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cobalt / cobalt / 308ed6b84664d59944cd65f4b4359c28a2443be6 / . / src / v8 / test / unittests / heap / item-parallel-job-unittest.cc
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// Copyright 2017 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/heap/item-parallel-job.h"
#include "src/execution/isolate.h"
#include "test/unittests/test-utils.h"
namespace v8 {
namespace internal {
class ItemParallelJobTest : public TestWithIsolate {
public:
ItemParallelJobTest() : parallel_job_semaphore_(0) {}
base::Semaphore* parallel_job_semaphore() { return &parallel_job_semaphore_; }
private:
base::Semaphore parallel_job_semaphore_;
DISALLOW_COPY_AND_ASSIGN(ItemParallelJobTest);
};
namespace {
class SimpleTask : public ItemParallelJob::Task {
public:
SimpleTask(Isolate* isolate, bool* did_run)
: ItemParallelJob::Task(isolate), did_run_(did_run) {}
void RunInParallel(Runner runner) override {
ItemParallelJob::Item* item = nullptr;
while ((item = GetItem<ItemParallelJob::Item>()) != nullptr) {
item->MarkFinished();
}
*did_run_ = true;
}
private:
bool* did_run_;
};
// A simple work item which sets |was_processed| to true, if non-null, when it
// is processed.
class SimpleItem : public ItemParallelJob::Item {
public:
explicit SimpleItem(bool* was_processed = nullptr)
: ItemParallelJob::Item(), was_processed_(was_processed) {}
void Process() {
if (was_processed_) *was_processed_ = true;
}
private:
bool* was_processed_;
};
class EagerTask : public ItemParallelJob::Task {
public:
explicit EagerTask(Isolate* isolate) : ItemParallelJob::Task(isolate) {}
void RunInParallel(Runner runner) override {
SimpleItem* item = nullptr;
while ((item = GetItem<SimpleItem>()) != nullptr) {
item->Process();
item->MarkFinished();
}
}
};
// A OneShotBarrier is meant to be passed to |counter| users. Users should
// either Signal() or Wait() when done (based on whether they want to return
// immediately or wait until others are also done).
class OneShotBarrier {
public:
explicit OneShotBarrier(size_t counter) : counter_(counter) {
DCHECK_GE(counter_, 0);
}
void Wait() {
DCHECK_NE(counter_, 0);
mutex_.Lock();
counter_--;
if (counter_ == 0) {
condition_.NotifyAll();
} else {
while (counter_ > 0) {
condition_.Wait(&mutex_);
}
}
mutex_.Unlock();
}
void Signal() {
mutex_.Lock();
counter_--;
if (counter_ == 0) {
condition_.NotifyAll();
}
mutex_.Unlock();
}
private:
base::Mutex mutex_;
base::ConditionVariable condition_;
size_t counter_;
};
// A task that only processes a single item. Signals |barrier| when done; if
// |wait_when_done|, will blocks until all other tasks have signaled |barrier|.
// If |did_process_an_item| is non-null, will set it to true if it does process
// an item. Otherwise, it will expect to get an item to process (and will report
// a failure if it doesn't).
class TaskProcessingOneItem : public ItemParallelJob::Task {
public:
TaskProcessingOneItem(Isolate* isolate, OneShotBarrier* barrier,
bool wait_when_done,
bool* did_process_an_item = nullptr)
: ItemParallelJob::Task(isolate),
barrier_(barrier),
wait_when_done_(wait_when_done),
did_process_an_item_(did_process_an_item) {}
void RunInParallel(Runner runner) override {
SimpleItem* item = GetItem<SimpleItem>();
if (did_process_an_item_) {
*did_process_an_item_ = item != nullptr;
} else {
EXPECT_NE(nullptr, item);
}
if (item) {
item->Process();
item->MarkFinished();
}
if (wait_when_done_) {
barrier_->Wait();
} else {
barrier_->Signal();
}
}
private:
OneShotBarrier* barrier_;
bool wait_when_done_;
bool* did_process_an_item_;
};
class TaskForDifferentItems;
class BaseItem : public ItemParallelJob::Item {
public:
~BaseItem() override = default;
virtual void ProcessItem(TaskForDifferentItems* task) = 0;
};
class TaskForDifferentItems : public ItemParallelJob::Task {
public:
explicit TaskForDifferentItems(Isolate* isolate, bool* processed_a,
bool* processed_b)
: ItemParallelJob::Task(isolate),
processed_a_(processed_a),
processed_b_(processed_b) {}
~TaskForDifferentItems() override = default;
void RunInParallel(Runner runner) override {
BaseItem* item = nullptr;
while ((item = GetItem<BaseItem>()) != nullptr) {
item->ProcessItem(this);
item->MarkFinished();
}
}
void ProcessA() { *processed_a_ = true; }
void ProcessB() { *processed_b_ = true; }
private:
bool* processed_a_;
bool* processed_b_;
};
class ItemA : public BaseItem {
public:
~ItemA() override = default;
void ProcessItem(TaskForDifferentItems* task) override { task->ProcessA(); }
};
class ItemB : public BaseItem {
public:
~ItemB() override = default;
void ProcessItem(TaskForDifferentItems* task) override { task->ProcessB(); }
};
} // namespace
// ItemParallelJob runs tasks even without work items (as requested tasks may be
// responsible for post-processing).
TEST_F(ItemParallelJobTest, SimpleTaskWithNoItemsRuns) {
bool did_run = false;
ItemParallelJob job(i_isolate()->cancelable_task_manager(),
parallel_job_semaphore());
job.AddTask(new SimpleTask(i_isolate(), &did_run));
job.Run();
EXPECT_TRUE(did_run);
}
TEST_F(ItemParallelJobTest, SimpleTaskWithSimpleItemRuns) {
bool did_run = false;
ItemParallelJob job(i_isolate()->cancelable_task_manager(),
parallel_job_semaphore());
job.AddTask(new SimpleTask(i_isolate(), &did_run));
job.AddItem(new ItemParallelJob::Item);
job.Run();
EXPECT_TRUE(did_run);
}
TEST_F(ItemParallelJobTest, MoreTasksThanItems) {
const int kNumTasks = 128;
const int kNumItems = kNumTasks - 4;
TaskProcessingOneItem* tasks[kNumTasks] = {};
bool did_process_an_item[kNumTasks] = {};
ItemParallelJob job(i_isolate()->cancelable_task_manager(),
parallel_job_semaphore());
// The barrier ensures that all tasks run. But only the first kNumItems tasks
// should be assigned an item to execute.
OneShotBarrier barrier(kNumTasks);
for (int i = 0; i < kNumTasks; i++) {
// Block the main thread when done to prevent it from returning control to
// the job (which could cancel tasks that have yet to be scheduled).
const bool wait_when_done = i == 0;
tasks[i] = new TaskProcessingOneItem(i_isolate(), &barrier, wait_when_done,
&did_process_an_item[i]);
job.AddTask(tasks[i]);
}
for (int i = 0; i < kNumItems; i++) {
job.AddItem(new SimpleItem);
}
job.Run();
for (int i = 0; i < kNumTasks; i++) {
// Only the first kNumItems tasks should have been assigned a work item.
EXPECT_EQ(i < kNumItems, did_process_an_item[i]);
}
}
TEST_F(ItemParallelJobTest, SingleThreadProcessing) {
const int kItems = 111;
bool was_processed[kItems] = {};
ItemParallelJob job(i_isolate()->cancelable_task_manager(),
parallel_job_semaphore());
job.AddTask(new EagerTask(i_isolate()));
for (int i = 0; i < kItems; i++) {
job.AddItem(new SimpleItem(&was_processed[i]));
}
job.Run();
for (int i = 0; i < kItems; i++) {
EXPECT_TRUE(was_processed[i]);
}
}
TEST_F(ItemParallelJobTest, DistributeItemsMultipleTasks) {
const int kItemsAndTasks = 256;
bool was_processed[kItemsAndTasks] = {};
OneShotBarrier barrier(kItemsAndTasks);
ItemParallelJob job(i_isolate()->cancelable_task_manager(),
parallel_job_semaphore());
for (int i = 0; i < kItemsAndTasks; i++) {
job.AddItem(new SimpleItem(&was_processed[i]));
// Block the main thread when done to prevent it from returning control to
// the job (which could cancel tasks that have yet to be scheduled).
const bool wait_when_done = i == 0;
job.AddTask(
new TaskProcessingOneItem(i_isolate(), &barrier, wait_when_done));
}
job.Run();
for (int i = 0; i < kItemsAndTasks; i++) {
EXPECT_TRUE(was_processed[i]);
}
}
TEST_F(ItemParallelJobTest, DifferentItems) {
bool item_a = false;
bool item_b = false;
ItemParallelJob job(i_isolate()->cancelable_task_manager(),
parallel_job_semaphore());
job.AddItem(new ItemA());
job.AddItem(new ItemB());
job.AddTask(new TaskForDifferentItems(i_isolate(), &item_a, &item_b));
job.Run();
EXPECT_TRUE(item_a);
EXPECT_TRUE(item_b);
}
} // namespace internal
} // namespace v8