// Copyright 2014 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "src/v8.h" #include "src/interpreter/bytecode-array-builder.h" #include "src/interpreter/bytecode-array-iterator.h" #include "src/interpreter/bytecode-label.h" #include "src/interpreter/bytecode-register-allocator.h" #include "test/unittests/test-utils.h" namespace v8 { namespace internal { namespace interpreter { class BytecodeArrayBuilderTest : public TestWithIsolateAndZone { public: BytecodeArrayBuilderTest() {} ~BytecodeArrayBuilderTest() override {} }; TEST_F(BytecodeArrayBuilderTest, AllBytecodesGenerated) { CanonicalHandleScope canonical(isolate()); BytecodeArrayBuilder builder(isolate(), zone(), 0, 1, 131); Factory* factory = isolate()->factory(); CHECK_EQ(builder.locals_count(), 131); CHECK_EQ(builder.context_count(), 1); CHECK_EQ(builder.fixed_register_count(), 132); Register reg(0); Register other(reg.index() + 1); Register wide(128); RegisterList reg_list; RegisterList pair(0, 2), triple(0, 3); // Emit argument creation operations. builder.CreateArguments(CreateArgumentsType::kMappedArguments) .CreateArguments(CreateArgumentsType::kUnmappedArguments) .CreateArguments(CreateArgumentsType::kRestParameter); // Emit constant loads. builder.LoadLiteral(Smi::kZero) .StoreAccumulatorInRegister(reg) .LoadLiteral(Smi::FromInt(8)) .CompareOperation(Token::Value::NE, reg, 1) // Prevent peephole optimization // LdaSmi, Star -> LdrSmi. .StoreAccumulatorInRegister(reg) .LoadLiteral(Smi::FromInt(10000000)) .StoreAccumulatorInRegister(reg) .LoadLiteral(factory->NewStringFromStaticChars("A constant")) .StoreAccumulatorInRegister(reg) .LoadUndefined() .StoreAccumulatorInRegister(reg) .LoadNull() .StoreAccumulatorInRegister(reg) .LoadTheHole() .StoreAccumulatorInRegister(reg) .LoadTrue() .StoreAccumulatorInRegister(reg) .LoadFalse() .StoreAccumulatorInRegister(wide); // Emit Ldar and Star taking care to foil the register optimizer. builder.StackCheck(0) .LoadAccumulatorWithRegister(other) .BinaryOperation(Token::ADD, reg, 1) .StoreAccumulatorInRegister(reg) .LoadNull(); // Emit register-register transfer. builder.MoveRegister(reg, other); builder.MoveRegister(reg, wide); // Emit global load / store operations. Handle name = factory->NewStringFromStaticChars("var_name"); builder.LoadGlobal(name, 1, TypeofMode::NOT_INSIDE_TYPEOF) .LoadGlobal(name, 1, TypeofMode::INSIDE_TYPEOF) .StoreGlobal(name, 1, LanguageMode::SLOPPY) .StoreGlobal(name, 1, LanguageMode::STRICT); // Emit context operations. builder.PushContext(reg) .PopContext(reg) .LoadContextSlot(reg, 1, 0) .StoreContextSlot(reg, 1, 0); // Emit context operations which operate on the local context. builder.LoadContextSlot(Register::current_context(), 1, 0) .StoreContextSlot(Register::current_context(), 1, 0); // Emit load / store property operations. builder.LoadNamedProperty(reg, name, 0) .LoadKeyedProperty(reg, 0) .StoreNamedProperty(reg, name, 0, LanguageMode::SLOPPY) .StoreKeyedProperty(reg, reg, 0, LanguageMode::SLOPPY) .StoreNamedProperty(reg, name, 0, LanguageMode::STRICT) .StoreKeyedProperty(reg, reg, 0, LanguageMode::STRICT); // Emit load / store lookup slots. builder.LoadLookupSlot(name, TypeofMode::NOT_INSIDE_TYPEOF) .LoadLookupSlot(name, TypeofMode::INSIDE_TYPEOF) .StoreLookupSlot(name, LanguageMode::SLOPPY) .StoreLookupSlot(name, LanguageMode::STRICT); // Emit load / store lookup slots with context fast paths. builder.LoadLookupContextSlot(name, TypeofMode::NOT_INSIDE_TYPEOF, 1, 0) .LoadLookupContextSlot(name, TypeofMode::INSIDE_TYPEOF, 1, 0); // Emit load / store lookup slots with global fast paths. builder.LoadLookupGlobalSlot(name, TypeofMode::NOT_INSIDE_TYPEOF, 1, 0) .LoadLookupGlobalSlot(name, TypeofMode::INSIDE_TYPEOF, 1, 0); // Emit closure operations. builder.CreateClosure(0, NOT_TENURED); // Emit create context operation. builder.CreateBlockContext(factory->NewScopeInfo(1)); builder.CreateCatchContext(reg, name, factory->NewScopeInfo(1)); builder.CreateFunctionContext(1); builder.CreateEvalContext(1); builder.CreateWithContext(reg, factory->NewScopeInfo(1)); // Emit literal creation operations. builder.CreateRegExpLiteral(factory->NewStringFromStaticChars("a"), 0, 0) .CreateArrayLiteral(factory->NewConstantElementsPair( FAST_ELEMENTS, factory->empty_fixed_array()), 0, 0) .CreateObjectLiteral(factory->NewFixedArray(1), 0, 0, reg); // Call operations. builder.Call(reg, reg_list, 1, Call::GLOBAL_CALL) .Call(reg, reg_list, 1, Call::NAMED_PROPERTY_CALL, TailCallMode::kDisallow) .Call(reg, reg_list, 1, Call::GLOBAL_CALL, TailCallMode::kAllow) .CallRuntime(Runtime::kIsArray, reg) .CallRuntimeForPair(Runtime::kLoadLookupSlotForCall, reg_list, pair) .CallJSRuntime(Context::SPREAD_ITERABLE_INDEX, reg_list) .NewWithSpread(reg_list); // Emit binary operator invocations. builder.BinaryOperation(Token::Value::ADD, reg, 1) .BinaryOperation(Token::Value::SUB, reg, 2) .BinaryOperation(Token::Value::MUL, reg, 3) .BinaryOperation(Token::Value::DIV, reg, 4) .BinaryOperation(Token::Value::MOD, reg, 5); // Emit bitwise operator invocations builder.BinaryOperation(Token::Value::BIT_OR, reg, 6) .BinaryOperation(Token::Value::BIT_XOR, reg, 7) .BinaryOperation(Token::Value::BIT_AND, reg, 8); // Emit shift operator invocations builder.BinaryOperation(Token::Value::SHL, reg, 9) .BinaryOperation(Token::Value::SAR, reg, 10) .BinaryOperation(Token::Value::SHR, reg, 11); // Emit peephole optimizations of LdaSmi followed by binary operation. builder.LoadLiteral(Smi::FromInt(1)) .BinaryOperation(Token::Value::ADD, reg, 1) .LoadLiteral(Smi::FromInt(2)) .BinaryOperation(Token::Value::SUB, reg, 2) .LoadLiteral(Smi::FromInt(3)) .BinaryOperation(Token::Value::BIT_AND, reg, 3) .LoadLiteral(Smi::FromInt(4)) .BinaryOperation(Token::Value::BIT_OR, reg, 4) .LoadLiteral(Smi::FromInt(5)) .BinaryOperation(Token::Value::SHL, reg, 5) .LoadLiteral(Smi::FromInt(6)) .BinaryOperation(Token::Value::SAR, reg, 6); // Emit count operatior invocations builder.CountOperation(Token::Value::ADD, 1) .CountOperation(Token::Value::SUB, 1); // Emit unary operator invocations. builder .LogicalNot() // ToBooleanLogicalNot .LogicalNot() // non-ToBoolean LogicalNot .TypeOf(); // Emit delete builder.Delete(reg, LanguageMode::SLOPPY).Delete(reg, LanguageMode::STRICT); // Emit new. builder.New(reg, reg_list, 1); // Emit test operator invocations. builder.CompareOperation(Token::Value::EQ, reg, 1) .CompareOperation(Token::Value::NE, reg, 2) .CompareOperation(Token::Value::EQ_STRICT, reg, 3) .CompareOperation(Token::Value::LT, reg, 4) .CompareOperation(Token::Value::GT, reg, 5) .CompareOperation(Token::Value::LTE, reg, 6) .CompareOperation(Token::Value::GTE, reg, 7) .CompareOperation(Token::Value::INSTANCEOF, reg, 8) .CompareOperation(Token::Value::IN, reg, 9); // Emit peephole optimizations of equality with Null or Undefined. builder.LoadUndefined() .CompareOperation(Token::Value::EQ, reg, 1) .LoadNull() .CompareOperation(Token::Value::EQ, reg, 1) .LoadUndefined() .CompareOperation(Token::Value::EQ_STRICT, reg, 1) .LoadNull() .CompareOperation(Token::Value::EQ_STRICT, reg, 1); // Emit conversion operator invocations. builder.ConvertAccumulatorToNumber(reg) .ConvertAccumulatorToObject(reg) .ConvertAccumulatorToName(reg); // Emit GetSuperConstructor. builder.GetSuperConstructor(reg); // Short jumps with Imm8 operands { BytecodeLabel start, after_jump1, after_jump2, after_jump3, after_jump4, after_jump5; builder.Bind(&start) .Jump(&after_jump1) .Bind(&after_jump1) .JumpIfNull(&after_jump2) .Bind(&after_jump2) .JumpIfUndefined(&after_jump3) .Bind(&after_jump3) .JumpIfNotHole(&after_jump4) .Bind(&after_jump4) .JumpIfJSReceiver(&after_jump5) .Bind(&after_jump5) .JumpLoop(&start, 0); } // Longer jumps with constant operands BytecodeLabel end[9]; { BytecodeLabel after_jump; builder.Jump(&end[0]) .Bind(&after_jump) .LoadTrue() .JumpIfTrue(&end[1]) .LoadTrue() .JumpIfFalse(&end[2]) .LoadLiteral(Smi::kZero) .JumpIfTrue(&end[3]) .LoadLiteral(Smi::kZero) .JumpIfFalse(&end[4]) .JumpIfNull(&end[5]) .JumpIfUndefined(&end[6]) .JumpIfNotHole(&end[7]) .LoadLiteral(factory->prototype_string()) .JumpIfJSReceiver(&end[8]); } // Perform an operation that returns boolean value to // generate JumpIfTrue/False { BytecodeLabel after_jump1, after_jump2; builder.CompareOperation(Token::Value::EQ, reg, 1) .JumpIfTrue(&after_jump1) .Bind(&after_jump1) .CompareOperation(Token::Value::EQ, reg, 2) .JumpIfFalse(&after_jump2) .Bind(&after_jump2); } // Perform an operation that returns a non-boolean operation to // generate JumpIfToBooleanTrue/False. { BytecodeLabel after_jump1, after_jump2; builder.BinaryOperation(Token::Value::ADD, reg, 1) .JumpIfTrue(&after_jump1) .Bind(&after_jump1) .BinaryOperation(Token::Value::ADD, reg, 2) .JumpIfFalse(&after_jump2) .Bind(&after_jump2); } // Emit set pending message bytecode. builder.SetPendingMessage(); // Emit stack check bytecode. builder.StackCheck(0); // Emit throw and re-throw in it's own basic block so that the rest of the // code isn't omitted due to being dead. BytecodeLabel after_throw; builder.Throw().Bind(&after_throw); BytecodeLabel after_rethrow; builder.ReThrow().Bind(&after_rethrow); builder.ForInPrepare(reg, triple) .ForInContinue(reg, reg) .ForInNext(reg, reg, pair, 1) .ForInStep(reg); // Wide constant pool loads for (int i = 0; i < 256; i++) { // Emit junk in constant pool to force wide constant pool index. builder.LoadLiteral(factory->NewNumber(2.5321 + i)); } builder.LoadLiteral(Smi::FromInt(20000000)); Handle wide_name = factory->NewStringFromStaticChars("var_wide_name"); // Emit wide global load / store operations. builder.LoadGlobal(name, 1024, TypeofMode::NOT_INSIDE_TYPEOF) .LoadGlobal(name, 1024, TypeofMode::INSIDE_TYPEOF) .LoadGlobal(name, 1024, TypeofMode::INSIDE_TYPEOF) .StoreGlobal(name, 1024, LanguageMode::SLOPPY) .StoreGlobal(wide_name, 1, LanguageMode::STRICT); // Emit extra wide global load. builder.LoadGlobal(name, 1024 * 1024, TypeofMode::NOT_INSIDE_TYPEOF); // Emit wide load / store property operations. builder.LoadNamedProperty(reg, wide_name, 0) .LoadKeyedProperty(reg, 2056) .StoreNamedProperty(reg, wide_name, 0, LanguageMode::SLOPPY) .StoreKeyedProperty(reg, reg, 2056, LanguageMode::SLOPPY) .StoreNamedProperty(reg, wide_name, 0, LanguageMode::STRICT) .StoreKeyedProperty(reg, reg, 2056, LanguageMode::STRICT); builder.StoreDataPropertyInLiteral(reg, reg, reg, DataPropertyInLiteralFlag::kNoFlags); // Emit wide context operations. builder.LoadContextSlot(reg, 1024, 0).StoreContextSlot(reg, 1024, 0); // Emit wide load / store lookup slots. builder.LoadLookupSlot(wide_name, TypeofMode::NOT_INSIDE_TYPEOF) .LoadLookupSlot(wide_name, TypeofMode::INSIDE_TYPEOF) .StoreLookupSlot(wide_name, LanguageMode::SLOPPY) .StoreLookupSlot(wide_name, LanguageMode::STRICT); // CreateClosureWide builder.CreateClosure(1000, NOT_TENURED); // Emit wide variant of literal creation operations. builder .CreateRegExpLiteral(factory->NewStringFromStaticChars("wide_literal"), 0, 0) .CreateArrayLiteral(factory->NewConstantElementsPair( FAST_ELEMENTS, factory->empty_fixed_array()), 0, 0) .CreateObjectLiteral(factory->NewFixedArray(2), 0, 0, reg); // Emit load and store operations for module variables. builder.LoadModuleVariable(-1, 42) .LoadModuleVariable(0, 42) .LoadModuleVariable(1, 42) .StoreModuleVariable(-1, 42) .StoreModuleVariable(0, 42) .StoreModuleVariable(1, 42); // Emit generator operations. builder.SuspendGenerator(reg) .ResumeGenerator(reg); // Intrinsics handled by the interpreter. builder.CallRuntime(Runtime::kInlineIsArray, reg_list); // Emit debugger bytecode. builder.Debugger(); // Insert dummy ops to force longer jumps. for (int i = 0; i < 128; i++) { builder.LoadTrue(); } // Bind labels for long jumps at the very end. for (size_t i = 0; i < arraysize(end); i++) { builder.Bind(&end[i]); } // Return must be the last instruction. builder.Return(); // Generate BytecodeArray. Handle the_array = builder.ToBytecodeArray(isolate()); CHECK_EQ(the_array->frame_size(), builder.total_register_count() * kPointerSize); // Build scorecard of bytecodes encountered in the BytecodeArray. std::vector scorecard(Bytecodes::ToByte(Bytecode::kLast) + 1); Bytecode final_bytecode = Bytecode::kLdaZero; int i = 0; while (i < the_array->length()) { uint8_t code = the_array->get(i); scorecard[code] += 1; final_bytecode = Bytecodes::FromByte(code); OperandScale operand_scale = OperandScale::kSingle; int prefix_offset = 0; if (Bytecodes::IsPrefixScalingBytecode(final_bytecode)) { operand_scale = Bytecodes::PrefixBytecodeToOperandScale(final_bytecode); prefix_offset = 1; code = the_array->get(i + 1); final_bytecode = Bytecodes::FromByte(code); } i += prefix_offset + Bytecodes::Size(final_bytecode, operand_scale); } // Insert entry for illegal bytecode as this is never willingly emitted. scorecard[Bytecodes::ToByte(Bytecode::kIllegal)] = 1; // Insert entry for nop bytecode as this often gets optimized out. scorecard[Bytecodes::ToByte(Bytecode::kNop)] = 1; if (!FLAG_ignition_peephole) { // Insert entries for bytecodes only emitted by peephole optimizer. scorecard[Bytecodes::ToByte(Bytecode::kLogicalNot)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kJump)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kJumpIfTrue)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kJumpIfFalse)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kJumpIfTrueConstant)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kJumpIfFalseConstant)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kAddSmi)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kSubSmi)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kBitwiseAndSmi)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kBitwiseOrSmi)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kShiftLeftSmi)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kShiftRightSmi)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kTestUndetectable)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kTestUndefined)] = 1; scorecard[Bytecodes::ToByte(Bytecode::kTestNull)] = 1; } // Check return occurs at the end and only once in the BytecodeArray. CHECK_EQ(final_bytecode, Bytecode::kReturn); CHECK_EQ(scorecard[Bytecodes::ToByte(final_bytecode)], 1); #define CHECK_BYTECODE_PRESENT(Name, ...) \ /* Check Bytecode is marked in scorecard, unless it's a debug break */ \ if (!Bytecodes::IsDebugBreak(Bytecode::k##Name)) { \ CHECK_GE(scorecard[Bytecodes::ToByte(Bytecode::k##Name)], 1); \ } BYTECODE_LIST(CHECK_BYTECODE_PRESENT) #undef CHECK_BYTECODE_PRESENT } TEST_F(BytecodeArrayBuilderTest, FrameSizesLookGood) { CanonicalHandleScope canonical(isolate()); for (int locals = 0; locals < 5; locals++) { for (int contexts = 0; contexts < 4; contexts++) { for (int temps = 0; temps < 3; temps++) { BytecodeArrayBuilder builder(isolate(), zone(), 0, contexts, locals); BytecodeRegisterAllocator* allocator(builder.register_allocator()); for (int i = 0; i < locals + contexts; i++) { builder.LoadLiteral(Smi::kZero); builder.StoreAccumulatorInRegister(Register(i)); } for (int i = 0; i < temps; i++) { Register temp = allocator->NewRegister(); builder.LoadLiteral(Smi::kZero); builder.StoreAccumulatorInRegister(temp); // Ensure temporaries are used so not optimized away by the // register optimizer. builder.ConvertAccumulatorToName(temp); } builder.Return(); Handle the_array = builder.ToBytecodeArray(isolate()); int total_registers = locals + contexts + temps; CHECK_EQ(the_array->frame_size(), total_registers * kPointerSize); } } } } TEST_F(BytecodeArrayBuilderTest, RegisterValues) { CanonicalHandleScope canonical(isolate()); int index = 1; Register the_register(index); CHECK_EQ(the_register.index(), index); int actual_operand = the_register.ToOperand(); int actual_index = Register::FromOperand(actual_operand).index(); CHECK_EQ(actual_index, index); } TEST_F(BytecodeArrayBuilderTest, Parameters) { CanonicalHandleScope canonical(isolate()); BytecodeArrayBuilder builder(isolate(), zone(), 10, 0, 0); Register param0(builder.Parameter(0)); Register param9(builder.Parameter(9)); CHECK_EQ(param9.index() - param0.index(), 9); } TEST_F(BytecodeArrayBuilderTest, Constants) { CanonicalHandleScope canonical(isolate()); BytecodeArrayBuilder builder(isolate(), zone(), 0, 0, 0); Factory* factory = isolate()->factory(); Handle heap_num_1 = factory->NewHeapNumber(3.14); Handle heap_num_2 = factory->NewHeapNumber(5.2); Handle large_smi(Smi::FromInt(0x12345678), isolate()); Handle heap_num_2_copy(*heap_num_2); builder.LoadLiteral(heap_num_1) .LoadLiteral(heap_num_2) .LoadLiteral(large_smi) .LoadLiteral(heap_num_1) .LoadLiteral(heap_num_1) .LoadLiteral(heap_num_2_copy) .Return(); Handle array = builder.ToBytecodeArray(isolate()); // Should only have one entry for each identical constant. CHECK_EQ(array->constant_pool()->length(), 3); } static Bytecode PeepholeToBoolean(Bytecode jump_bytecode) { return FLAG_ignition_peephole ? Bytecodes::GetJumpWithoutToBoolean(jump_bytecode) : jump_bytecode; } TEST_F(BytecodeArrayBuilderTest, ForwardJumps) { CanonicalHandleScope canonical(isolate()); static const int kFarJumpDistance = 256; BytecodeArrayBuilder builder(isolate(), zone(), 0, 0, 1); Register reg(0); BytecodeLabel far0, far1, far2, far3, far4; BytecodeLabel near0, near1, near2, near3, near4; BytecodeLabel after_jump0, after_jump1; builder.Jump(&near0) .Bind(&after_jump0) .CompareOperation(Token::Value::EQ, reg, 1) .JumpIfTrue(&near1) .CompareOperation(Token::Value::EQ, reg, 2) .JumpIfFalse(&near2) .BinaryOperation(Token::Value::ADD, reg, 1) .JumpIfTrue(&near3) .BinaryOperation(Token::Value::ADD, reg, 2) .JumpIfFalse(&near4) .Bind(&near0) .Bind(&near1) .Bind(&near2) .Bind(&near3) .Bind(&near4) .Jump(&far0) .Bind(&after_jump1) .CompareOperation(Token::Value::EQ, reg, 3) .JumpIfTrue(&far1) .CompareOperation(Token::Value::EQ, reg, 4) .JumpIfFalse(&far2) .BinaryOperation(Token::Value::ADD, reg, 3) .JumpIfTrue(&far3) .BinaryOperation(Token::Value::ADD, reg, 4) .JumpIfFalse(&far4); for (int i = 0; i < kFarJumpDistance - 22; i++) { builder.Debugger(); } builder.Bind(&far0).Bind(&far1).Bind(&far2).Bind(&far3).Bind(&far4); builder.Return(); Handle array = builder.ToBytecodeArray(isolate()); DCHECK_EQ(array->length(), 44 + kFarJumpDistance - 22 + 1); BytecodeArrayIterator iterator(array); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJump); CHECK_EQ(iterator.GetImmediateOperand(0), 22); iterator.Advance(); // Ignore compare operation. iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), PeepholeToBoolean(Bytecode::kJumpIfToBooleanTrue)); CHECK_EQ(iterator.GetImmediateOperand(0), 17); iterator.Advance(); // Ignore compare operation. iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), PeepholeToBoolean(Bytecode::kJumpIfToBooleanFalse)); CHECK_EQ(iterator.GetImmediateOperand(0), 12); iterator.Advance(); // Ignore add operation. iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpIfToBooleanTrue); CHECK_EQ(iterator.GetImmediateOperand(0), 7); iterator.Advance(); // Ignore add operation. iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpIfToBooleanFalse); CHECK_EQ(iterator.GetImmediateOperand(0), 2); iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpConstant); CHECK_EQ(*iterator.GetConstantForIndexOperand(0), Smi::FromInt(kFarJumpDistance)); iterator.Advance(); // Ignore compare operation. iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), PeepholeToBoolean(Bytecode::kJumpIfToBooleanTrueConstant)); CHECK_EQ(*iterator.GetConstantForIndexOperand(0), Smi::FromInt(kFarJumpDistance - 5)); iterator.Advance(); // Ignore compare operation. iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), PeepholeToBoolean(Bytecode::kJumpIfToBooleanFalseConstant)); CHECK_EQ(*iterator.GetConstantForIndexOperand(0), Smi::FromInt(kFarJumpDistance - 10)); iterator.Advance(); // Ignore add operation. iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpIfToBooleanTrueConstant); CHECK_EQ(*iterator.GetConstantForIndexOperand(0), Smi::FromInt(kFarJumpDistance - 15)); iterator.Advance(); // Ignore add operation. iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpIfToBooleanFalseConstant); CHECK_EQ(*iterator.GetConstantForIndexOperand(0), Smi::FromInt(kFarJumpDistance - 20)); iterator.Advance(); } TEST_F(BytecodeArrayBuilderTest, BackwardJumps) { CanonicalHandleScope canonical(isolate()); BytecodeArrayBuilder builder(isolate(), zone(), 0, 0, 1); Register reg(0); BytecodeLabel label0; builder.Bind(&label0).JumpLoop(&label0, 0); for (int i = 0; i < 42; i++) { BytecodeLabel after_jump; builder.JumpLoop(&label0, 0).Bind(&after_jump); } // Add padding to force wide backwards jumps. for (int i = 0; i < 256; i++) { builder.Debugger(); } builder.JumpLoop(&label0, 0); BytecodeLabel end; builder.Bind(&end); builder.Return(); Handle array = builder.ToBytecodeArray(isolate()); BytecodeArrayIterator iterator(array); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpLoop); CHECK_EQ(iterator.GetImmediateOperand(0), 0); iterator.Advance(); for (int i = 0; i < 42; i++) { CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpLoop); CHECK_EQ(iterator.current_operand_scale(), OperandScale::kSingle); // offset of 3 (because kJumpLoop takes two immediate operands) CHECK_EQ(iterator.GetImmediateOperand(0), -i * 3 - 3); iterator.Advance(); } // Check padding to force wide backwards jumps. for (int i = 0; i < 256; i++) { CHECK_EQ(iterator.current_bytecode(), Bytecode::kDebugger); iterator.Advance(); } CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpLoop); CHECK_EQ(iterator.current_operand_scale(), OperandScale::kDouble); CHECK_EQ(iterator.GetImmediateOperand(0), -386); iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kReturn); iterator.Advance(); CHECK(iterator.done()); } TEST_F(BytecodeArrayBuilderTest, LabelReuse) { CanonicalHandleScope canonical(isolate()); BytecodeArrayBuilder builder(isolate(), zone(), 0, 0, 0); // Labels can only have 1 forward reference, but // can be referred to mulitple times once bound. BytecodeLabel label, after_jump0, after_jump1; builder.Jump(&label) .Bind(&label) .JumpLoop(&label, 0) .Bind(&after_jump0) .JumpLoop(&label, 0) .Bind(&after_jump1) .Return(); Handle array = builder.ToBytecodeArray(isolate()); BytecodeArrayIterator iterator(array); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJump); CHECK_EQ(iterator.GetImmediateOperand(0), 2); iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpLoop); CHECK_EQ(iterator.GetImmediateOperand(0), 0); iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpLoop); CHECK_EQ(iterator.GetImmediateOperand(0), -3); iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kReturn); iterator.Advance(); CHECK(iterator.done()); } TEST_F(BytecodeArrayBuilderTest, LabelAddressReuse) { CanonicalHandleScope canonical(isolate()); static const int kRepeats = 3; BytecodeArrayBuilder builder(isolate(), zone(), 0, 0, 0); for (int i = 0; i < kRepeats; i++) { BytecodeLabel label, after_jump0, after_jump1; builder.Jump(&label) .Bind(&label) .JumpLoop(&label, 0) .Bind(&after_jump0) .JumpLoop(&label, 0) .Bind(&after_jump1); } builder.Return(); Handle array = builder.ToBytecodeArray(isolate()); BytecodeArrayIterator iterator(array); for (int i = 0; i < kRepeats; i++) { CHECK_EQ(iterator.current_bytecode(), Bytecode::kJump); CHECK_EQ(iterator.GetImmediateOperand(0), 2); iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpLoop); CHECK_EQ(iterator.GetImmediateOperand(0), 0); iterator.Advance(); CHECK_EQ(iterator.current_bytecode(), Bytecode::kJumpLoop); CHECK_EQ(iterator.GetImmediateOperand(0), -3); iterator.Advance(); } CHECK_EQ(iterator.current_bytecode(), Bytecode::kReturn); iterator.Advance(); CHECK(iterator.done()); } } // namespace interpreter } // namespace internal } // namespace v8