base/test/repeating_test_future.h - chromium/src - Git at Google

 // Copyright 2021 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_TEST_REPEATING_TEST_FUTURE_H_
 #define BASE_TEST_REPEATING_TEST_FUTURE_H_

 #include <utility>

 #include "base/check.h"
 #include "base/containers/queue.h"
 #include "base/memory/weak_ptr.h"
 #include "base/run_loop.h"
 #include "base/sequence_checker.h"
 #include "base/test/test_future_internal.h"
 #include "base/thread_annotations.h"
 #include "third_party/abseil-cpp/absl/types/optional.h"

 namespace base::test {

 // Related class to |base::test::TestFuture|, which allows its callback and
 // AddValue() method to be called multiple times.
 //
 // Each call to Take() will return one element in FIFO fashion.
 // If no element is available, Take() will wait until an element becomes
 // available.
 //
 // Just like |base::test::TestFuture|, |base::test::RepeatingTestFuture| also
 // supports callbacks which take multiple values. If this is the case Take()
 // will return a tuple containing all values passed to the callback.
 //
 // Example usage:
 //
 //   TEST_F(MyTestFixture, MyTest) {
 //     RepeatingTestFuture<ResultType> future;
 //
 //     InvokeCallbackAsyncTwice(future.GetCallback());
 //
 //     ResultType first_result = future.Get();
 //     ResultType second_result = future.Get();
 //
 //     // When you come here, InvokeCallbackAsyncTwice has finished,
 //     // |first_result| contains the value passed to the first invocation
 //     // of the callback, and |second_result| has the result of the second
 //     // invocation.
 //   }
 //
 // Example without using a callback but using AddValue() instead:
 //
 //   TEST_F(MyTestFixture, MyTest) {
 //     RepeatingTestFuture<std::string> future;
 //
 //     // AddValue() can be used to add an element to the future.
 //     future.AddValue("first-value");
 //     future.AddValue("second-value");
 //
 //     EXPECT_EQ("first-value", future.Take());
 //     EXPECT_EQ("second-value", future.Take());
 //   }
 //
 // Or an example using RepeatingTestFuture::Wait():
 //
 //   TEST_F(MyTestFixture, MyWaitTest) {
 //     RepeatingTestFuture<ResultType> future;
 //
 //     object_under_test.DoSomethingAsync(future.GetCallback());
 //
 //     // Optional. The Take() call below will also wait until the value
 //     // arrives, but this explicit call to Wait() can be useful if you want to
 //     // add extra information.
 //     ASSERT_TRUE(future.Wait()) << "Detailed error message";
 //
 //     ResultType actual_result = future.Take();
 //   }
 //
 // All access to this class must be made from the same sequence.
 template <typename... Types>
 class RepeatingTestFuture {
  public:
   using TupleType = std::tuple<std::decay_t<Types>...>;
   using FirstType = typename std::tuple_element<0, TupleType>::type;

   RepeatingTestFuture() = default;
   RepeatingTestFuture(const RepeatingTestFuture&) = delete;
   RepeatingTestFuture& operator=(const RepeatingTestFuture&) = delete;
   RepeatingTestFuture(RepeatingTestFuture&&) = delete;
   RepeatingTestFuture& operator=(RepeatingTestFuture&&) = delete;
   ~RepeatingTestFuture() = default;

   void AddValue(Types... values) {
     DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);

     elements_.push(std::make_tuple(std::forward<Types>(values)...));
     SignalElementIsAvailable();
   }

   // Waits until an element is available.
   // Returns immediately if one or more elements are already available.
   //
   // Returns true if an element arrived, or false if a timeout happens.
   //
   // Directly calling Wait() is not required as Take() will also wait for
   // the value to arrive, however you can use a direct call to Wait() to
   // improve the error reported:
   //
   //   ASSERT_TRUE(queue.Wait()) << "Detailed error message";
   //
   [[nodiscard]] bool Wait() {
     DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);

     if (IsEmpty())
       WaitForANewElement();

     return !IsEmpty();
   }

   // Returns a callback that when invoked will store all the argument values,
   // and unblock any waiters.
   // This method is templated so you can specify how you need the arguments to
   // be passed - be it const, as reference, or anything you can think off.
   // By default the callback accepts the arguments as |Types...|.
   //
   // Example usage:
   //
   //   RepeatingTestFuture<int, std::string> future;
   //
   //   // returns base::RepeatingCallback<void(int, std::string)>
   //   future.GetCallback();
   //
   //   // returns base::RepeatingCallback<void(int, const std::string&)>
   //   future.GetCallback<int, const std::string&>();
   //
   template <typename... CallbackArgumentsTypes>
   base::RepeatingCallback<void(CallbackArgumentsTypes...)> GetCallback() {
     DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
     return base::BindRepeating(
         [](WeakPtr<RepeatingTestFuture<Types...>> future,
            CallbackArgumentsTypes... values) {
           if (future)
             future->AddValue(std::forward<CallbackArgumentsTypes>(values)...);
         },
         weak_ptr_factory_.GetWeakPtr());
   }

   base::RepeatingCallback<void(Types...)> GetCallback() {
     return GetCallback<Types...>();
   }

   // Returns true if no elements are currently present. Note that consuming all
   // elements through Take() will cause this method to return true after the
   // last available element has been consumed.
   bool IsEmpty() const {
     DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);

     return elements_.empty();
   }

   //////////////////////////////////////////////////////////////////////////////
   //  Accessor methods only available if each element in the future holds a
   //  single value.
   //////////////////////////////////////////////////////////////////////////////

   // Wait for an element to arrive, and move its value out.
   //
   // Will DCHECK if a timeout happens.
   template <typename T = TupleType, internal::EnableIfSingleValue<T> = true>
   FirstType Take() {
     return std::get<0>(TakeTuple());
   }

   //////////////////////////////////////////////////////////////////////////////
   //  Accessor methods only available if each element in the future holds
   //  multiple values.
   //////////////////////////////////////////////////////////////////////////////

   // Wait for an element to arrive, and move a tuple with its values out.
   //
   // Will DCHECK if a timeout happens.
   template <typename T = TupleType, internal::EnableIfMultiValue<T> = true>
   TupleType Take() {
     return TakeTuple();
   }

  private:
   // Wait until a new element is available.
   void WaitForANewElement() VALID_CONTEXT_REQUIRED(sequence_checker_) {
     DCHECK(!run_loop_.has_value());

     // Create a new run loop.
     run_loop_.emplace();
     // Wait until 'run_loop_->Quit()' is called.
     run_loop_->Run();
     run_loop_.reset();
   }

   void SignalElementIsAvailable() VALID_CONTEXT_REQUIRED(sequence_checker_) {
     if (run_loop_.has_value())
       run_loop_->Quit();
   }

   TupleType TakeTuple() {
     DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);

     // Ensure an element is available.
     bool success = Wait();
     DCHECK(success) << "Waiting for an element timed out.";

     auto result = std::move(elements_.front());
     elements_.pop();
     return result;
   }

   base::queue<TupleType> elements_ GUARDED_BY_CONTEXT(sequence_checker_);

   // Used by Wait() to know when AddValue() is called.
   absl::optional<base::RunLoop> run_loop_ GUARDED_BY_CONTEXT(sequence_checker_);

   SEQUENCE_CHECKER(sequence_checker_);

   base::WeakPtrFactory<RepeatingTestFuture<Types...>> weak_ptr_factory_{this};
 };

 }  // namespace base::test

 #endif  // BASE_TEST_REPEATING_TEST_FUTURE_H_
	// Copyright 2021 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_TEST_REPEATING_TEST_FUTURE_H_
	#define BASE_TEST_REPEATING_TEST_FUTURE_H_

	#include <utility>

	#include "base/check.h"
	#include "base/containers/queue.h"
	#include "base/memory/weak_ptr.h"
	#include "base/run_loop.h"
	#include "base/sequence_checker.h"
	#include "base/test/test_future_internal.h"
	#include "base/thread_annotations.h"
	#include "third_party/abseil-cpp/absl/types/optional.h"

	namespace base::test {

	// Related class to \|base::test::TestFuture\|, which allows its callback and
	// AddValue() method to be called multiple times.
	//
	// Each call to Take() will return one element in FIFO fashion.
	// If no element is available, Take() will wait until an element becomes
	// available.
	//
	// Just like \|base::test::TestFuture\|, \|base::test::RepeatingTestFuture\| also
	// supports callbacks which take multiple values. If this is the case Take()
	// will return a tuple containing all values passed to the callback.
	//
	// Example usage:
	//
	// TEST_F(MyTestFixture, MyTest) {
	// RepeatingTestFuture<ResultType> future;
	//
	// InvokeCallbackAsyncTwice(future.GetCallback());
	//
	// ResultType first_result = future.Get();
	// ResultType second_result = future.Get();
	//
	// // When you come here, InvokeCallbackAsyncTwice has finished,
	// // \|first_result\| contains the value passed to the first invocation
	// // of the callback, and \|second_result\| has the result of the second
	// // invocation.
	// }
	//
	// Example without using a callback but using AddValue() instead:
	//
	// TEST_F(MyTestFixture, MyTest) {
	// RepeatingTestFuture<std::string> future;
	//
	// // AddValue() can be used to add an element to the future.
	// future.AddValue("first-value");
	// future.AddValue("second-value");
	//
	// EXPECT_EQ("first-value", future.Take());
	// EXPECT_EQ("second-value", future.Take());
	// }
	//
	// Or an example using RepeatingTestFuture::Wait():
	//
	// TEST_F(MyTestFixture, MyWaitTest) {
	// RepeatingTestFuture<ResultType> future;
	//
	// object_under_test.DoSomethingAsync(future.GetCallback());
	//
	// // Optional. The Take() call below will also wait until the value
	// // arrives, but this explicit call to Wait() can be useful if you want to
	// // add extra information.
	// ASSERT_TRUE(future.Wait()) << "Detailed error message";
	//
	// ResultType actual_result = future.Take();
	// }
	//
	// All access to this class must be made from the same sequence.
	template <typename... Types>
	class RepeatingTestFuture {
	public:
	using TupleType = std::tuple<std::decay_t<Types>...>;
	using FirstType = typename std::tuple_element<0, TupleType>::type;

	RepeatingTestFuture() = default;
	RepeatingTestFuture(const RepeatingTestFuture&) = delete;
	RepeatingTestFuture& operator=(const RepeatingTestFuture&) = delete;
	RepeatingTestFuture(RepeatingTestFuture&&) = delete;
	RepeatingTestFuture& operator=(RepeatingTestFuture&&) = delete;
	~RepeatingTestFuture() = default;

	void AddValue(Types... values) {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);

	elements_.push(std::make_tuple(std::forward<Types>(values)...));
	SignalElementIsAvailable();
	}

	// Waits until an element is available.
	// Returns immediately if one or more elements are already available.
	//
	// Returns true if an element arrived, or false if a timeout happens.
	//
	// Directly calling Wait() is not required as Take() will also wait for
	// the value to arrive, however you can use a direct call to Wait() to
	// improve the error reported:
	//
	// ASSERT_TRUE(queue.Wait()) << "Detailed error message";
	//
	[[nodiscard]] bool Wait() {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);

	if (IsEmpty())
	WaitForANewElement();

	return !IsEmpty();
	}

	// Returns a callback that when invoked will store all the argument values,
	// and unblock any waiters.
	// This method is templated so you can specify how you need the arguments to
	// be passed - be it const, as reference, or anything you can think off.
	// By default the callback accepts the arguments as \|Types...\|.
	//
	// Example usage:
	//
	// RepeatingTestFuture<int, std::string> future;
	//
	// // returns base::RepeatingCallback<void(int, std::string)>
	// future.GetCallback();
	//
	// // returns base::RepeatingCallback<void(int, const std::string&)>
	// future.GetCallback<int, const std::string&>();
	//
	template <typename... CallbackArgumentsTypes>
	base::RepeatingCallback<void(CallbackArgumentsTypes...)> GetCallback() {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
	return base::BindRepeating(
	[](WeakPtr<RepeatingTestFuture<Types...>> future,
	CallbackArgumentsTypes... values) {
	if (future)
	future->AddValue(std::forward<CallbackArgumentsTypes>(values)...);
	},
	weak_ptr_factory_.GetWeakPtr());
	}

	base::RepeatingCallback<void(Types...)> GetCallback() {
	return GetCallback<Types...>();
	}

	// Returns true if no elements are currently present. Note that consuming all
	// elements through Take() will cause this method to return true after the
	// last available element has been consumed.
	bool IsEmpty() const {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);

	return elements_.empty();
	}

	//////////////////////////////////////////////////////////////////////////////
	// Accessor methods only available if each element in the future holds a
	// single value.
	//////////////////////////////////////////////////////////////////////////////

	// Wait for an element to arrive, and move its value out.
	//
	// Will DCHECK if a timeout happens.
	template <typename T = TupleType, internal::EnableIfSingleValue<T> = true>
	FirstType Take() {
	return std::get<0>(TakeTuple());
	}

	//////////////////////////////////////////////////////////////////////////////
	// Accessor methods only available if each element in the future holds
	// multiple values.
	//////////////////////////////////////////////////////////////////////////////

	// Wait for an element to arrive, and move a tuple with its values out.
	//
	// Will DCHECK if a timeout happens.
	template <typename T = TupleType, internal::EnableIfMultiValue<T> = true>
	TupleType Take() {
	return TakeTuple();
	}

	private:
	// Wait until a new element is available.
	void WaitForANewElement() VALID_CONTEXT_REQUIRED(sequence_checker_) {
	DCHECK(!run_loop_.has_value());

	// Create a new run loop.
	run_loop_.emplace();
	// Wait until 'run_loop_->Quit()' is called.
	run_loop_->Run();
	run_loop_.reset();
	}

	void SignalElementIsAvailable() VALID_CONTEXT_REQUIRED(sequence_checker_) {
	if (run_loop_.has_value())
	run_loop_->Quit();
	}

	TupleType TakeTuple() {
	DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);

	// Ensure an element is available.
	bool success = Wait();
	DCHECK(success) << "Waiting for an element timed out.";

	auto result = std::move(elements_.front());
	elements_.pop();
	return result;
	}

	base::queue<TupleType> elements_ GUARDED_BY_CONTEXT(sequence_checker_);

	// Used by Wait() to know when AddValue() is called.
	absl::optional<base::RunLoop> run_loop_ GUARDED_BY_CONTEXT(sequence_checker_);

	SEQUENCE_CHECKER(sequence_checker_);

	base::WeakPtrFactory<RepeatingTestFuture<Types...>> weak_ptr_factory_{this};
	};

	} // namespace base::test

	#endif // BASE_TEST_REPEATING_TEST_FUTURE_H_