg = 0; CfgUnorderedMap PhiMap; CfgUnorderedMap DefNodeMap; Operand *WasmMemory = nullptr; InstPhi *getDefiningInst(Operand *Op) const { const auto &Iter = PhiMap.find(Op); if (Iter == PhiMap.end()) { return nullptr; } return Iter->second; } void setDefiningInst(Operand *Op, InstPhi *Phi) { LOG(out << "\n== setDefiningInst(" << Op << ", " << Phi << ") ==\n"); PhiMap.emplace(Op, Phi); } template T *makeVariable(Ice::Type Type) { return makeVariable(Type, Control()); } template T *makeVariable(Ice::Type Type, CfgNode *DefNode) { auto *Var = Func->makeVariable(Type); DefNodeMap.emplace(Var, DefNode); return Var; } CfgNode *getDefNode(Operand *Op) const { const auto &Iter = DefNodeMap.find(Op); if (Iter == DefNodeMap.end()) { return nullptr; } return Iter->second; } CfgNode *getBoundsFailTarget() { if (!BoundsFailTarget) { // TODO (eholk): Move this node to the end of the CFG, or even better, // have only one abort block for the whole module. BoundsFailTarget = Func->makeNode(); BoundsFailTarget->appendInst(InstCall::create( Func, 0, nullptr, Ctx->getConstantExternSym(Ctx->getGlobalString("__Sz_bounds_fail")), false)); BoundsFailTarget->appendInst(InstUnreachable::create(Func)); } return BoundsFailTarget; } CfgNode *getIndirectFailTarget() { if (!IndirectFailTarget) { // TODO (eholk): Move this node to the end of the CFG, or even better, // have only one abort block for the whole module. IndirectFailTarget = Func->makeNode(); IndirectFailTarget->appendInst(InstCall::create( Func, 0, nullptr, Ctx->getConstantExternSym(Ctx->getGlobalString("__Sz_indirect_fail")), false)); IndirectFailTarget->appendInst(InstUnreachable::create(Func)); } return IndirectFailTarget; } Operand *getWasmMemory() { assert(WasmMemory != nullptr); return WasmMemory; } Operand *sanitizeAddress(Operand *Base, uint32_t Offset) { SizeT MemSize = Module->module->min_mem_pages * WASM_PAGE_SIZE; bool ConstZeroBase = false; // first, add the index and the offset together. if (auto *ConstBase = llvm::dyn_cast(Base)) { uint32_t RealOffset = Offset + ConstBase->getValue(); if (RealOffset >= MemSize) { // We've proven this will always be an out of bounds access, so insert // an unconditional trap. Control()->appendInst(InstUnreachable::create(Func)); // It doesn't matter what we return here, so return something that will // allow the rest of code generation to happen. // // We might be tempted to just abort translation here, but out of bounds // memory access is a runtime trap, not a compile error. return Ctx->getConstantZero(getPointerType()); } Base = Ctx->getConstantInt32(RealOffset); ConstZeroBase = (0 == RealOffset); } else if (0 != Offset) { auto *Addr = makeVariable(Ice::getPointerType()); auto *OffsetConstant = Ctx->getConstantInt32(Offset); Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Add, Addr, Base, OffsetConstant)); Base = Addr; } // Do the bounds check if enabled if (getFlags().getWasmBoundsCheck() && !llvm::isa(Base)) { // TODO (eholk): creating a new basic block on every memory access is // terrible (see https://goo.gl/Zj7DTr). Try adding a new instruction that // encapsulates this "abort if false" pattern. auto *CheckPassed = Func->makeNode(); auto *CheckFailed = getBoundsFailTarget(); auto *Check = makeVariable(IceType_i1); Control()->appendInst(InstIcmp::create(Func, InstIcmp::Ult, Check, Base, Ctx->getConstantInt32(MemSize))); Control()->appendInst( InstBr::create(Func, Check, CheckPassed, CheckFailed)); *ControlPtr = OperandNode(CheckPassed); } Ice::Operand *RealAddr = nullptr; auto MemBase = getWasmMemory(); if (!ConstZeroBase) { auto RealAddrV = Func->makeVariable(Ice::getPointerType()); Control()->appendInst(InstArithmetic::create(Func, InstArithmetic::Add, RealAddrV, Base, MemBase)); RealAddr = RealAddrV; } else { RealAddr = MemBase; } return RealAddr; } template > void log(F Fn) const { if (BuildDefs::dump() && (getFlags().getVerbose() & IceV_Wasm)) { Fn(Ctx->getStrDump()); Ctx->getStrDump().flush(); } } }; std::unique_ptr WasmTranslator::translateFunction(Zone *Zone, FunctionBody &Body) { OstreamLocker L1(Ctx); auto Func = Cfg::create(Ctx, getNextSequenceNumber()); TimerMarker T(TimerStack::TT_wasmGenIce, Func.get()); Ice::CfgLocalAllocatorScope L2(Func.get()); // TODO(eholk): parse the function signature... Func->setEntryNode(Func->makeNode()); IceBuilder Builder(Func.get()); SR_WasmDecoder Decoder(Zone, &Builder, Body); LOG(out << getFlags().getDefaultGlobalPrefix() << "\n"); Decoder.Decode(); // We don't always know where the incoming branches are in phi nodes, so this // function finds them. Func->fixPhiNodes(); Func->computeInOutEdges(); return Func; } constexpr SizeT InitialBufferSize = 16 << 10; // 16KB WasmTranslator::WasmTranslator(GlobalContext *Ctx) : Translator(Ctx), Buffer(InitialBufferSize) {} void WasmTranslator::translate( const std::string &IRFilename, std::unique_ptr InputStream) { TimerMarker T(TimerStack::TT_wasm, Ctx); LOG(out << "Initializing v8/wasm stuff..." << "\n"); Zone Zone; ZoneScope _(&Zone); SizeT BytesRead = 0; while (true) { BytesRead += InputStream->GetBytes(&Buffer[BytesRead], Buffer.size() - BytesRead); LOG(out << "Read " << BytesRead << " bytes" << "\n"); if (BytesRead < Buffer.size()) break; Buffer.resize(Buffer.size() * 2); } LOG(out << "Decoding module " << IRFilename << "\n"); constexpr v8::internal::Isolate *NoIsolate = nullptr; auto Result = DecodeWasmModule(NoIsolate, &Zone, Buffer.data(), Buffer.data() + BytesRead, false, kWasmOrigin); auto Module = Result.val; LOG(out << "Module info:" << "\n"); LOG(out << " min_mem_pages: " << Module->min_mem_pages << "\n"); LOG(out << " max_mem_pages: " << Module->max_mem_pages << "\n"); LOG(out << " number of globals: " << Module->globals.size() << "\n"); LOG(out << " number of signatures: " << Module->signatures.size() << "\n"); LOG(out << " number of functions: " << Module->functions.size() << "\n"); LOG(out << " number of data_segments: " << Module->data_segments.size() << "\n"); LOG(out << " function table size: " << Module->function_table.size() << "\n"); LOG(out << " import table size: " << Module->import_table.size() << "\n"); LOG(out << " export table size: " << Module->export_table.size() << "\n"); LOG(out << "\n" << "Data segment information:" << "\n"); uint32_t Id = 0; for (const auto Seg : Module->data_segments) { LOG(out << Id << ": (" << Seg.source_offset << ", " << Seg.source_size << ") => " << Seg.dest_addr); if (Seg.init) { LOG(out << " init\n"); } else { LOG(out << "\n"); } Id++; } LOG(out << "\n" << "Import information:" << "\n"); for (const auto Import : Module->import_table) { auto ModuleName = toStdString( Module->GetName(Import.module_name_offset, Import.module_name_length)); auto FnName = toStdString(Module->GetName(Import.function_name_offset, Import.function_name_length)); LOG(out << " " << Import.sig_index << ": " << ModuleName << "::" << FnName << "\n"); } LOG(out << "\n" << "Export information:" << "\n"); for (const auto Export : Module->export_table) { LOG(out << " " << Export.func_index << ": " << toStdString( Module->GetName(Export.name_offset, Export.name_length)) << " (" << Export.name_offset << ", " << Export.name_length << ")"); LOG(out << "\n"); } LOG(out << "\n" << "Function information:" << "\n"); for (const auto F : Module->functions) { LOG(out << " " << F.func_index << ": " << toStdString(Module->GetName(F.name_offset, F.name_length)) << " (" << F.name_offset << ", " << F.name_length << ")"); if (F.exported) LOG(out << " export"); if (F.external) LOG(out << " extern"); LOG(out << "\n"); } LOG(out << "\n" << "Indirect table:" << "\n"); for (uint32_t F : Module->function_table) { LOG(out << " " << F << ": " << getFunctionName(Module, F) << "\n"); } ModuleEnv ModuleEnv; ModuleEnv.module = Module; FunctionBody Body; Body.module = &ModuleEnv; LOG(out << "Translating " << IRFilename << "\n"); { unique_ptr Globals = makeUnique(); // Global variables, etc go here. auto *WasmMemory = VariableDeclaration::createExternal(Globals.get()); WasmMemory->setName(Ctx->getGlobalString("WASM_DATA_INIT")); // Fill in the segments SizeT WritePtr = 0; for (const auto Seg : Module->data_segments) { // fill in gaps with zero. if (Seg.dest_addr > WritePtr) { WasmMemory->addInitializer(VariableDeclaration::ZeroInitializer::create( Globals.get(), Seg.dest_addr - WritePtr)); WritePtr = Seg.dest_addr; } // Add the data WasmMemory->addInitializer(VariableDeclaration::DataInitializer::create( Globals.get(), reinterpret_cast(Module->module_start) + Seg.source_offset, Seg.source_size)); WritePtr += Seg.source_size; } // Save the size of the initialized data in a global variable so the runtime // can use it to determine the initial heap break. auto *GlobalDataSize = VariableDeclaration::createExternal(Globals.get()); GlobalDataSize->setName(Ctx->getGlobalString("WASM_DATA_SIZE")); GlobalDataSize->addInitializer(VariableDeclaration::DataInitializer::create( Globals.get(), reinterpret_cast(&WritePtr), sizeof(WritePtr))); // Save the number of pages for the runtime auto *GlobalNumPages = VariableDeclaration::createExternal(Globals.get()); GlobalNumPages->setName(Ctx->getGlobalString("WASM_NUM_PAGES")); GlobalNumPages->addInitializer(VariableDeclaration::DataInitializer::create( Globals.get(), reinterpret_cast(&Module->min_mem_pages), sizeof(Module->min_mem_pages))); Globals->push_back(WasmMemory); Globals->push_back(GlobalDataSize); Globals->push_back(GlobalNumPages); lowerGlobals(std::move(Globals)); } // Translate each function. for (const auto Fn : Module->functions) { const auto FnName = getFunctionName(Module, Fn.func_index); LOG(out << " " << Fn.func_index << ": " << FnName << "..."); Body.sig = Fn.sig; Body.base = Buffer.data(); Body.start = Buffer.data() + Fn.code_start_offset; Body.end = Buffer.data() + Fn.code_end_offset; std::unique_ptr Func = nullptr; { TimerMarker T_func(getContext(), FnName); Func = translateFunction(&Zone, Body); Func->setFunctionName(Ctx->getGlobalString(FnName)); } Ctx->optQueueBlockingPush(makeUnique(std::move(Func))); LOG(out << "done.\n"); } return; } #endif // ALLOW_WASM