src/third_party/v8/test/unittests/interpreter/bytecode-array-writer-unittest.cc - cobalt - Git at Google

 // 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/init/v8.h"

 #include "src/api/api.h"
 #include "src/codegen/source-position-table.h"
 #include "src/execution/isolate.h"
 #include "src/heap/factory.h"
 #include "src/interpreter/bytecode-array-writer.h"
 #include "src/interpreter/bytecode-label.h"
 #include "src/interpreter/bytecode-node.h"
 #include "src/interpreter/bytecode-register.h"
 #include "src/interpreter/bytecode-source-info.h"
 #include "src/interpreter/constant-array-builder.h"
 #include "src/utils/utils.h"
 #include "src/objects/objects-inl.h"
 #include "test/unittests/interpreter/bytecode-utils.h"
 #include "test/unittests/test-utils.h"

 namespace v8 {
 namespace internal {
 namespace interpreter {
 namespace bytecode_array_writer_unittest {

 #define B(Name) static_cast<uint8_t>(Bytecode::k##Name)
 #define R(i) static_cast<uint32_t>(Register(i).ToOperand())

 class BytecodeArrayWriterUnittest : public TestWithIsolateAndZone {
  public:
   BytecodeArrayWriterUnittest()
       : constant_array_builder_(zone()),
         bytecode_array_writer_(
             zone(), &constant_array_builder_,
             SourcePositionTableBuilder::RECORD_SOURCE_POSITIONS) {}
   ~BytecodeArrayWriterUnittest() override = default;

   void Write(Bytecode bytecode, BytecodeSourceInfo info = BytecodeSourceInfo());
   void Write(Bytecode bytecode, uint32_t operand0,
              BytecodeSourceInfo info = BytecodeSourceInfo());
   void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
              BytecodeSourceInfo info = BytecodeSourceInfo());
   void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
              uint32_t operand2, BytecodeSourceInfo info = BytecodeSourceInfo());
   void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
              uint32_t operand2, uint32_t operand3,
              BytecodeSourceInfo info = BytecodeSourceInfo());

   void WriteJump(Bytecode bytecode, BytecodeLabel* label,
                  BytecodeSourceInfo info = BytecodeSourceInfo());
   void WriteJumpLoop(Bytecode bytecode, BytecodeLoopHeader* loop_header,
                      int depth, BytecodeSourceInfo info = BytecodeSourceInfo());

   BytecodeArrayWriter* writer() { return &bytecode_array_writer_; }
   ZoneVector<unsigned char>* bytecodes() { return writer()->bytecodes(); }
   SourcePositionTableBuilder* source_position_table_builder() {
     return writer()->source_position_table_builder();
   }

  private:
   ConstantArrayBuilder constant_array_builder_;
   BytecodeArrayWriter bytecode_array_writer_;
 };

 void BytecodeArrayWriterUnittest::Write(Bytecode bytecode,
                                         BytecodeSourceInfo info) {
   BytecodeNode node(bytecode, info);
   writer()->Write(&node);
 }

 void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0,
                                         BytecodeSourceInfo info) {
   BytecodeNode node(bytecode, operand0, info);
   writer()->Write(&node);
 }

 void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0,
                                         uint32_t operand1,
                                         BytecodeSourceInfo info) {
   BytecodeNode node(bytecode, operand0, operand1, info);
   writer()->Write(&node);
 }

 void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0,
                                         uint32_t operand1, uint32_t operand2,
                                         BytecodeSourceInfo info) {
   BytecodeNode node(bytecode, operand0, operand1, operand2, info);
   writer()->Write(&node);
 }

 void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0,
                                         uint32_t operand1, uint32_t operand2,
                                         uint32_t operand3,
                                         BytecodeSourceInfo info) {
   BytecodeNode node(bytecode, operand0, operand1, operand2, operand3, info);
   writer()->Write(&node);
 }

 void BytecodeArrayWriterUnittest::WriteJump(Bytecode bytecode,
                                             BytecodeLabel* label,
                                             BytecodeSourceInfo info) {
   BytecodeNode node(bytecode, 0, info);
   writer()->WriteJump(&node, label);
 }

 void BytecodeArrayWriterUnittest::WriteJumpLoop(Bytecode bytecode,
                                                 BytecodeLoopHeader* loop_header,
                                                 int depth,
                                                 BytecodeSourceInfo info) {
   BytecodeNode node(bytecode, 0, depth, info);
   writer()->WriteJumpLoop(&node, loop_header);
 }

 TEST_F(BytecodeArrayWriterUnittest, SimpleExample) {
   CHECK_EQ(bytecodes()->size(), 0u);

   Write(Bytecode::kLdaSmi, 127, {55, true});
   CHECK_EQ(bytecodes()->size(), 2u);

   Write(Bytecode::kStar, Register(20).ToOperand());
   CHECK_EQ(bytecodes()->size(), 4u);

   Write(Bytecode::kLdar, Register(200).ToOperand());
   CHECK_EQ(bytecodes()->size(), 8u);

   Write(Bytecode::kReturn, {70, true});
   CHECK_EQ(bytecodes()->size(), 9u);

   static const uint8_t expected_bytes[] = {
       // clang-format off
       /*  0 55 S> */ B(LdaSmi), U8(127),
       /*  2       */ B(Star), R8(20),
       /*  4       */ B(Wide), B(Ldar), R16(200),
       /*  8 70 S> */ B(Return),
       // clang-format on
   };
   CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes));
   for (size_t i = 0; i < arraysize(expected_bytes); ++i) {
     CHECK_EQ(bytecodes()->at(i), expected_bytes[i]);
   }

   Handle<BytecodeArray> bytecode_array =
       writer()->ToBytecodeArray(isolate(), 0, 0, factory()->empty_byte_array());
   bytecode_array->set_source_position_table(
       *writer()->ToSourcePositionTable(isolate()), kReleaseStore);
   CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes));

   PositionTableEntry expected_positions[] = {{0, 55, true}, {8, 70, true}};
   SourcePositionTableIterator source_iterator(
       bytecode_array->SourcePositionTable());
   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().ScriptOffset(),
              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 42 S> */ B(LdaConstant), U8(0),
       /*  2 42 E> */ B(Add), R8(1), U8(1),
       /*  4 68 S> */ B(JumpIfUndefined), U8(38),
       /*  6       */ B(JumpIfNull), U8(36),
       /*  8       */ B(ToObject), R8(3),
       /* 10       */ B(ForInPrepare), R8(3), U8(4),
       /* 13       */ B(LdaZero),
       /* 14       */ B(Star), R8(7),
       /* 16 63 S> */ B(ForInContinue), R8(7), R8(6),
       /* 19       */ B(JumpIfFalse), U8(23),
       /* 21       */ B(ForInNext), R8(3), R8(7), R8(4), U8(1),
       /* 26       */ B(JumpIfUndefined), U8(9),
       /* 28       */ B(Star), R8(0),
       /* 30       */ B(Ldar), R8(0),
       /* 32       */ B(Star), R8(2),
       /* 34 85 S> */ B(Return),
       /* 35       */ B(ForInStep), R8(7),
       /* 37       */ B(Star), R8(7),
       /* 39       */ B(JumpLoop), U8(23), U8(0),
       /* 42       */ B(LdaUndefined),
       /* 43 85 S> */ B(Return),
       // clang-format on
   };

   static const PositionTableEntry expected_positions[] = {
       {0, 42, true},  {2, 42, false}, {5, 68, true},
       {17, 63, true}, {35, 85, true}, {44, 85, true}};

   BytecodeLoopHeader loop_header;
   BytecodeLabel jump_for_in, jump_end_1, jump_end_2, jump_end_3;

   Write(Bytecode::kLdaConstant, U8(0), {42, true});
   Write(Bytecode::kAdd, R(1), U8(1), {42, false});
   WriteJump(Bytecode::kJumpIfUndefined, &jump_end_1, {68, true});
   WriteJump(Bytecode::kJumpIfNull, &jump_end_2);
   Write(Bytecode::kToObject, R(3));
   Write(Bytecode::kForInPrepare, R(3), U8(4));
   Write(Bytecode::kLdaZero);
   Write(Bytecode::kStar, R(7));
   writer()->BindLoopHeader(&loop_header);
   Write(Bytecode::kForInContinue, R(7), R(6), {63, true});
   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::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));
   WriteJumpLoop(Bytecode::kJumpLoop, &loop_header, 0);
   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(bytecodes()->size(), arraysize(expected_bytes));
   for (size_t i = 0; i < arraysize(expected_bytes); ++i) {
     CHECK_EQ(static_cast<int>(bytecodes()->at(i)),
              static_cast<int>(expected_bytes[i]));
   }

   Handle<BytecodeArray> bytecode_array =
       writer()->ToBytecodeArray(isolate(), 0, 0, factory()->empty_byte_array());
   bytecode_array->set_source_position_table(
       *writer()->ToSourcePositionTable(isolate()), kReleaseStore);
   SourcePositionTableIterator source_iterator(
       bytecode_array->SourcePositionTable());
   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().ScriptOffset(),
              expected.source_position);
     CHECK_EQ(source_iterator.is_statement(), expected.is_statement);
     source_iterator.Advance();
   }
   CHECK(source_iterator.done());
 }

 TEST_F(BytecodeArrayWriterUnittest, ElideNoneffectfulBytecodes) {
   if (!i::FLAG_ignition_elide_noneffectful_bytecodes) return;

   static const uint8_t expected_bytes[] = {
       // clang-format off
       /*  0  55 S> */ B(Ldar), R8(20),
       /*  2        */ B(Star), R8(20),
       /*  4        */ B(CreateMappedArguments),
       /*  5  60 S> */ B(LdaSmi), U8(127),
       /*  7  70 S> */ B(Ldar), R8(20),
       /*  9 75 S> */ B(Return),
       // clang-format on
   };

   static const PositionTableEntry expected_positions[] = {
       {0, 55, true}, {5, 60, false}, {7, 70, true}, {9, 75, true}};

   Write(Bytecode::kLdaSmi, 127, {55, true});  // Should be elided.
   Write(Bytecode::kLdar, Register(20).ToOperand());
   Write(Bytecode::kStar, Register(20).ToOperand());
   Write(Bytecode::kLdar, Register(20).ToOperand());  // Should be elided.
   Write(Bytecode::kCreateMappedArguments);
   Write(Bytecode::kLdaSmi, 127, {60, false});  // Not elided due to source info.
   Write(Bytecode::kLdar, Register(20).ToOperand(), {70, true});
   Write(Bytecode::kReturn, {75, true});

   CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes));
   for (size_t i = 0; i < arraysize(expected_bytes); ++i) {
     CHECK_EQ(static_cast<int>(bytecodes()->at(i)),
              static_cast<int>(expected_bytes[i]));
   }

   Handle<BytecodeArray> bytecode_array =
       writer()->ToBytecodeArray(isolate(), 0, 0, factory()->empty_byte_array());
   bytecode_array->set_source_position_table(
       *writer()->ToSourcePositionTable(isolate()), kReleaseStore);
   SourcePositionTableIterator source_iterator(
       bytecode_array->SourcePositionTable());
   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().ScriptOffset(),
              expected.source_position);
     CHECK_EQ(source_iterator.is_statement(), expected.is_statement);
     source_iterator.Advance();
   }
   CHECK(source_iterator.done());
 }

 TEST_F(BytecodeArrayWriterUnittest, DeadcodeElimination) {
   static const uint8_t expected_bytes[] = {
       // clang-format off
       /*  0  55 S> */ B(LdaSmi), U8(127),
       /*  2        */ B(Jump), U8(2),
       /*  4  65 S> */ B(LdaSmi), U8(127),
       /*  6        */ B(JumpIfFalse), U8(3),
       /*  8  75 S> */ B(Return),
       /*  9       */ B(JumpIfFalse), U8(3),
       /*  11       */ B(Throw),
       /*  12       */ B(JumpIfFalse), U8(3),
       /*  14       */ B(ReThrow),
       /*  15       */ B(Return),
       // clang-format on
   };

   static const PositionTableEntry expected_positions[] = {
       {0, 55, true}, {4, 65, true}, {8, 75, true}};

   BytecodeLabel after_jump, after_conditional_jump, after_return, after_throw,
       after_rethrow;

   Write(Bytecode::kLdaSmi, 127, {55, true});
   WriteJump(Bytecode::kJump, &after_jump);
   Write(Bytecode::kLdaSmi, 127);                               // Dead code.
   WriteJump(Bytecode::kJumpIfFalse, &after_conditional_jump);  // Dead code.
   writer()->BindLabel(&after_jump);
   // We would bind the after_conditional_jump label here, but the jump to it is
   // dead.
   CHECK(!after_conditional_jump.has_referrer_jump());
   Write(Bytecode::kLdaSmi, 127, {65, true});
   WriteJump(Bytecode::kJumpIfFalse, &after_return);
   Write(Bytecode::kReturn, {75, true});
   Write(Bytecode::kLdaSmi, 127, {100, true});  // Dead code.
   writer()->BindLabel(&after_return);
   WriteJump(Bytecode::kJumpIfFalse, &after_throw);
   Write(Bytecode::kThrow);
   Write(Bytecode::kLdaSmi, 127);  // Dead code.
   writer()->BindLabel(&after_throw);
   WriteJump(Bytecode::kJumpIfFalse, &after_rethrow);
   Write(Bytecode::kReThrow);
   Write(Bytecode::kLdaSmi, 127);  // Dead code.
   writer()->BindLabel(&after_rethrow);
   Write(Bytecode::kReturn);

   CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes));
   for (size_t i = 0; i < arraysize(expected_bytes); ++i) {
     CHECK_EQ(static_cast<int>(bytecodes()->at(i)),
              static_cast<int>(expected_bytes[i]));
   }

   Handle<BytecodeArray> bytecode_array =
       writer()->ToBytecodeArray(isolate(), 0, 0, factory()->empty_byte_array());
   bytecode_array->set_source_position_table(
       *writer()->ToSourcePositionTable(isolate()), kReleaseStore);
   SourcePositionTableIterator source_iterator(
       bytecode_array->SourcePositionTable());
   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().ScriptOffset(),
              expected.source_position);
     CHECK_EQ(source_iterator.is_statement(), expected.is_statement);
     source_iterator.Advance();
   }
   CHECK(source_iterator.done());
 }

 #undef B
 #undef R

 }  // namespace bytecode_array_writer_unittest
 }  // namespace interpreter
 }  // namespace internal
 }  // namespace v8
	// 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/init/v8.h"

	#include "src/api/api.h"
	#include "src/codegen/source-position-table.h"
	#include "src/execution/isolate.h"
	#include "src/heap/factory.h"
	#include "src/interpreter/bytecode-array-writer.h"
	#include "src/interpreter/bytecode-label.h"
	#include "src/interpreter/bytecode-node.h"
	#include "src/interpreter/bytecode-register.h"
	#include "src/interpreter/bytecode-source-info.h"
	#include "src/interpreter/constant-array-builder.h"
	#include "src/utils/utils.h"
	#include "src/objects/objects-inl.h"
	#include "test/unittests/interpreter/bytecode-utils.h"
	#include "test/unittests/test-utils.h"

	namespace v8 {
	namespace internal {
	namespace interpreter {
	namespace bytecode_array_writer_unittest {

	#define B(Name) static_cast<uint8_t>(Bytecode::k##Name)
	#define R(i) static_cast<uint32_t>(Register(i).ToOperand())

	class BytecodeArrayWriterUnittest : public TestWithIsolateAndZone {
	public:
	BytecodeArrayWriterUnittest()
	: constant_array_builder_(zone()),
	bytecode_array_writer_(
	zone(), &constant_array_builder_,
	SourcePositionTableBuilder::RECORD_SOURCE_POSITIONS) {}
	~BytecodeArrayWriterUnittest() override = default;

	void Write(Bytecode bytecode, BytecodeSourceInfo info = BytecodeSourceInfo());
	void Write(Bytecode bytecode, uint32_t operand0,
	BytecodeSourceInfo info = BytecodeSourceInfo());
	void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
	BytecodeSourceInfo info = BytecodeSourceInfo());
	void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
	uint32_t operand2, BytecodeSourceInfo info = BytecodeSourceInfo());
	void Write(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
	uint32_t operand2, uint32_t operand3,
	BytecodeSourceInfo info = BytecodeSourceInfo());

	void WriteJump(Bytecode bytecode, BytecodeLabel* label,
	BytecodeSourceInfo info = BytecodeSourceInfo());
	void WriteJumpLoop(Bytecode bytecode, BytecodeLoopHeader* loop_header,
	int depth, BytecodeSourceInfo info = BytecodeSourceInfo());

	BytecodeArrayWriter* writer() { return &bytecode_array_writer_; }
	ZoneVector<unsigned char>* bytecodes() { return writer()->bytecodes(); }
	SourcePositionTableBuilder* source_position_table_builder() {
	return writer()->source_position_table_builder();
	}

	private:
	ConstantArrayBuilder constant_array_builder_;
	BytecodeArrayWriter bytecode_array_writer_;
	};

	void BytecodeArrayWriterUnittest::Write(Bytecode bytecode,
	BytecodeSourceInfo info) {
	BytecodeNode node(bytecode, info);
	writer()->Write(&node);
	}

	void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0,
	BytecodeSourceInfo info) {
	BytecodeNode node(bytecode, operand0, info);
	writer()->Write(&node);
	}

	void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0,
	uint32_t operand1,
	BytecodeSourceInfo info) {
	BytecodeNode node(bytecode, operand0, operand1, info);
	writer()->Write(&node);
	}

	void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0,
	uint32_t operand1, uint32_t operand2,
	BytecodeSourceInfo info) {
	BytecodeNode node(bytecode, operand0, operand1, operand2, info);
	writer()->Write(&node);
	}

	void BytecodeArrayWriterUnittest::Write(Bytecode bytecode, uint32_t operand0,
	uint32_t operand1, uint32_t operand2,
	uint32_t operand3,
	BytecodeSourceInfo info) {
	BytecodeNode node(bytecode, operand0, operand1, operand2, operand3, info);
	writer()->Write(&node);
	}

	void BytecodeArrayWriterUnittest::WriteJump(Bytecode bytecode,
	BytecodeLabel* label,
	BytecodeSourceInfo info) {
	BytecodeNode node(bytecode, 0, info);
	writer()->WriteJump(&node, label);
	}

	void BytecodeArrayWriterUnittest::WriteJumpLoop(Bytecode bytecode,
	BytecodeLoopHeader* loop_header,
	int depth,
	BytecodeSourceInfo info) {
	BytecodeNode node(bytecode, 0, depth, info);
	writer()->WriteJumpLoop(&node, loop_header);
	}

	TEST_F(BytecodeArrayWriterUnittest, SimpleExample) {
	CHECK_EQ(bytecodes()->size(), 0u);

	Write(Bytecode::kLdaSmi, 127, {55, true});
	CHECK_EQ(bytecodes()->size(), 2u);

	Write(Bytecode::kStar, Register(20).ToOperand());
	CHECK_EQ(bytecodes()->size(), 4u);

	Write(Bytecode::kLdar, Register(200).ToOperand());
	CHECK_EQ(bytecodes()->size(), 8u);

	Write(Bytecode::kReturn, {70, true});
	CHECK_EQ(bytecodes()->size(), 9u);

	static const uint8_t expected_bytes[] = {
	// clang-format off
	/* 0 55 S> */ B(LdaSmi), U8(127),
	/* 2 */ B(Star), R8(20),
	/* 4 */ B(Wide), B(Ldar), R16(200),
	/* 8 70 S> */ B(Return),
	// clang-format on
	};
	CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes));
	for (size_t i = 0; i < arraysize(expected_bytes); ++i) {
	CHECK_EQ(bytecodes()->at(i), expected_bytes[i]);
	}

	Handle<BytecodeArray> bytecode_array =
	writer()->ToBytecodeArray(isolate(), 0, 0, factory()->empty_byte_array());
	bytecode_array->set_source_position_table(
	*writer()->ToSourcePositionTable(isolate()), kReleaseStore);
	CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes));

	PositionTableEntry expected_positions[] = {{0, 55, true}, {8, 70, true}};
	SourcePositionTableIterator source_iterator(
	bytecode_array->SourcePositionTable());
	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().ScriptOffset(),
	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 42 S> */ B(LdaConstant), U8(0),
	/* 2 42 E> */ B(Add), R8(1), U8(1),
	/* 4 68 S> */ B(JumpIfUndefined), U8(38),
	/* 6 */ B(JumpIfNull), U8(36),
	/* 8 */ B(ToObject), R8(3),
	/* 10 */ B(ForInPrepare), R8(3), U8(4),
	/* 13 */ B(LdaZero),
	/* 14 */ B(Star), R8(7),
	/* 16 63 S> */ B(ForInContinue), R8(7), R8(6),
	/* 19 */ B(JumpIfFalse), U8(23),
	/* 21 */ B(ForInNext), R8(3), R8(7), R8(4), U8(1),
	/* 26 */ B(JumpIfUndefined), U8(9),
	/* 28 */ B(Star), R8(0),
	/* 30 */ B(Ldar), R8(0),
	/* 32 */ B(Star), R8(2),
	/* 34 85 S> */ B(Return),
	/* 35 */ B(ForInStep), R8(7),
	/* 37 */ B(Star), R8(7),
	/* 39 */ B(JumpLoop), U8(23), U8(0),
	/* 42 */ B(LdaUndefined),
	/* 43 85 S> */ B(Return),
	// clang-format on
	};

	static const PositionTableEntry expected_positions[] = {
	{0, 42, true}, {2, 42, false}, {5, 68, true},
	{17, 63, true}, {35, 85, true}, {44, 85, true}};

	BytecodeLoopHeader loop_header;
	BytecodeLabel jump_for_in, jump_end_1, jump_end_2, jump_end_3;

	Write(Bytecode::kLdaConstant, U8(0), {42, true});
	Write(Bytecode::kAdd, R(1), U8(1), {42, false});
	WriteJump(Bytecode::kJumpIfUndefined, &jump_end_1, {68, true});
	WriteJump(Bytecode::kJumpIfNull, &jump_end_2);
	Write(Bytecode::kToObject, R(3));
	Write(Bytecode::kForInPrepare, R(3), U8(4));
	Write(Bytecode::kLdaZero);
	Write(Bytecode::kStar, R(7));
	writer()->BindLoopHeader(&loop_header);
	Write(Bytecode::kForInContinue, R(7), R(6), {63, true});
	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::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));
	WriteJumpLoop(Bytecode::kJumpLoop, &loop_header, 0);
	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(bytecodes()->size(), arraysize(expected_bytes));
	for (size_t i = 0; i < arraysize(expected_bytes); ++i) {
	CHECK_EQ(static_cast<int>(bytecodes()->at(i)),
	static_cast<int>(expected_bytes[i]));
	}

	Handle<BytecodeArray> bytecode_array =
	writer()->ToBytecodeArray(isolate(), 0, 0, factory()->empty_byte_array());
	bytecode_array->set_source_position_table(
	*writer()->ToSourcePositionTable(isolate()), kReleaseStore);
	SourcePositionTableIterator source_iterator(
	bytecode_array->SourcePositionTable());
	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().ScriptOffset(),
	expected.source_position);
	CHECK_EQ(source_iterator.is_statement(), expected.is_statement);
	source_iterator.Advance();
	}
	CHECK(source_iterator.done());
	}

	TEST_F(BytecodeArrayWriterUnittest, ElideNoneffectfulBytecodes) {
	if (!i::FLAG_ignition_elide_noneffectful_bytecodes) return;

	static const uint8_t expected_bytes[] = {
	// clang-format off
	/* 0 55 S> */ B(Ldar), R8(20),
	/* 2 */ B(Star), R8(20),
	/* 4 */ B(CreateMappedArguments),
	/* 5 60 S> */ B(LdaSmi), U8(127),
	/* 7 70 S> */ B(Ldar), R8(20),
	/* 9 75 S> */ B(Return),
	// clang-format on
	};

	static const PositionTableEntry expected_positions[] = {
	{0, 55, true}, {5, 60, false}, {7, 70, true}, {9, 75, true}};

	Write(Bytecode::kLdaSmi, 127, {55, true}); // Should be elided.
	Write(Bytecode::kLdar, Register(20).ToOperand());
	Write(Bytecode::kStar, Register(20).ToOperand());
	Write(Bytecode::kLdar, Register(20).ToOperand()); // Should be elided.
	Write(Bytecode::kCreateMappedArguments);
	Write(Bytecode::kLdaSmi, 127, {60, false}); // Not elided due to source info.
	Write(Bytecode::kLdar, Register(20).ToOperand(), {70, true});
	Write(Bytecode::kReturn, {75, true});

	CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes));
	for (size_t i = 0; i < arraysize(expected_bytes); ++i) {
	CHECK_EQ(static_cast<int>(bytecodes()->at(i)),
	static_cast<int>(expected_bytes[i]));
	}

	Handle<BytecodeArray> bytecode_array =
	writer()->ToBytecodeArray(isolate(), 0, 0, factory()->empty_byte_array());
	bytecode_array->set_source_position_table(
	*writer()->ToSourcePositionTable(isolate()), kReleaseStore);
	SourcePositionTableIterator source_iterator(
	bytecode_array->SourcePositionTable());
	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().ScriptOffset(),
	expected.source_position);
	CHECK_EQ(source_iterator.is_statement(), expected.is_statement);
	source_iterator.Advance();
	}
	CHECK(source_iterator.done());
	}

	TEST_F(BytecodeArrayWriterUnittest, DeadcodeElimination) {
	static const uint8_t expected_bytes[] = {
	// clang-format off
	/* 0 55 S> */ B(LdaSmi), U8(127),
	/* 2 */ B(Jump), U8(2),
	/* 4 65 S> */ B(LdaSmi), U8(127),
	/* 6 */ B(JumpIfFalse), U8(3),
	/* 8 75 S> */ B(Return),
	/* 9 */ B(JumpIfFalse), U8(3),
	/* 11 */ B(Throw),
	/* 12 */ B(JumpIfFalse), U8(3),
	/* 14 */ B(ReThrow),
	/* 15 */ B(Return),
	// clang-format on
	};

	static const PositionTableEntry expected_positions[] = {
	{0, 55, true}, {4, 65, true}, {8, 75, true}};

	BytecodeLabel after_jump, after_conditional_jump, after_return, after_throw,
	after_rethrow;

	Write(Bytecode::kLdaSmi, 127, {55, true});
	WriteJump(Bytecode::kJump, &after_jump);
	Write(Bytecode::kLdaSmi, 127); // Dead code.
	WriteJump(Bytecode::kJumpIfFalse, &after_conditional_jump); // Dead code.
	writer()->BindLabel(&after_jump);
	// We would bind the after_conditional_jump label here, but the jump to it is
	// dead.
	CHECK(!after_conditional_jump.has_referrer_jump());
	Write(Bytecode::kLdaSmi, 127, {65, true});
	WriteJump(Bytecode::kJumpIfFalse, &after_return);
	Write(Bytecode::kReturn, {75, true});
	Write(Bytecode::kLdaSmi, 127, {100, true}); // Dead code.
	writer()->BindLabel(&after_return);
	WriteJump(Bytecode::kJumpIfFalse, &after_throw);
	Write(Bytecode::kThrow);
	Write(Bytecode::kLdaSmi, 127); // Dead code.
	writer()->BindLabel(&after_throw);
	WriteJump(Bytecode::kJumpIfFalse, &after_rethrow);
	Write(Bytecode::kReThrow);
	Write(Bytecode::kLdaSmi, 127); // Dead code.
	writer()->BindLabel(&after_rethrow);
	Write(Bytecode::kReturn);

	CHECK_EQ(bytecodes()->size(), arraysize(expected_bytes));
	for (size_t i = 0; i < arraysize(expected_bytes); ++i) {
	CHECK_EQ(static_cast<int>(bytecodes()->at(i)),
	static_cast<int>(expected_bytes[i]));
	}

	Handle<BytecodeArray> bytecode_array =
	writer()->ToBytecodeArray(isolate(), 0, 0, factory()->empty_byte_array());
	bytecode_array->set_source_position_table(
	*writer()->ToSourcePositionTable(isolate()), kReleaseStore);
	SourcePositionTableIterator source_iterator(
	bytecode_array->SourcePositionTable());
	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().ScriptOffset(),
	expected.source_position);
	CHECK_EQ(source_iterator.is_statement(), expected.is_statement);
	source_iterator.Advance();
	}
	CHECK(source_iterator.done());
	}

	#undef B
	#undef R

	} // namespace bytecode_array_writer_unittest
	} // namespace interpreter
	} // namespace internal
	} // namespace v8