pw_multibuf/allocator.cc - pigweed/pigweed - Git at Google

 // Copyright 2024 The Pigweed Authors
 //
 // Licensed under the Apache License, Version 2.0 (the "License"); you may not
 // use this file except in compliance with the License. You may obtain a copy of
 // the License at
 //
 //     https://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
 // WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
 // License for the specific language governing permissions and limitations under
 // the License.

 #include "pw_multibuf/allocator.h"

 #include "pw_assert/check.h"

 namespace pw::multibuf {

 std::optional<MultiBuf> MultiBufAllocator::Allocate(size_t size) {
   return Allocate(size, size);
 }

 std::optional<MultiBuf> MultiBufAllocator::Allocate(size_t min_size,
                                                     size_t desired_size) {
   pw::Result<MultiBuf> result = DoAllocate(min_size, desired_size, false);
   if (result.ok()) {
     return std::move(*result);
   }
   return std::nullopt;
 }

 std::optional<MultiBuf> MultiBufAllocator::AllocateContiguous(size_t size) {
   return AllocateContiguous(size, size);
 }

 std::optional<MultiBuf> MultiBufAllocator::AllocateContiguous(
     size_t min_size, size_t desired_size) {
   pw::Result<MultiBuf> result = DoAllocate(min_size, desired_size, true);
   if (result.ok()) {
     return std::move(*result);
   }
   return std::nullopt;
 }

 MultiBufAllocationFuture MultiBufAllocator::AllocateAsync(size_t size) {
   return MultiBufAllocationFuture(*this, size, size, false);
 }
 MultiBufAllocationFuture MultiBufAllocator::AllocateAsync(size_t min_size,
                                                           size_t desired_size) {
   return MultiBufAllocationFuture(*this, min_size, desired_size, false);
 }
 MultiBufAllocationFuture MultiBufAllocator::AllocateContiguousAsync(
     size_t size) {
   return MultiBufAllocationFuture(*this, size, size, true);
 }
 MultiBufAllocationFuture MultiBufAllocator::AllocateContiguousAsync(
     size_t min_size, size_t desired_size) {
   return MultiBufAllocationFuture(*this, min_size, desired_size, true);
 }

 void MultiBufAllocator::MoreMemoryAvailable(size_t size_available,
                                             size_t contiguous_size_available)
     // Disable lock safety analysis: the access to `next_` requires locking
     // `waiter->allocator_->lock_`, but that's the same as `lock_` which we
     // already hold.
     PW_NO_LOCK_SAFETY_ANALYSIS {
   std::lock_guard lock(lock_);
   internal::AllocationWaiter* current = first_waiter_;
   while (current != nullptr) {
     PW_DCHECK(current->allocator_ == this);
     if ((current->min_size_ <= contiguous_size_available) ||
         (!current->needs_contiguous_ && current->min_size_ <= size_available)) {
       std::move(current->waker_).Wake();
     }
     current = current->next_;
   }
 }

 void MultiBufAllocator::AddWaiter(internal::AllocationWaiter* waiter) {
   std::lock_guard lock(lock_);
   AddWaiterLocked(waiter);
 }

 void MultiBufAllocator::AddWaiterLocked(internal::AllocationWaiter* waiter)
     // Disable lock safety analysis: the access to `next_` requires locking
     // `waiter->allocator_->lock_`, but that's the same as `lock_` which we
     // already hold.
     PW_NO_LOCK_SAFETY_ANALYSIS {
   PW_DCHECK(waiter->allocator_ == this);
   PW_DCHECK(waiter->next_ == nullptr);
   auto old_first = first_waiter_;
   first_waiter_ = waiter;
   waiter->next_ = old_first;
 }

 void MultiBufAllocator::RemoveWaiter(internal::AllocationWaiter* waiter)
     // Disable lock safety analysis: the access to `next_` requires locking
     // `waiter->allocator_->lock_`, but that's the same as `lock_` which we
     // already hold.
     PW_NO_LOCK_SAFETY_ANALYSIS {
   std::lock_guard lock(lock_);
   RemoveWaiterLocked(waiter);
   PW_DCHECK(waiter->next_ == nullptr);
 }

 void MultiBufAllocator::RemoveWaiterLocked(internal::AllocationWaiter* waiter)
     // Disable lock safety analysis: the access to `next_` requires locking
     // `waiter->allocator_->lock_`, but that's the same as `lock_` which we
     // already hold.
     PW_NO_LOCK_SAFETY_ANALYSIS {
   PW_DCHECK(waiter->allocator_ == this);
   if (waiter == first_waiter_) {
     first_waiter_ = first_waiter_->next_;
     waiter->next_ = nullptr;
     return;
   }
   auto current = first_waiter_;
   while (current != nullptr) {
     if (current->next_ == waiter) {
       current->next_ = waiter->next_;
       waiter->next_ = nullptr;
       return;
     }
     current = current->next_;
   }
 }

 namespace internal {

 AllocationWaiter::AllocationWaiter(AllocationWaiter&& other)
     : allocator_(other.allocator_),
       waker_(),
       next_(nullptr),
       min_size_(other.min_size_),
       desired_size_(other.desired_size_),
       needs_contiguous_(other.needs_contiguous_) {
   std::lock_guard lock(allocator_->lock_);
   allocator_->RemoveWaiterLocked(&other);
   allocator_->AddWaiterLocked(this);
   // We must move the waker under the lock in order to ensure that there is no
   // race between swapping ``AllocationWaiter``s and the waker being awoken by
   // the allocator.
   waker_ = std::move(other.waker_);
 }

 AllocationWaiter& AllocationWaiter::operator=(AllocationWaiter&& other) {
   allocator_->RemoveWaiter(this);

   allocator_ = other.allocator_;
   min_size_ = other.min_size_;
   desired_size_ = other.desired_size_;
   needs_contiguous_ = other.needs_contiguous_;

   std::lock_guard lock(allocator_->lock_);
   allocator_->RemoveWaiterLocked(&other);
   allocator_->AddWaiterLocked(this);
   // We must move the waker under the lock in order to ensure that there is no
   // race between swapping ``AllocationWaiter``s and the waker being awoken by
   // the allocator.
   waker_ = std::move(other.waker_);

   return *this;
 }

 AllocationWaiter::~AllocationWaiter() { allocator_->RemoveWaiter(this); }

 }  // namespace internal

 async2::Poll<std::optional<MultiBuf>> MultiBufAllocationFuture::Pend(
     async2::Context& cx) {
   bool should_attempt = waiter_.ShouldAttemptAllocate();
   // We set the waker prior to attempting allocation because we want
   // to receive notifications that may have raced with our attempt
   // to allocate. If we wait to set until after attempting,
   // we'd have to re-attempt in order to ensure that no new memory
   // became available between our attempt and setting the waker.
   waiter_.SetWaker(cx.GetWaker(async2::WaitReason::Unspecified()));
   if (!should_attempt) {
     return async2::Pending();
   }
   auto result = TryAllocate();
   if (result.IsReady()) {
     waiter_.ClearWaker();
   }
   return result;
 }

 async2::Poll<std::optional<MultiBuf>> MultiBufAllocationFuture::TryAllocate() {
   pw::Result<MultiBuf> buf_opt = waiter_.allocator().DoAllocate(
       waiter_.min_size(), waiter_.desired_size(), waiter_.needs_contiguous());
   if (buf_opt.ok()) {
     return async2::Ready<std::optional<MultiBuf>>(std::move(*buf_opt));
   }
   if (buf_opt.status().IsOutOfRange()) {
     return async2::Ready<std::optional<MultiBuf>>(std::nullopt);
   }
   return async2::Pending();
 }

 }  // namespace pw::multibuf
	// Copyright 2024 The Pigweed Authors
	//
	// Licensed under the Apache License, Version 2.0 (the "License"); you may not
	// use this file except in compliance with the License. You may obtain a copy of
	// the License at
	//
	// https://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
	// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
	// License for the specific language governing permissions and limitations under
	// the License.

	#include "pw_multibuf/allocator.h"

	#include "pw_assert/check.h"

	namespace pw::multibuf {

	std::optional<MultiBuf> MultiBufAllocator::Allocate(size_t size) {
	return Allocate(size, size);
	}

	std::optional<MultiBuf> MultiBufAllocator::Allocate(size_t min_size,
	size_t desired_size) {
	pw::Result<MultiBuf> result = DoAllocate(min_size, desired_size, false);
	if (result.ok()) {
	return std::move(*result);
	}
	return std::nullopt;
	}

	std::optional<MultiBuf> MultiBufAllocator::AllocateContiguous(size_t size) {
	return AllocateContiguous(size, size);
	}

	std::optional<MultiBuf> MultiBufAllocator::AllocateContiguous(
	size_t min_size, size_t desired_size) {
	pw::Result<MultiBuf> result = DoAllocate(min_size, desired_size, true);
	if (result.ok()) {
	return std::move(*result);
	}
	return std::nullopt;
	}

	MultiBufAllocationFuture MultiBufAllocator::AllocateAsync(size_t size) {
	return MultiBufAllocationFuture(*this, size, size, false);
	}
	MultiBufAllocationFuture MultiBufAllocator::AllocateAsync(size_t min_size,
	size_t desired_size) {
	return MultiBufAllocationFuture(*this, min_size, desired_size, false);
	}
	MultiBufAllocationFuture MultiBufAllocator::AllocateContiguousAsync(
	size_t size) {
	return MultiBufAllocationFuture(*this, size, size, true);
	}
	MultiBufAllocationFuture MultiBufAllocator::AllocateContiguousAsync(
	size_t min_size, size_t desired_size) {
	return MultiBufAllocationFuture(*this, min_size, desired_size, true);
	}

	void MultiBufAllocator::MoreMemoryAvailable(size_t size_available,
	size_t contiguous_size_available)
	// Disable lock safety analysis: the access to `next_` requires locking
	// `waiter->allocator_->lock_`, but that's the same as `lock_` which we
	// already hold.
	PW_NO_LOCK_SAFETY_ANALYSIS {
	std::lock_guard lock(lock_);
	internal::AllocationWaiter* current = first_waiter_;
	while (current != nullptr) {
	PW_DCHECK(current->allocator_ == this);
	if ((current->min_size_ <= contiguous_size_available) \|\|
	(!current->needs_contiguous_ && current->min_size_ <= size_available)) {
	std::move(current->waker_).Wake();
	}
	current = current->next_;
	}
	}

	void MultiBufAllocator::AddWaiter(internal::AllocationWaiter* waiter) {
	std::lock_guard lock(lock_);
	AddWaiterLocked(waiter);
	}

	void MultiBufAllocator::AddWaiterLocked(internal::AllocationWaiter* waiter)
	// Disable lock safety analysis: the access to `next_` requires locking
	// `waiter->allocator_->lock_`, but that's the same as `lock_` which we
	// already hold.
	PW_NO_LOCK_SAFETY_ANALYSIS {
	PW_DCHECK(waiter->allocator_ == this);
	PW_DCHECK(waiter->next_ == nullptr);
	auto old_first = first_waiter_;
	first_waiter_ = waiter;
	waiter->next_ = old_first;
	}

	void MultiBufAllocator::RemoveWaiter(internal::AllocationWaiter* waiter)
	// Disable lock safety analysis: the access to `next_` requires locking
	// `waiter->allocator_->lock_`, but that's the same as `lock_` which we
	// already hold.
	PW_NO_LOCK_SAFETY_ANALYSIS {
	std::lock_guard lock(lock_);
	RemoveWaiterLocked(waiter);
	PW_DCHECK(waiter->next_ == nullptr);
	}

	void MultiBufAllocator::RemoveWaiterLocked(internal::AllocationWaiter* waiter)
	// Disable lock safety analysis: the access to `next_` requires locking
	// `waiter->allocator_->lock_`, but that's the same as `lock_` which we
	// already hold.
	PW_NO_LOCK_SAFETY_ANALYSIS {
	PW_DCHECK(waiter->allocator_ == this);
	if (waiter == first_waiter_) {
	first_waiter_ = first_waiter_->next_;
	waiter->next_ = nullptr;
	return;
	}
	auto current = first_waiter_;
	while (current != nullptr) {
	if (current->next_ == waiter) {
	current->next_ = waiter->next_;
	waiter->next_ = nullptr;
	return;
	}
	current = current->next_;
	}
	}

	namespace internal {

	AllocationWaiter::AllocationWaiter(AllocationWaiter&& other)
	: allocator_(other.allocator_),
	waker_(),
	next_(nullptr),
	min_size_(other.min_size_),
	desired_size_(other.desired_size_),
	needs_contiguous_(other.needs_contiguous_) {
	std::lock_guard lock(allocator_->lock_);
	allocator_->RemoveWaiterLocked(&other);
	allocator_->AddWaiterLocked(this);
	// We must move the waker under the lock in order to ensure that there is no
	// race between swapping ``AllocationWaiter``s and the waker being awoken by
	// the allocator.
	waker_ = std::move(other.waker_);
	}

	AllocationWaiter& AllocationWaiter::operator=(AllocationWaiter&& other) {
	allocator_->RemoveWaiter(this);

	allocator_ = other.allocator_;
	min_size_ = other.min_size_;
	desired_size_ = other.desired_size_;
	needs_contiguous_ = other.needs_contiguous_;

	std::lock_guard lock(allocator_->lock_);
	allocator_->RemoveWaiterLocked(&other);
	allocator_->AddWaiterLocked(this);
	// We must move the waker under the lock in order to ensure that there is no
	// race between swapping ``AllocationWaiter``s and the waker being awoken by
	// the allocator.
	waker_ = std::move(other.waker_);

	return *this;
	}

	AllocationWaiter::~AllocationWaiter() { allocator_->RemoveWaiter(this); }

	} // namespace internal

	async2::Poll<std::optional<MultiBuf>> MultiBufAllocationFuture::Pend(
	async2::Context& cx) {
	bool should_attempt = waiter_.ShouldAttemptAllocate();
	// We set the waker prior to attempting allocation because we want
	// to receive notifications that may have raced with our attempt
	// to allocate. If we wait to set until after attempting,
	// we'd have to re-attempt in order to ensure that no new memory
	// became available between our attempt and setting the waker.
	waiter_.SetWaker(cx.GetWaker(async2::WaitReason::Unspecified()));
	if (!should_attempt) {
	return async2::Pending();
	}
	auto result = TryAllocate();
	if (result.IsReady()) {
	waiter_.ClearWaker();
	}
	return result;
	}

	async2::Poll<std::optional<MultiBuf>> MultiBufAllocationFuture::TryAllocate() {
	pw::Result<MultiBuf> buf_opt = waiter_.allocator().DoAllocate(
	waiter_.min_size(), waiter_.desired_size(), waiter_.needs_contiguous());
	if (buf_opt.ok()) {
	return async2::Ready<std::optional<MultiBuf>>(std::move(*buf_opt));
	}
	if (buf_opt.status().IsOutOfRange()) {
	return async2::Ready<std::optional<MultiBuf>>(std::nullopt);
	}
	return async2::Pending();
	}

	} // namespace pw::multibuf