src/v8/test/unittests/execution/microtask-queue-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/execution/microtask-queue.h"

 #include <algorithm>
 #include <functional>
 #include <memory>
 #include <vector>

 #include "src/heap/factory.h"
 #include "src/objects/foreign.h"
 #include "src/objects/js-array-inl.h"
 #include "src/objects/js-objects-inl.h"
 #include "src/objects/objects-inl.h"
 #include "src/objects/promise-inl.h"
 #include "src/objects/visitors.h"
 #include "test/unittests/test-utils.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace v8 {
 namespace internal {

 using Closure = std::function<void()>;

 void RunStdFunction(void* data) {
   std::unique_ptr<Closure> f(static_cast<Closure*>(data));
   (*f)();
 }

 template <typename TMixin>
 class WithFinalizationGroupMixin : public TMixin {
  public:
   WithFinalizationGroupMixin() = default;
   ~WithFinalizationGroupMixin() override = default;

   static void SetUpTestCase() {
     CHECK_NULL(save_flags_);
     save_flags_ = new SaveFlags();
     FLAG_harmony_weak_refs = true;
     FLAG_expose_gc = true;
     FLAG_allow_natives_syntax = true;
     TMixin::SetUpTestCase();
   }

   static void TearDownTestCase() {
     TMixin::TearDownTestCase();
     CHECK_NOT_NULL(save_flags_);
     delete save_flags_;
     save_flags_ = nullptr;
   }

  private:
   static SaveFlags* save_flags_;

   DISALLOW_COPY_AND_ASSIGN(WithFinalizationGroupMixin);
 };

 template <typename TMixin>
 SaveFlags* WithFinalizationGroupMixin<TMixin>::save_flags_ = nullptr;

 using TestWithNativeContextAndFinalizationGroup =  //
     WithInternalIsolateMixin<                      //
         WithContextMixin<                          //
             WithFinalizationGroupMixin<            //
                 WithIsolateScopeMixin<             //
                     WithSharedIsolateMixin<        //
                         ::testing::Test>>>>>;

 class MicrotaskQueueTest : public TestWithNativeContextAndFinalizationGroup {
  public:
   template <typename F>
   Handle<Microtask> NewMicrotask(F&& f) {
     Handle<Foreign> runner =
         factory()->NewForeign(reinterpret_cast<Address>(&RunStdFunction));
     Handle<Foreign> data = factory()->NewForeign(
         reinterpret_cast<Address>(new Closure(std::forward<F>(f))));
     return factory()->NewCallbackTask(runner, data);
   }

   void SetUp() override {
     microtask_queue_ = MicrotaskQueue::New(isolate());
     native_context()->set_microtask_queue(microtask_queue());
   }

   void TearDown() override {
     if (microtask_queue()) {
       microtask_queue()->RunMicrotasks(isolate());
       context()->DetachGlobal();
     }
   }

   MicrotaskQueue* microtask_queue() const { return microtask_queue_.get(); }

   void ClearTestMicrotaskQueue() {
     context()->DetachGlobal();
     microtask_queue_ = nullptr;
   }

   template <size_t N>
   Handle<Name> NameFromChars(const char (&chars)[N]) {
     return isolate()->factory()->NewStringFromStaticChars(chars);
   }

  private:
   std::unique_ptr<MicrotaskQueue> microtask_queue_;
 };

 class RecordingVisitor : public RootVisitor {
  public:
   RecordingVisitor() = default;
   ~RecordingVisitor() override = default;

   void VisitRootPointers(Root root, const char* description,
                          FullObjectSlot start, FullObjectSlot end) override {
     for (FullObjectSlot current = start; current != end; ++current) {
       visited_.push_back(*current);
     }
   }

   const std::vector<Object>& visited() const { return visited_; }

  private:
   std::vector<Object> visited_;
 };

 // Sanity check. Ensure a microtask is stored in a queue and run.
 TEST_F(MicrotaskQueueTest, EnqueueAndRun) {
   bool ran = false;
   EXPECT_EQ(0, microtask_queue()->capacity());
   EXPECT_EQ(0, microtask_queue()->size());
   microtask_queue()->EnqueueMicrotask(*NewMicrotask([&ran] {
     EXPECT_FALSE(ran);
     ran = true;
   }));
   EXPECT_EQ(MicrotaskQueue::kMinimumCapacity, microtask_queue()->capacity());
   EXPECT_EQ(1, microtask_queue()->size());
   EXPECT_EQ(1, microtask_queue()->RunMicrotasks(isolate()));
   EXPECT_TRUE(ran);
   EXPECT_EQ(0, microtask_queue()->size());
 }

 // Check for a buffer growth.
 TEST_F(MicrotaskQueueTest, BufferGrowth) {
   int count = 0;

   // Enqueue and flush the queue first to have non-zero |start_|.
   microtask_queue()->EnqueueMicrotask(
       *NewMicrotask([&count] { EXPECT_EQ(0, count++); }));
   EXPECT_EQ(1, microtask_queue()->RunMicrotasks(isolate()));

   EXPECT_LT(0, microtask_queue()->capacity());
   EXPECT_EQ(0, microtask_queue()->size());
   EXPECT_EQ(1, microtask_queue()->start());

   // Fill the queue with Microtasks.
   for (int i = 1; i <= MicrotaskQueue::kMinimumCapacity; ++i) {
     microtask_queue()->EnqueueMicrotask(
         *NewMicrotask([&count, i] { EXPECT_EQ(i, count++); }));
   }
   EXPECT_EQ(MicrotaskQueue::kMinimumCapacity, microtask_queue()->capacity());
   EXPECT_EQ(MicrotaskQueue::kMinimumCapacity, microtask_queue()->size());

   // Add another to grow the ring buffer.
   microtask_queue()->EnqueueMicrotask(*NewMicrotask(
       [&] { EXPECT_EQ(MicrotaskQueue::kMinimumCapacity + 1, count++); }));

   EXPECT_LT(MicrotaskQueue::kMinimumCapacity, microtask_queue()->capacity());
   EXPECT_EQ(MicrotaskQueue::kMinimumCapacity + 1, microtask_queue()->size());

   // Run all pending Microtasks to ensure they run in the proper order.
   EXPECT_EQ(MicrotaskQueue::kMinimumCapacity + 1,
             microtask_queue()->RunMicrotasks(isolate()));
   EXPECT_EQ(MicrotaskQueue::kMinimumCapacity + 2, count);
 }

 // MicrotaskQueue instances form a doubly linked list.
 TEST_F(MicrotaskQueueTest, InstanceChain) {
   ClearTestMicrotaskQueue();

   MicrotaskQueue* default_mtq = isolate()->default_microtask_queue();
   ASSERT_TRUE(default_mtq);
   EXPECT_EQ(default_mtq, default_mtq->next());
   EXPECT_EQ(default_mtq, default_mtq->prev());

   // Create two instances, and check their connection.
   // The list contains all instances in the creation order, and the next of the
   // last instance is the first instance:
   //   default_mtq -> mtq1 -> mtq2 -> default_mtq.
   std::unique_ptr<MicrotaskQueue> mtq1 = MicrotaskQueue::New(isolate());
   std::unique_ptr<MicrotaskQueue> mtq2 = MicrotaskQueue::New(isolate());
   EXPECT_EQ(default_mtq->next(), mtq1.get());
   EXPECT_EQ(mtq1->next(), mtq2.get());
   EXPECT_EQ(mtq2->next(), default_mtq);
   EXPECT_EQ(default_mtq, mtq1->prev());
   EXPECT_EQ(mtq1.get(), mtq2->prev());
   EXPECT_EQ(mtq2.get(), default_mtq->prev());

   // Deleted item should be also removed from the list.
   mtq1 = nullptr;
   EXPECT_EQ(default_mtq->next(), mtq2.get());
   EXPECT_EQ(mtq2->next(), default_mtq);
   EXPECT_EQ(default_mtq, mtq2->prev());
   EXPECT_EQ(mtq2.get(), default_mtq->prev());
 }

 // Pending Microtasks in MicrotaskQueues are strong roots. Ensure they are
 // visited exactly once.
 TEST_F(MicrotaskQueueTest, VisitRoot) {
   // Ensure that the ring buffer has separate in-use region.
   for (int i = 0; i < MicrotaskQueue::kMinimumCapacity / 2 + 1; ++i) {
     microtask_queue()->EnqueueMicrotask(*NewMicrotask([] {}));
   }
   EXPECT_EQ(MicrotaskQueue::kMinimumCapacity / 2 + 1,
             microtask_queue()->RunMicrotasks(isolate()));

   std::vector<Object> expected;
   for (int i = 0; i < MicrotaskQueue::kMinimumCapacity / 2 + 1; ++i) {
     Handle<Microtask> microtask = NewMicrotask([] {});
     expected.push_back(*microtask);
     microtask_queue()->EnqueueMicrotask(*microtask);
   }
   EXPECT_GT(microtask_queue()->start() + microtask_queue()->size(),
             microtask_queue()->capacity());

   RecordingVisitor visitor;
   microtask_queue()->IterateMicrotasks(&visitor);

   std::vector<Object> actual = visitor.visited();
   std::sort(expected.begin(), expected.end());
   std::sort(actual.begin(), actual.end());
   EXPECT_EQ(expected, actual);
 }

 TEST_F(MicrotaskQueueTest, PromiseHandlerContext) {
   Local<v8::Context> v8_context2 = v8::Context::New(v8_isolate());
   Local<v8::Context> v8_context3 = v8::Context::New(v8_isolate());
   Local<v8::Context> v8_context4 = v8::Context::New(v8_isolate());
   Handle<Context> context2 = Utils::OpenHandle(*v8_context2, isolate());
   Handle<Context> context3 = Utils::OpenHandle(*v8_context3, isolate());
   Handle<Context> context4 = Utils::OpenHandle(*v8_context3, isolate());
   context2->native_context().set_microtask_queue(microtask_queue());
   context3->native_context().set_microtask_queue(microtask_queue());
   context4->native_context().set_microtask_queue(microtask_queue());

   Handle<JSFunction> handler;
   Handle<JSProxy> proxy;
   Handle<JSProxy> revoked_proxy;
   Handle<JSBoundFunction> bound;

   // Create a JSFunction on |context2|
   {
     v8::Context::Scope scope(v8_context2);
     handler = RunJS<JSFunction>("()=>{}");
     EXPECT_EQ(*context2,
               *JSReceiver::GetContextForMicrotask(handler).ToHandleChecked());
   }

   // Create a JSProxy on |context3|.
   {
     v8::Context::Scope scope(v8_context3);
     ASSERT_TRUE(
         v8_context3->Global()
             ->Set(v8_context3, NewString("handler"), Utils::ToLocal(handler))
             .FromJust());
     proxy = RunJS<JSProxy>("new Proxy(handler, {})");
     revoked_proxy = RunJS<JSProxy>(
         "let {proxy, revoke} = Proxy.revocable(handler, {});"
         "revoke();"
         "proxy");
     EXPECT_EQ(*context2,
               *JSReceiver::GetContextForMicrotask(proxy).ToHandleChecked());
     EXPECT_TRUE(JSReceiver::GetContextForMicrotask(revoked_proxy).is_null());
   }

   // Create a JSBoundFunction on |context4|.
   // Note that its CreationContext and ContextForTaskCancellation is |context2|.
   {
     v8::Context::Scope scope(v8_context4);
     ASSERT_TRUE(
         v8_context4->Global()
             ->Set(v8_context4, NewString("handler"), Utils::ToLocal(handler))
             .FromJust());
     bound = RunJS<JSBoundFunction>("handler.bind()");
     EXPECT_EQ(*context2,
               *JSReceiver::GetContextForMicrotask(bound).ToHandleChecked());
   }

   // Give the objects to the main context.
   SetGlobalProperty("handler", Utils::ToLocal(handler));
   SetGlobalProperty("proxy", Utils::ToLocal(proxy));
   SetGlobalProperty("revoked_proxy", Utils::ToLocal(revoked_proxy));
   SetGlobalProperty("bound", Utils::ToLocal(Handle<JSReceiver>::cast(bound)));
   RunJS(
       "Promise.resolve().then(handler);"
       "Promise.reject().catch(proxy);"
       "Promise.resolve().then(revoked_proxy);"
       "Promise.resolve().then(bound);");

   ASSERT_EQ(4, microtask_queue()->size());
   Handle<Microtask> microtask1(microtask_queue()->get(0), isolate());
   ASSERT_TRUE(microtask1->IsPromiseFulfillReactionJobTask());
   EXPECT_EQ(*context2,
             Handle<PromiseFulfillReactionJobTask>::cast(microtask1)->context());

   Handle<Microtask> microtask2(microtask_queue()->get(1), isolate());
   ASSERT_TRUE(microtask2->IsPromiseRejectReactionJobTask());
   EXPECT_EQ(*context2,
             Handle<PromiseRejectReactionJobTask>::cast(microtask2)->context());

   Handle<Microtask> microtask3(microtask_queue()->get(2), isolate());
   ASSERT_TRUE(microtask3->IsPromiseFulfillReactionJobTask());
   // |microtask3| corresponds to a PromiseReaction for |revoked_proxy|.
   // As |revoked_proxy| doesn't have a context, the current context should be
   // used as the fallback context.
   EXPECT_EQ(*native_context(),
             Handle<PromiseFulfillReactionJobTask>::cast(microtask3)->context());

   Handle<Microtask> microtask4(microtask_queue()->get(3), isolate());
   ASSERT_TRUE(microtask4->IsPromiseFulfillReactionJobTask());
   EXPECT_EQ(*context2,
             Handle<PromiseFulfillReactionJobTask>::cast(microtask4)->context());

   v8_context4->DetachGlobal();
   v8_context3->DetachGlobal();
   v8_context2->DetachGlobal();
 }

 TEST_F(MicrotaskQueueTest, DetachGlobal_Enqueue) {
   EXPECT_EQ(0, microtask_queue()->size());

   // Detach MicrotaskQueue from the current context.
   context()->DetachGlobal();

   // No microtask should be enqueued after DetachGlobal call.
   EXPECT_EQ(0, microtask_queue()->size());
   RunJS("Promise.resolve().then(()=>{})");
   EXPECT_EQ(0, microtask_queue()->size());
 }

 TEST_F(MicrotaskQueueTest, DetachGlobal_Run) {
   EXPECT_EQ(0, microtask_queue()->size());

   // Enqueue microtasks to the current context.
   Handle<JSArray> ran = RunJS<JSArray>(
       "var ran = [false, false, false, false];"
       "Promise.resolve().then(() => { ran[0] = true; });"
       "Promise.reject().catch(() => { ran[1] = true; });"
       "ran");

   Handle<JSFunction> function =
       RunJS<JSFunction>("(function() { ran[2] = true; })");
   Handle<CallableTask> callable =
       factory()->NewCallableTask(function, Utils::OpenHandle(*context()));
   microtask_queue()->EnqueueMicrotask(*callable);

   // The handler should not run at this point.
   const int kNumExpectedTasks = 3;
   for (int i = 0; i < kNumExpectedTasks; ++i) {
     EXPECT_TRUE(
         Object::GetElement(isolate(), ran, i).ToHandleChecked()->IsFalse());
   }
   EXPECT_EQ(kNumExpectedTasks, microtask_queue()->size());

   // Detach MicrotaskQueue from the current context.
   context()->DetachGlobal();

   // RunMicrotasks processes pending Microtasks, but Microtasks that are
   // associated to a detached context should be cancelled and should not take
   // effect.
   microtask_queue()->RunMicrotasks(isolate());
   EXPECT_EQ(0, microtask_queue()->size());
   for (int i = 0; i < kNumExpectedTasks; ++i) {
     EXPECT_TRUE(
         Object::GetElement(isolate(), ran, i).ToHandleChecked()->IsFalse());
   }
 }

 TEST_F(MicrotaskQueueTest, DetachGlobal_FinalizationGroup) {
   // Enqueue an FinalizationGroupCleanupTask.
   Handle<JSArray> ran = RunJS<JSArray>(
       "var ran = [false];"
       "var wf = new FinalizationGroup(() => { ran[0] = true; });"
       "(function() { wf.register({}, {}); })();"
       "gc();"
       "ran");

   EXPECT_TRUE(
       Object::GetElement(isolate(), ran, 0).ToHandleChecked()->IsFalse());
   EXPECT_EQ(1, microtask_queue()->size());

   // Detach MicrotaskQueue from the current context.
   context()->DetachGlobal();

   microtask_queue()->RunMicrotasks(isolate());

   // RunMicrotasks processes the pending Microtask, but Microtasks that are
   // associated to a detached context should be cancelled and should not take
   // effect.
   EXPECT_EQ(0, microtask_queue()->size());
   EXPECT_TRUE(
       Object::GetElement(isolate(), ran, 0).ToHandleChecked()->IsFalse());
 }

 namespace {

 void DummyPromiseHook(PromiseHookType type, Local<Promise> promise,
                       Local<Value> parent) {}

 }  // namespace

 TEST_F(MicrotaskQueueTest, DetachGlobal_PromiseResolveThenableJobTask) {
   // Use a PromiseHook to switch the implementation to ResolvePromise runtime,
   // instead of ResolvePromise builtin.
   v8_isolate()->SetPromiseHook(&DummyPromiseHook);

   RunJS(
       "var resolve;"
       "var promise = new Promise(r => { resolve = r; });"
       "promise.then(() => {});"
       "resolve({});");

   // A PromiseResolveThenableJobTask is pending in the MicrotaskQueue.
   EXPECT_EQ(1, microtask_queue()->size());

   // Detach MicrotaskQueue from the current context.
   context()->DetachGlobal();

   // RunMicrotasks processes the pending Microtask, but Microtasks that are
   // associated to a detached context should be cancelled and should not take
   // effect.
   // As PromiseResolveThenableJobTask queues another task for resolution,
   // the return value is 2 if it ran.
   EXPECT_EQ(1, microtask_queue()->RunMicrotasks(isolate()));
   EXPECT_EQ(0, microtask_queue()->size());
 }

 TEST_F(MicrotaskQueueTest, DetachGlobal_HandlerContext) {
   // EnqueueMicrotask should use the context associated to the handler instead
   // of the current context. E.g.
   //   // At Context A.
   //   let resolved = Promise.resolve();
   //   // Call DetachGlobal on A, so that microtasks associated to A is
   //   // cancelled.
   //
   //   // At Context B.
   //   let handler = () => {
   //     console.log("here");
   //   };
   //   // The microtask to run |handler| should be associated to B instead of A,
   //   // so that handler runs even |resolved| is on the detached context A.
   //   resolved.then(handler);

   Handle<JSReceiver> results = isolate()->factory()->NewJSObjectWithNullProto();

   // These belong to a stale Context.
   Handle<JSPromise> stale_resolved_promise;
   Handle<JSPromise> stale_rejected_promise;
   Handle<JSReceiver> stale_handler;

   Local<v8::Context> sub_context = v8::Context::New(v8_isolate());
   {
     v8::Context::Scope scope(sub_context);
     stale_resolved_promise = RunJS<JSPromise>("Promise.resolve()");
     stale_rejected_promise = RunJS<JSPromise>("Promise.reject()");
     stale_handler = RunJS<JSReceiver>(
         "(results, label) => {"
         "  results[label] = true;"
         "}");
   }
   // DetachGlobal() cancells all microtasks associated to the context.
   sub_context->DetachGlobal();
   sub_context.Clear();

   SetGlobalProperty("results", Utils::ToLocal(results));
   SetGlobalProperty(
       "stale_resolved_promise",
       Utils::ToLocal(Handle<JSReceiver>::cast(stale_resolved_promise)));
   SetGlobalProperty(
       "stale_rejected_promise",
       Utils::ToLocal(Handle<JSReceiver>::cast(stale_rejected_promise)));
   SetGlobalProperty("stale_handler", Utils::ToLocal(stale_handler));

   // Set valid handlers to stale promises.
   RunJS(
       "stale_resolved_promise.then(() => {"
       "  results['stale_resolved_promise'] = true;"
       "})");
   RunJS(
       "stale_rejected_promise.catch(() => {"
       "  results['stale_rejected_promise'] = true;"
       "})");
   microtask_queue()->RunMicrotasks(isolate());
   EXPECT_TRUE(
       JSReceiver::HasProperty(results, NameFromChars("stale_resolved_promise"))
           .FromJust());
   EXPECT_TRUE(
       JSReceiver::HasProperty(results, NameFromChars("stale_rejected_promise"))
           .FromJust());

   // Set stale handlers to valid promises.
   RunJS(
       "Promise.resolve("
       "    stale_handler.bind(null, results, 'stale_handler_resolve'))");
   RunJS(
       "Promise.reject("
       "    stale_handler.bind(null, results, 'stale_handler_reject'))");
   microtask_queue()->RunMicrotasks(isolate());
   EXPECT_FALSE(
       JSReceiver::HasProperty(results, NameFromChars("stale_handler_resolve"))
           .FromJust());
   EXPECT_FALSE(
       JSReceiver::HasProperty(results, NameFromChars("stale_handler_reject"))
           .FromJust());
 }

 TEST_F(MicrotaskQueueTest, DetachGlobal_Chain) {
   Handle<JSPromise> stale_rejected_promise;

   Local<v8::Context> sub_context = v8::Context::New(v8_isolate());
   {
     v8::Context::Scope scope(sub_context);
     stale_rejected_promise = RunJS<JSPromise>("Promise.reject()");
   }
   sub_context->DetachGlobal();
   sub_context.Clear();

   SetGlobalProperty(
       "stale_rejected_promise",
       Utils::ToLocal(Handle<JSReceiver>::cast(stale_rejected_promise)));
   Handle<JSArray> result = RunJS<JSArray>(
       "let result = [false];"
       "stale_rejected_promise"
       "  .then(() => {})"
       "  .catch(() => {"
       "    result[0] = true;"
       "  });"
       "result");
   microtask_queue()->RunMicrotasks(isolate());
   EXPECT_TRUE(
       Object::GetElement(isolate(), result, 0).ToHandleChecked()->IsTrue());
 }

 TEST_F(MicrotaskQueueTest, DetachGlobal_InactiveHandler) {
   Local<v8::Context> sub_context = v8::Context::New(v8_isolate());
   Utils::OpenHandle(*sub_context)
       ->native_context()
       .set_microtask_queue(microtask_queue());

   Handle<JSArray> result;
   Handle<JSFunction> stale_handler;
   Handle<JSPromise> stale_promise;
   {
     v8::Context::Scope scope(sub_context);
     result = RunJS<JSArray>("var result = [false, false]; result");
     stale_handler = RunJS<JSFunction>("() => { result[0] = true; }");
     stale_promise = RunJS<JSPromise>(
         "var stale_promise = new Promise(()=>{});"
         "stale_promise");
     RunJS("stale_promise.then(() => { result [1] = true; });");
   }
   sub_context->DetachGlobal();
   sub_context.Clear();

   // The context of |stale_handler| and |stale_promise| is detached at this
   // point.
   // Ensure that resolution handling for |stale_handler| is cancelled without
   // crash. Also, the resolution of |stale_promise| is also cancelled.

   SetGlobalProperty("stale_handler", Utils::ToLocal(stale_handler));
   RunJS("%EnqueueMicrotask(stale_handler)");

   v8_isolate()->EnqueueMicrotask(Utils::ToLocal(stale_handler));

   JSPromise::Fulfill(
       stale_promise,
       handle(ReadOnlyRoots(isolate()).undefined_value(), isolate()));

   microtask_queue()->RunMicrotasks(isolate());
   EXPECT_TRUE(
       Object::GetElement(isolate(), result, 0).ToHandleChecked()->IsFalse());
   EXPECT_TRUE(
       Object::GetElement(isolate(), result, 1).ToHandleChecked()->IsFalse());
 }

 TEST_F(MicrotaskQueueTest, MicrotasksScope) {
   ASSERT_NE(isolate()->default_microtask_queue(), microtask_queue());
   microtask_queue()->set_microtasks_policy(MicrotasksPolicy::kScoped);

   bool ran = false;
   {
     MicrotasksScope scope(v8_isolate(), microtask_queue(),
                           MicrotasksScope::kRunMicrotasks);
     microtask_queue()->EnqueueMicrotask(*NewMicrotask([&ran]() {
       EXPECT_FALSE(ran);
       ran = true;
     }));
   }
   EXPECT_TRUE(ran);
 }

 }  // 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/execution/microtask-queue.h"

	#include <algorithm>
	#include <functional>
	#include <memory>
	#include <vector>

	#include "src/heap/factory.h"
	#include "src/objects/foreign.h"
	#include "src/objects/js-array-inl.h"
	#include "src/objects/js-objects-inl.h"
	#include "src/objects/objects-inl.h"
	#include "src/objects/promise-inl.h"
	#include "src/objects/visitors.h"
	#include "test/unittests/test-utils.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace v8 {
	namespace internal {

	using Closure = std::function<void()>;

	void RunStdFunction(void* data) {
	std::unique_ptr<Closure> f(static_cast<Closure*>(data));
	(*f)();
	}

	template <typename TMixin>
	class WithFinalizationGroupMixin : public TMixin {
	public:
	WithFinalizationGroupMixin() = default;
	~WithFinalizationGroupMixin() override = default;

	static void SetUpTestCase() {
	CHECK_NULL(save_flags_);
	save_flags_ = new SaveFlags();
	FLAG_harmony_weak_refs = true;
	FLAG_expose_gc = true;
	FLAG_allow_natives_syntax = true;
	TMixin::SetUpTestCase();
	}

	static void TearDownTestCase() {
	TMixin::TearDownTestCase();
	CHECK_NOT_NULL(save_flags_);
	delete save_flags_;
	save_flags_ = nullptr;
	}

	private:
	static SaveFlags* save_flags_;

	DISALLOW_COPY_AND_ASSIGN(WithFinalizationGroupMixin);
	};

	template <typename TMixin>
	SaveFlags* WithFinalizationGroupMixin<TMixin>::save_flags_ = nullptr;

	using TestWithNativeContextAndFinalizationGroup = //
	WithInternalIsolateMixin< //
	WithContextMixin< //
	WithFinalizationGroupMixin< //
	WithIsolateScopeMixin< //
	WithSharedIsolateMixin< //
	::testing::Test>>>>>;

	class MicrotaskQueueTest : public TestWithNativeContextAndFinalizationGroup {
	public:
	template <typename F>
	Handle<Microtask> NewMicrotask(F&& f) {
	Handle<Foreign> runner =
	factory()->NewForeign(reinterpret_cast<Address>(&RunStdFunction));
	Handle<Foreign> data = factory()->NewForeign(
	reinterpret_cast<Address>(new Closure(std::forward<F>(f))));
	return factory()->NewCallbackTask(runner, data);
	}

	void SetUp() override {
	microtask_queue_ = MicrotaskQueue::New(isolate());
	native_context()->set_microtask_queue(microtask_queue());
	}

	void TearDown() override {
	if (microtask_queue()) {
	microtask_queue()->RunMicrotasks(isolate());
	context()->DetachGlobal();
	}
	}

	MicrotaskQueue* microtask_queue() const { return microtask_queue_.get(); }

	void ClearTestMicrotaskQueue() {
	context()->DetachGlobal();
	microtask_queue_ = nullptr;
	}

	template <size_t N>
	Handle<Name> NameFromChars(const char (&chars)[N]) {
	return isolate()->factory()->NewStringFromStaticChars(chars);
	}

	private:
	std::unique_ptr<MicrotaskQueue> microtask_queue_;
	};

	class RecordingVisitor : public RootVisitor {
	public:
	RecordingVisitor() = default;
	~RecordingVisitor() override = default;

	void VisitRootPointers(Root root, const char* description,
	FullObjectSlot start, FullObjectSlot end) override {
	for (FullObjectSlot current = start; current != end; ++current) {
	visited_.push_back(*current);
	}
	}

	const std::vector<Object>& visited() const { return visited_; }

	private:
	std::vector<Object> visited_;
	};

	// Sanity check. Ensure a microtask is stored in a queue and run.
	TEST_F(MicrotaskQueueTest, EnqueueAndRun) {
	bool ran = false;
	EXPECT_EQ(0, microtask_queue()->capacity());
	EXPECT_EQ(0, microtask_queue()->size());
	microtask_queue()->EnqueueMicrotask(*NewMicrotask([&ran] {
	EXPECT_FALSE(ran);
	ran = true;
	}));
	EXPECT_EQ(MicrotaskQueue::kMinimumCapacity, microtask_queue()->capacity());
	EXPECT_EQ(1, microtask_queue()->size());
	EXPECT_EQ(1, microtask_queue()->RunMicrotasks(isolate()));
	EXPECT_TRUE(ran);
	EXPECT_EQ(0, microtask_queue()->size());
	}

	// Check for a buffer growth.
	TEST_F(MicrotaskQueueTest, BufferGrowth) {
	int count = 0;

	// Enqueue and flush the queue first to have non-zero \|start_\|.
	microtask_queue()->EnqueueMicrotask(
	*NewMicrotask([&count] { EXPECT_EQ(0, count++); }));
	EXPECT_EQ(1, microtask_queue()->RunMicrotasks(isolate()));

	EXPECT_LT(0, microtask_queue()->capacity());
	EXPECT_EQ(0, microtask_queue()->size());
	EXPECT_EQ(1, microtask_queue()->start());

	// Fill the queue with Microtasks.
	for (int i = 1; i <= MicrotaskQueue::kMinimumCapacity; ++i) {
	microtask_queue()->EnqueueMicrotask(
	*NewMicrotask([&count, i] { EXPECT_EQ(i, count++); }));
	}
	EXPECT_EQ(MicrotaskQueue::kMinimumCapacity, microtask_queue()->capacity());
	EXPECT_EQ(MicrotaskQueue::kMinimumCapacity, microtask_queue()->size());

	// Add another to grow the ring buffer.
	microtask_queue()->EnqueueMicrotask(*NewMicrotask(
	[&] { EXPECT_EQ(MicrotaskQueue::kMinimumCapacity + 1, count++); }));

	EXPECT_LT(MicrotaskQueue::kMinimumCapacity, microtask_queue()->capacity());
	EXPECT_EQ(MicrotaskQueue::kMinimumCapacity + 1, microtask_queue()->size());

	// Run all pending Microtasks to ensure they run in the proper order.
	EXPECT_EQ(MicrotaskQueue::kMinimumCapacity + 1,
	microtask_queue()->RunMicrotasks(isolate()));
	EXPECT_EQ(MicrotaskQueue::kMinimumCapacity + 2, count);
	}

	// MicrotaskQueue instances form a doubly linked list.
	TEST_F(MicrotaskQueueTest, InstanceChain) {
	ClearTestMicrotaskQueue();

	MicrotaskQueue* default_mtq = isolate()->default_microtask_queue();
	ASSERT_TRUE(default_mtq);
	EXPECT_EQ(default_mtq, default_mtq->next());
	EXPECT_EQ(default_mtq, default_mtq->prev());

	// Create two instances, and check their connection.
	// The list contains all instances in the creation order, and the next of the
	// last instance is the first instance:
	// default_mtq -> mtq1 -> mtq2 -> default_mtq.
	std::unique_ptr<MicrotaskQueue> mtq1 = MicrotaskQueue::New(isolate());
	std::unique_ptr<MicrotaskQueue> mtq2 = MicrotaskQueue::New(isolate());
	EXPECT_EQ(default_mtq->next(), mtq1.get());
	EXPECT_EQ(mtq1->next(), mtq2.get());
	EXPECT_EQ(mtq2->next(), default_mtq);
	EXPECT_EQ(default_mtq, mtq1->prev());
	EXPECT_EQ(mtq1.get(), mtq2->prev());
	EXPECT_EQ(mtq2.get(), default_mtq->prev());

	// Deleted item should be also removed from the list.
	mtq1 = nullptr;
	EXPECT_EQ(default_mtq->next(), mtq2.get());
	EXPECT_EQ(mtq2->next(), default_mtq);
	EXPECT_EQ(default_mtq, mtq2->prev());
	EXPECT_EQ(mtq2.get(), default_mtq->prev());
	}

	// Pending Microtasks in MicrotaskQueues are strong roots. Ensure they are
	// visited exactly once.
	TEST_F(MicrotaskQueueTest, VisitRoot) {
	// Ensure that the ring buffer has separate in-use region.
	for (int i = 0; i < MicrotaskQueue::kMinimumCapacity / 2 + 1; ++i) {
	microtask_queue()->EnqueueMicrotask(*NewMicrotask([] {}));
	}
	EXPECT_EQ(MicrotaskQueue::kMinimumCapacity / 2 + 1,
	microtask_queue()->RunMicrotasks(isolate()));

	std::vector<Object> expected;
	for (int i = 0; i < MicrotaskQueue::kMinimumCapacity / 2 + 1; ++i) {
	Handle<Microtask> microtask = NewMicrotask([] {});
	expected.push_back(*microtask);
	microtask_queue()->EnqueueMicrotask(*microtask);
	}
	EXPECT_GT(microtask_queue()->start() + microtask_queue()->size(),
	microtask_queue()->capacity());

	RecordingVisitor visitor;
	microtask_queue()->IterateMicrotasks(&visitor);

	std::vector<Object> actual = visitor.visited();
	std::sort(expected.begin(), expected.end());
	std::sort(actual.begin(), actual.end());
	EXPECT_EQ(expected, actual);
	}

	TEST_F(MicrotaskQueueTest, PromiseHandlerContext) {
	Local<v8::Context> v8_context2 = v8::Context::New(v8_isolate());
	Local<v8::Context> v8_context3 = v8::Context::New(v8_isolate());
	Local<v8::Context> v8_context4 = v8::Context::New(v8_isolate());
	Handle<Context> context2 = Utils::OpenHandle(*v8_context2, isolate());
	Handle<Context> context3 = Utils::OpenHandle(*v8_context3, isolate());
	Handle<Context> context4 = Utils::OpenHandle(*v8_context3, isolate());
	context2->native_context().set_microtask_queue(microtask_queue());
	context3->native_context().set_microtask_queue(microtask_queue());
	context4->native_context().set_microtask_queue(microtask_queue());

	Handle<JSFunction> handler;
	Handle<JSProxy> proxy;
	Handle<JSProxy> revoked_proxy;
	Handle<JSBoundFunction> bound;

	// Create a JSFunction on \|context2\|
	{
	v8::Context::Scope scope(v8_context2);
	handler = RunJS<JSFunction>("()=>{}");
	EXPECT_EQ(*context2,
	*JSReceiver::GetContextForMicrotask(handler).ToHandleChecked());
	}

	// Create a JSProxy on \|context3\|.
	{
	v8::Context::Scope scope(v8_context3);
	ASSERT_TRUE(
	v8_context3->Global()
	->Set(v8_context3, NewString("handler"), Utils::ToLocal(handler))
	.FromJust());
	proxy = RunJS<JSProxy>("new Proxy(handler, {})");
	revoked_proxy = RunJS<JSProxy>(
	"let {proxy, revoke} = Proxy.revocable(handler, {});"
	"revoke();"
	"proxy");
	EXPECT_EQ(*context2,
	*JSReceiver::GetContextForMicrotask(proxy).ToHandleChecked());
	EXPECT_TRUE(JSReceiver::GetContextForMicrotask(revoked_proxy).is_null());
	}

	// Create a JSBoundFunction on \|context4\|.
	// Note that its CreationContext and ContextForTaskCancellation is \|context2\|.
	{
	v8::Context::Scope scope(v8_context4);
	ASSERT_TRUE(
	v8_context4->Global()
	->Set(v8_context4, NewString("handler"), Utils::ToLocal(handler))
	.FromJust());
	bound = RunJS<JSBoundFunction>("handler.bind()");
	EXPECT_EQ(*context2,
	*JSReceiver::GetContextForMicrotask(bound).ToHandleChecked());
	}

	// Give the objects to the main context.
	SetGlobalProperty("handler", Utils::ToLocal(handler));
	SetGlobalProperty("proxy", Utils::ToLocal(proxy));
	SetGlobalProperty("revoked_proxy", Utils::ToLocal(revoked_proxy));
	SetGlobalProperty("bound", Utils::ToLocal(Handle<JSReceiver>::cast(bound)));
	RunJS(
	"Promise.resolve().then(handler);"
	"Promise.reject().catch(proxy);"
	"Promise.resolve().then(revoked_proxy);"
	"Promise.resolve().then(bound);");

	ASSERT_EQ(4, microtask_queue()->size());
	Handle<Microtask> microtask1(microtask_queue()->get(0), isolate());
	ASSERT_TRUE(microtask1->IsPromiseFulfillReactionJobTask());
	EXPECT_EQ(*context2,
	Handle<PromiseFulfillReactionJobTask>::cast(microtask1)->context());

	Handle<Microtask> microtask2(microtask_queue()->get(1), isolate());
	ASSERT_TRUE(microtask2->IsPromiseRejectReactionJobTask());
	EXPECT_EQ(*context2,
	Handle<PromiseRejectReactionJobTask>::cast(microtask2)->context());

	Handle<Microtask> microtask3(microtask_queue()->get(2), isolate());
	ASSERT_TRUE(microtask3->IsPromiseFulfillReactionJobTask());
	// \|microtask3\| corresponds to a PromiseReaction for \|revoked_proxy\|.
	// As \|revoked_proxy\| doesn't have a context, the current context should be
	// used as the fallback context.
	EXPECT_EQ(*native_context(),
	Handle<PromiseFulfillReactionJobTask>::cast(microtask3)->context());

	Handle<Microtask> microtask4(microtask_queue()->get(3), isolate());
	ASSERT_TRUE(microtask4->IsPromiseFulfillReactionJobTask());
	EXPECT_EQ(*context2,
	Handle<PromiseFulfillReactionJobTask>::cast(microtask4)->context());

	v8_context4->DetachGlobal();
	v8_context3->DetachGlobal();
	v8_context2->DetachGlobal();
	}

	TEST_F(MicrotaskQueueTest, DetachGlobal_Enqueue) {
	EXPECT_EQ(0, microtask_queue()->size());

	// Detach MicrotaskQueue from the current context.
	context()->DetachGlobal();

	// No microtask should be enqueued after DetachGlobal call.
	EXPECT_EQ(0, microtask_queue()->size());
	RunJS("Promise.resolve().then(()=>{})");
	EXPECT_EQ(0, microtask_queue()->size());
	}

	TEST_F(MicrotaskQueueTest, DetachGlobal_Run) {
	EXPECT_EQ(0, microtask_queue()->size());

	// Enqueue microtasks to the current context.
	Handle<JSArray> ran = RunJS<JSArray>(
	"var ran = [false, false, false, false];"
	"Promise.resolve().then(() => { ran[0] = true; });"
	"Promise.reject().catch(() => { ran[1] = true; });"
	"ran");

	Handle<JSFunction> function =
	RunJS<JSFunction>("(function() { ran[2] = true; })");
	Handle<CallableTask> callable =
	factory()->NewCallableTask(function, Utils::OpenHandle(*context()));
	microtask_queue()->EnqueueMicrotask(*callable);

	// The handler should not run at this point.
	const int kNumExpectedTasks = 3;
	for (int i = 0; i < kNumExpectedTasks; ++i) {
	EXPECT_TRUE(
	Object::GetElement(isolate(), ran, i).ToHandleChecked()->IsFalse());
	}
	EXPECT_EQ(kNumExpectedTasks, microtask_queue()->size());

	// Detach MicrotaskQueue from the current context.
	context()->DetachGlobal();

	// RunMicrotasks processes pending Microtasks, but Microtasks that are
	// associated to a detached context should be cancelled and should not take
	// effect.
	microtask_queue()->RunMicrotasks(isolate());
	EXPECT_EQ(0, microtask_queue()->size());
	for (int i = 0; i < kNumExpectedTasks; ++i) {
	EXPECT_TRUE(
	Object::GetElement(isolate(), ran, i).ToHandleChecked()->IsFalse());
	}
	}

	TEST_F(MicrotaskQueueTest, DetachGlobal_FinalizationGroup) {
	// Enqueue an FinalizationGroupCleanupTask.
	Handle<JSArray> ran = RunJS<JSArray>(
	"var ran = [false];"
	"var wf = new FinalizationGroup(() => { ran[0] = true; });"
	"(function() { wf.register({}, {}); })();"
	"gc();"
	"ran");

	EXPECT_TRUE(
	Object::GetElement(isolate(), ran, 0).ToHandleChecked()->IsFalse());
	EXPECT_EQ(1, microtask_queue()->size());

	// Detach MicrotaskQueue from the current context.
	context()->DetachGlobal();

	microtask_queue()->RunMicrotasks(isolate());

	// RunMicrotasks processes the pending Microtask, but Microtasks that are
	// associated to a detached context should be cancelled and should not take
	// effect.
	EXPECT_EQ(0, microtask_queue()->size());
	EXPECT_TRUE(
	Object::GetElement(isolate(), ran, 0).ToHandleChecked()->IsFalse());
	}

	namespace {

	void DummyPromiseHook(PromiseHookType type, Local<Promise> promise,
	Local<Value> parent) {}

	} // namespace

	TEST_F(MicrotaskQueueTest, DetachGlobal_PromiseResolveThenableJobTask) {
	// Use a PromiseHook to switch the implementation to ResolvePromise runtime,
	// instead of ResolvePromise builtin.
	v8_isolate()->SetPromiseHook(&DummyPromiseHook);

	RunJS(
	"var resolve;"
	"var promise = new Promise(r => { resolve = r; });"
	"promise.then(() => {});"
	"resolve({});");

	// A PromiseResolveThenableJobTask is pending in the MicrotaskQueue.
	EXPECT_EQ(1, microtask_queue()->size());

	// Detach MicrotaskQueue from the current context.
	context()->DetachGlobal();

	// RunMicrotasks processes the pending Microtask, but Microtasks that are
	// associated to a detached context should be cancelled and should not take
	// effect.
	// As PromiseResolveThenableJobTask queues another task for resolution,
	// the return value is 2 if it ran.
	EXPECT_EQ(1, microtask_queue()->RunMicrotasks(isolate()));
	EXPECT_EQ(0, microtask_queue()->size());
	}

	TEST_F(MicrotaskQueueTest, DetachGlobal_HandlerContext) {
	// EnqueueMicrotask should use the context associated to the handler instead
	// of the current context. E.g.
	// // At Context A.
	// let resolved = Promise.resolve();
	// // Call DetachGlobal on A, so that microtasks associated to A is
	// // cancelled.
	//
	// // At Context B.
	// let handler = () => {
	// console.log("here");
	// };
	// // The microtask to run \|handler\| should be associated to B instead of A,
	// // so that handler runs even \|resolved\| is on the detached context A.
	// resolved.then(handler);

	Handle<JSReceiver> results = isolate()->factory()->NewJSObjectWithNullProto();

	// These belong to a stale Context.
	Handle<JSPromise> stale_resolved_promise;
	Handle<JSPromise> stale_rejected_promise;
	Handle<JSReceiver> stale_handler;

	Local<v8::Context> sub_context = v8::Context::New(v8_isolate());
	{
	v8::Context::Scope scope(sub_context);
	stale_resolved_promise = RunJS<JSPromise>("Promise.resolve()");
	stale_rejected_promise = RunJS<JSPromise>("Promise.reject()");
	stale_handler = RunJS<JSReceiver>(
	"(results, label) => {"
	" results[label] = true;"
	"}");
	}
	// DetachGlobal() cancells all microtasks associated to the context.
	sub_context->DetachGlobal();
	sub_context.Clear();

	SetGlobalProperty("results", Utils::ToLocal(results));
	SetGlobalProperty(
	"stale_resolved_promise",
	Utils::ToLocal(Handle<JSReceiver>::cast(stale_resolved_promise)));
	SetGlobalProperty(
	"stale_rejected_promise",
	Utils::ToLocal(Handle<JSReceiver>::cast(stale_rejected_promise)));
	SetGlobalProperty("stale_handler", Utils::ToLocal(stale_handler));

	// Set valid handlers to stale promises.
	RunJS(
	"stale_resolved_promise.then(() => {"
	" results['stale_resolved_promise'] = true;"
	"})");
	RunJS(
	"stale_rejected_promise.catch(() => {"
	" results['stale_rejected_promise'] = true;"
	"})");
	microtask_queue()->RunMicrotasks(isolate());
	EXPECT_TRUE(
	JSReceiver::HasProperty(results, NameFromChars("stale_resolved_promise"))
	.FromJust());
	EXPECT_TRUE(
	JSReceiver::HasProperty(results, NameFromChars("stale_rejected_promise"))
	.FromJust());

	// Set stale handlers to valid promises.
	RunJS(
	"Promise.resolve("
	" stale_handler.bind(null, results, 'stale_handler_resolve'))");
	RunJS(
	"Promise.reject("
	" stale_handler.bind(null, results, 'stale_handler_reject'))");
	microtask_queue()->RunMicrotasks(isolate());
	EXPECT_FALSE(
	JSReceiver::HasProperty(results, NameFromChars("stale_handler_resolve"))
	.FromJust());
	EXPECT_FALSE(
	JSReceiver::HasProperty(results, NameFromChars("stale_handler_reject"))
	.FromJust());
	}

	TEST_F(MicrotaskQueueTest, DetachGlobal_Chain) {
	Handle<JSPromise> stale_rejected_promise;

	Local<v8::Context> sub_context = v8::Context::New(v8_isolate());
	{
	v8::Context::Scope scope(sub_context);
	stale_rejected_promise = RunJS<JSPromise>("Promise.reject()");
	}
	sub_context->DetachGlobal();
	sub_context.Clear();

	SetGlobalProperty(
	"stale_rejected_promise",
	Utils::ToLocal(Handle<JSReceiver>::cast(stale_rejected_promise)));
	Handle<JSArray> result = RunJS<JSArray>(
	"let result = [false];"
	"stale_rejected_promise"
	" .then(() => {})"
	" .catch(() => {"
	" result[0] = true;"
	" });"
	"result");
	microtask_queue()->RunMicrotasks(isolate());
	EXPECT_TRUE(
	Object::GetElement(isolate(), result, 0).ToHandleChecked()->IsTrue());
	}

	TEST_F(MicrotaskQueueTest, DetachGlobal_InactiveHandler) {
	Local<v8::Context> sub_context = v8::Context::New(v8_isolate());
	Utils::OpenHandle(*sub_context)
	->native_context()
	.set_microtask_queue(microtask_queue());

	Handle<JSArray> result;
	Handle<JSFunction> stale_handler;
	Handle<JSPromise> stale_promise;
	{
	v8::Context::Scope scope(sub_context);
	result = RunJS<JSArray>("var result = [false, false]; result");
	stale_handler = RunJS<JSFunction>("() => { result[0] = true; }");
	stale_promise = RunJS<JSPromise>(
	"var stale_promise = new Promise(()=>{});"
	"stale_promise");
	RunJS("stale_promise.then(() => { result [1] = true; });");
	}
	sub_context->DetachGlobal();
	sub_context.Clear();

	// The context of \|stale_handler\| and \|stale_promise\| is detached at this
	// point.
	// Ensure that resolution handling for \|stale_handler\| is cancelled without
	// crash. Also, the resolution of \|stale_promise\| is also cancelled.

	SetGlobalProperty("stale_handler", Utils::ToLocal(stale_handler));
	RunJS("%EnqueueMicrotask(stale_handler)");

	v8_isolate()->EnqueueMicrotask(Utils::ToLocal(stale_handler));

	JSPromise::Fulfill(
	stale_promise,
	handle(ReadOnlyRoots(isolate()).undefined_value(), isolate()));

	microtask_queue()->RunMicrotasks(isolate());
	EXPECT_TRUE(
	Object::GetElement(isolate(), result, 0).ToHandleChecked()->IsFalse());
	EXPECT_TRUE(
	Object::GetElement(isolate(), result, 1).ToHandleChecked()->IsFalse());
	}

	TEST_F(MicrotaskQueueTest, MicrotasksScope) {
	ASSERT_NE(isolate()->default_microtask_queue(), microtask_queue());
	microtask_queue()->set_microtasks_policy(MicrotasksPolicy::kScoped);

	bool ran = false;
	{
	MicrotasksScope scope(v8_isolate(), microtask_queue(),
	MicrotasksScope::kRunMicrotasks);
	microtask_queue()->EnqueueMicrotask(*NewMicrotask([&ran]() {
	EXPECT_FALSE(ran);
	ran = true;
	}));
	}
	EXPECT_TRUE(ran);
	}

	} // namespace internal
	} // namespace v8