// Copyright 2016 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/api.h" #include "src/factory.h" #include "src/interpreter/bytecode-array-writer.h" #include "src/interpreter/bytecode-label.h" #include "src/interpreter/constant-array-builder.h" #include "src/isolate.h" #include "src/source-position-table.h" #include "src/utils.h" #include "test/unittests/interpreter/bytecode-utils.h" #include "test/unittests/test-utils.h" namespace v8 { namespace internal { namespace interpreter { class BytecodeArrayWriterUnittest : public TestWithIsolateAndZone { public: BytecodeArrayWriterUnittest() : constant_array_builder_(zone(), isolate()->factory()->the_hole_value()), bytecode_array_writer_( zone(), &constant_array_builder_, SourcePositionTableBuilder::RECORD_SOURCE_POSITIONS) {} ~BytecodeArrayWriterUnittest() override {} void Write(BytecodeNode* node, const BytecodeSourceInfo& info); void Write(Bytecode bytecode, const BytecodeSourceInfo& info = BytecodeSourceInfo()); void Write(Bytecode bytecode, uint32_t operand0, const BytecodeSourceInfo& info = BytecodeSourceInfo()); void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1, const BytecodeSourceInfo& info = BytecodeSourceInfo()); void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1, uint32_t operand2, const BytecodeSourceInfo& info = BytecodeSourceInfo()); void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1, uint32_t operand2, uint32_t operand3, const BytecodeSourceInfo& info = BytecodeSourceInfo()); void WriteJump(Bytecode bytecode, BytecodeLabel* label, const BytecodeSourceInfo& info = BytecodeSourceInfo()); BytecodeArrayWriter* writer() { return &bytecode_array_writer_; } ZoneVector* bytecodes() { return writer()->bytecodes(); } SourcePositionTableBuilder* source_position_table_builder() { return writer()->source_position_table_builder(); } int max_register_count() { return writer()->max_register_count(); } private: ConstantArrayBuilder constant_array_builder_; BytecodeArrayWriter bytecode_array_writer_; }; void BytecodeArrayWriterUnittest::Write(BytecodeNode* node, const BytecodeSourceInfo& info) { if (info.is_valid()) { node->source_info().Clone(info); } writer()->Write(node); } void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, const BytecodeSourceInfo& info) { BytecodeNode node(bytecode); Write(&node, info); } void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0, const BytecodeSourceInfo& info) { BytecodeNode node(bytecode, operand0); Write(&node, info); } void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1, const BytecodeSourceInfo& info) { BytecodeNode node(bytecode, operand0, operand1); Write(&node, info); } void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1, uint32_t operand2, const BytecodeSourceInfo& info) { BytecodeNode node(bytecode, operand0, operand1, operand2); Write(&node, info); } void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1, uint32_t operand2, uint32_t operand3, const BytecodeSourceInfo& info) { BytecodeNode node(bytecode, operand0, operand1, operand2, operand3); Write(&node, info); } void BytecodeArrayWriterUnittest::WriteJump(Bytecode bytecode, BytecodeLabel* label, const BytecodeSourceInfo& info) { BytecodeNode node(bytecode, 0); if (info.is_valid()) { node.source_info().Clone(info); } writer()->WriteJump(&node, label); } TEST_F(BytecodeArrayWriterUnittest, SimpleExample) { CHECK_EQ(bytecodes()->size(), 0); Write(Bytecode::kStackCheck, {10, false}); CHECK_EQ(bytecodes()->size(), 1); CHECK_EQ(max_register_count(), 0); Write(Bytecode::kLdaSmi, 127, {55, true}); CHECK_EQ(bytecodes()->size(), 3); CHECK_EQ(max_register_count(), 0); Write(Bytecode::kLdar, Register(200).ToOperand()); CHECK_EQ(bytecodes()->size(), 7); CHECK_EQ(max_register_count(), 201); Write(Bytecode::kReturn, {70, true}); CHECK_EQ(bytecodes()->size(), 8); CHECK_EQ(max_register_count(), 201); static const uint8_t bytes[] = {B(StackCheck), B(LdaSmi), U8(127), B(Wide), B(Ldar), R16(200), B(Return)}; CHECK_EQ(bytecodes()->size(), arraysize(bytes)); for (size_t i = 0; i < arraysize(bytes); ++i) { CHECK_EQ(bytecodes()->at(i), bytes[i]); } Handle bytecode_array = writer()->ToBytecodeArray( isolate(), 0, 0, factory()->empty_fixed_array()); CHECK_EQ(bytecodes()->size(), arraysize(bytes)); PositionTableEntry expected_positions[] = { {0, 10, false}, {1, 55, true}, {7, 70, true}}; SourcePositionTableIterator source_iterator( bytecode_array->source_position_table()); for (size_t i = 0; i < arraysize(expected_positions); ++i) { const PositionTableEntry& expected = expected_positions[i]; CHECK_EQ(source_iterator.code_offset(), expected.code_offset); CHECK_EQ(source_iterator.source_position(), expected.source_position); CHECK_EQ(source_iterator.is_statement(), expected.is_statement); source_iterator.Advance(); } CHECK(source_iterator.done()); } TEST_F(BytecodeArrayWriterUnittest, ComplexExample) { static const uint8_t expected_bytes[] = { // clang-format off /* 0 30 E> */ B(StackCheck), /* 1 42 S> */ B(LdaConstant), U8(0), /* 3 42 E> */ B(Star), R8(1), /* 5 68 S> */ B(JumpIfUndefined), U8(38), /* 7 */ B(JumpIfNull), U8(36), /* 9 */ B(ToObject), R8(3), /* 11 */ B(ForInPrepare), R8(3), R8(4), /* 14 */ B(LdaZero), /* 15 */ B(Star), R8(7), /* 17 63 S> */ B(ForInContinue), R8(7), R8(6), /* 20 */ B(JumpIfFalse), U8(23), /* 22 */ B(ForInNext), R8(3), R8(7), R8(4), U8(1), /* 27 */ B(JumpIfUndefined), U8(10), /* 29 */ B(Star), R8(0), /* 31 54 E> */ B(StackCheck), /* 32 */ B(Ldar), R8(0), /* 34 */ B(Star), R8(2), /* 36 85 S> */ B(Return), /* 37 */ B(ForInStep), R8(7), /* 39 */ B(Star), R8(7), /* 41 */ B(Jump), U8(-24), /* 43 */ B(LdaUndefined), /* 44 85 S> */ B(Return), // clang-format on }; static const PositionTableEntry expected_positions[] = { {0, 30, false}, {1, 42, true}, {3, 42, false}, {5, 68, true}, {17, 63, true}, {31, 54, false}, {36, 85, true}, {44, 85, true}}; BytecodeLabel back_jump, jump_for_in, jump_end_1, jump_end_2, jump_end_3; #define R(i) static_cast(Register(i).ToOperand()) Write(Bytecode::kStackCheck, {30, false}); Write(Bytecode::kLdaConstant, U8(0), {42, true}); CHECK_EQ(max_register_count(), 0); Write(Bytecode::kStar, R(1), {42, false}); CHECK_EQ(max_register_count(), 2); WriteJump(Bytecode::kJumpIfUndefined, &jump_end_1, {68, true}); WriteJump(Bytecode::kJumpIfNull, &jump_end_2); Write(Bytecode::kToObject, R(3)); CHECK_EQ(max_register_count(), 4); Write(Bytecode::kForInPrepare, R(3), R(4)); CHECK_EQ(max_register_count(), 7); Write(Bytecode::kLdaZero); CHECK_EQ(max_register_count(), 7); Write(Bytecode::kStar, R(7)); CHECK_EQ(max_register_count(), 8); writer()->BindLabel(&back_jump); Write(Bytecode::kForInContinue, R(7), R(6), {63, true}); CHECK_EQ(max_register_count(), 8); WriteJump(Bytecode::kJumpIfFalse, &jump_end_3); Write(Bytecode::kForInNext, R(3), R(7), R(4), U8(1)); WriteJump(Bytecode::kJumpIfUndefined, &jump_for_in); Write(Bytecode::kStar, R(0)); Write(Bytecode::kStackCheck, {54, false}); Write(Bytecode::kLdar, R(0)); Write(Bytecode::kStar, R(2)); Write(Bytecode::kReturn, {85, true}); writer()->BindLabel(&jump_for_in); Write(Bytecode::kForInStep, R(7)); Write(Bytecode::kStar, R(7)); WriteJump(Bytecode::kJump, &back_jump); writer()->BindLabel(&jump_end_1); writer()->BindLabel(&jump_end_2); writer()->BindLabel(&jump_end_3); Write(Bytecode::kLdaUndefined); Write(Bytecode::kReturn, {85, true}); CHECK_EQ(max_register_count(), 8); #undef R CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes)); for (size_t i = 0; i < arraysize(expected_bytes); ++i) { CHECK_EQ(static_cast(bytecodes()->at(i)), static_cast(expected_bytes[i])); } Handle bytecode_array = writer()->ToBytecodeArray( isolate(), 0, 0, factory()->empty_fixed_array()); SourcePositionTableIterator source_iterator( bytecode_array->source_position_table()); for (size_t i = 0; i < arraysize(expected_positions); ++i) { const PositionTableEntry& expected = expected_positions[i]; CHECK_EQ(source_iterator.code_offset(), expected.code_offset); CHECK_EQ(source_iterator.source_position(), expected.source_position); CHECK_EQ(source_iterator.is_statement(), expected.is_statement); source_iterator.Advance(); } CHECK(source_iterator.done()); } } // namespace interpreter } // namespace internal } // namespace v8