src/v8/test/cctest/test-sync-primitives-arm.cc - cobalt - Git at Google

 // Copyright 2016 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 #include "src/v8.h"
 #include "test/cctest/assembler-helper-arm.h"
 #include "test/cctest/cctest.h"

 #include "src/assembler-inl.h"
 #include "src/disassembler.h"
 #include "src/factory.h"
 #include "src/macro-assembler.h"
 #include "src/simulator.h"

 namespace v8 {
 namespace internal {

 // These tests rely on the behaviour specific to the simulator so we cannot
 // expect the same results on real hardware. The reason for this is that our
 // simulation of synchronisation primitives is more conservative than the
 // reality.
 // For example:
 //   ldrex r1, [r2] ; Load acquire at address r2; r2 is now marked as exclusive.
 //   ldr r0, [r4]   ; This is a normal load, and at a different address.
 //                  ; However, any memory accesses can potentially clear the
 //                  ; exclusivity (See ARM DDI 0406C.c A3.4.5). This is unlikely
 //                  ; on real hardware but to be conservative, the simulator
 //                  ; always does it.
 //   strex r3, r1, [r2] ; As a result, this will always fail in the simulator
 //                      ; but will likely succeed on hardware.
 #if defined(USE_SIMULATOR)

 #ifndef V8_TARGET_LITTLE_ENDIAN
 #error Expected ARM to be little-endian
 #endif

 #define __ assm.

 namespace {

 struct MemoryAccess {
   enum class Kind {
     None,
     Load,
     LoadExcl,
     Store,
     StoreExcl,
   };

   enum class Size {
     Byte,
     HalfWord,
     Word,
   };

   MemoryAccess() : kind(Kind::None) {}
   MemoryAccess(Kind kind, Size size, size_t offset, int value = 0)
       : kind(kind), size(size), offset(offset), value(value) {}

   Kind kind = Kind::None;
   Size size = Size::Byte;
   size_t offset = 0;
   int value = 0;
 };

 struct TestData {
   explicit TestData(int w) : w(w) {}

   union {
     int32_t w;
     int16_t h;
     int8_t b;
   };
   int dummy;
 };

 void AssembleMemoryAccess(Assembler* assembler, MemoryAccess access,
                           Register dest_reg, Register value_reg,
                           Register addr_reg) {
   Assembler& assm = *assembler;
   __ add(addr_reg, r0, Operand(access.offset));

   switch (access.kind) {
     case MemoryAccess::Kind::None:
       break;

     case MemoryAccess::Kind::Load:
       switch (access.size) {
         case MemoryAccess::Size::Byte:
           __ ldrb(value_reg, MemOperand(addr_reg));
           break;

         case MemoryAccess::Size::HalfWord:
           __ ldrh(value_reg, MemOperand(addr_reg));
           break;

         case MemoryAccess::Size::Word:
           __ ldr(value_reg, MemOperand(addr_reg));
           break;
       }
       break;

     case MemoryAccess::Kind::LoadExcl:
       switch (access.size) {
         case MemoryAccess::Size::Byte:
           __ ldrexb(value_reg, addr_reg);
           break;

         case MemoryAccess::Size::HalfWord:
           __ ldrexh(value_reg, addr_reg);
           break;

         case MemoryAccess::Size::Word:
           __ ldrex(value_reg, addr_reg);
           break;
       }
       break;

     case MemoryAccess::Kind::Store:
       switch (access.size) {
         case MemoryAccess::Size::Byte:
           __ mov(value_reg, Operand(access.value));
           __ strb(value_reg, MemOperand(addr_reg));
           break;

         case MemoryAccess::Size::HalfWord:
           __ mov(value_reg, Operand(access.value));
           __ strh(value_reg, MemOperand(addr_reg));
           break;

         case MemoryAccess::Size::Word:
           __ mov(value_reg, Operand(access.value));
           __ str(value_reg, MemOperand(addr_reg));
           break;
       }
       break;

     case MemoryAccess::Kind::StoreExcl:
       switch (access.size) {
         case MemoryAccess::Size::Byte:
           __ mov(value_reg, Operand(access.value));
           __ strexb(dest_reg, value_reg, addr_reg);
           break;

         case MemoryAccess::Size::HalfWord:
           __ mov(value_reg, Operand(access.value));
           __ strexh(dest_reg, value_reg, addr_reg);
           break;

         case MemoryAccess::Size::Word:
           __ mov(value_reg, Operand(access.value));
           __ strex(dest_reg, value_reg, addr_reg);
           break;
       }
       break;
   }
 }

 void AssembleLoadExcl(Assembler* assembler, MemoryAccess access,
                       Register value_reg, Register addr_reg) {
   DCHECK(access.kind == MemoryAccess::Kind::LoadExcl);
   AssembleMemoryAccess(assembler, access, no_reg, value_reg, addr_reg);
 }

 void AssembleStoreExcl(Assembler* assembler, MemoryAccess access,
                        Register dest_reg, Register value_reg,
                        Register addr_reg) {
   DCHECK(access.kind == MemoryAccess::Kind::StoreExcl);
   AssembleMemoryAccess(assembler, access, dest_reg, value_reg, addr_reg);
 }

 void TestInvalidateExclusiveAccess(TestData initial_data, MemoryAccess access1,
                                    MemoryAccess access2, MemoryAccess access3,
                                    int expected_res, TestData expected_data) {
   Isolate* isolate = CcTest::i_isolate();
   HandleScope scope(isolate);

   auto f = AssembleCode<int(TestData*, int, int, int)>([&](Assembler& assm) {
     AssembleLoadExcl(&assm, access1, r1, r1);
     AssembleMemoryAccess(&assm, access2, r3, r2, r1);
     AssembleStoreExcl(&assm, access3, r0, r3, r1);
   });

   TestData t = initial_data;

   int res = f.Call(&t, 0, 0, 0);
   CHECK_EQ(expected_res, res);
   switch (access3.size) {
     case MemoryAccess::Size::Byte:
       CHECK_EQ(expected_data.b, t.b);
       break;

     case MemoryAccess::Size::HalfWord:
       CHECK_EQ(expected_data.h, t.h);
       break;

     case MemoryAccess::Size::Word:
       CHECK_EQ(expected_data.w, t.w);
       break;
   }
 }

 }  // namespace

 TEST(simulator_invalidate_exclusive_access) {
   using Kind = MemoryAccess::Kind;
   using Size = MemoryAccess::Size;

   MemoryAccess ldrex_w(Kind::LoadExcl, Size::Word, offsetof(TestData, w));
   MemoryAccess strex_w(Kind::StoreExcl, Size::Word, offsetof(TestData, w), 7);

   // Address mismatch.
   TestInvalidateExclusiveAccess(
       TestData(1), ldrex_w,
       MemoryAccess(Kind::LoadExcl, Size::Word, offsetof(TestData, dummy)),
       strex_w, 1, TestData(1));

   // Size mismatch.
   TestInvalidateExclusiveAccess(
       TestData(1), ldrex_w, MemoryAccess(),
       MemoryAccess(Kind::StoreExcl, Size::HalfWord, offsetof(TestData, w), 7),
       1, TestData(1));

   // Load between ldrex/strex.
   TestInvalidateExclusiveAccess(
       TestData(1), ldrex_w,
       MemoryAccess(Kind::Load, Size::Word, offsetof(TestData, dummy)), strex_w,
       1, TestData(1));

   // Store between ldrex/strex.
   TestInvalidateExclusiveAccess(
       TestData(1), ldrex_w,
       MemoryAccess(Kind::Store, Size::Word, offsetof(TestData, dummy)), strex_w,
       1, TestData(1));

   // Match
   TestInvalidateExclusiveAccess(TestData(1), ldrex_w, MemoryAccess(), strex_w,
                                 0, TestData(7));
 }

 namespace {

 int ExecuteMemoryAccess(Isolate* isolate, TestData* test_data,
                         MemoryAccess access) {
   HandleScope scope(isolate);
   auto f = AssembleCode<int(TestData*, int, int)>([&](Assembler& assm) {
     AssembleMemoryAccess(&assm, access, r0, r2, r1);
   });

   return f.Call(test_data, 0, 0);
 }

 }  // namespace

 class MemoryAccessThread : public v8::base::Thread {
  public:
   MemoryAccessThread()
       : Thread(Options("MemoryAccessThread")),
         test_data_(nullptr),
         is_finished_(false),
         has_request_(false),
         did_request_(false),
         isolate_(nullptr) {}

   virtual void Run() {
     v8::Isolate::CreateParams create_params;
     create_params.array_buffer_allocator = CcTest::array_buffer_allocator();
     isolate_ = v8::Isolate::New(create_params);
     Isolate* i_isolate = reinterpret_cast<Isolate*>(isolate_);
     {
       v8::Isolate::Scope scope(isolate_);
       v8::base::LockGuard<v8::base::Mutex> lock_guard(&mutex_);
       while (!is_finished_) {
         while (!(has_request_ || is_finished_)) {
           has_request_cv_.Wait(&mutex_);
         }

         if (is_finished_) {
           break;
         }

         ExecuteMemoryAccess(i_isolate, test_data_, access_);
         has_request_ = false;
         did_request_ = true;
         did_request_cv_.NotifyOne();
       }
     }
     isolate_->Dispose();
   }

   void NextAndWait(TestData* test_data, MemoryAccess access) {
     DCHECK(!has_request_);
     v8::base::LockGuard<v8::base::Mutex> lock_guard(&mutex_);
     test_data_ = test_data;
     access_ = access;
     has_request_ = true;
     has_request_cv_.NotifyOne();
     while (!did_request_) {
       did_request_cv_.Wait(&mutex_);
     }
     did_request_ = false;
   }

   void Finish() {
     v8::base::LockGuard<v8::base::Mutex> lock_guard(&mutex_);
     is_finished_ = true;
     has_request_cv_.NotifyOne();
   }

  private:
   TestData* test_data_;
   MemoryAccess access_;
   bool is_finished_;
   bool has_request_;
   bool did_request_;
   v8::base::Mutex mutex_;
   v8::base::ConditionVariable has_request_cv_;
   v8::base::ConditionVariable did_request_cv_;
   v8::Isolate* isolate_;
 };

 TEST(simulator_invalidate_exclusive_access_threaded) {
   using Kind = MemoryAccess::Kind;
   using Size = MemoryAccess::Size;

   Isolate* isolate = CcTest::i_isolate();
   HandleScope scope(isolate);

   TestData test_data(1);

   MemoryAccessThread thread;
   thread.Start();

   MemoryAccess ldrex_w(Kind::LoadExcl, Size::Word, offsetof(TestData, w));
   MemoryAccess strex_w(Kind::StoreExcl, Size::Word, offsetof(TestData, w), 7);

   // Exclusive store completed by another thread first.
   test_data = TestData(1);
   thread.NextAndWait(&test_data, MemoryAccess(Kind::LoadExcl, Size::Word,
                                               offsetof(TestData, w)));
   ExecuteMemoryAccess(isolate, &test_data, ldrex_w);
   thread.NextAndWait(&test_data, MemoryAccess(Kind::StoreExcl, Size::Word,
                                               offsetof(TestData, w), 5));
   CHECK_EQ(1, ExecuteMemoryAccess(isolate, &test_data, strex_w));
   CHECK_EQ(5, test_data.w);

   // Exclusive store completed by another thread; different address, but masked
   // to same
   test_data = TestData(1);
   ExecuteMemoryAccess(isolate, &test_data, ldrex_w);
   thread.NextAndWait(&test_data, MemoryAccess(Kind::LoadExcl, Size::Word,
                                               offsetof(TestData, dummy)));
   thread.NextAndWait(&test_data, MemoryAccess(Kind::StoreExcl, Size::Word,
                                               offsetof(TestData, dummy), 5));
   CHECK_EQ(1, ExecuteMemoryAccess(isolate, &test_data, strex_w));
   CHECK_EQ(1, test_data.w);

   // Test failure when store between ldrex/strex.
   test_data = TestData(1);
   ExecuteMemoryAccess(isolate, &test_data, ldrex_w);
   thread.NextAndWait(&test_data, MemoryAccess(Kind::Store, Size::Word,
                                               offsetof(TestData, dummy)));
   CHECK_EQ(1, ExecuteMemoryAccess(isolate, &test_data, strex_w));
   CHECK_EQ(1, test_data.w);

   thread.Finish();
   thread.Join();
 }

 #undef __

 #endif  // defined(USE_SIMULATOR)

 }  // namespace internal
 }  // namespace v8
	// Copyright 2016 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	#include "src/v8.h"
	#include "test/cctest/assembler-helper-arm.h"
	#include "test/cctest/cctest.h"

	#include "src/assembler-inl.h"
	#include "src/disassembler.h"
	#include "src/factory.h"
	#include "src/macro-assembler.h"
	#include "src/simulator.h"

	namespace v8 {
	namespace internal {

	// These tests rely on the behaviour specific to the simulator so we cannot
	// expect the same results on real hardware. The reason for this is that our
	// simulation of synchronisation primitives is more conservative than the
	// reality.
	// For example:
	// ldrex r1, [r2] ; Load acquire at address r2; r2 is now marked as exclusive.
	// ldr r0, [r4] ; This is a normal load, and at a different address.
	// ; However, any memory accesses can potentially clear the
	// ; exclusivity (See ARM DDI 0406C.c A3.4.5). This is unlikely
	// ; on real hardware but to be conservative, the simulator
	// ; always does it.
	// strex r3, r1, [r2] ; As a result, this will always fail in the simulator
	// ; but will likely succeed on hardware.
	#if defined(USE_SIMULATOR)

	#ifndef V8_TARGET_LITTLE_ENDIAN
	#error Expected ARM to be little-endian
	#endif

	#define __ assm.

	namespace {

	struct MemoryAccess {
	enum class Kind {
	None,
	Load,
	LoadExcl,
	Store,
	StoreExcl,
	};

	enum class Size {
	Byte,
	HalfWord,
	Word,
	};

	MemoryAccess() : kind(Kind::None) {}
	MemoryAccess(Kind kind, Size size, size_t offset, int value = 0)
	: kind(kind), size(size), offset(offset), value(value) {}

	Kind kind = Kind::None;
	Size size = Size::Byte;
	size_t offset = 0;
	int value = 0;
	};

	struct TestData {
	explicit TestData(int w) : w(w) {}

	union {
	int32_t w;
	int16_t h;
	int8_t b;
	};
	int dummy;
	};

	void AssembleMemoryAccess(Assembler* assembler, MemoryAccess access,
	Register dest_reg, Register value_reg,
	Register addr_reg) {
	Assembler& assm = *assembler;
	__ add(addr_reg, r0, Operand(access.offset));

	switch (access.kind) {
	case MemoryAccess::Kind::None:
	break;

	case MemoryAccess::Kind::Load:
	switch (access.size) {
	case MemoryAccess::Size::Byte:
	__ ldrb(value_reg, MemOperand(addr_reg));
	break;

	case MemoryAccess::Size::HalfWord:
	__ ldrh(value_reg, MemOperand(addr_reg));
	break;

	case MemoryAccess::Size::Word:
	__ ldr(value_reg, MemOperand(addr_reg));
	break;
	}
	break;

	case MemoryAccess::Kind::LoadExcl:
	switch (access.size) {
	case MemoryAccess::Size::Byte:
	__ ldrexb(value_reg, addr_reg);
	break;

	case MemoryAccess::Size::HalfWord:
	__ ldrexh(value_reg, addr_reg);
	break;

	case MemoryAccess::Size::Word:
	__ ldrex(value_reg, addr_reg);
	break;
	}
	break;

	case MemoryAccess::Kind::Store:
	switch (access.size) {
	case MemoryAccess::Size::Byte:
	__ mov(value_reg, Operand(access.value));
	__ strb(value_reg, MemOperand(addr_reg));
	break;

	case MemoryAccess::Size::HalfWord:
	__ mov(value_reg, Operand(access.value));
	__ strh(value_reg, MemOperand(addr_reg));
	break;

	case MemoryAccess::Size::Word:
	__ mov(value_reg, Operand(access.value));
	__ str(value_reg, MemOperand(addr_reg));
	break;
	}
	break;

	case MemoryAccess::Kind::StoreExcl:
	switch (access.size) {
	case MemoryAccess::Size::Byte:
	__ mov(value_reg, Operand(access.value));
	__ strexb(dest_reg, value_reg, addr_reg);
	break;

	case MemoryAccess::Size::HalfWord:
	__ mov(value_reg, Operand(access.value));
	__ strexh(dest_reg, value_reg, addr_reg);
	break;

	case MemoryAccess::Size::Word:
	__ mov(value_reg, Operand(access.value));
	__ strex(dest_reg, value_reg, addr_reg);
	break;
	}
	break;
	}
	}

	void AssembleLoadExcl(Assembler* assembler, MemoryAccess access,
	Register value_reg, Register addr_reg) {
	DCHECK(access.kind == MemoryAccess::Kind::LoadExcl);
	AssembleMemoryAccess(assembler, access, no_reg, value_reg, addr_reg);
	}

	void AssembleStoreExcl(Assembler* assembler, MemoryAccess access,
	Register dest_reg, Register value_reg,
	Register addr_reg) {
	DCHECK(access.kind == MemoryAccess::Kind::StoreExcl);
	AssembleMemoryAccess(assembler, access, dest_reg, value_reg, addr_reg);
	}

	void TestInvalidateExclusiveAccess(TestData initial_data, MemoryAccess access1,
	MemoryAccess access2, MemoryAccess access3,
	int expected_res, TestData expected_data) {
	Isolate* isolate = CcTest::i_isolate();
	HandleScope scope(isolate);

	auto f = AssembleCode<int(TestData*, int, int, int)>([&](Assembler& assm) {
	AssembleLoadExcl(&assm, access1, r1, r1);
	AssembleMemoryAccess(&assm, access2, r3, r2, r1);
	AssembleStoreExcl(&assm, access3, r0, r3, r1);
	});

	TestData t = initial_data;

	int res = f.Call(&t, 0, 0, 0);
	CHECK_EQ(expected_res, res);
	switch (access3.size) {
	case MemoryAccess::Size::Byte:
	CHECK_EQ(expected_data.b, t.b);
	break;

	case MemoryAccess::Size::HalfWord:
	CHECK_EQ(expected_data.h, t.h);
	break;

	case MemoryAccess::Size::Word:
	CHECK_EQ(expected_data.w, t.w);
	break;
	}
	}

	} // namespace

	TEST(simulator_invalidate_exclusive_access) {
	using Kind = MemoryAccess::Kind;
	using Size = MemoryAccess::Size;

	MemoryAccess ldrex_w(Kind::LoadExcl, Size::Word, offsetof(TestData, w));
	MemoryAccess strex_w(Kind::StoreExcl, Size::Word, offsetof(TestData, w), 7);

	// Address mismatch.
	TestInvalidateExclusiveAccess(
	TestData(1), ldrex_w,
	MemoryAccess(Kind::LoadExcl, Size::Word, offsetof(TestData, dummy)),
	strex_w, 1, TestData(1));

	// Size mismatch.
	TestInvalidateExclusiveAccess(
	TestData(1), ldrex_w, MemoryAccess(),
	MemoryAccess(Kind::StoreExcl, Size::HalfWord, offsetof(TestData, w), 7),
	1, TestData(1));

	// Load between ldrex/strex.
	TestInvalidateExclusiveAccess(
	TestData(1), ldrex_w,
	MemoryAccess(Kind::Load, Size::Word, offsetof(TestData, dummy)), strex_w,
	1, TestData(1));

	// Store between ldrex/strex.
	TestInvalidateExclusiveAccess(
	TestData(1), ldrex_w,
	MemoryAccess(Kind::Store, Size::Word, offsetof(TestData, dummy)), strex_w,
	1, TestData(1));

	// Match
	TestInvalidateExclusiveAccess(TestData(1), ldrex_w, MemoryAccess(), strex_w,
	0, TestData(7));
	}

	namespace {

	int ExecuteMemoryAccess(Isolate* isolate, TestData* test_data,
	MemoryAccess access) {
	HandleScope scope(isolate);
	auto f = AssembleCode<int(TestData*, int, int)>([&](Assembler& assm) {
	AssembleMemoryAccess(&assm, access, r0, r2, r1);
	});

	return f.Call(test_data, 0, 0);
	}

	} // namespace

	class MemoryAccessThread : public v8::base::Thread {
	public:
	MemoryAccessThread()
	: Thread(Options("MemoryAccessThread")),
	test_data_(nullptr),
	is_finished_(false),
	has_request_(false),
	did_request_(false),
	isolate_(nullptr) {}

	virtual void Run() {
	v8::Isolate::CreateParams create_params;
	create_params.array_buffer_allocator = CcTest::array_buffer_allocator();
	isolate_ = v8::Isolate::New(create_params);
	Isolate* i_isolate = reinterpret_cast<Isolate*>(isolate_);
	{
	v8::Isolate::Scope scope(isolate_);
	v8::base::LockGuard<v8::base::Mutex> lock_guard(&mutex_);
	while (!is_finished_) {
	while (!(has_request_ \|\| is_finished_)) {
	has_request_cv_.Wait(&mutex_);
	}

	if (is_finished_) {
	break;
	}

	ExecuteMemoryAccess(i_isolate, test_data_, access_);
	has_request_ = false;
	did_request_ = true;
	did_request_cv_.NotifyOne();
	}
	}
	isolate_->Dispose();
	}

	void NextAndWait(TestData* test_data, MemoryAccess access) {
	DCHECK(!has_request_);
	v8::base::LockGuard<v8::base::Mutex> lock_guard(&mutex_);
	test_data_ = test_data;
	access_ = access;
	has_request_ = true;
	has_request_cv_.NotifyOne();
	while (!did_request_) {
	did_request_cv_.Wait(&mutex_);
	}
	did_request_ = false;
	}

	void Finish() {
	v8::base::LockGuard<v8::base::Mutex> lock_guard(&mutex_);
	is_finished_ = true;
	has_request_cv_.NotifyOne();
	}

	private:
	TestData* test_data_;
	MemoryAccess access_;
	bool is_finished_;
	bool has_request_;
	bool did_request_;
	v8::base::Mutex mutex_;
	v8::base::ConditionVariable has_request_cv_;
	v8::base::ConditionVariable did_request_cv_;
	v8::Isolate* isolate_;
	};

	TEST(simulator_invalidate_exclusive_access_threaded) {
	using Kind = MemoryAccess::Kind;
	using Size = MemoryAccess::Size;

	Isolate* isolate = CcTest::i_isolate();
	HandleScope scope(isolate);

	TestData test_data(1);

	MemoryAccessThread thread;
	thread.Start();

	MemoryAccess ldrex_w(Kind::LoadExcl, Size::Word, offsetof(TestData, w));
	MemoryAccess strex_w(Kind::StoreExcl, Size::Word, offsetof(TestData, w), 7);

	// Exclusive store completed by another thread first.
	test_data = TestData(1);
	thread.NextAndWait(&test_data, MemoryAccess(Kind::LoadExcl, Size::Word,
	offsetof(TestData, w)));
	ExecuteMemoryAccess(isolate, &test_data, ldrex_w);
	thread.NextAndWait(&test_data, MemoryAccess(Kind::StoreExcl, Size::Word,
	offsetof(TestData, w), 5));
	CHECK_EQ(1, ExecuteMemoryAccess(isolate, &test_data, strex_w));
	CHECK_EQ(5, test_data.w);

	// Exclusive store completed by another thread; different address, but masked
	// to same
	test_data = TestData(1);
	ExecuteMemoryAccess(isolate, &test_data, ldrex_w);
	thread.NextAndWait(&test_data, MemoryAccess(Kind::LoadExcl, Size::Word,
	offsetof(TestData, dummy)));
	thread.NextAndWait(&test_data, MemoryAccess(Kind::StoreExcl, Size::Word,
	offsetof(TestData, dummy), 5));
	CHECK_EQ(1, ExecuteMemoryAccess(isolate, &test_data, strex_w));
	CHECK_EQ(1, test_data.w);

	// Test failure when store between ldrex/strex.
	test_data = TestData(1);
	ExecuteMemoryAccess(isolate, &test_data, ldrex_w);
	thread.NextAndWait(&test_data, MemoryAccess(Kind::Store, Size::Word,
	offsetof(TestData, dummy)));
	CHECK_EQ(1, ExecuteMemoryAccess(isolate, &test_data, strex_w));
	CHECK_EQ(1, test_data.w);

	thread.Finish();
	thread.Join();
	}

	#undef __

	#endif // defined(USE_SIMULATOR)

	} // namespace internal
	} // namespace v8