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cobalt / cobalt / e83fce97d7405b0b5e569d961aa431b1112ac6ac / . / src / net / base / prioritized_dispatcher_unittest.cc
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// 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.
#include "net/base/prioritized_dispatcher.h"
#include <ctype.h>
#include <memory>
#include <string>
#include "base/compiler_specific.h"
#include "base/logging.h"
#include "net/base/request_priority.h"
#include "starboard/types.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace net {
namespace {
// We rely on the priority enum values being sequential having starting at 0,
// and increasing for higher priorities.
static_assert(MINIMUM_PRIORITY == 0u && MINIMUM_PRIORITY == THROTTLED &&
THROTTLED < IDLE &&
IDLE < LOWEST &&
LOWEST < HIGHEST &&
HIGHEST <= MAXIMUM_PRIORITY,
"priority indexes incompatible");
class PrioritizedDispatcherTest : public testing::Test {
public:
typedef PrioritizedDispatcher::Priority Priority;
// A job that appends |tag| to |log| when started and '.' when finished.
// This is intended to confirm the execution order of a sequence of jobs added
// to the dispatcher. Note that finishing order of jobs does not matter.
class TestJob : public PrioritizedDispatcher::Job {
public:
TestJob(PrioritizedDispatcher* dispatcher,
char tag,
Priority priority,
std::string* log)
: dispatcher_(dispatcher),
tag_(tag),
priority_(priority),
running_(false),
log_(log) {}
bool running() const {
return running_;
}
const PrioritizedDispatcher::Handle handle() const {
return handle_;
}
void Add(bool at_head) {
CHECK(handle_.is_null());
CHECK(!running_);
size_t num_queued = dispatcher_->num_queued_jobs();
size_t num_running = dispatcher_->num_running_jobs();
if (!at_head) {
handle_ = dispatcher_->Add(this, priority_);
} else {
handle_ = dispatcher_->AddAtHead(this, priority_);
}
if (handle_.is_null()) {
EXPECT_EQ(num_queued, dispatcher_->num_queued_jobs());
EXPECT_TRUE(running_);
EXPECT_EQ(num_running + 1, dispatcher_->num_running_jobs());
} else {
EXPECT_FALSE(running_);
EXPECT_EQ(priority_, handle_.priority());
EXPECT_EQ(tag_, reinterpret_cast<TestJob*>(handle_.value())->tag_);
EXPECT_EQ(num_running, dispatcher_->num_running_jobs());
}
}
void ChangePriority(Priority priority) {
CHECK(!handle_.is_null());
CHECK(!running_);
size_t num_queued = dispatcher_->num_queued_jobs();
size_t num_running = dispatcher_->num_running_jobs();
handle_ = dispatcher_->ChangePriority(handle_, priority);
if (handle_.is_null()) {
EXPECT_TRUE(running_);
EXPECT_EQ(num_queued - 1, dispatcher_->num_queued_jobs());
EXPECT_EQ(num_running + 1, dispatcher_->num_running_jobs());
} else {
EXPECT_FALSE(running_);
EXPECT_EQ(priority, handle_.priority());
EXPECT_EQ(tag_, reinterpret_cast<TestJob*>(handle_.value())->tag_);
EXPECT_EQ(num_queued, dispatcher_->num_queued_jobs());
EXPECT_EQ(num_running, dispatcher_->num_running_jobs());
}
}
void Cancel() {
CHECK(!handle_.is_null());
CHECK(!running_);
size_t num_queued = dispatcher_->num_queued_jobs();
dispatcher_->Cancel(handle_);
EXPECT_EQ(num_queued - 1, dispatcher_->num_queued_jobs());
handle_ = PrioritizedDispatcher::Handle();
}
void Finish() {
CHECK(running_);
running_ = false;
log_->append(1u, '.');
dispatcher_->OnJobFinished();
}
// PriorityDispatch::Job interface
void Start() override {
EXPECT_FALSE(running_);
handle_ = PrioritizedDispatcher::Handle();
running_ = true;
log_->append(1u, tag_);
}
private:
PrioritizedDispatcher* dispatcher_;
char tag_;
Priority priority_;
PrioritizedDispatcher::Handle handle_;
bool running_;
std::string* log_;
};
protected:
void Prepare(const PrioritizedDispatcher::Limits& limits) {
dispatcher_.reset(new PrioritizedDispatcher(limits));
}
std::unique_ptr<TestJob> AddJob(char data, Priority priority) {
std::unique_ptr<TestJob> job(
new TestJob(dispatcher_.get(), data, priority, &log_));
job->Add(false);
return job;
}
std::unique_ptr<TestJob> AddJobAtHead(char data, Priority priority) {
std::unique_ptr<TestJob> job(
new TestJob(dispatcher_.get(), data, priority, &log_));
job->Add(true);
return job;
}
void Expect(const std::string& log) {
EXPECT_EQ(0u, dispatcher_->num_queued_jobs());
EXPECT_EQ(0u, dispatcher_->num_running_jobs());
EXPECT_EQ(log, log_);
log_.clear();
}
std::string log_;
std::unique_ptr<PrioritizedDispatcher> dispatcher_;
};
TEST_F(PrioritizedDispatcherTest, GetLimits) {
// Set non-trivial initial limits.
PrioritizedDispatcher::Limits original_limits(NUM_PRIORITIES, 5);
original_limits.reserved_slots[HIGHEST] = 1;
original_limits.reserved_slots[LOW] = 2;
Prepare(original_limits);
// Get current limits, make sure the original limits are returned.
PrioritizedDispatcher::Limits retrieved_limits = dispatcher_->GetLimits();
ASSERT_EQ(original_limits.total_jobs, retrieved_limits.total_jobs);
ASSERT_EQ(static_cast<size_t>(NUM_PRIORITIES),
retrieved_limits.reserved_slots.size());
for (size_t priority = MINIMUM_PRIORITY; priority <= MAXIMUM_PRIORITY;
++priority) {
EXPECT_EQ(original_limits.reserved_slots[priority],
retrieved_limits.reserved_slots[priority]);
}
// Set new limits.
PrioritizedDispatcher::Limits new_limits(NUM_PRIORITIES, 6);
new_limits.reserved_slots[MEDIUM] = 3;
new_limits.reserved_slots[LOWEST] = 1;
Prepare(new_limits);
// Get current limits, make sure the new limits are returned.
retrieved_limits = dispatcher_->GetLimits();
ASSERT_EQ(new_limits.total_jobs, retrieved_limits.total_jobs);
ASSERT_EQ(static_cast<size_t>(NUM_PRIORITIES),
retrieved_limits.reserved_slots.size());
for (size_t priority = MINIMUM_PRIORITY; priority <= MAXIMUM_PRIORITY;
++priority) {
EXPECT_EQ(new_limits.reserved_slots[priority],
retrieved_limits.reserved_slots[priority]);
}
}
TEST_F(PrioritizedDispatcherTest, AddAFIFO) {
// Allow only one running job.
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', IDLE);
std::unique_ptr<TestJob> job_b = AddJob('b', IDLE);
std::unique_ptr<TestJob> job_c = AddJob('c', IDLE);
std::unique_ptr<TestJob> job_d = AddJob('d', IDLE);
ASSERT_TRUE(job_a->running());
job_a->Finish();
ASSERT_TRUE(job_b->running());
job_b->Finish();
ASSERT_TRUE(job_c->running());
job_c->Finish();
ASSERT_TRUE(job_d->running());
job_d->Finish();
Expect("a.b.c.d.");
}
TEST_F(PrioritizedDispatcherTest, AddPriority) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', IDLE);
std::unique_ptr<TestJob> job_b = AddJob('b', MEDIUM);
std::unique_ptr<TestJob> job_c = AddJob('c', HIGHEST);
std::unique_ptr<TestJob> job_d = AddJob('d', HIGHEST);
std::unique_ptr<TestJob> job_e = AddJob('e', MEDIUM);
ASSERT_TRUE(job_a->running());
job_a->Finish();
ASSERT_TRUE(job_c->running());
job_c->Finish();
ASSERT_TRUE(job_d->running());
job_d->Finish();
ASSERT_TRUE(job_b->running());
job_b->Finish();
ASSERT_TRUE(job_e->running());
job_e->Finish();
Expect("a.c.d.b.e.");
}
TEST_F(PrioritizedDispatcherTest, AddAtHead) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', MEDIUM);
std::unique_ptr<TestJob> job_b = AddJobAtHead('b', MEDIUM);
std::unique_ptr<TestJob> job_c = AddJobAtHead('c', HIGHEST);
std::unique_ptr<TestJob> job_d = AddJobAtHead('d', HIGHEST);
std::unique_ptr<TestJob> job_e = AddJobAtHead('e', MEDIUM);
std::unique_ptr<TestJob> job_f = AddJob('f', MEDIUM);
ASSERT_TRUE(job_a->running());
job_a->Finish();
ASSERT_TRUE(job_d->running());
job_d->Finish();
ASSERT_TRUE(job_c->running());
job_c->Finish();
ASSERT_TRUE(job_e->running());
job_e->Finish();
ASSERT_TRUE(job_b->running());
job_b->Finish();
ASSERT_TRUE(job_f->running());
job_f->Finish();
Expect("a.d.c.e.b.f.");
}
TEST_F(PrioritizedDispatcherTest, EnforceLimits) {
// Reserve 2 for HIGHEST and 1 for LOW or higher.
// This leaves 2 for LOWEST or lower.
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 5);
limits.reserved_slots[HIGHEST] = 2;
limits.reserved_slots[LOW] = 1;
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', IDLE); // Uses unreserved slot.
std::unique_ptr<TestJob> job_b = AddJob('b', IDLE); // Uses unreserved slot.
std::unique_ptr<TestJob> job_c = AddJob('c', LOWEST); // Must wait.
std::unique_ptr<TestJob> job_d = AddJob('d', LOW); // Uses reserved slot.
std::unique_ptr<TestJob> job_e = AddJob('e', MEDIUM); // Must wait.
std::unique_ptr<TestJob> job_f = AddJob('f', HIGHEST); // Uses reserved slot.
std::unique_ptr<TestJob> job_g = AddJob('g', HIGHEST); // Uses reserved slot.
std::unique_ptr<TestJob> job_h = AddJob('h', HIGHEST); // Must wait.
EXPECT_EQ(5u, dispatcher_->num_running_jobs());
EXPECT_EQ(3u, dispatcher_->num_queued_jobs());
ASSERT_TRUE(job_a->running());
ASSERT_TRUE(job_b->running());
ASSERT_TRUE(job_d->running());
ASSERT_TRUE(job_f->running());
ASSERT_TRUE(job_g->running());
// a, b, d, f, g are running. Finish them in any order.
job_b->Finish(); // Releases h.
job_f->Finish();
job_a->Finish();
job_g->Finish(); // Releases e.
job_d->Finish();
ASSERT_TRUE(job_e->running());
ASSERT_TRUE(job_h->running());
// h, e are running.
job_e->Finish(); // Releases c.
ASSERT_TRUE(job_c->running());
job_c->Finish();
job_h->Finish();
Expect("abdfg.h...e..c..");
}
TEST_F(PrioritizedDispatcherTest, ChangePriority) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 2);
// Reserve one slot only for HIGHEST priority requests.
limits.reserved_slots[HIGHEST] = 1;
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', IDLE);
std::unique_ptr<TestJob> job_b = AddJob('b', LOW);
std::unique_ptr<TestJob> job_c = AddJob('c', MEDIUM);
std::unique_ptr<TestJob> job_d = AddJob('d', MEDIUM);
std::unique_ptr<TestJob> job_e = AddJob('e', IDLE);
ASSERT_FALSE(job_b->running());
ASSERT_FALSE(job_c->running());
job_b->ChangePriority(MEDIUM);
job_c->ChangePriority(LOW);
ASSERT_TRUE(job_a->running());
job_a->Finish();
ASSERT_TRUE(job_d->running());
job_d->Finish();
EXPECT_FALSE(job_e->running());
// Increasing |job_e|'s priority to HIGHEST should result in it being
// started immediately.
job_e->ChangePriority(HIGHEST);
ASSERT_TRUE(job_e->running());
job_e->Finish();
ASSERT_TRUE(job_b->running());
job_b->Finish();
ASSERT_TRUE(job_c->running());
job_c->Finish();
Expect("a.d.be..c.");
}
TEST_F(PrioritizedDispatcherTest, Cancel) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', IDLE);
std::unique_ptr<TestJob> job_b = AddJob('b', IDLE);
std::unique_ptr<TestJob> job_c = AddJob('c', IDLE);
std::unique_ptr<TestJob> job_d = AddJob('d', IDLE);
std::unique_ptr<TestJob> job_e = AddJob('e', IDLE);
ASSERT_FALSE(job_b->running());
ASSERT_FALSE(job_d->running());
job_b->Cancel();
job_d->Cancel();
ASSERT_TRUE(job_a->running());
job_a->Finish();
ASSERT_TRUE(job_c->running());
job_c->Finish();
ASSERT_TRUE(job_e->running());
job_e->Finish();
Expect("a.c.e.");
}
TEST_F(PrioritizedDispatcherTest, Evict) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', IDLE);
std::unique_ptr<TestJob> job_b = AddJob('b', LOW);
std::unique_ptr<TestJob> job_c = AddJob('c', HIGHEST);
std::unique_ptr<TestJob> job_d = AddJob('d', LOW);
std::unique_ptr<TestJob> job_e = AddJob('e', HIGHEST);
EXPECT_EQ(job_b.get(), dispatcher_->EvictOldestLowest());
EXPECT_EQ(job_d.get(), dispatcher_->EvictOldestLowest());
ASSERT_TRUE(job_a->running());
job_a->Finish();
ASSERT_TRUE(job_c->running());
job_c->Finish();
ASSERT_TRUE(job_e->running());
job_e->Finish();
Expect("a.c.e.");
}
TEST_F(PrioritizedDispatcherTest, EvictFromEmpty) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
EXPECT_TRUE(dispatcher_->EvictOldestLowest() == NULL);
}
TEST_F(PrioritizedDispatcherTest, AddWhileZeroLimits) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 2);
Prepare(limits);
dispatcher_->SetLimitsToZero();
std::unique_ptr<TestJob> job_a = AddJob('a', LOW);
std::unique_ptr<TestJob> job_b = AddJob('b', MEDIUM);
std::unique_ptr<TestJob> job_c = AddJobAtHead('c', MEDIUM);
EXPECT_EQ(0u, dispatcher_->num_running_jobs());
EXPECT_EQ(3u, dispatcher_->num_queued_jobs());
dispatcher_->SetLimits(limits);
EXPECT_EQ(2u, dispatcher_->num_running_jobs());
EXPECT_EQ(1u, dispatcher_->num_queued_jobs());
ASSERT_TRUE(job_b->running());
job_b->Finish();
ASSERT_TRUE(job_c->running());
job_c->Finish();
ASSERT_TRUE(job_a->running());
job_a->Finish();
Expect("cb.a..");
}
TEST_F(PrioritizedDispatcherTest, ReduceLimitsWhileJobQueued) {
PrioritizedDispatcher::Limits initial_limits(NUM_PRIORITIES, 2);
Prepare(initial_limits);
std::unique_ptr<TestJob> job_a = AddJob('a', MEDIUM);
std::unique_ptr<TestJob> job_b = AddJob('b', MEDIUM);
std::unique_ptr<TestJob> job_c = AddJob('c', MEDIUM);
std::unique_ptr<TestJob> job_d = AddJob('d', MEDIUM);
std::unique_ptr<TestJob> job_e = AddJob('e', MEDIUM);
EXPECT_EQ(2u, dispatcher_->num_running_jobs());
EXPECT_EQ(3u, dispatcher_->num_queued_jobs());
// Reduce limits to just allow one job at a time. Running jobs should not
// be affected.
dispatcher_->SetLimits(PrioritizedDispatcher::Limits(NUM_PRIORITIES, 1));
EXPECT_EQ(2u, dispatcher_->num_running_jobs());
EXPECT_EQ(3u, dispatcher_->num_queued_jobs());
// Finishing a job should not result in another job starting.
ASSERT_TRUE(job_a->running());
job_a->Finish();
EXPECT_EQ(1u, dispatcher_->num_running_jobs());
EXPECT_EQ(3u, dispatcher_->num_queued_jobs());
ASSERT_TRUE(job_b->running());
job_b->Finish();
EXPECT_EQ(1u, dispatcher_->num_running_jobs());
EXPECT_EQ(2u, dispatcher_->num_queued_jobs());
// Increasing the limits again should let c start.
dispatcher_->SetLimits(initial_limits);
ASSERT_TRUE(job_c->running());
job_c->Finish();
ASSERT_TRUE(job_d->running());
job_d->Finish();
ASSERT_TRUE(job_e->running());
job_e->Finish();
Expect("ab..cd.e..");
}
TEST_F(PrioritizedDispatcherTest, ZeroLimitsThenCancel) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', IDLE);
std::unique_ptr<TestJob> job_b = AddJob('b', IDLE);
std::unique_ptr<TestJob> job_c = AddJob('c', IDLE);
dispatcher_->SetLimitsToZero();
ASSERT_TRUE(job_a->running());
EXPECT_FALSE(job_b->running());
EXPECT_FALSE(job_c->running());
job_a->Finish();
EXPECT_FALSE(job_b->running());
EXPECT_FALSE(job_c->running());
// Cancelling b shouldn't start job c.
job_b->Cancel();
EXPECT_FALSE(job_c->running());
// Restoring the limits should start c.
dispatcher_->SetLimits(limits);
ASSERT_TRUE(job_c->running());
job_c->Finish();
Expect("a.c.");
}
TEST_F(PrioritizedDispatcherTest, ZeroLimitsThenIncreasePriority) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 2);
limits.reserved_slots[HIGHEST] = 1;
Prepare(limits);
std::unique_ptr<TestJob> job_a = AddJob('a', IDLE);
std::unique_ptr<TestJob> job_b = AddJob('b', IDLE);
EXPECT_TRUE(job_a->running());
EXPECT_FALSE(job_b->running());
dispatcher_->SetLimitsToZero();
job_b->ChangePriority(HIGHEST);
EXPECT_FALSE(job_b->running());
job_a->Finish();
EXPECT_FALSE(job_b->running());
job_b->Cancel();
Expect("a.");
}
#if GTEST_HAS_DEATH_TEST && !defined(NDEBUG)
TEST_F(PrioritizedDispatcherTest, CancelNull) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
EXPECT_DEBUG_DEATH(dispatcher_->Cancel(PrioritizedDispatcher::Handle()), "");
}
TEST_F(PrioritizedDispatcherTest, CancelMissing) {
PrioritizedDispatcher::Limits limits(NUM_PRIORITIES, 1);
Prepare(limits);
AddJob('a', IDLE);
std::unique_ptr<TestJob> job_b = AddJob('b', IDLE);
PrioritizedDispatcher::Handle handle = job_b->handle();
ASSERT_FALSE(handle.is_null());
dispatcher_->Cancel(handle);
EXPECT_DEBUG_DEATH(dispatcher_->Cancel(handle), "");
}
#endif // GTEST_HAS_DEATH_TEST && !defined(NDEBUG)
} // namespace
} // namespace net