naiveproxy/base/task/task_scheduler/tracked_ref.h
2018-12-09 21:59:24 -05:00

172 lines
6.1 KiB
C++

// Copyright 2018 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_TASK_TASK_SCHEDULER_TRACKED_REF_H_
#define BASE_TASK_TASK_SCHEDULER_TRACKED_REF_H_
#include <memory>
#include "base/atomic_ref_count.h"
#include "base/gtest_prod_util.h"
#include "base/logging.h"
#include "base/macros.h"
#include "base/memory/ptr_util.h"
#include "base/synchronization/waitable_event.h"
namespace base {
namespace internal {
// TrackedRefs are effectively a ref-counting scheme for objects that have a
// single owner.
//
// Deletion is still controlled by the single owner but ~T() itself will block
// until all the TrackedRefs handed by its TrackedRefFactory have been released
// (by ~TrackedRef<T>()).
//
// Just like WeakPtrFactory: TrackedRefFactory<T> should be the last member of T
// to ensure ~TrackedRefFactory<T>() runs first in ~T().
//
// The owner of a T should hence be certain that the last TrackedRefs to T are
// already gone or on their way out before destroying it or ~T() will hang
// (indicating a bug in the tear down logic -- proper refcounting on the other
// hand would result in a leak).
//
// TrackedRefFactory only makes sense to use on types that are always leaked in
// production but need to be torn down in tests (blocking destruction is
// impractical in production -- ref. ScopedAllowBaseSyncPrimitivesForTesting
// below).
//
// Why would we ever need such a thing? In task_scheduler there is a clear
// ownership hierarchy with mostly single owners and little refcounting. In
// production nothing is ever torn down so this isn't a problem. In tests
// however we must JoinForTesting(). At that point, all the raw back T* refs
// used by the worker threads are problematic because they can result in use-
// after-frees if a worker outlives the deletion of its corresponding
// TaskScheduler/TaskTracker/SchedulerWorkerPool/etc.
//
// JoinForTesting() isn't so hard when all workers are managed. But with cleanup
// semantics (reclaiming a worker who's been idle for too long) it becomes
// tricky because workers can go unaccounted for before they exit their main
// (https://crbug.com/827615).
//
// For that reason and to clearly document the ownership model, task_scheduler
// uses TrackedRefs.
//
// On top of being a clearer ownership model than proper refcounting, a hang in
// tear down in a test with out-of-order tear down logic is much preferred to
// letting its worker thread and associated constructs outlive the test
// (potentially resulting in flakes in unrelated tests running later in the same
// process).
//
// Note: While there's nothing task_scheduler specific about TrackedRefs it
// requires an ownership model where all the TrackedRefs are released on other
// threads in sync with ~T(). This isn't a typical use case beyond shutting down
// TaskScheduler in tests and as such this is kept internal here for now.
template <class T>
class TrackedRefFactory;
// TrackedRef<T> can be used like a T*.
template <class T>
class TrackedRef {
public:
// Moveable and copyable.
TrackedRef(TrackedRef<T>&& other)
: ptr_(other.ptr_), factory_(other.factory_) {
// Null out |other_|'s factory so its destructor doesn't decrement
// |live_tracked_refs_|.
other.factory_ = nullptr;
}
TrackedRef(const TrackedRef<T>& other)
: ptr_(other.ptr_), factory_(other.factory_) {
factory_->live_tracked_refs_.Increment();
}
// Intentionally not assignable for now because it makes the logic slightly
// convoluted and it's not a use case that makes sense for the types using
// this at the moment.
TrackedRef& operator=(TrackedRef<T>&& other) = delete;
TrackedRef& operator=(const TrackedRef<T>& other) = delete;
~TrackedRef() {
if (factory_ && !factory_->live_tracked_refs_.Decrement()) {
DCHECK(factory_->ready_to_destroy_);
DCHECK(!factory_->ready_to_destroy_->IsSignaled());
factory_->ready_to_destroy_->Signal();
}
}
T& operator*() const { return *ptr_; }
T* operator->() const { return ptr_; }
explicit operator bool() const { return ptr_ != nullptr; }
private:
friend class TrackedRefFactory<T>;
TrackedRef(T* ptr, TrackedRefFactory<T>* factory)
: ptr_(ptr), factory_(factory) {
factory_->live_tracked_refs_.Increment();
}
T* ptr_;
TrackedRefFactory<T>* factory_;
};
// TrackedRefFactory<T> should be the last member of T.
template <class T>
class TrackedRefFactory {
public:
TrackedRefFactory(T* ptr)
: ptr_(ptr), self_ref_(WrapUnique(new TrackedRef<T>(ptr_, this))) {
DCHECK(ptr_);
}
~TrackedRefFactory() {
// Enter the destruction phase.
ready_to_destroy_ = std::make_unique<WaitableEvent>();
// Release self-ref (if this was the last one it will signal the event right
// away).
self_ref_.reset();
ready_to_destroy_->Wait();
}
TrackedRef<T> GetTrackedRef() {
// TrackedRefs cannot be obtained after |live_tracked_refs_| has already
// reached zero. In other words, the owner of a TrackedRefFactory shouldn't
// vend new TrackedRefs while it's being destroyed (owners of TrackedRefs
// may still copy/move their refs around during the destruction phase).
DCHECK(!live_tracked_refs_.IsZero());
return TrackedRef<T>(ptr_, this);
}
private:
friend class TrackedRef<T>;
FRIEND_TEST_ALL_PREFIXES(TrackedRefTest, CopyAndMoveSemantics);
T* const ptr_;
// The number of live TrackedRefs vended by this factory.
AtomicRefCount live_tracked_refs_{0};
// Non-null during the destruction phase. Signaled once |live_tracked_refs_|
// reaches 0. Note: while this could a direct member, only initializing it in
// the destruction phase avoids keeping a handle open for the entire session.
std::unique_ptr<WaitableEvent> ready_to_destroy_;
// TrackedRefFactory holds a TrackedRef as well to prevent
// |live_tracked_refs_| from ever reaching zero before ~TrackedRefFactory().
std::unique_ptr<TrackedRef<T>> self_ref_;
DISALLOW_COPY_AND_ASSIGN(TrackedRefFactory);
};
} // namespace internal
} // namespace base
#endif // BASE_TASK_TASK_SCHEDULER_TRACKED_REF_H_