kern: use new AtomicRef, use Atomic<bool>

2024-11-09 22:56:35 +00:00 · 2021-10-20 13:29:38 -07:00 · 2021-10-20 13:29:38 -07:00 · 20716cb3de
commit 20716cb3de
parent aed9d3f535
7 changed files with 334 additions and 160 deletions
--- a/libraries/libmesosphere/include/mesosphere/kern_k_scheduler.hpp
+++ b/libraries/libmesosphere/include/mesosphere/kern_k_scheduler.hpp
@ -39,13 +39,13 @@ namespace ams::kern {
            static_assert(ams::svc::HighestThreadPriority <= HighestCoreMigrationAllowedPriority);
            struct SchedulingState {
-                util::Atomic<u8> needs_scheduling{false};
+                util::Atomic<bool> needs_scheduling{false};
                bool interrupt_task_runnable{false};
                bool should_count_idle{false};
                u64  idle_count{0};
                KThread *highest_priority_thread{nullptr};
                void *idle_thread_stack{nullptr};
-                util::Atomic<KThread *> prev_thread{nullptr};
+                KThread *prev_thread{nullptr};
                KInterruptTaskManager *interrupt_task_manager{nullptr};
                constexpr SchedulingState() = default;
@ -100,7 +100,7 @@ namespace ams::kern {
            }
            ALWAYS_INLINE KThread *GetPreviousThread() const {
-                return m_state.prev_thread.Load<std::memory_order_relaxed>();
+                return m_state.prev_thread;
            }
            ALWAYS_INLINE KThread *GetSchedulerCurrentThread() const {
--- a/libraries/libmesosphere/include/mesosphere/kern_k_slab_heap.hpp
+++ b/libraries/libmesosphere/include/mesosphere/kern_k_slab_heap.hpp
@ -76,18 +76,20 @@ namespace ams::kern {
        NON_MOVEABLE(KSlabHeapBase);
        private:
            size_t m_obj_size{};
-            util::Atomic<uintptr_t> m_peak{0};
+            uintptr_t m_peak{};
            uintptr_t m_start{};
            uintptr_t m_end{};
        private:
            ALWAYS_INLINE void UpdatePeakImpl(uintptr_t obj) {
                const util::AtomicRef<uintptr_t> peak_ref(m_peak);
                const uintptr_t alloc_peak = obj + this->GetObjectSize();
-                uintptr_t cur_peak = m_peak.Load<std::memory_order_relaxed>();
+                uintptr_t cur_peak = m_peak;
                do {
                    if (alloc_peak <= cur_peak) {
                        break;
                    }
-                } while (!m_peak.CompareExchangeStrong(cur_peak, alloc_peak));
+                } while (!peak_ref.CompareExchangeStrong(cur_peak, alloc_peak));
            }
        public:
            constexpr KSlabHeapBase() = default;
@ -110,8 +112,7 @@ namespace ams::kern {
                const size_t num_obj = (memory_size / obj_size);
                m_start = reinterpret_cast<uintptr_t>(memory);
                m_end   = m_start + num_obj * obj_size;
-
+                m_peak  = m_start;
                m_peak.Store<std::memory_order_relaxed>(m_start);
                /* Free the objects. */
                u8 *cur = reinterpret_cast<u8 *>(m_end);
@ -175,7 +176,7 @@ namespace ams::kern {
            }
            ALWAYS_INLINE size_t GetPeakIndex() const {
-                return this->GetObjectIndex(reinterpret_cast<const void *>(m_peak.Load<std::memory_order_relaxed>()));
+                return this->GetObjectIndex(reinterpret_cast<const void *>(m_peak));
            }
            ALWAYS_INLINE uintptr_t GetSlabHeapAddress() const {
--- a/libraries/libmesosphere/include/mesosphere/kern_k_thread.hpp
+++ b/libraries/libmesosphere/include/mesosphere/kern_k_thread.hpp
@ -225,7 +225,7 @@ namespace ams::kern {
            s32                             m_original_physical_ideal_core_id{};
            s32                             m_num_core_migration_disables{};
            ThreadState                     m_thread_state{};
-            util::Atomic<u8>                m_termination_requested{false};
+            util::Atomic<bool>              m_termination_requested{false};
            bool                            m_wait_cancelled{};
            bool                            m_cancellable{};
            bool                            m_signaled{};
--- a/libraries/libmesosphere/source/kern_k_scheduler.cpp
+++ b/libraries/libmesosphere/source/kern_k_scheduler.cpp
@ -246,9 +246,9 @@ namespace ams::kern {
        if (cur_process != nullptr) {
            /* NOTE: Combining this into AMS_LIKELY(!... && ...) triggers an internal compiler error: Segmentation fault in GCC 9.2.0. */
            if (AMS_LIKELY(!cur_thread->IsTerminationRequested()) && AMS_LIKELY(cur_thread->GetActiveCore() == m_core_id)) {
-                m_state.prev_thread.Store<std::memory_order_relaxed>(cur_thread);
+                m_state.prev_thread = cur_thread;
            } else {
-                m_state.prev_thread.Store<std::memory_order_relaxed>(nullptr);
+                m_state.prev_thread =nullptr;
            }
        }
@ -270,9 +270,12 @@ namespace ams::kern {
    void KScheduler::ClearPreviousThread(KThread *thread) {
        MESOSPHERE_ASSERT(IsSchedulerLockedByCurrentThread());
        for (size_t i = 0; i < cpu::NumCores; ++i) {
            /* Get an atomic reference to the core scheduler's previous thread. */
            const util::AtomicRef<KThread *> prev_thread(Kernel::GetScheduler(static_cast<s32>(i)).m_state.prev_thread);
            /* Atomically clear the previous thread if it's our target. */
            KThread *compare = thread;
-            Kernel::GetScheduler(static_cast<s32>(i)).m_state.prev_thread.CompareExchangeStrong(compare, nullptr);
+            prev_thread.CompareExchangeStrong(compare, nullptr);
        }
    }
--- a/libraries/libmesosphere/source/kern_k_thread.cpp
+++ b/libraries/libmesosphere/source/kern_k_thread.cpp
@ -1184,7 +1184,7 @@ namespace ams::kern {
        /* Determine if this is the first termination request. */
        const bool first_request = [&] ALWAYS_INLINE_LAMBDA () -> bool {
            /* Perform an atomic compare-and-swap from false to true. */
-            u8 expected = false;
+            bool expected = false;
            return m_termination_requested.CompareExchangeStrong(expected, true);
        }();
--- a/libraries/libvapours/include/vapours/util/arch/arm64/util_atomic.hpp
+++ b/libraries/libvapours/include/vapours/util/arch/arm64/util_atomic.hpp
@ -100,6 +100,121 @@ namespace ams::util {
        #undef AMS_UTIL_IMPL_DEFINE_ATOMIC_STORE_EXCLUSIVE_FUNCTION
        template<UsableAtomicType T>
        constexpr ALWAYS_INLINE T ConvertToTypeForAtomic(AtomicStorage<T> s) {
            if constexpr (std::integral<T>) {
                return static_cast<T>(s);
            } else if constexpr(std::is_pointer<T>::value) {
                return reinterpret_cast<T>(s);
            } else {
                return std::bit_cast<T>(s);
            }
        }
        template<UsableAtomicType T>
        constexpr ALWAYS_INLINE AtomicStorage<T> ConvertToStorageForAtomic(T arg) {
            if constexpr (std::integral<T>) {
                return static_cast<AtomicStorage<T>>(arg);
            } else if constexpr(std::is_pointer<T>::value) {
                if (std::is_constant_evaluated() && arg == nullptr) {
                    return 0;
                }
                return reinterpret_cast<AtomicStorage<T>>(arg);
            } else {
                return std::bit_cast<AtomicStorage<T>>(arg);
            }
        }
        template<std::memory_order Order, std::unsigned_integral StorageType>
        ALWAYS_INLINE StorageType AtomicLoadImpl(volatile StorageType * const p) {
            if constexpr (Order != std::memory_order_relaxed) {
                return ::ams::util::impl::LoadAcquireForAtomic(p);
            } else {
                return *p;
            }
        }
        template<std::memory_order Order, std::unsigned_integral StorageType>
        ALWAYS_INLINE void AtomicStoreImpl(volatile StorageType * const p, const StorageType s) {
            if constexpr (Order != std::memory_order_relaxed) {
                ::ams::util::impl::StoreReleaseForAtomic(p, s);
            } else {
                *p = s;
            }
        }
        template<std::memory_order Order, std::unsigned_integral StorageType>
        ALWAYS_INLINE StorageType LoadExclusiveForAtomicByMemoryOrder(volatile StorageType * const p) {
            if constexpr (Order == std::memory_order_relaxed) {
                return ::ams::util::impl::LoadExclusiveForAtomic(p);
            }  else if constexpr (Order == std::memory_order_consume || Order == std::memory_order_acquire) {
                return ::ams::util::impl::LoadAcquireExclusiveForAtomic(p);
            } else if constexpr (Order == std::memory_order_release) {
                return ::ams::util::impl::LoadExclusiveForAtomic(p);
            } else if constexpr (Order == std::memory_order_acq_rel || Order == std::memory_order_seq_cst) {
                return ::ams::util::impl::LoadAcquireExclusiveForAtomic(p);
            } else {
                static_assert(Order != Order, "Invalid memory order");
            }
        }
        template<std::memory_order Order, std::unsigned_integral StorageType>
        ALWAYS_INLINE bool StoreExclusiveForAtomicByMemoryOrder(volatile StorageType * const p, const StorageType s) {
            if constexpr (Order == std::memory_order_relaxed) {
                return ::ams::util::impl::StoreExclusiveForAtomic(p, s);
            }  else if constexpr (Order == std::memory_order_consume || Order == std::memory_order_acquire) {
                return ::ams::util::impl::StoreExclusiveForAtomic(p, s);
            } else if constexpr (Order == std::memory_order_release) {
                return ::ams::util::impl::StoreReleaseExclusiveForAtomic(p, s);
            } else if constexpr (Order == std::memory_order_acq_rel || Order == std::memory_order_seq_cst) {
                return ::ams::util::impl::StoreReleaseExclusiveForAtomic(p, s);
            } else {
                static_assert(Order != Order, "Invalid memory order");
            }
        }
        template<std::memory_order Order, std::unsigned_integral StorageType>
        ALWAYS_INLINE StorageType AtomicExchangeImpl(volatile StorageType * const p, const StorageType s) {
            StorageType current;
            do {
                current = ::ams::util::impl::LoadExclusiveForAtomicByMemoryOrder<Order>(p);
            } while(AMS_UNLIKELY(!impl::StoreExclusiveForAtomicByMemoryOrder<Order>(p, s)));
            return current;
        }
        template<std::memory_order Order, UsableAtomicType T>
        ALWAYS_INLINE bool AtomicCompareExchangeWeakImpl(volatile AtomicStorage<T> * const p, T &expected, T desired) {
            const AtomicStorage<T> e = ::ams::util::impl::ConvertToStorageForAtomic(expected);
            const AtomicStorage<T> d = ::ams::util::impl::ConvertToStorageForAtomic(desired);
            const AtomicStorage<T> current = ::ams::util::impl::LoadExclusiveForAtomicByMemoryOrder<Order>(p);
            if (AMS_UNLIKELY(current != e)) {
                impl::ClearExclusiveForAtomic();
                expected = ::ams::util::impl::ConvertToTypeForAtomic<T>(current);
                return false;
            }
            return AMS_LIKELY(impl::StoreExclusiveForAtomicByMemoryOrder<Order>(p, d));
        }
        template<std::memory_order Order, UsableAtomicType T>
        ALWAYS_INLINE bool AtomicCompareExchangeStrongImpl(volatile AtomicStorage<T> * const p, T &expected, T desired) {
            const AtomicStorage<T> e = ::ams::util::impl::ConvertToStorageForAtomic(expected);
            const AtomicStorage<T> d = ::ams::util::impl::ConvertToStorageForAtomic(desired);
            do {
                if (const AtomicStorage<T> current = ::ams::util::impl::LoadExclusiveForAtomicByMemoryOrder<Order>(p); AMS_UNLIKELY(current != e)) {
                    impl::ClearExclusiveForAtomic();
                    expected = ::ams::util::impl::ConvertToTypeForAtomic<T>(current);
                    return false;
                }
            } while (AMS_UNLIKELY(!impl::StoreExclusiveForAtomicByMemoryOrder<Order>(p, d)));
            return true;
        }
    }
    template<impl::UsableAtomicType T>
@ -117,27 +232,11 @@ namespace ams::util {
            using DifferenceType = typename std::conditional<IsIntegral, T, typename std::conditional<IsPointer, std::ptrdiff_t, void>::type>::type;
            static constexpr ALWAYS_INLINE T ConvertToType(StorageType s) {
-                if constexpr (std::integral<T>) {
+                return impl::ConvertToTypeForAtomic<T>(s);
                    return static_cast<T>(s);
                } else if constexpr(std::is_pointer<T>::value) {
                    return reinterpret_cast<T>(s);
                } else {
                    return std::bit_cast<T>(s);
                }
            }
            static constexpr ALWAYS_INLINE StorageType ConvertToStorage(T arg) {
-                if constexpr (std::integral<T>) {
+                return impl::ConvertToStorageForAtomic<T>(arg);
                    return static_cast<StorageType>(arg);
                } else if constexpr(std::is_pointer<T>::value) {
                    if (std::is_constant_evaluated() && arg == nullptr) {
                        return 0;
                    }
                    return reinterpret_cast<StorageType>(arg);
                } else {
                    return std::bit_cast<StorageType>(arg);
                }
            }
        private:
            StorageType m_v;
@ -157,148 +256,31 @@ namespace ams::util {
                return desired;
            }
            ALWAYS_INLINE operator T() const { return this->Load(); }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE T Load() const {
-                if constexpr (Order != std::memory_order_relaxed) {
+                return ConvertToType(impl::AtomicLoadImpl<Order>(this->GetStoragePointer()));
                    return ConvertToType(impl::LoadAcquireForAtomic(this->GetStoragePointer()));
                } else {
                    return ConvertToType(*this->GetStoragePointer());
                }
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE void Store(T arg) {
-                if constexpr (Order != std::memory_order_relaxed) {
+                return impl::AtomicStoreImpl<Order>(this->GetStoragePointer(), ConvertToStorage(arg));
                    impl::StoreReleaseForAtomic(this->GetStoragePointer(), ConvertToStorage(arg));
                } else {
                    *this->GetStoragePointer() = ConvertToStorage(arg);
                }
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE T Exchange(T arg) {
-                volatile StorageType * const p = this->GetStoragePointer();
+                return ConvertToType(impl::AtomicExchangeImpl(this->GetStoragePointer(), ConvertToStorage(arg)));
                const StorageType s = ConvertToStorage(arg);
                StorageType current;
                if constexpr (Order == std::memory_order_relaxed) {
                    do {
                        current = impl::LoadExclusiveForAtomic(p);
                    } while (AMS_UNLIKELY(!impl::StoreExclusiveForAtomic(p, s)));
                } else if constexpr (Order == std::memory_order_consume || Order == std::memory_order_acquire) {
                    do {
                        current = impl::LoadAcquireExclusiveForAtomic(p);
                    } while (AMS_UNLIKELY(!impl::StoreExclusiveForAtomic(p, s)));
                } else if constexpr (Order == std::memory_order_release) {
                    do {
                        current = impl::LoadExclusiveForAtomic(p);
                    } while (AMS_UNLIKELY(!impl::StoreReleaseExclusiveForAtomic(p, s)));
                } else if constexpr (Order == std::memory_order_acq_rel || Order == std::memory_order_seq_cst) {
                    do {
                        current = impl::LoadAcquireExclusiveForAtomic(p);
                    } while (AMS_UNLIKELY(!impl::StoreReleaseExclusiveForAtomic(p, s)));
                } else {
                    static_assert(Order != Order, "Invalid memory order");
                }
                return current;
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE bool CompareExchangeWeak(T &expected, T desired) {
-                volatile StorageType * const p = this->GetStoragePointer();
+                return impl::AtomicCompareExchangeWeakImpl<Order, T>(this->GetStoragePointer(), expected, desired);
                const StorageType e = ConvertToStorage(expected);
                const StorageType d = ConvertToStorage(desired);
                if constexpr (Order == std::memory_order_relaxed) {
                    const StorageType current = impl::LoadExclusiveForAtomic(p);
                    if (AMS_UNLIKELY(current != e)) {
                        impl::ClearExclusiveForAtomic();
                        expected = ConvertToType(current);
                        return false;
                    }
                    return AMS_LIKELY(impl::StoreExclusiveForAtomic(p, d));
                } else if constexpr (Order == std::memory_order_consume || Order == std::memory_order_acquire) {
                    const StorageType current = impl::LoadAcquireExclusiveForAtomic(p);
                    if (AMS_UNLIKELY(current != e)) {
                        impl::ClearExclusiveForAtomic();
                        expected = ConvertToType(current);
                        return false;
                    }
                    return AMS_LIKELY(impl::StoreExclusiveForAtomic(p, d));
                } else if constexpr (Order == std::memory_order_release) {
                    const StorageType current = impl::LoadExclusiveForAtomic(p);
                    if (AMS_UNLIKELY(current != e)) {
                        impl::ClearExclusiveForAtomic();
                        expected = ConvertToType(current);
                        return false;
                    }
                    return AMS_LIKELY(impl::StoreReleaseExclusiveForAtomic(p, d));
                } else if constexpr (Order == std::memory_order_acq_rel || Order == std::memory_order_seq_cst) {
                    const StorageType current = impl::LoadAcquireExclusiveForAtomic(p);
                    if (AMS_UNLIKELY(current != e)) {
                        impl::ClearExclusiveForAtomic();
                        expected = ConvertToType(current);
                        return false;
                    }
                    return AMS_LIKELY(impl::StoreReleaseExclusiveForAtomic(p, d));
                } else {
                    static_assert(Order != Order, "Invalid memory order");
                }
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE bool CompareExchangeStrong(T &expected, T desired) {
-                volatile StorageType * const p = this->GetStoragePointer();
+                return impl::AtomicCompareExchangeStrongImpl<Order, T>(this->GetStoragePointer(), expected, desired);
                const StorageType e = ConvertToStorage(expected);
                const StorageType d = ConvertToStorage(desired);
                if constexpr (Order == std::memory_order_relaxed) {
                    StorageType current;
                    do {
                        if (current = impl::LoadExclusiveForAtomic(p); current != e) {
                            impl::ClearExclusiveForAtomic();
                            expected = ConvertToType(current);
                            return false;
                        }
                    } while (!impl::StoreExclusiveForAtomic(p, d));
                } else if constexpr (Order == std::memory_order_consume || Order == std::memory_order_acquire) {
                    StorageType current;
                    do {
                        if (current = impl::LoadAcquireExclusiveForAtomic(p); current != e) {
                            impl::ClearExclusiveForAtomic();
                            expected = ConvertToType(current);
                            return false;
                        }
                    } while (!impl::StoreExclusiveForAtomic(p, d));
                } else if constexpr (Order == std::memory_order_release) {
                    StorageType current;
                    do {
                        if (current = impl::LoadExclusiveForAtomic(p); current != e) {
                            impl::ClearExclusiveForAtomic();
                            expected = ConvertToType(current);
                            return false;
                        }
                    } while (!impl::StoreReleaseExclusiveForAtomic(p, d));
                } else if constexpr (Order == std::memory_order_acq_rel || Order == std::memory_order_seq_cst) {
                    StorageType current;
                    do {
                        if (current = impl::LoadAcquireExclusiveForAtomic(p); current != e) {
                            impl::ClearExclusiveForAtomic();
                            expected = ConvertToType(current);
                            return false;
                        }
                    } while (!impl::StoreReleaseExclusiveForAtomic(p, d));
                } else {
                    static_assert(Order != Order, "Invalid memory order");
                }
                return true;
            }
            #define AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(_OPERATION_, _OPERATOR_, _POINTER_ALLOWED_)                                          \
@ -341,5 +323,108 @@ namespace ams::util {
            ALWAYS_INLINE T operator--(int) { static_assert(Enable == HasArithmeticFunctions); return this->FetchSub(1); }
    };
    template<impl::UsableAtomicType T>
    class AtomicRef {
        NON_MOVEABLE(AtomicRef);
        public:
            static constexpr size_t RequiredAlignment = std::max<size_t>(sizeof(T), alignof(T));
        private:
            using StorageType = impl::AtomicStorage<T>;
            static_assert(sizeof(StorageType)  == sizeof(T));
            static_assert(alignof(StorageType) >= alignof(T));
            static constexpr bool IsIntegral = std::integral<T>;
            static constexpr bool IsPointer  = std::is_pointer<T>::value;
            static constexpr bool HasArithmeticFunctions = IsIntegral || IsPointer;
            using DifferenceType = typename std::conditional<IsIntegral, T, typename std::conditional<IsPointer, std::ptrdiff_t, void>::type>::type;
            static constexpr ALWAYS_INLINE T ConvertToType(StorageType s) {
                return impl::ConvertToTypeForAtomic<T>(s);
            }
            static constexpr ALWAYS_INLINE StorageType ConvertToStorage(T arg) {
                return impl::ConvertToStorageForAtomic<T>(arg);
            }
        private:
            volatile StorageType * const m_p;
        private:
            ALWAYS_INLINE volatile StorageType *GetStoragePointer() const { return m_p; }
        public:
            explicit ALWAYS_INLINE AtomicRef(T &t) : m_p(reinterpret_cast<volatile StorageType *>(std::addressof(t))) { /* ... */ }
            ALWAYS_INLINE AtomicRef(const AtomicRef &) noexcept = default;
            AtomicRef() = delete;
            AtomicRef &operator=(const AtomicRef &) = delete;
            ALWAYS_INLINE T operator=(T desired) const { return const_cast<AtomicRef *>(this)->Store(desired); }
            ALWAYS_INLINE operator T() const { return this->Load(); }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE T Load() const {
                return ConvertToType(impl::AtomicLoadImpl<Order>(this->GetStoragePointer()));
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE void Store(T arg) const {
                return impl::AtomicStoreImpl<Order>(this->GetStoragePointer(), ConvertToStorage(arg));
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE T Exchange(T arg) const {
                return ConvertToType(impl::AtomicExchangeImpl(this->GetStoragePointer(), ConvertToStorage(arg)));
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE bool CompareExchangeWeak(T &expected, T desired) const {
                return impl::AtomicCompareExchangeWeakImpl<Order, T>(this->GetStoragePointer(), expected, desired);
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE bool CompareExchangeStrong(T &expected, T desired) const {
                return impl::AtomicCompareExchangeStrongImpl<Order, T>(this->GetStoragePointer(), expected, desired);
            }
            #define AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(_OPERATION_, _OPERATOR_, _POINTER_ALLOWED_)                                          \
                template<bool Enable = (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)), typename = typename std::enable_if<Enable, void>::type>            \
                ALWAYS_INLINE T Fetch ## _OPERATION_(DifferenceType arg) const {                                                                            \
                    static_assert(Enable == (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)));                                                              \
                    volatile StorageType * const p = this->GetStoragePointer();                                                                             \
                                                                                                                                                            \
                    StorageType current;                                                                                                                    \
                    do {                                                                                                                                    \
                        current = impl::LoadAcquireExclusiveForAtomic<StorageType>(p);                                                                      \
                    } while (AMS_UNLIKELY(!impl::StoreReleaseExclusiveForAtomic<StorageType>(p, ConvertToStorage(ConvertToType(current) _OPERATOR_ arg)))); \
                    return ConvertToType(current);                                                                                                          \
                }                                                                                                                                           \
                                                                                                                                                            \
                template<bool Enable = (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)), typename = typename std::enable_if<Enable, void>::type>            \
                ALWAYS_INLINE T operator _OPERATOR_##=(DifferenceType arg) const {                                                                          \
                    static_assert(Enable == (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)));                                                              \
                    return this->Fetch ## _OPERATION_(arg) _OPERATOR_ arg;                                                                                  \
                }
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(Add, +, true)
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(Sub, -, true)
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(And, &, false)
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(Or,  |, false)
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(Xor, ^, false)
            #undef AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION
            template<bool Enable = HasArithmeticFunctions, typename = typename std::enable_if<Enable, void>::type>
            ALWAYS_INLINE T operator++() const { static_assert(Enable == HasArithmeticFunctions); return this->FetchAdd(1) + 1; }
            template<bool Enable = HasArithmeticFunctions, typename = typename std::enable_if<Enable, void>::type>
            ALWAYS_INLINE T operator++(int) const { static_assert(Enable == HasArithmeticFunctions); return this->FetchAdd(1); }
            template<bool Enable = HasArithmeticFunctions, typename = typename std::enable_if<Enable, void>::type>
            ALWAYS_INLINE T operator--() const { static_assert(Enable == HasArithmeticFunctions); return this->FetchSub(1) - 1; }
            template<bool Enable = HasArithmeticFunctions, typename = typename std::enable_if<Enable, void>::type>
            ALWAYS_INLINE T operator--(int) const { static_assert(Enable == HasArithmeticFunctions); return this->FetchSub(1); }
    };
 }
--- a/libraries/libvapours/include/vapours/util/arch/generic/util_atomic.hpp
+++ b/libraries/libvapours/include/vapours/util/arch/generic/util_atomic.hpp
@ -74,6 +74,8 @@ namespace ams::util {
                return (m_v = desired);
            }
            ALWAYS_INLINE operator T() const { return this->Load(); }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE T Load() const {
                return m_v.load(Order);
@ -84,22 +86,21 @@ namespace ams::util {
                return m_v.store(Order);
            }
-            template<std::memory_order Order>
+            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE T Exchange(T arg) {
                return m_v.exchange(arg, Order);
            }
-            template<std::memory_order Order>
+            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE bool CompareExchangeWeak(T &expected, T desired) {
                return m_v.compare_exchange_weak(expected, desired, Order);
            }
-            template<std::memory_order Order>
+            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE bool CompareExchangeStrong(T &expected, T desired) {
                return m_v.compare_exchange_strong(expected, desired, Order);
            }
            #define AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(_OPERATION_, _OPERATION_LOWER_, _OPERATOR_, _POINTER_ALLOWED_)            \
                template<bool Enable = (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)), typename = typename std::enable_if<Enable, void>::type> \
                ALWAYS_INLINE T Fetch ## _OPERATION_(DifferenceType arg) {                                                                       \
@ -134,5 +135,89 @@ namespace ams::util {
            ALWAYS_INLINE T operator--(int) { static_assert(Enable == HasArithmeticFunctions); return this->FetchSub(1); }
    };
    template<impl::UsableAtomicType T>
    class AtomicRef {
        NON_MOVEABLE(AtomicRef);
        public:
            static constexpr size_t RequiredAlignment = std::atomic_ref<T>::required_alignment;
        private:
            static constexpr bool IsIntegral = std::integral<T>;
            static constexpr bool IsPointer  = std::is_pointer<T>::value;
            static constexpr bool HasArithmeticFunctions = IsIntegral || IsPointer;
            using DifferenceType = typename std::conditional<IsIntegral, T, typename std::conditional<IsPointer, std::ptrdiff_t, void>::type>::type;
        private:
            static_assert(std::atomic_ref<T>::is_always_lock_free);
        private:
            std::atomic_ref<T> m_ref;
        public:
            explicit ALWAYS_INLINE AtomicRef(T &t) : m_ref(t) { /* ... */ }
            ALWAYS_INLINE AtomicRef(const AtomicRef &) noexcept = default;
            AtomicRef() = delete;
            AtomicRef &operator=(const AtomicRef &) = delete;
            ALWAYS_INLINE T operator=(T desired) const { return (m_ref = desired); }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE T Load() const {
                return m_ref.load(Order);
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE void Store(T arg) const {
                return m_ref.store(arg, Order);
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE T Exchange(T arg) const {
                return m_ref.exchange(arg, Order);
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE bool CompareExchangeWeak(T &expected, T desired) const {
                return m_ref.compare_exchange_weak(expected, desired, Order);
            }
            template<std::memory_order Order = std::memory_order_seq_cst>
            ALWAYS_INLINE bool CompareExchangeStrong(T &expected, T desired) const {
                return m_ref.compare_exchange_strong(expected, desired, Order);
            }
            #define AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(_OPERATION_, _OPERATION_LOWER_, _OPERATOR_, _POINTER_ALLOWED_)            \
                template<bool Enable = (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)), typename = typename std::enable_if<Enable, void>::type> \
                ALWAYS_INLINE T Fetch ## _OPERATION_(DifferenceType arg) const {                                                                 \
                    static_assert(Enable == (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)));                                                   \
                    return m_ref.fetch_##_OPERATION_LOWER_(arg);                                                                                 \
                }                                                                                                                                \
                                                                                                                                                 \
                template<bool Enable = (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)), typename = typename std::enable_if<Enable, void>::type> \
                ALWAYS_INLINE T operator _OPERATOR_##=(DifferenceType arg) const {                                                               \
                    static_assert(Enable == (IsIntegral || (_POINTER_ALLOWED_ && IsPointer)));                                                   \
                    return this->Fetch##_OPERATION_(arg) _OPERATOR_ arg;                                                                         \
                }
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(Add, add, +, true)
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(Sub, sub, -, true)
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(And, and, &, false)
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(Or,  or,  |, false)
            AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION(Xor, xor, ^, false)
            #undef AMS_UTIL_IMPL_DEFINE_ATOMIC_FETCH_OPERATE_FUNCTION
            template<bool Enable = HasArithmeticFunctions, typename = typename std::enable_if<Enable, void>::type>
            ALWAYS_INLINE T operator++() const { static_assert(Enable == HasArithmeticFunctions); return this->FetchAdd(1) + 1; }
            template<bool Enable = HasArithmeticFunctions, typename = typename std::enable_if<Enable, void>::type>
            ALWAYS_INLINE T operator++(int) const { static_assert(Enable == HasArithmeticFunctions); return this->FetchAdd(1); }
            template<bool Enable = HasArithmeticFunctions, typename = typename std::enable_if<Enable, void>::type>
            ALWAYS_INLINE T operator--() const { static_assert(Enable == HasArithmeticFunctions); return this->FetchSub(1) - 1; }
            template<bool Enable = HasArithmeticFunctions, typename = typename std::enable_if<Enable, void>::type>
            ALWAYS_INLINE T operator--(int) const { static_assert(Enable == HasArithmeticFunctions); return this->FetchSub(1); }
    };
 }