base/task/sequence_manager/atomic_flag_set.cc - chromium/src - Git at Google

 // Copyright 2019 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 "base/task/sequence_manager/atomic_flag_set.h"

 #include <utility>

 #include "base/bits.h"
 #include "base/callback.h"
 #include "base/logging.h"

 namespace base {
 namespace sequence_manager {
 namespace internal {

 AtomicFlagSet::AtomicFlagSet(
     scoped_refptr<AssociatedThreadId> associated_thread)
     : associated_thread_(std::move(associated_thread)) {}

 AtomicFlagSet::~AtomicFlagSet() {
   DCHECK(!alloc_list_head_);
   DCHECK(!partially_free_list_head_);
 }

 AtomicFlagSet::AtomicFlag::AtomicFlag() = default;

 AtomicFlagSet::AtomicFlag::~AtomicFlag() {
   ReleaseAtomicFlag();
 }

 AtomicFlagSet::AtomicFlag::AtomicFlag(AtomicFlagSet* outer,
                                       Group* element,
                                       size_t flag_bit)
     : outer_(outer), group_(element), flag_bit_(flag_bit) {}

 AtomicFlagSet::AtomicFlag::AtomicFlag(AtomicFlag&& other)
     : outer_(other.outer_), group_(other.group_), flag_bit_(other.flag_bit_) {
   other.outer_ = nullptr;
   other.group_ = nullptr;
 }

 void AtomicFlagSet::AtomicFlag::SetActive(bool active) {
   DCHECK(group_);
   if (active) {
     // Release semantics are required to ensure that all memory accesses made on
     // this thread happen-before any others done on the thread running the
     // active callbacks.
     group_->flags.fetch_or(flag_bit_, std::memory_order_release);
   } else {
     // No operation is being performed based on the bit *not* being set (i.e.
     // state of other memory is irrelevant); hence no memory order is required
     // when unsetting it.
     group_->flags.fetch_and(~flag_bit_, std::memory_order_relaxed);
   }
 }

 void AtomicFlagSet::AtomicFlag::ReleaseAtomicFlag() {
   if (!group_)
     return;

   DCHECK_CALLED_ON_VALID_THREAD(outer_->associated_thread_->thread_checker);
   SetActive(false);

   // If |group_| was full then add it on the partially free list.
   if (group_->IsFull())
     outer_->AddToPartiallyFreeList(group_);

   int index = Group::IndexOfFirstFlagSet(flag_bit_);
   DCHECK(!group_->flag_callbacks[index].is_null());
   group_->flag_callbacks[index] = RepeatingClosure();
   group_->allocated_flags &= ~flag_bit_;

   // If |group_| has become empty delete it.
   if (group_->IsEmpty()) {
     outer_->RemoveFromPartiallyFreeList(group_);
     outer_->RemoveFromAllocList(group_);
   }

   outer_ = nullptr;
   group_ = nullptr;
 }

 AtomicFlagSet::AtomicFlag AtomicFlagSet::AddFlag(RepeatingClosure callback) {
   DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
   // Allocate a new Group if needed.
   if (!partially_free_list_head_) {
     AddToAllocList(std::make_unique<Group>());
     AddToPartiallyFreeList(alloc_list_head_.get());
   }

   DCHECK(partially_free_list_head_);
   Group* group = partially_free_list_head_;
   size_t first_unoccupied_index =
       static_cast<size_t>(group->FindFirstUnallocatedFlag());
   DCHECK(!group->flag_callbacks[first_unoccupied_index]);
   group->flag_callbacks[first_unoccupied_index] = std::move(callback);

   size_t flag_bit = size_t{1} << first_unoccupied_index;
   group->allocated_flags |= flag_bit;

   if (group->IsFull())
     RemoveFromPartiallyFreeList(group);

   return AtomicFlag(this, group, flag_bit);
 }

 void AtomicFlagSet::RunActiveCallbacks() const {
   DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
   for (Group* iter = alloc_list_head_.get(); iter; iter = iter->next.get()) {
     // Acquire semantics are required to guarantee that all memory side-effects
     // made by other threads that were allowed to perform operations are
     // synchronized with this thread before it returns from this method.
     size_t active_flags = std::atomic_exchange_explicit(
         &iter->flags, size_t{0}, std::memory_order_acquire);
     // This is O(number of bits set).
     while (active_flags) {
       int index = Group::IndexOfFirstFlagSet(active_flags);
       // Clear the flag.
       active_flags ^= size_t{1} << index;
       iter->flag_callbacks[index].Run();
     }
   }
 }

 AtomicFlagSet::Group::Group() = default;

 AtomicFlagSet::Group::~Group() {
   DCHECK_EQ(allocated_flags, 0u);
   DCHECK(!partially_free_list_prev);
   DCHECK(!partially_free_list_next);
 }

 bool AtomicFlagSet::Group::IsFull() const {
   return (~allocated_flags) == 0u;
 }

 bool AtomicFlagSet::Group::IsEmpty() const {
   return allocated_flags == 0u;
 }

 int AtomicFlagSet::Group::FindFirstUnallocatedFlag() const {
   size_t unallocated_flags = ~allocated_flags;
   DCHECK_NE(unallocated_flags, 0u);
   int index = IndexOfFirstFlagSet(unallocated_flags);
   DCHECK_LT(index, kNumFlags);
   return index;
 }

 // static
 int AtomicFlagSet::Group::IndexOfFirstFlagSet(size_t flag) {
   DCHECK_NE(flag, 0u);
   return bits::CountTrailingZeroBits(flag);
 }

 void AtomicFlagSet::AddToAllocList(std::unique_ptr<Group> group) {
   DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
   if (alloc_list_head_)
     alloc_list_head_->prev = group.get();

   group->next = std::move(alloc_list_head_);
   alloc_list_head_ = std::move(group);
 }

 void AtomicFlagSet::RemoveFromAllocList(Group* group) {
   DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
   if (group->next)
     group->next->prev = group->prev;

   if (group->prev) {
     group->prev->next = std::move(group->next);
   } else {
     alloc_list_head_ = std::move(group->next);
   }
 }

 void AtomicFlagSet::AddToPartiallyFreeList(Group* group) {
   DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
   DCHECK_NE(partially_free_list_head_, group);
   DCHECK(!group->partially_free_list_prev);
   DCHECK(!group->partially_free_list_next);
   if (partially_free_list_head_)
     partially_free_list_head_->partially_free_list_prev = group;

   group->partially_free_list_next = partially_free_list_head_;
   partially_free_list_head_ = group;
 }

 void AtomicFlagSet::RemoveFromPartiallyFreeList(Group* group) {
   DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
   DCHECK(partially_free_list_head_);
   // Check |group| is in the list.
   DCHECK(partially_free_list_head_ == group || group->partially_free_list_prev);
   if (group->partially_free_list_next) {
     group->partially_free_list_next->partially_free_list_prev =
         group->partially_free_list_prev;
   }

   if (group->partially_free_list_prev) {
     group->partially_free_list_prev->partially_free_list_next =
         group->partially_free_list_next;
   } else {
     partially_free_list_head_ = group->partially_free_list_next;
   }

   group->partially_free_list_prev = nullptr;
   group->partially_free_list_next = nullptr;
 }

 }  // namespace internal
 }  // namespace sequence_manager
 }  // namespace base
	// Copyright 2019 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 "base/task/sequence_manager/atomic_flag_set.h"

	#include <utility>

	#include "base/bits.h"
	#include "base/callback.h"
	#include "base/logging.h"

	namespace base {
	namespace sequence_manager {
	namespace internal {

	AtomicFlagSet::AtomicFlagSet(
	scoped_refptr<AssociatedThreadId> associated_thread)
	: associated_thread_(std::move(associated_thread)) {}

	AtomicFlagSet::~AtomicFlagSet() {
	DCHECK(!alloc_list_head_);
	DCHECK(!partially_free_list_head_);
	}

	AtomicFlagSet::AtomicFlag::AtomicFlag() = default;

	AtomicFlagSet::AtomicFlag::~AtomicFlag() {
	ReleaseAtomicFlag();
	}

	AtomicFlagSet::AtomicFlag::AtomicFlag(AtomicFlagSet* outer,
	Group* element,
	size_t flag_bit)
	: outer_(outer), group_(element), flag_bit_(flag_bit) {}

	AtomicFlagSet::AtomicFlag::AtomicFlag(AtomicFlag&& other)
	: outer_(other.outer_), group_(other.group_), flag_bit_(other.flag_bit_) {
	other.outer_ = nullptr;
	other.group_ = nullptr;
	}

	void AtomicFlagSet::AtomicFlag::SetActive(bool active) {
	DCHECK(group_);
	if (active) {
	// Release semantics are required to ensure that all memory accesses made on
	// this thread happen-before any others done on the thread running the
	// active callbacks.
	group_->flags.fetch_or(flag_bit_, std::memory_order_release);
	} else {
	// No operation is being performed based on the bit not being set (i.e.
	// state of other memory is irrelevant); hence no memory order is required
	// when unsetting it.
	group_->flags.fetch_and(~flag_bit_, std::memory_order_relaxed);
	}
	}

	void AtomicFlagSet::AtomicFlag::ReleaseAtomicFlag() {
	if (!group_)
	return;

	DCHECK_CALLED_ON_VALID_THREAD(outer_->associated_thread_->thread_checker);
	SetActive(false);

	// If \|group_\| was full then add it on the partially free list.
	if (group_->IsFull())
	outer_->AddToPartiallyFreeList(group_);

	int index = Group::IndexOfFirstFlagSet(flag_bit_);
	DCHECK(!group_->flag_callbacks[index].is_null());
	group_->flag_callbacks[index] = RepeatingClosure();
	group_->allocated_flags &= ~flag_bit_;

	// If \|group_\| has become empty delete it.
	if (group_->IsEmpty()) {
	outer_->RemoveFromPartiallyFreeList(group_);
	outer_->RemoveFromAllocList(group_);
	}

	outer_ = nullptr;
	group_ = nullptr;
	}

	AtomicFlagSet::AtomicFlag AtomicFlagSet::AddFlag(RepeatingClosure callback) {
	DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
	// Allocate a new Group if needed.
	if (!partially_free_list_head_) {
	AddToAllocList(std::make_unique<Group>());
	AddToPartiallyFreeList(alloc_list_head_.get());
	}

	DCHECK(partially_free_list_head_);
	Group* group = partially_free_list_head_;
	size_t first_unoccupied_index =
	static_cast<size_t>(group->FindFirstUnallocatedFlag());
	DCHECK(!group->flag_callbacks[first_unoccupied_index]);
	group->flag_callbacks[first_unoccupied_index] = std::move(callback);

	size_t flag_bit = size_t{1} << first_unoccupied_index;
	group->allocated_flags \|= flag_bit;

	if (group->IsFull())
	RemoveFromPartiallyFreeList(group);

	return AtomicFlag(this, group, flag_bit);
	}

	void AtomicFlagSet::RunActiveCallbacks() const {
	DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
	for (Group* iter = alloc_list_head_.get(); iter; iter = iter->next.get()) {
	// Acquire semantics are required to guarantee that all memory side-effects
	// made by other threads that were allowed to perform operations are
	// synchronized with this thread before it returns from this method.
	size_t active_flags = std::atomic_exchange_explicit(
	&iter->flags, size_t{0}, std::memory_order_acquire);
	// This is O(number of bits set).
	while (active_flags) {
	int index = Group::IndexOfFirstFlagSet(active_flags);
	// Clear the flag.
	active_flags ^= size_t{1} << index;
	iter->flag_callbacks[index].Run();
	}
	}
	}

	AtomicFlagSet::Group::Group() = default;

	AtomicFlagSet::Group::~Group() {
	DCHECK_EQ(allocated_flags, 0u);
	DCHECK(!partially_free_list_prev);
	DCHECK(!partially_free_list_next);
	}

	bool AtomicFlagSet::Group::IsFull() const {
	return (~allocated_flags) == 0u;
	}

	bool AtomicFlagSet::Group::IsEmpty() const {
	return allocated_flags == 0u;
	}

	int AtomicFlagSet::Group::FindFirstUnallocatedFlag() const {
	size_t unallocated_flags = ~allocated_flags;
	DCHECK_NE(unallocated_flags, 0u);
	int index = IndexOfFirstFlagSet(unallocated_flags);
	DCHECK_LT(index, kNumFlags);
	return index;
	}

	// static
	int AtomicFlagSet::Group::IndexOfFirstFlagSet(size_t flag) {
	DCHECK_NE(flag, 0u);
	return bits::CountTrailingZeroBits(flag);
	}

	void AtomicFlagSet::AddToAllocList(std::unique_ptr<Group> group) {
	DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
	if (alloc_list_head_)
	alloc_list_head_->prev = group.get();

	group->next = std::move(alloc_list_head_);
	alloc_list_head_ = std::move(group);
	}

	void AtomicFlagSet::RemoveFromAllocList(Group* group) {
	DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
	if (group->next)
	group->next->prev = group->prev;

	if (group->prev) {
	group->prev->next = std::move(group->next);
	} else {
	alloc_list_head_ = std::move(group->next);
	}
	}

	void AtomicFlagSet::AddToPartiallyFreeList(Group* group) {
	DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
	DCHECK_NE(partially_free_list_head_, group);
	DCHECK(!group->partially_free_list_prev);
	DCHECK(!group->partially_free_list_next);
	if (partially_free_list_head_)
	partially_free_list_head_->partially_free_list_prev = group;

	group->partially_free_list_next = partially_free_list_head_;
	partially_free_list_head_ = group;
	}

	void AtomicFlagSet::RemoveFromPartiallyFreeList(Group* group) {
	DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
	DCHECK(partially_free_list_head_);
	// Check \|group\| is in the list.
	DCHECK(partially_free_list_head_ == group \|\| group->partially_free_list_prev);
	if (group->partially_free_list_next) {
	group->partially_free_list_next->partially_free_list_prev =
	group->partially_free_list_prev;
	}

	if (group->partially_free_list_prev) {
	group->partially_free_list_prev->partially_free_list_next =
	group->partially_free_list_next;
	} else {
	partially_free_list_head_ = group->partially_free_list_next;
	}

	group->partially_free_list_prev = nullptr;
	group->partially_free_list_next = nullptr;
	}

	} // namespace internal
	} // namespace sequence_manager
	} // namespace base