Rocket.Chat.ReactNative/ios/Pods/Folly/folly/LockTraits.h

672 lines
20 KiB
C++

/*
* Copyright (c) Facebook, Inc. and its affiliates.
*
* 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
*
* http://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.
*/
/**
* This module provides a traits class for describing properties about mutex
* classes.
*
* This is a primitive for building higher-level abstractions that can work
* with a variety of mutex classes. For instance, this allows
* folly::Synchronized to support a number of different mutex types.
*/
#pragma once
#include <chrono>
#include <type_traits>
#include <folly/functional/Invoke.h>
// Android, OSX, and Cygwin don't have timed mutexes
#if defined(ANDROID) || defined(__ANDROID__) || defined(__APPLE__) || \
defined(__CYGWIN__)
#define FOLLY_LOCK_TRAITS_HAVE_TIMED_MUTEXES 0
#else
#define FOLLY_LOCK_TRAITS_HAVE_TIMED_MUTEXES 1
#endif
namespace folly {
namespace detail {
namespace member {
FOLLY_CREATE_MEMBER_INVOKER(lock_invoker, lock);
FOLLY_CREATE_MEMBER_INVOKER(try_lock_for_invoker, try_lock_for);
FOLLY_CREATE_MEMBER_INVOKER(lock_shared_invoker, lock_shared);
FOLLY_CREATE_MEMBER_INVOKER(lock_upgrade_invoker, lock_upgrade);
} // namespace member
/**
* An enum to describe the "level" of a mutex. The supported levels are
* Unique - a normal mutex that supports only exclusive locking
* Shared - a shared mutex which has shared locking and unlocking functions;
* Upgrade - a mutex that has all the methods of the two above along with
* support for upgradable locking
*/
enum class MutexLevel { UNIQUE, SHARED, UPGRADE };
/**
* A template dispatch mechanism that is used to determine the level of the
* mutex based on its interface. As decided by LockInterfaceDispatcher.
*/
template <bool is_unique, bool is_shared, bool is_upgrade>
struct MutexLevelValueImpl;
template <>
struct MutexLevelValueImpl<true, false, false> {
static constexpr MutexLevel value = MutexLevel::UNIQUE;
};
template <>
struct MutexLevelValueImpl<true, true, false> {
static constexpr MutexLevel value = MutexLevel::SHARED;
};
template <>
struct MutexLevelValueImpl<true, true, true> {
static constexpr MutexLevel value = MutexLevel::UPGRADE;
};
/**
* An internal helper class to help identify the interface supported by the
* mutex. This is used in conjunction with the above MutexLevel
* specializations and the LockTraitsImpl to determine what functions are
* supported by objects of type Mutex
*/
template <class Mutex>
class LockInterfaceDispatcher {
private:
// assert that the mutex type has basic lock and unlock functions
static_assert(
folly::is_invocable<member::lock_invoker, Mutex>::value,
"The mutex type must support lock and unlock functions");
using duration = std::chrono::milliseconds;
public:
static constexpr bool has_lock_unique = true;
static constexpr bool has_lock_timed =
folly::is_invocable<member::try_lock_for_invoker, Mutex, duration>::value;
static constexpr bool has_lock_shared =
folly::is_invocable<member::lock_shared_invoker, Mutex>::value;
static constexpr bool has_lock_upgrade =
folly::is_invocable<member::lock_upgrade_invoker, Mutex>::value;
};
/**
* LockTraitsImpl is the base that is used to desribe the interface used by
* different mutex types. It accepts a MutexLevel argument and a boolean to
* show whether the mutex is a timed mutex or not. The implementations are
* partially specialized and inherit from the other implementations to get
* similar functionality
*/
template <class Mutex, MutexLevel level, bool is_timed>
struct LockTraitsImpl;
template <class Mutex>
struct LockTraitsImpl<Mutex, MutexLevel::UNIQUE, false> {
static constexpr bool is_timed{false};
static constexpr bool is_shared{false};
static constexpr bool is_upgrade{false};
/**
* Acquire the lock exclusively.
*/
static void lock(Mutex& mutex) {
mutex.lock();
}
/**
* Release an exclusively-held lock.
*/
static void unlock(Mutex& mutex) {
mutex.unlock();
}
/**
* Try to acquire the mutex
*/
static bool try_lock(Mutex& mutex) {
return mutex.try_lock();
}
};
/**
* Higher level mutexes have all the capabilities of the lower levels so
* inherit
*/
template <class Mutex>
struct LockTraitsImpl<Mutex, MutexLevel::SHARED, false>
: public LockTraitsImpl<Mutex, MutexLevel::UNIQUE, false> {
static constexpr bool is_timed{false};
static constexpr bool is_shared{true};
static constexpr bool is_upgrade{false};
/**
* Acquire the lock in shared (read) mode.
*/
static void lock_shared(Mutex& mutex) {
mutex.lock_shared();
}
/**
* Release a lock held in shared mode.
*/
static void unlock_shared(Mutex& mutex) {
mutex.unlock_shared();
}
/**
* Try to acquire the mutex in shared mode
*/
static bool try_lock_shared(Mutex& mutex) {
return mutex.try_lock_shared();
}
};
/**
* The following methods are supported. There are a few methods
*
* m.lock_upgrade()
* m.unlock_upgrade()
* m.try_lock_upgrade()
*
* m.unlock_upgrade_and_lock()
*
* m.unlock_and_lock_upgrade()
* m.unlock_and_lock_shared()
* m.unlock_upgrade_and_lock_shared()
*
* m.try_lock_upgrade_for(rel_time)
* m.try_unlock_upgrade_and_lock_for(rel_time)
*
* Upgrading a shared lock is likely to deadlock when there is more than one
* thread performing an upgrade. This applies both to upgrading a shared lock
* to an upgrade lock and to upgrading a shared lock to a unique lock.
*
* Therefore, none of the following methods is supported:
* unlock_shared_and_lock_upgrade
* unlock_shared_and_lock
* try_unlock_shared_and_lock_upgrade
* try_unlock_shared_and_lock
* try_unlock_shared_and_lock_upgrade_for
* try_unlock_shared_and_lock_for
*/
template <class Mutex>
struct LockTraitsImpl<Mutex, MutexLevel::UPGRADE, false>
: public LockTraitsImpl<Mutex, MutexLevel::SHARED, false> {
static constexpr bool is_timed{false};
static constexpr bool is_shared{true};
static constexpr bool is_upgrade{true};
/**
* Acquire the lock in upgradable mode.
*/
static void lock_upgrade(Mutex& mutex) {
mutex.lock_upgrade();
}
/**
* Release the lock in upgrade mode
*/
static void unlock_upgrade(Mutex& mutex) {
mutex.unlock_upgrade();
}
/**
* Try and acquire the lock in upgrade mode
*/
static bool try_lock_upgrade(Mutex& mutex) {
return mutex.try_lock_upgrade();
}
/**
* Upgrade from an upgradable state to an exclusive state
*/
static void unlock_upgrade_and_lock(Mutex& mutex) {
mutex.unlock_upgrade_and_lock();
}
/**
* Downgrade from an exclusive state to an upgrade state
*/
static void unlock_and_lock_upgrade(Mutex& mutex) {
mutex.unlock_and_lock_upgrade();
}
/**
* Downgrade from an exclusive state to a shared state
*/
static void unlock_and_lock_shared(Mutex& mutex) {
mutex.unlock_and_lock_shared();
}
/**
* Downgrade from an upgrade state to a shared state
*/
static void unlock_upgrade_and_lock_shared(Mutex& mutex) {
mutex.unlock_upgrade_and_lock_shared();
}
};
template <class Mutex>
struct LockTraitsImpl<Mutex, MutexLevel::UNIQUE, true>
: public LockTraitsImpl<Mutex, MutexLevel::UNIQUE, false> {
static constexpr bool is_timed{true};
static constexpr bool is_shared{false};
static constexpr bool is_upgrade{false};
/**
* Acquire the lock exclusively, with a timeout.
*
* Returns true or false indicating if the lock was acquired or not.
*/
template <class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return mutex.try_lock_for(timeout);
}
};
/**
* Note that there is no deadly diamond here because all the structs only have
* static functions and static bools which are going to be overridden by the
* lowest level implementation
*/
template <class Mutex>
struct LockTraitsImpl<Mutex, MutexLevel::SHARED, true>
: public LockTraitsImpl<Mutex, MutexLevel::SHARED, false>,
public LockTraitsImpl<Mutex, MutexLevel::UNIQUE, true> {
static constexpr bool is_timed{true};
static constexpr bool is_shared{true};
static constexpr bool is_upgrade{false};
/**
* Acquire the lock exclusively, with a timeout.
*
* Returns true or false indicating if the lock was acquired or not.
*/
template <class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return mutex.try_lock_for(timeout);
}
/**
* Acquire the lock in shared (read) mode, with a timeout.
*
* Returns true or false indicating if the lock was acquired or not.
*/
template <class Rep, class Period>
static bool try_lock_shared_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return mutex.try_lock_shared_for(timeout);
}
};
template <class Mutex>
struct LockTraitsImpl<Mutex, MutexLevel::UPGRADE, true>
: public LockTraitsImpl<Mutex, MutexLevel::UPGRADE, false>,
public LockTraitsImpl<Mutex, MutexLevel::SHARED, true> {
static constexpr bool is_timed{true};
static constexpr bool is_shared{true};
static constexpr bool is_upgrade{true};
/**
* Acquire the lock in upgrade mode with a timeout
*
* Returns true or false indicating whether the lock was acquired or not
*/
template <class Rep, class Period>
static bool try_lock_upgrade_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return mutex.try_lock_upgrade_for(timeout);
}
/**
* Try to upgrade from an upgradable state to an exclusive state.
*
* Returns true or false indicating whether the lock was acquired or not
*/
template <class Rep, class Period>
static bool try_unlock_upgrade_and_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return mutex.try_unlock_upgrade_and_lock_for(timeout);
}
};
/**
* Unlock helpers
*
* These help in determining whether it is safe for Synchronized::LockedPtr
* instances to be move assigned from one another. It is safe if they both
* have the same unlock policy, and it is not if they don't have the same
* unlock policy. For example
*
* auto wlock = synchronized.wlock();
* wlock.unlock();
*
* wlock = synchronized.rlock();
*
* This code would try to release the shared lock with a call to unlock(),
* resulting in possibly undefined behavior. By allowing the LockPolicy
* classes (defined below) to know what their unlocking behavior is, we can
* prevent against this by disabling unsafe conversions to and from
* incompatible LockedPtr types (they are incompatible if the underlying
* LockPolicy has different unlock policies.
*/
template <template <typename...> class LockTraits>
struct UnlockPolicyExclusive {
constexpr static bool allows_concurrent_access = false;
template <typename Mutex>
static void unlock(Mutex& mutex) {
LockTraits<Mutex>::unlock(mutex);
}
};
template <template <typename...> class LockTraits>
struct UnlockPolicyShared {
constexpr static bool allows_concurrent_access = true;
template <typename Mutex>
static void unlock(Mutex& mutex) {
LockTraits<Mutex>::unlock_shared(mutex);
}
};
template <template <typename...> class LockTraits>
struct UnlockPolicyUpgrade {
constexpr static bool allows_concurrent_access = true;
template <typename Mutex>
static void unlock(Mutex& mutex) {
LockTraits<Mutex>::unlock_upgrade(mutex);
}
};
} // namespace detail
/**
* LockTraits describes details about a particular mutex type.
*
* The default implementation automatically attempts to detect traits
* based on the presence of various member functions.
*
* You can specialize LockTraits to provide custom behavior for lock
* classes that do not use the standard method names
* (lock()/unlock()/lock_shared()/unlock_shared()/try_lock_for())
*
*
* LockTraits contains the following members variables:
* - static constexpr bool is_shared
* True if the lock supports separate shared vs exclusive locking states.
* - static constexpr bool is_timed
* True if the lock supports acquiring the lock with a timeout.
* - static constexpr bool is_upgrade
* True if the lock supports an upgradable state
*
* The following static methods always exist:
* - lock(Mutex& mutex)
* - unlock(Mutex& mutex)
* - try_lock(Mutex& mutex)
*
* The following static methods may exist, depending on is_shared, is_timed
* and is_upgrade:
* - lock_shared()
* - try_lock_shared()
*
* - try_lock_for()
* - try_lock_shared_for()
*
* - lock_upgrade()
* - try_lock_upgrade()
* - unlock_upgrade_and_lock()
* - unlock_and_lock_upgrade()
* - unlock_and_lock_shared()
* - unlock_upgrade_and_lock_shared()
*
* - try_lock_upgrade_for()
* - try_unlock_upgrade_and_lock_for()
*
* - unlock_shared()
* - unlock_upgrade()
*/
/**
* Decoupling LockTraits and LockTraitsBase so that if people want to fully
* specialize LockTraits then they can inherit from LockTraitsBase instead
* of LockTraits with all the same goodies :)
*/
template <class Mutex>
struct LockTraitsBase
: public detail::LockTraitsImpl<
Mutex,
detail::MutexLevelValueImpl<
detail::LockInterfaceDispatcher<Mutex>::has_lock_unique,
detail::LockInterfaceDispatcher<Mutex>::has_lock_shared,
detail::LockInterfaceDispatcher<Mutex>::has_lock_upgrade>::value,
detail::LockInterfaceDispatcher<Mutex>::has_lock_timed> {};
template <class Mutex>
struct LockTraits : public LockTraitsBase<Mutex> {};
/*
* Lock policy classes.
*
* These can be used as template parameters to provide compile-time
* selection over the type of lock operation to perform.
*/
/**
* A lock policy that performs exclusive lock operations.
*/
struct LockPolicyExclusive : detail::UnlockPolicyExclusive<LockTraits> {
using UnlockPolicy = detail::UnlockPolicyExclusive<LockTraits>;
template <class Mutex>
static std::true_type lock(Mutex& mutex) {
LockTraits<Mutex>::lock(mutex);
return std::true_type{};
}
template <class Mutex, class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return LockTraits<Mutex>::try_lock_for(mutex, timeout);
}
};
/**
* A lock policy that performs shared lock operations.
* This policy only works with shared mutex types.
*/
struct LockPolicyShared : detail::UnlockPolicyShared<LockTraits> {
using UnlockPolicy = detail::UnlockPolicyShared<LockTraits>;
template <class Mutex>
static std::true_type lock(Mutex& mutex) {
LockTraits<Mutex>::lock_shared(mutex);
return std::true_type{};
}
template <class Mutex, class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return LockTraits<Mutex>::try_lock_shared_for(mutex, timeout);
}
};
/**
* A lock policy with the following mapping
*
* lock() -> lock_upgrade()
* unlock() -> unlock_upgrade()
* try_lock_for -> try_lock_upgrade_for()
*/
struct LockPolicyUpgrade : detail::UnlockPolicyUpgrade<LockTraits> {
using UnlockPolicy = detail::UnlockPolicyUpgrade<LockTraits>;
template <class Mutex>
static std::true_type lock(Mutex& mutex) {
LockTraits<Mutex>::lock_upgrade(mutex);
return std::true_type{};
}
template <class Mutex, class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return LockTraits<Mutex>::try_lock_upgrade_for(mutex, timeout);
}
};
/*****************************************************************************
* Policies for optional mutex locking
****************************************************************************/
/**
* A lock policy that tries to acquire write locks and returns true or false
* based on whether the lock operation succeeds
*/
struct LockPolicyTryExclusive : detail::UnlockPolicyExclusive<LockTraits> {
using UnlockPolicy = detail::UnlockPolicyExclusive<LockTraits>;
template <class Mutex>
static bool lock(Mutex& mutex) {
return LockTraits<Mutex>::try_lock(mutex);
}
};
/**
* A lock policy that tries to acquire a read lock and returns true or false
* based on whether the lock operation succeeds
*/
struct LockPolicyTryShared : detail::UnlockPolicyShared<LockTraits> {
using UnlockPolicy = detail::UnlockPolicyShared<LockTraits>;
template <class Mutex>
static bool lock(Mutex& mutex) {
return LockTraits<Mutex>::try_lock_shared(mutex);
}
};
/**
* A lock policy that tries to acquire an upgrade lock and returns true or
* false based on whether the lock operation succeeds
*/
struct LockPolicyTryUpgrade : detail::UnlockPolicyUpgrade<LockTraits> {
using UnlockPolicy = detail::UnlockPolicyUpgrade<LockTraits>;
template <class Mutex>
static bool lock(Mutex& mutex) {
return LockTraits<Mutex>::try_lock_upgrade(mutex);
}
};
/*****************************************************************************
* Policies for all the transitions from possible mutex levels
****************************************************************************/
/**
* A lock policy with the following mapping
*
* lock() -> unlock_upgrade_and_lock()
* unlock() -> unlock()
* try_lock_for -> try_unlock_upgrade_and_lock_for()
*/
struct LockPolicyFromUpgradeToExclusive : LockPolicyExclusive {
template <class Mutex>
static std::true_type lock(Mutex& mutex) {
LockTraits<Mutex>::unlock_upgrade_and_lock(mutex);
return std::true_type{};
}
template <class Mutex, class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>& timeout) {
return LockTraits<Mutex>::try_unlock_upgrade_and_lock_for(mutex, timeout);
}
};
/**
* A lock policy with the following mapping
*
* lock() -> unlock_and_lock_upgrade()
* unlock() -> unlock_upgrade()
* try_lock_for -> unlock_and_lock_upgrade()
*/
struct LockPolicyFromExclusiveToUpgrade : LockPolicyUpgrade {
template <class Mutex>
static std::true_type lock(Mutex& mutex) {
LockTraits<Mutex>::unlock_and_lock_upgrade(mutex);
return std::true_type{};
}
template <class Mutex, class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>&) {
LockTraits<Mutex>::unlock_and_lock_upgrade(mutex);
// downgrade should be non blocking and should succeed
return true;
}
};
/**
* A lock policy with the following mapping
*
* lock() -> unlock_upgrade_and_lock_shared()
* unlock() -> unlock_shared()
* try_lock_for -> unlock_upgrade_and_lock_shared()
*/
struct LockPolicyFromUpgradeToShared : LockPolicyShared {
template <class Mutex>
static std::true_type lock(Mutex& mutex) {
LockTraits<Mutex>::unlock_upgrade_and_lock_shared(mutex);
return std::true_type{};
}
template <class Mutex, class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>&) {
LockTraits<Mutex>::unlock_upgrade_and_lock_shared(mutex);
// downgrade should be non blocking and should succeed
return true;
}
};
/**
* A lock policy with the following mapping
*
* lock() -> unlock_and_lock_shared()
* unlock() -> unlock_shared()
* try_lock_for() -> unlock_and_lock_shared()
*/
struct LockPolicyFromExclusiveToShared : LockPolicyShared {
template <class Mutex>
static std::true_type lock(Mutex& mutex) {
LockTraits<Mutex>::unlock_and_lock_shared(mutex);
return std::true_type{};
}
template <class Mutex, class Rep, class Period>
static bool try_lock_for(
Mutex& mutex,
const std::chrono::duration<Rep, Period>&) {
LockTraits<Mutex>::unlock_and_lock_shared(mutex);
// downgrade should be non blocking and should succeed
return true;
}
};
} // namespace folly