naiveproxy/base/test/sequenced_task_runner_test_template.h
2018-12-09 21:59:24 -05:00

351 lines
13 KiB
C++

// Copyright (c) 2012 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.
// SequencedTaskRunnerTest defines tests that implementations of
// SequencedTaskRunner should pass in order to be conformant.
// See task_runner_test_template.h for a description of how to use the
// constructs in this file; these work the same.
#ifndef BASE_TEST_SEQUENCED_TASK_RUNNER_TEST_TEMPLATE_H_
#define BASE_TEST_SEQUENCED_TASK_RUNNER_TEST_TEMPLATE_H_
#include <cstddef>
#include <iosfwd>
#include <vector>
#include "base/bind.h"
#include "base/callback.h"
#include "base/macros.h"
#include "base/memory/ref_counted.h"
#include "base/sequenced_task_runner.h"
#include "base/synchronization/condition_variable.h"
#include "base/synchronization/lock.h"
#include "base/time/time.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace base {
namespace internal {
struct TaskEvent {
enum Type { POST, START, END };
TaskEvent(int i, Type type);
int i;
Type type;
};
// Utility class used in the tests below.
class SequencedTaskTracker : public RefCountedThreadSafe<SequencedTaskTracker> {
public:
SequencedTaskTracker();
// Posts the non-nestable task |task|, and records its post event.
void PostWrappedNonNestableTask(SequencedTaskRunner* task_runner,
const Closure& task);
// Posts the nestable task |task|, and records its post event.
void PostWrappedNestableTask(SequencedTaskRunner* task_runner,
const Closure& task);
// Posts the delayed non-nestable task |task|, and records its post event.
void PostWrappedDelayedNonNestableTask(SequencedTaskRunner* task_runner,
const Closure& task,
TimeDelta delay);
// Posts |task_count| non-nestable tasks.
void PostNonNestableTasks(SequencedTaskRunner* task_runner, int task_count);
const std::vector<TaskEvent>& GetTaskEvents() const;
// Returns after the tracker observes a total of |count| task completions.
void WaitForCompletedTasks(int count);
private:
friend class RefCountedThreadSafe<SequencedTaskTracker>;
~SequencedTaskTracker();
// A task which runs |task|, recording the start and end events.
void RunTask(const Closure& task, int task_i);
// Records a post event for task |i|. The owner is expected to be holding
// |lock_| (unlike |TaskStarted| and |TaskEnded|).
void TaskPosted(int i);
// Records a start event for task |i|.
void TaskStarted(int i);
// Records a end event for task |i|.
void TaskEnded(int i);
// Protects events_, next_post_i_, task_end_count_ and task_end_cv_.
Lock lock_;
// The events as they occurred for each task (protected by lock_).
std::vector<TaskEvent> events_;
// The ordinal to be used for the next task-posting task (protected by
// lock_).
int next_post_i_;
// The number of task end events we've received.
int task_end_count_;
ConditionVariable task_end_cv_;
DISALLOW_COPY_AND_ASSIGN(SequencedTaskTracker);
};
void PrintTo(const TaskEvent& event, std::ostream* os);
// Checks the non-nestable task invariants for all tasks in |events|.
//
// The invariants are:
// 1) Events started and ended in the same order that they were posted.
// 2) Events for an individual tasks occur in the order {POST, START, END},
// and there is only one instance of each event type for a task.
// 3) The only events between a task's START and END events are the POSTs of
// other tasks. I.e. tasks were run sequentially, not interleaved.
::testing::AssertionResult CheckNonNestableInvariants(
const std::vector<TaskEvent>& events,
int task_count);
} // namespace internal
template <typename TaskRunnerTestDelegate>
class SequencedTaskRunnerTest : public testing::Test {
protected:
SequencedTaskRunnerTest()
: task_tracker_(new internal::SequencedTaskTracker()) {}
const scoped_refptr<internal::SequencedTaskTracker> task_tracker_;
TaskRunnerTestDelegate delegate_;
};
TYPED_TEST_CASE_P(SequencedTaskRunnerTest);
// This test posts N non-nestable tasks in sequence, and expects them to run
// in FIFO order, with no part of any two tasks' execution
// overlapping. I.e. that each task starts only after the previously-posted
// one has finished.
TYPED_TEST_P(SequencedTaskRunnerTest, SequentialNonNestable) {
const int kTaskCount = 1000;
this->delegate_.StartTaskRunner();
const scoped_refptr<SequencedTaskRunner> task_runner =
this->delegate_.GetTaskRunner();
this->task_tracker_->PostWrappedNonNestableTask(
task_runner.get(),
Bind(&PlatformThread::Sleep, TimeDelta::FromSeconds(1)));
for (int i = 1; i < kTaskCount; ++i) {
this->task_tracker_->PostWrappedNonNestableTask(task_runner.get(),
Closure());
}
this->delegate_.StopTaskRunner();
EXPECT_TRUE(CheckNonNestableInvariants(this->task_tracker_->GetTaskEvents(),
kTaskCount));
}
// This test posts N nestable tasks in sequence. It has the same expectations
// as SequentialNonNestable because even though the tasks are nestable, they
// will not be run nestedly in this case.
TYPED_TEST_P(SequencedTaskRunnerTest, SequentialNestable) {
const int kTaskCount = 1000;
this->delegate_.StartTaskRunner();
const scoped_refptr<SequencedTaskRunner> task_runner =
this->delegate_.GetTaskRunner();
this->task_tracker_->PostWrappedNestableTask(
task_runner.get(),
Bind(&PlatformThread::Sleep, TimeDelta::FromSeconds(1)));
for (int i = 1; i < kTaskCount; ++i) {
this->task_tracker_->PostWrappedNestableTask(task_runner.get(), Closure());
}
this->delegate_.StopTaskRunner();
EXPECT_TRUE(CheckNonNestableInvariants(this->task_tracker_->GetTaskEvents(),
kTaskCount));
}
// This test posts non-nestable tasks in order of increasing delay, and checks
// that that the tasks are run in FIFO order and that there is no execution
// overlap whatsoever between any two tasks.
TYPED_TEST_P(SequencedTaskRunnerTest, SequentialDelayedNonNestable) {
const int kTaskCount = 20;
const int kDelayIncrementMs = 50;
this->delegate_.StartTaskRunner();
const scoped_refptr<SequencedTaskRunner> task_runner =
this->delegate_.GetTaskRunner();
for (int i = 0; i < kTaskCount; ++i) {
this->task_tracker_->PostWrappedDelayedNonNestableTask(
task_runner.get(), Closure(),
TimeDelta::FromMilliseconds(kDelayIncrementMs * i));
}
this->task_tracker_->WaitForCompletedTasks(kTaskCount);
this->delegate_.StopTaskRunner();
EXPECT_TRUE(CheckNonNestableInvariants(this->task_tracker_->GetTaskEvents(),
kTaskCount));
}
// This test posts a fast, non-nestable task from within each of a number of
// slow, non-nestable tasks and checks that they all run in the sequence they
// were posted in and that there is no execution overlap whatsoever.
TYPED_TEST_P(SequencedTaskRunnerTest, NonNestablePostFromNonNestableTask) {
const int kParentCount = 10;
const int kChildrenPerParent = 10;
this->delegate_.StartTaskRunner();
const scoped_refptr<SequencedTaskRunner> task_runner =
this->delegate_.GetTaskRunner();
for (int i = 0; i < kParentCount; ++i) {
Closure task = Bind(
&internal::SequencedTaskTracker::PostNonNestableTasks,
this->task_tracker_,
RetainedRef(task_runner),
kChildrenPerParent);
this->task_tracker_->PostWrappedNonNestableTask(task_runner.get(), task);
}
this->delegate_.StopTaskRunner();
EXPECT_TRUE(CheckNonNestableInvariants(
this->task_tracker_->GetTaskEvents(),
kParentCount * (kChildrenPerParent + 1)));
}
// This test posts two tasks with the same delay, and checks that the tasks are
// run in the order in which they were posted.
//
// NOTE: This is actually an approximate test since the API only takes a
// "delay" parameter, so we are not exactly simulating two tasks that get
// posted at the exact same time. It would be nice if the API allowed us to
// specify the desired run time.
TYPED_TEST_P(SequencedTaskRunnerTest, DelayedTasksSameDelay) {
const int kTaskCount = 2;
const TimeDelta kDelay = TimeDelta::FromMilliseconds(100);
this->delegate_.StartTaskRunner();
const scoped_refptr<SequencedTaskRunner> task_runner =
this->delegate_.GetTaskRunner();
this->task_tracker_->PostWrappedDelayedNonNestableTask(task_runner.get(),
Closure(), kDelay);
this->task_tracker_->PostWrappedDelayedNonNestableTask(task_runner.get(),
Closure(), kDelay);
this->task_tracker_->WaitForCompletedTasks(kTaskCount);
this->delegate_.StopTaskRunner();
EXPECT_TRUE(CheckNonNestableInvariants(this->task_tracker_->GetTaskEvents(),
kTaskCount));
}
// This test posts a normal task and a delayed task, and checks that the
// delayed task runs after the normal task even if the normal task takes
// a long time to run.
TYPED_TEST_P(SequencedTaskRunnerTest, DelayedTaskAfterLongTask) {
const int kTaskCount = 2;
this->delegate_.StartTaskRunner();
const scoped_refptr<SequencedTaskRunner> task_runner =
this->delegate_.GetTaskRunner();
this->task_tracker_->PostWrappedNonNestableTask(
task_runner.get(),
base::Bind(&PlatformThread::Sleep, TimeDelta::FromMilliseconds(50)));
this->task_tracker_->PostWrappedDelayedNonNestableTask(
task_runner.get(), Closure(), TimeDelta::FromMilliseconds(10));
this->task_tracker_->WaitForCompletedTasks(kTaskCount);
this->delegate_.StopTaskRunner();
EXPECT_TRUE(CheckNonNestableInvariants(this->task_tracker_->GetTaskEvents(),
kTaskCount));
}
// Test that a pile of normal tasks and a delayed task run in the
// time-to-run order.
TYPED_TEST_P(SequencedTaskRunnerTest, DelayedTaskAfterManyLongTasks) {
const int kTaskCount = 11;
this->delegate_.StartTaskRunner();
const scoped_refptr<SequencedTaskRunner> task_runner =
this->delegate_.GetTaskRunner();
for (int i = 0; i < kTaskCount - 1; i++) {
this->task_tracker_->PostWrappedNonNestableTask(
task_runner.get(),
base::Bind(&PlatformThread::Sleep, TimeDelta::FromMilliseconds(50)));
}
this->task_tracker_->PostWrappedDelayedNonNestableTask(
task_runner.get(), Closure(), TimeDelta::FromMilliseconds(10));
this->task_tracker_->WaitForCompletedTasks(kTaskCount);
this->delegate_.StopTaskRunner();
EXPECT_TRUE(CheckNonNestableInvariants(this->task_tracker_->GetTaskEvents(),
kTaskCount));
}
// TODO(francoisk777@gmail.com) Add a test, similiar to the above, which runs
// some tasked nestedly (which should be implemented in the test
// delegate). Also add, to the the test delegate, a predicate which checks
// whether the implementation supports nested tasks.
//
// The SequencedTaskRunnerTest test case verifies behaviour that is expected
// from a sequenced task runner in order to be conformant.
REGISTER_TYPED_TEST_CASE_P(SequencedTaskRunnerTest,
SequentialNonNestable,
SequentialNestable,
SequentialDelayedNonNestable,
NonNestablePostFromNonNestableTask,
DelayedTasksSameDelay,
DelayedTaskAfterLongTask,
DelayedTaskAfterManyLongTasks);
template <typename TaskRunnerTestDelegate>
class SequencedTaskRunnerDelayedTest
: public SequencedTaskRunnerTest<TaskRunnerTestDelegate> {};
TYPED_TEST_CASE_P(SequencedTaskRunnerDelayedTest);
// This test posts a delayed task, and checks that the task is run later than
// the specified time.
TYPED_TEST_P(SequencedTaskRunnerDelayedTest, DelayedTaskBasic) {
const int kTaskCount = 1;
const TimeDelta kDelay = TimeDelta::FromMilliseconds(100);
this->delegate_.StartTaskRunner();
const scoped_refptr<SequencedTaskRunner> task_runner =
this->delegate_.GetTaskRunner();
Time time_before_run = Time::Now();
this->task_tracker_->PostWrappedDelayedNonNestableTask(task_runner.get(),
Closure(), kDelay);
this->task_tracker_->WaitForCompletedTasks(kTaskCount);
this->delegate_.StopTaskRunner();
Time time_after_run = Time::Now();
EXPECT_TRUE(CheckNonNestableInvariants(this->task_tracker_->GetTaskEvents(),
kTaskCount));
EXPECT_LE(kDelay, time_after_run - time_before_run);
}
// SequencedTaskRunnerDelayedTest tests that the |delay| parameter of
// is used to actually wait for |delay| ms before executing the task.
// This is not mandatory for a SequencedTaskRunner to be compliant.
REGISTER_TYPED_TEST_CASE_P(SequencedTaskRunnerDelayedTest, DelayedTaskBasic);
} // namespace base
#endif // BASE_TEST_SEQUENCED_TASK_RUNNER_TEST_TEMPLATE_H_