src/v8/test/unittests/assembler/turbo-assembler-arm-unittest.cc - cobalt - Git at Google

 // Copyright 2018 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/codegen/arm/assembler-arm-inl.h"
 #include "src/codegen/macro-assembler.h"
 #include "src/execution/simulator.h"
 #include "src/utils/ostreams.h"
 #include "test/common/assembler-tester.h"
 #include "test/unittests/test-utils.h"
 #include "testing/gtest-support.h"

 namespace v8 {
 namespace internal {

 #define __ tasm.

 // If we are running on android and the output is not redirected (i.e. ends up
 // in the android log) then we cannot find the error message in the output. This
 // macro just returns the empty string in that case.
 #if defined(ANDROID) && !defined(V8_ANDROID_LOG_STDOUT)
 #define ERROR_MESSAGE(msg) ""
 #else
 #define ERROR_MESSAGE(msg) msg
 #endif

 // Test the x64 assembler by compiling some simple functions into
 // a buffer and executing them.  These tests do not initialize the
 // V8 library, create a context, or use any V8 objects.

 class TurboAssemblerTest : public TestWithIsolate {};

 TEST_F(TurboAssemblerTest, TestHardAbort) {
   auto buffer = AllocateAssemblerBuffer();
   TurboAssembler tasm(nullptr, AssemblerOptions{}, CodeObjectRequired::kNo,
                       buffer->CreateView());
   __ set_abort_hard(true);

   __ Abort(AbortReason::kNoReason);

   CodeDesc desc;
   tasm.GetCode(nullptr, &desc);
   buffer->MakeExecutable();
   // We need an isolate here to execute in the simulator.
   auto f = GeneratedCode<void>::FromBuffer(isolate(), buffer->start());

   ASSERT_DEATH_IF_SUPPORTED({ f.Call(); }, ERROR_MESSAGE("abort: no reason"));
 }

 TEST_F(TurboAssemblerTest, TestCheck) {
   auto buffer = AllocateAssemblerBuffer();
   TurboAssembler tasm(nullptr, AssemblerOptions{}, CodeObjectRequired::kNo,
                       buffer->CreateView());
   __ set_abort_hard(true);

   // Fail if the first parameter is 17.
   __ Move32BitImmediate(r1, Operand(17));
   __ cmp(r0, r1);  // 1st parameter is in {r0}.
   __ Check(Condition::ne, AbortReason::kNoReason);
   __ Ret();

   CodeDesc desc;
   tasm.GetCode(nullptr, &desc);
   buffer->MakeExecutable();
   // We need an isolate here to execute in the simulator.
   auto f = GeneratedCode<void, int>::FromBuffer(isolate(), buffer->start());

   f.Call(0);
   f.Call(18);
   ASSERT_DEATH_IF_SUPPORTED({ f.Call(17); }, ERROR_MESSAGE("abort: no reason"));
 }

 struct MoveObjectAndSlotTestCase {
   const char* comment;
   Register dst_object;
   Register dst_slot;
   Register object;
   Register offset_register = no_reg;
 };

 const MoveObjectAndSlotTestCase kMoveObjectAndSlotTestCases[] = {
     {"no overlap", r0, r1, r2},
     {"no overlap", r0, r1, r2, r3},

     {"object == dst_object", r2, r1, r2},
     {"object == dst_object", r2, r1, r2, r3},

     {"object == dst_slot", r1, r2, r2},
     {"object == dst_slot", r1, r2, r2, r3},

     {"offset == dst_object", r0, r1, r2, r0},

     {"offset == dst_object && object == dst_slot", r0, r1, r1, r0},

     {"offset == dst_slot", r0, r1, r2, r1},

     {"offset == dst_slot && object == dst_object", r0, r1, r0, r1}};

 // Make sure we include offsets that cannot be encoded in an add instruction.
 const int kOffsets[] = {0, 42, kMaxRegularHeapObjectSize, 0x101001};

 template <typename T>
 class TurboAssemblerTestWithParam : public TurboAssemblerTest,
                                     public ::testing::WithParamInterface<T> {};

 using TurboAssemblerTestMoveObjectAndSlot =
     TurboAssemblerTestWithParam<MoveObjectAndSlotTestCase>;

 TEST_P(TurboAssemblerTestMoveObjectAndSlot, MoveObjectAndSlot) {
   const MoveObjectAndSlotTestCase test_case = GetParam();
   TRACED_FOREACH(int32_t, offset, kOffsets) {
     auto buffer = AllocateAssemblerBuffer();
     TurboAssembler tasm(nullptr, AssemblerOptions{}, CodeObjectRequired::kNo,
                         buffer->CreateView());
     __ Push(r0);
     __ Move(test_case.object, r1);

     Register src_object = test_case.object;
     Register dst_object = test_case.dst_object;
     Register dst_slot = test_case.dst_slot;

     Operand offset_operand(0);
     if (test_case.offset_register == no_reg) {
       offset_operand = Operand(offset);
     } else {
       __ mov(test_case.offset_register, Operand(offset));
       offset_operand = Operand(test_case.offset_register);
     }

     std::stringstream comment;
     comment << "-- " << test_case.comment << ": MoveObjectAndSlot("
             << dst_object << ", " << dst_slot << ", " << src_object << ", ";
     if (test_case.offset_register == no_reg) {
       comment << "#" << offset;
     } else {
       comment << test_case.offset_register;
     }
     comment << ") --";
     __ RecordComment(comment.str().c_str());
     __ MoveObjectAndSlot(dst_object, dst_slot, src_object, offset_operand);
     __ RecordComment("--");

     // The `result` pointer was saved on the stack.
     UseScratchRegisterScope temps(&tasm);
     Register scratch = temps.Acquire();
     __ Pop(scratch);
     __ str(dst_object, MemOperand(scratch));
     __ str(dst_slot, MemOperand(scratch, kSystemPointerSize));

     __ Ret();

     CodeDesc desc;
     tasm.GetCode(nullptr, &desc);
     if (FLAG_print_code) {
       Handle<Code> code =
           Factory::CodeBuilder(isolate(), desc, Code::STUB).Build();
       StdoutStream os;
       code->Print(os);
     }

     buffer->MakeExecutable();
     // We need an isolate here to execute in the simulator.
     auto f = GeneratedCode<void, byte**, byte*>::FromBuffer(isolate(),
                                                             buffer->start());

     byte* object = new byte[offset];
     byte* result[] = {nullptr, nullptr};

     f.Call(result, object);

     // The first element must be the address of the object, and the second the
     // slot addressed by `offset`.
     EXPECT_EQ(result[0], &object[0]);
     EXPECT_EQ(result[1], &object[offset]);

     delete[] object;
   }
 }

 INSTANTIATE_TEST_SUITE_P(TurboAssemblerTest,
                          TurboAssemblerTestMoveObjectAndSlot,
                          ::testing::ValuesIn(kMoveObjectAndSlotTestCases));

 #undef __
 #undef ERROR_MESSAGE

 }  // namespace internal
 }  // namespace v8
	// Copyright 2018 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/codegen/arm/assembler-arm-inl.h"
	#include "src/codegen/macro-assembler.h"
	#include "src/execution/simulator.h"
	#include "src/utils/ostreams.h"
	#include "test/common/assembler-tester.h"
	#include "test/unittests/test-utils.h"
	#include "testing/gtest-support.h"

	namespace v8 {
	namespace internal {

	#define __ tasm.

	// If we are running on android and the output is not redirected (i.e. ends up
	// in the android log) then we cannot find the error message in the output. This
	// macro just returns the empty string in that case.
	#if defined(ANDROID) && !defined(V8_ANDROID_LOG_STDOUT)
	#define ERROR_MESSAGE(msg) ""
	#else
	#define ERROR_MESSAGE(msg) msg
	#endif

	// Test the x64 assembler by compiling some simple functions into
	// a buffer and executing them. These tests do not initialize the
	// V8 library, create a context, or use any V8 objects.

	class TurboAssemblerTest : public TestWithIsolate {};

	TEST_F(TurboAssemblerTest, TestHardAbort) {
	auto buffer = AllocateAssemblerBuffer();
	TurboAssembler tasm(nullptr, AssemblerOptions{}, CodeObjectRequired::kNo,
	buffer->CreateView());
	__ set_abort_hard(true);

	__ Abort(AbortReason::kNoReason);

	CodeDesc desc;
	tasm.GetCode(nullptr, &desc);
	buffer->MakeExecutable();
	// We need an isolate here to execute in the simulator.
	auto f = GeneratedCode<void>::FromBuffer(isolate(), buffer->start());

	ASSERT_DEATH_IF_SUPPORTED({ f.Call(); }, ERROR_MESSAGE("abort: no reason"));
	}

	TEST_F(TurboAssemblerTest, TestCheck) {
	auto buffer = AllocateAssemblerBuffer();
	TurboAssembler tasm(nullptr, AssemblerOptions{}, CodeObjectRequired::kNo,
	buffer->CreateView());
	__ set_abort_hard(true);

	// Fail if the first parameter is 17.
	__ Move32BitImmediate(r1, Operand(17));
	__ cmp(r0, r1); // 1st parameter is in {r0}.
	__ Check(Condition::ne, AbortReason::kNoReason);
	__ Ret();

	CodeDesc desc;
	tasm.GetCode(nullptr, &desc);
	buffer->MakeExecutable();
	// We need an isolate here to execute in the simulator.
	auto f = GeneratedCode<void, int>::FromBuffer(isolate(), buffer->start());

	f.Call(0);
	f.Call(18);
	ASSERT_DEATH_IF_SUPPORTED({ f.Call(17); }, ERROR_MESSAGE("abort: no reason"));
	}

	struct MoveObjectAndSlotTestCase {
	const char* comment;
	Register dst_object;
	Register dst_slot;
	Register object;
	Register offset_register = no_reg;
	};

	const MoveObjectAndSlotTestCase kMoveObjectAndSlotTestCases[] = {
	{"no overlap", r0, r1, r2},
	{"no overlap", r0, r1, r2, r3},

	{"object == dst_object", r2, r1, r2},
	{"object == dst_object", r2, r1, r2, r3},

	{"object == dst_slot", r1, r2, r2},
	{"object == dst_slot", r1, r2, r2, r3},

	{"offset == dst_object", r0, r1, r2, r0},

	{"offset == dst_object && object == dst_slot", r0, r1, r1, r0},

	{"offset == dst_slot", r0, r1, r2, r1},

	{"offset == dst_slot && object == dst_object", r0, r1, r0, r1}};

	// Make sure we include offsets that cannot be encoded in an add instruction.
	const int kOffsets[] = {0, 42, kMaxRegularHeapObjectSize, 0x101001};

	template <typename T>
	class TurboAssemblerTestWithParam : public TurboAssemblerTest,
	public ::testing::WithParamInterface<T> {};

	using TurboAssemblerTestMoveObjectAndSlot =
	TurboAssemblerTestWithParam<MoveObjectAndSlotTestCase>;

	TEST_P(TurboAssemblerTestMoveObjectAndSlot, MoveObjectAndSlot) {
	const MoveObjectAndSlotTestCase test_case = GetParam();
	TRACED_FOREACH(int32_t, offset, kOffsets) {
	auto buffer = AllocateAssemblerBuffer();
	TurboAssembler tasm(nullptr, AssemblerOptions{}, CodeObjectRequired::kNo,
	buffer->CreateView());
	__ Push(r0);
	__ Move(test_case.object, r1);

	Register src_object = test_case.object;
	Register dst_object = test_case.dst_object;
	Register dst_slot = test_case.dst_slot;

	Operand offset_operand(0);
	if (test_case.offset_register == no_reg) {
	offset_operand = Operand(offset);
	} else {
	__ mov(test_case.offset_register, Operand(offset));
	offset_operand = Operand(test_case.offset_register);
	}

	std::stringstream comment;
	comment << "-- " << test_case.comment << ": MoveObjectAndSlot("
	<< dst_object << ", " << dst_slot << ", " << src_object << ", ";
	if (test_case.offset_register == no_reg) {
	comment << "#" << offset;
	} else {
	comment << test_case.offset_register;
	}
	comment << ") --";
	__ RecordComment(comment.str().c_str());
	__ MoveObjectAndSlot(dst_object, dst_slot, src_object, offset_operand);
	__ RecordComment("--");

	// The `result` pointer was saved on the stack.
	UseScratchRegisterScope temps(&tasm);
	Register scratch = temps.Acquire();
	__ Pop(scratch);
	__ str(dst_object, MemOperand(scratch));
	__ str(dst_slot, MemOperand(scratch, kSystemPointerSize));

	__ Ret();

	CodeDesc desc;
	tasm.GetCode(nullptr, &desc);
	if (FLAG_print_code) {
	Handle<Code> code =
	Factory::CodeBuilder(isolate(), desc, Code::STUB).Build();
	StdoutStream os;
	code->Print(os);
	}

	buffer->MakeExecutable();
	// We need an isolate here to execute in the simulator.
	auto f = GeneratedCode<void, byte*, byte>::FromBuffer(isolate(),
	buffer->start());

	byte* object = new byte[offset];
	byte* result[] = {nullptr, nullptr};

	f.Call(result, object);

	// The first element must be the address of the object, and the second the
	// slot addressed by `offset`.
	EXPECT_EQ(result[0], &object[0]);
	EXPECT_EQ(result[1], &object[offset]);

	delete[] object;
	}
	}

	INSTANTIATE_TEST_SUITE_P(TurboAssemblerTest,
	TurboAssemblerTestMoveObjectAndSlot,
	::testing::ValuesIn(kMoveObjectAndSlotTestCases));

	#undef __
	#undef ERROR_MESSAGE

	} // namespace internal
	} // namespace v8