Merge pull request #8013 from bunnei/kernel-slab-rework-v2

Kernel Memory Updates (Part 6): Use guest memory for slab heaps & update TLS.
2022-03-16 12:15:33 +01:00 · 2022-03-16 12:15:33 +01:00 · 2db5076ec9
commit 2db5076ec9
parent c3c351e2c2 e95bb782f0
32 changed files with 1383 additions and 961 deletions
--- a/src/common/intrusive_red_black_tree.h
+++ b/src/common/intrusive_red_black_tree.h
@ -4,6 +4,8 @@
 #pragma once
 #include "common/alignment.h"
 #include "common/common_funcs.h"
 #include "common/parent_of_member.h"
 #include "common/tree.h"
@ -15,32 +17,33 @@ class IntrusiveRedBlackTreeImpl;
 }
 #pragma pack(push, 4)
 struct IntrusiveRedBlackTreeNode {
    YUZU_NON_COPYABLE(IntrusiveRedBlackTreeNode);
 public:
-    using EntryType = RBEntry<IntrusiveRedBlackTreeNode>;
+    using RBEntry = freebsd::RBEntry<IntrusiveRedBlackTreeNode>;
    constexpr IntrusiveRedBlackTreeNode() = default;
    void SetEntry(const EntryType& new_entry) {
        entry = new_entry;
    }
    [[nodiscard]] EntryType& GetEntry() {
        return entry;
    }
    [[nodiscard]] const EntryType& GetEntry() const {
        return entry;
    }
 private:
-    EntryType entry{};
+    RBEntry m_entry;
-    friend class impl::IntrusiveRedBlackTreeImpl;
+public:
    explicit IntrusiveRedBlackTreeNode() = default;
-    template <class, class, class>
+    [[nodiscard]] constexpr RBEntry& GetRBEntry() {
-    friend class IntrusiveRedBlackTree;
+        return m_entry;
    }
    [[nodiscard]] constexpr const RBEntry& GetRBEntry() const {
        return m_entry;
    }
    constexpr void SetRBEntry(const RBEntry& entry) {
        m_entry = entry;
    }
 };
 static_assert(sizeof(IntrusiveRedBlackTreeNode) ==
              3 * sizeof(void*) + std::max<size_t>(sizeof(freebsd::RBColor), 4));
 #pragma pack(pop)
 template <class T, class Traits, class Comparator>
 class IntrusiveRedBlackTree;
@ -48,12 +51,17 @@ class IntrusiveRedBlackTree;
 namespace impl {
 class IntrusiveRedBlackTreeImpl {
    YUZU_NON_COPYABLE(IntrusiveRedBlackTreeImpl);
 private:
    template <class, class, class>
    friend class ::Common::IntrusiveRedBlackTree;
-    using RootType = RBHead<IntrusiveRedBlackTreeNode>;
+private:
-    RootType root;
+    using RootType = freebsd::RBHead<IntrusiveRedBlackTreeNode>;
 private:
    RootType m_root;
 public:
    template <bool Const>
@ -81,149 +89,150 @@ public:
                                             IntrusiveRedBlackTreeImpl::reference>;
    private:
-        pointer node;
+        pointer m_node;
    public:
-        explicit Iterator(pointer n) : node(n) {}
+        constexpr explicit Iterator(pointer n) : m_node(n) {}
-        bool operator==(const Iterator& rhs) const {
+        constexpr bool operator==(const Iterator& rhs) const {
-            return this->node == rhs.node;
+            return m_node == rhs.m_node;
        }
-        bool operator!=(const Iterator& rhs) const {
+        constexpr bool operator!=(const Iterator& rhs) const {
            return !(*this == rhs);
        }
-        pointer operator->() const {
+        constexpr pointer operator->() const {
-            return this->node;
+            return m_node;
        }
-        reference operator*() const {
+        constexpr reference operator*() const {
-            return *this->node;
+            return *m_node;
        }
-        Iterator& operator++() {
+        constexpr Iterator& operator++() {
-            this->node = GetNext(this->node);
+            m_node = GetNext(m_node);
            return *this;
        }
-        Iterator& operator--() {
+        constexpr Iterator& operator--() {
-            this->node = GetPrev(this->node);
+            m_node = GetPrev(m_node);
            return *this;
        }
-        Iterator operator++(int) {
+        constexpr Iterator operator++(int) {
            const Iterator it{*this};
            ++(*this);
            return it;
        }
-        Iterator operator--(int) {
+        constexpr Iterator operator--(int) {
            const Iterator it{*this};
            --(*this);
            return it;
        }
-        operator Iterator<true>() const {
+        constexpr operator Iterator<true>() const {
-            return Iterator<true>(this->node);
+            return Iterator<true>(m_node);
        }
    };
 private:
-    // Define accessors using RB_* functions.
+    constexpr bool EmptyImpl() const {
-    bool EmptyImpl() const {
+        return m_root.IsEmpty();
        return root.IsEmpty();
    }
-    IntrusiveRedBlackTreeNode* GetMinImpl() const {
+    constexpr IntrusiveRedBlackTreeNode* GetMinImpl() const {
-        return RB_MIN(const_cast<RootType*>(&root));
+        return freebsd::RB_MIN(const_cast<RootType&>(m_root));
    }
-    IntrusiveRedBlackTreeNode* GetMaxImpl() const {
+    constexpr IntrusiveRedBlackTreeNode* GetMaxImpl() const {
-        return RB_MAX(const_cast<RootType*>(&root));
+        return freebsd::RB_MAX(const_cast<RootType&>(m_root));
    }
-    IntrusiveRedBlackTreeNode* RemoveImpl(IntrusiveRedBlackTreeNode* node) {
+    constexpr IntrusiveRedBlackTreeNode* RemoveImpl(IntrusiveRedBlackTreeNode* node) {
-        return RB_REMOVE(&root, node);
+        return freebsd::RB_REMOVE(m_root, node);
    }
 public:
-    static IntrusiveRedBlackTreeNode* GetNext(IntrusiveRedBlackTreeNode* node) {
+    static constexpr IntrusiveRedBlackTreeNode* GetNext(IntrusiveRedBlackTreeNode* node) {
-        return RB_NEXT(node);
+        return freebsd::RB_NEXT(node);
    }
-    static IntrusiveRedBlackTreeNode* GetPrev(IntrusiveRedBlackTreeNode* node) {
+    static constexpr IntrusiveRedBlackTreeNode* GetPrev(IntrusiveRedBlackTreeNode* node) {
-        return RB_PREV(node);
+        return freebsd::RB_PREV(node);
    }
-    static const IntrusiveRedBlackTreeNode* GetNext(const IntrusiveRedBlackTreeNode* node) {
+    static constexpr IntrusiveRedBlackTreeNode const* GetNext(
        IntrusiveRedBlackTreeNode const* node) {
        return static_cast<const IntrusiveRedBlackTreeNode*>(
            GetNext(const_cast<IntrusiveRedBlackTreeNode*>(node)));
    }
-    static const IntrusiveRedBlackTreeNode* GetPrev(const IntrusiveRedBlackTreeNode* node) {
+    static constexpr IntrusiveRedBlackTreeNode const* GetPrev(
        IntrusiveRedBlackTreeNode const* node) {
        return static_cast<const IntrusiveRedBlackTreeNode*>(
            GetPrev(const_cast<IntrusiveRedBlackTreeNode*>(node)));
    }
 public:
-    constexpr IntrusiveRedBlackTreeImpl() {}
+    constexpr IntrusiveRedBlackTreeImpl() = default;
    // Iterator accessors.
-    iterator begin() {
+    constexpr iterator begin() {
        return iterator(this->GetMinImpl());
    }
-    const_iterator begin() const {
+    constexpr const_iterator begin() const {
        return const_iterator(this->GetMinImpl());
    }
-    iterator end() {
+    constexpr iterator end() {
        return iterator(static_cast<IntrusiveRedBlackTreeNode*>(nullptr));
    }
-    const_iterator end() const {
+    constexpr const_iterator end() const {
        return const_iterator(static_cast<const IntrusiveRedBlackTreeNode*>(nullptr));
    }
-    const_iterator cbegin() const {
+    constexpr const_iterator cbegin() const {
        return this->begin();
    }
-    const_iterator cend() const {
+    constexpr const_iterator cend() const {
        return this->end();
    }
-    iterator iterator_to(reference ref) {
+    constexpr iterator iterator_to(reference ref) {
-        return iterator(&ref);
+        return iterator(std::addressof(ref));
    }
-    const_iterator iterator_to(const_reference ref) const {
+    constexpr const_iterator iterator_to(const_reference ref) const {
-        return const_iterator(&ref);
+        return const_iterator(std::addressof(ref));
    }
    // Content management.
-    bool empty() const {
+    constexpr bool empty() const {
        return this->EmptyImpl();
    }
-    reference back() {
+    constexpr reference back() {
        return *this->GetMaxImpl();
    }
-    const_reference back() const {
+    constexpr const_reference back() const {
        return *this->GetMaxImpl();
    }
-    reference front() {
+    constexpr reference front() {
        return *this->GetMinImpl();
    }
-    const_reference front() const {
+    constexpr const_reference front() const {
        return *this->GetMinImpl();
    }
-    iterator erase(iterator it) {
+    constexpr iterator erase(iterator it) {
        auto cur = std::addressof(*it);
        auto next = GetNext(cur);
        this->RemoveImpl(cur);
@ -234,16 +243,16 @@ public:
 } // namespace impl
 template <typename T>
-concept HasLightCompareType = requires {
+concept HasRedBlackKeyType = requires {
-    { std::is_same<typename T::LightCompareType, void>::value } -> std::convertible_to<bool>;
+    { std::is_same<typename T::RedBlackKeyType, void>::value } -> std::convertible_to<bool>;
 };
 namespace impl {
    template <typename T, typename Default>
-    consteval auto* GetLightCompareType() {
+    consteval auto* GetRedBlackKeyType() {
-        if constexpr (HasLightCompareType<T>) {
+        if constexpr (HasRedBlackKeyType<T>) {
-            return static_cast<typename T::LightCompareType*>(nullptr);
+            return static_cast<typename T::RedBlackKeyType*>(nullptr);
        } else {
            return static_cast<Default*>(nullptr);
        }
@ -252,16 +261,17 @@ namespace impl {
 } // namespace impl
 template <typename T, typename Default>
-using LightCompareType = std::remove_pointer_t<decltype(impl::GetLightCompareType<T, Default>())>;
+using RedBlackKeyType = std::remove_pointer_t<decltype(impl::GetRedBlackKeyType<T, Default>())>;
 template <class T, class Traits, class Comparator>
 class IntrusiveRedBlackTree {
    YUZU_NON_COPYABLE(IntrusiveRedBlackTree);
 public:
    using ImplType = impl::IntrusiveRedBlackTreeImpl;
 private:
-    ImplType impl{};
+    ImplType m_impl;
 public:
    template <bool Const>
@ -277,9 +287,9 @@ public:
    using iterator = Iterator<false>;
    using const_iterator = Iterator<true>;
-    using light_value_type = LightCompareType<Comparator, value_type>;
+    using key_type = RedBlackKeyType<Comparator, value_type>;
-    using const_light_pointer = const light_value_type*;
+    using const_key_pointer = const key_type*;
-    using const_light_reference = const light_value_type&;
+    using const_key_reference = const key_type&;
    template <bool Const>
    class Iterator {
@ -298,183 +308,201 @@ public:
                                             IntrusiveRedBlackTree::reference>;
    private:
-        ImplIterator iterator;
+        ImplIterator m_impl;
    private:
-        explicit Iterator(ImplIterator it) : iterator(it) {}
+        constexpr explicit Iterator(ImplIterator it) : m_impl(it) {}
-        explicit Iterator(typename std::conditional<Const, ImplType::const_iterator,
+        constexpr explicit Iterator(typename ImplIterator::pointer p) : m_impl(p) {}
                                                    ImplType::iterator>::type::pointer ptr)
            : iterator(ptr) {}
-        ImplIterator GetImplIterator() const {
+        constexpr ImplIterator GetImplIterator() const {
-            return this->iterator;
+            return m_impl;
        }
    public:
-        bool operator==(const Iterator& rhs) const {
+        constexpr bool operator==(const Iterator& rhs) const {
-            return this->iterator == rhs.iterator;
+            return m_impl == rhs.m_impl;
        }
-        bool operator!=(const Iterator& rhs) const {
+        constexpr bool operator!=(const Iterator& rhs) const {
            return !(*this == rhs);
        }
-        pointer operator->() const {
+        constexpr pointer operator->() const {
-            return Traits::GetParent(std::addressof(*this->iterator));
+            return Traits::GetParent(std::addressof(*m_impl));
        }
-        reference operator*() const {
+        constexpr reference operator*() const {
-            return *Traits::GetParent(std::addressof(*this->iterator));
+            return *Traits::GetParent(std::addressof(*m_impl));
        }
-        Iterator& operator++() {
+        constexpr Iterator& operator++() {
-            ++this->iterator;
+            ++m_impl;
            return *this;
        }
-        Iterator& operator--() {
+        constexpr Iterator& operator--() {
-            --this->iterator;
+            --m_impl;
            return *this;
        }
-        Iterator operator++(int) {
+        constexpr Iterator operator++(int) {
            const Iterator it{*this};
-            ++this->iterator;
+            ++m_impl;
            return it;
        }
-        Iterator operator--(int) {
+        constexpr Iterator operator--(int) {
            const Iterator it{*this};
-            --this->iterator;
+            --m_impl;
            return it;
        }
-        operator Iterator<true>() const {
+        constexpr operator Iterator<true>() const {
-            return Iterator<true>(this->iterator);
+            return Iterator<true>(m_impl);
        }
    };
 private:
-    static int CompareImpl(const IntrusiveRedBlackTreeNode* lhs,
+    static constexpr int CompareImpl(const IntrusiveRedBlackTreeNode* lhs,
-                           const IntrusiveRedBlackTreeNode* rhs) {
+                                     const IntrusiveRedBlackTreeNode* rhs) {
        return Comparator::Compare(*Traits::GetParent(lhs), *Traits::GetParent(rhs));
    }
-    static int LightCompareImpl(const void* elm, const IntrusiveRedBlackTreeNode* rhs) {
+    static constexpr int CompareKeyImpl(const_key_reference key,
-        return Comparator::Compare(*static_cast<const_light_pointer>(elm), *Traits::GetParent(rhs));
+                                        const IntrusiveRedBlackTreeNode* rhs) {
        return Comparator::Compare(key, *Traits::GetParent(rhs));
    }
    // Define accessors using RB_* functions.
-    IntrusiveRedBlackTreeNode* InsertImpl(IntrusiveRedBlackTreeNode* node) {
+    constexpr IntrusiveRedBlackTreeNode* InsertImpl(IntrusiveRedBlackTreeNode* node) {
-        return RB_INSERT(&impl.root, node, CompareImpl);
+        return freebsd::RB_INSERT(m_impl.m_root, node, CompareImpl);
    }
-    IntrusiveRedBlackTreeNode* FindImpl(const IntrusiveRedBlackTreeNode* node) const {
+    constexpr IntrusiveRedBlackTreeNode* FindImpl(IntrusiveRedBlackTreeNode const* node) const {
-        return RB_FIND(const_cast<ImplType::RootType*>(&impl.root),
+        return freebsd::RB_FIND(const_cast<ImplType::RootType&>(m_impl.m_root),
-                       const_cast<IntrusiveRedBlackTreeNode*>(node), CompareImpl);
+                                const_cast<IntrusiveRedBlackTreeNode*>(node), CompareImpl);
    }
-    IntrusiveRedBlackTreeNode* NFindImpl(const IntrusiveRedBlackTreeNode* node) const {
+    constexpr IntrusiveRedBlackTreeNode* NFindImpl(IntrusiveRedBlackTreeNode const* node) const {
-        return RB_NFIND(const_cast<ImplType::RootType*>(&impl.root),
+        return freebsd::RB_NFIND(const_cast<ImplType::RootType&>(m_impl.m_root),
-                        const_cast<IntrusiveRedBlackTreeNode*>(node), CompareImpl);
+                                 const_cast<IntrusiveRedBlackTreeNode*>(node), CompareImpl);
    }
-    IntrusiveRedBlackTreeNode* FindLightImpl(const_light_pointer lelm) const {
+    constexpr IntrusiveRedBlackTreeNode* FindKeyImpl(const_key_reference key) const {
-        return RB_FIND_LIGHT(const_cast<ImplType::RootType*>(&impl.root),
+        return freebsd::RB_FIND_KEY(const_cast<ImplType::RootType&>(m_impl.m_root), key,
-                             static_cast<const void*>(lelm), LightCompareImpl);
+                                    CompareKeyImpl);
    }
-    IntrusiveRedBlackTreeNode* NFindLightImpl(const_light_pointer lelm) const {
+    constexpr IntrusiveRedBlackTreeNode* NFindKeyImpl(const_key_reference key) const {
-        return RB_NFIND_LIGHT(const_cast<ImplType::RootType*>(&impl.root),
+        return freebsd::RB_NFIND_KEY(const_cast<ImplType::RootType&>(m_impl.m_root), key,
-                              static_cast<const void*>(lelm), LightCompareImpl);
+                                     CompareKeyImpl);
    }
    constexpr IntrusiveRedBlackTreeNode* FindExistingImpl(
        IntrusiveRedBlackTreeNode const* node) const {
        return freebsd::RB_FIND_EXISTING(const_cast<ImplType::RootType&>(m_impl.m_root),
                                         const_cast<IntrusiveRedBlackTreeNode*>(node), CompareImpl);
    }
    constexpr IntrusiveRedBlackTreeNode* FindExistingKeyImpl(const_key_reference key) const {
        return freebsd::RB_FIND_EXISTING_KEY(const_cast<ImplType::RootType&>(m_impl.m_root), key,
                                             CompareKeyImpl);
    }
 public:
    constexpr IntrusiveRedBlackTree() = default;
    // Iterator accessors.
-    iterator begin() {
+    constexpr iterator begin() {
-        return iterator(this->impl.begin());
+        return iterator(m_impl.begin());
    }
-    const_iterator begin() const {
+    constexpr const_iterator begin() const {
-        return const_iterator(this->impl.begin());
+        return const_iterator(m_impl.begin());
    }
-    iterator end() {
+    constexpr iterator end() {
-        return iterator(this->impl.end());
+        return iterator(m_impl.end());
    }
-    const_iterator end() const {
+    constexpr const_iterator end() const {
-        return const_iterator(this->impl.end());
+        return const_iterator(m_impl.end());
    }
-    const_iterator cbegin() const {
+    constexpr const_iterator cbegin() const {
        return this->begin();
    }
-    const_iterator cend() const {
+    constexpr const_iterator cend() const {
        return this->end();
    }
-    iterator iterator_to(reference ref) {
+    constexpr iterator iterator_to(reference ref) {
-        return iterator(this->impl.iterator_to(*Traits::GetNode(std::addressof(ref))));
+        return iterator(m_impl.iterator_to(*Traits::GetNode(std::addressof(ref))));
    }
-    const_iterator iterator_to(const_reference ref) const {
+    constexpr const_iterator iterator_to(const_reference ref) const {
-        return const_iterator(this->impl.iterator_to(*Traits::GetNode(std::addressof(ref))));
+        return const_iterator(m_impl.iterator_to(*Traits::GetNode(std::addressof(ref))));
    }
    // Content management.
-    bool empty() const {
+    constexpr bool empty() const {
-        return this->impl.empty();
+        return m_impl.empty();
    }
-    reference back() {
+    constexpr reference back() {
-        return *Traits::GetParent(std::addressof(this->impl.back()));
+        return *Traits::GetParent(std::addressof(m_impl.back()));
    }
-    const_reference back() const {
+    constexpr const_reference back() const {
-        return *Traits::GetParent(std::addressof(this->impl.back()));
+        return *Traits::GetParent(std::addressof(m_impl.back()));
    }
-    reference front() {
+    constexpr reference front() {
-        return *Traits::GetParent(std::addressof(this->impl.front()));
+        return *Traits::GetParent(std::addressof(m_impl.front()));
    }
-    const_reference front() const {
+    constexpr const_reference front() const {
-        return *Traits::GetParent(std::addressof(this->impl.front()));
+        return *Traits::GetParent(std::addressof(m_impl.front()));
    }
-    iterator erase(iterator it) {
+    constexpr iterator erase(iterator it) {
-        return iterator(this->impl.erase(it.GetImplIterator()));
+        return iterator(m_impl.erase(it.GetImplIterator()));
    }
-    iterator insert(reference ref) {
+    constexpr iterator insert(reference ref) {
        ImplType::pointer node = Traits::GetNode(std::addressof(ref));
        this->InsertImpl(node);
        return iterator(node);
    }
-    iterator find(const_reference ref) const {
+    constexpr iterator find(const_reference ref) const {
        return iterator(this->FindImpl(Traits::GetNode(std::addressof(ref))));
    }
-    iterator nfind(const_reference ref) const {
+    constexpr iterator nfind(const_reference ref) const {
        return iterator(this->NFindImpl(Traits::GetNode(std::addressof(ref))));
    }
-    iterator find_light(const_light_reference ref) const {
+    constexpr iterator find_key(const_key_reference ref) const {
-        return iterator(this->FindLightImpl(std::addressof(ref)));
+        return iterator(this->FindKeyImpl(ref));
    }
-    iterator nfind_light(const_light_reference ref) const {
+    constexpr iterator nfind_key(const_key_reference ref) const {
-        return iterator(this->NFindLightImpl(std::addressof(ref)));
+        return iterator(this->NFindKeyImpl(ref));
    }
    constexpr iterator find_existing(const_reference ref) const {
        return iterator(this->FindExistingImpl(Traits::GetNode(std::addressof(ref))));
    }
    constexpr iterator find_existing_key(const_key_reference ref) const {
        return iterator(this->FindExistingKeyImpl(ref));
    }
 };
-template <auto T, class Derived = impl::GetParentType<T>>
+template <auto T, class Derived = Common::impl::GetParentType<T>>
 class IntrusiveRedBlackTreeMemberTraits;
 template <class Parent, IntrusiveRedBlackTreeNode Parent::*Member, class Derived>
@ -498,19 +526,16 @@ private:
        return std::addressof(parent->*Member);
    }
-    static constexpr Derived* GetParent(IntrusiveRedBlackTreeNode* node) {
+    static Derived* GetParent(IntrusiveRedBlackTreeNode* node) {
-        return GetParentPointer<Member, Derived>(node);
+        return Common::GetParentPointer<Member, Derived>(node);
    }
-    static constexpr Derived const* GetParent(const IntrusiveRedBlackTreeNode* node) {
+    static Derived const* GetParent(IntrusiveRedBlackTreeNode const* node) {
-        return GetParentPointer<Member, Derived>(node);
+        return Common::GetParentPointer<Member, Derived>(node);
    }
 private:
    static constexpr TypedStorage<Derived> DerivedStorage = {};
 };
-template <auto T, class Derived = impl::GetParentType<T>>
+template <auto T, class Derived = Common::impl::GetParentType<T>>
 class IntrusiveRedBlackTreeMemberTraitsDeferredAssert;
 template <class Parent, IntrusiveRedBlackTreeNode Parent::*Member, class Derived>
@ -521,11 +546,6 @@ public:
        IntrusiveRedBlackTree<Derived, IntrusiveRedBlackTreeMemberTraitsDeferredAssert, Comparator>;
    using TreeTypeImpl = impl::IntrusiveRedBlackTreeImpl;
    static constexpr bool IsValid() {
        TypedStorage<Derived> DerivedStorage = {};
        return GetParent(GetNode(GetPointer(DerivedStorage))) == GetPointer(DerivedStorage);
    }
 private:
    template <class, class, class>
    friend class IntrusiveRedBlackTree;
@ -540,30 +560,36 @@ private:
        return std::addressof(parent->*Member);
    }
-    static constexpr Derived* GetParent(IntrusiveRedBlackTreeNode* node) {
+    static Derived* GetParent(IntrusiveRedBlackTreeNode* node) {
-        return GetParentPointer<Member, Derived>(node);
+        return Common::GetParentPointer<Member, Derived>(node);
    }
-    static constexpr Derived const* GetParent(const IntrusiveRedBlackTreeNode* node) {
+    static Derived const* GetParent(IntrusiveRedBlackTreeNode const* node) {
-        return GetParentPointer<Member, Derived>(node);
+        return Common::GetParentPointer<Member, Derived>(node);
    }
 };
 template <class Derived>
-class IntrusiveRedBlackTreeBaseNode : public IntrusiveRedBlackTreeNode {
+class alignas(void*) IntrusiveRedBlackTreeBaseNode : public IntrusiveRedBlackTreeNode {
 public:
    using IntrusiveRedBlackTreeNode::IntrusiveRedBlackTreeNode;
    constexpr Derived* GetPrev() {
-        return static_cast<Derived*>(impl::IntrusiveRedBlackTreeImpl::GetPrev(this));
+        return static_cast<Derived*>(static_cast<IntrusiveRedBlackTreeBaseNode*>(
            impl::IntrusiveRedBlackTreeImpl::GetPrev(this)));
    }
    constexpr const Derived* GetPrev() const {
-        return static_cast<const Derived*>(impl::IntrusiveRedBlackTreeImpl::GetPrev(this));
+        return static_cast<const Derived*>(static_cast<const IntrusiveRedBlackTreeBaseNode*>(
            impl::IntrusiveRedBlackTreeImpl::GetPrev(this)));
    }
    constexpr Derived* GetNext() {
-        return static_cast<Derived*>(impl::IntrusiveRedBlackTreeImpl::GetNext(this));
+        return static_cast<Derived*>(static_cast<IntrusiveRedBlackTreeBaseNode*>(
            impl::IntrusiveRedBlackTreeImpl::GetNext(this)));
    }
    constexpr const Derived* GetNext() const {
-        return static_cast<const Derived*>(impl::IntrusiveRedBlackTreeImpl::GetNext(this));
+        return static_cast<const Derived*>(static_cast<const IntrusiveRedBlackTreeBaseNode*>(
            impl::IntrusiveRedBlackTreeImpl::GetNext(this)));
    }
 };
@ -581,19 +607,22 @@ private:
    friend class impl::IntrusiveRedBlackTreeImpl;
    static constexpr IntrusiveRedBlackTreeNode* GetNode(Derived* parent) {
-        return static_cast<IntrusiveRedBlackTreeNode*>(parent);
+        return static_cast<IntrusiveRedBlackTreeNode*>(
            static_cast<IntrusiveRedBlackTreeBaseNode<Derived>*>(parent));
    }
    static constexpr IntrusiveRedBlackTreeNode const* GetNode(Derived const* parent) {
-        return static_cast<const IntrusiveRedBlackTreeNode*>(parent);
+        return static_cast<const IntrusiveRedBlackTreeNode*>(
            static_cast<const IntrusiveRedBlackTreeBaseNode<Derived>*>(parent));
    }
    static constexpr Derived* GetParent(IntrusiveRedBlackTreeNode* node) {
-        return static_cast<Derived*>(node);
+        return static_cast<Derived*>(static_cast<IntrusiveRedBlackTreeBaseNode<Derived>*>(node));
    }
-    static constexpr Derived const* GetParent(const IntrusiveRedBlackTreeNode* node) {
+    static constexpr Derived const* GetParent(IntrusiveRedBlackTreeNode const* node) {
-        return static_cast<const Derived*>(node);
+        return static_cast<const Derived*>(
            static_cast<const IntrusiveRedBlackTreeBaseNode<Derived>*>(node));
    }
 };
--- a/src/common/tree.h
+++ b/src/common/tree.h
@ -43,246 +43,445 @@
 * The maximum height of a red-black tree is 2lg (n+1).
 */
-#include "common/assert.h"
+namespace Common::freebsd {
-namespace Common {
+enum class RBColor {
-template <typename T>
+    RB_BLACK = 0,
-class RBHead {
+    RB_RED = 1,
 public:
    [[nodiscard]] T* Root() {
        return rbh_root;
    }
    [[nodiscard]] const T* Root() const {
        return rbh_root;
    }
    void SetRoot(T* root) {
        rbh_root = root;
    }
    [[nodiscard]] bool IsEmpty() const {
        return Root() == nullptr;
    }
 private:
    T* rbh_root = nullptr;
 };
 enum class EntryColor {
    Black,
    Red,
 };
 #pragma pack(push, 4)
 template <typename T>
 class RBEntry {
 public:
-    [[nodiscard]] T* Left() {
+    constexpr RBEntry() = default;
-        return rbe_left;
+
    [[nodiscard]] constexpr T* Left() {
        return m_rbe_left;
    }
    [[nodiscard]] constexpr const T* Left() const {
        return m_rbe_left;
    }
-    [[nodiscard]] const T* Left() const {
+    constexpr void SetLeft(T* e) {
-        return rbe_left;
+        m_rbe_left = e;
    }
-    void SetLeft(T* left) {
+    [[nodiscard]] constexpr T* Right() {
-        rbe_left = left;
+        return m_rbe_right;
    }
    [[nodiscard]] constexpr const T* Right() const {
        return m_rbe_right;
    }
-    [[nodiscard]] T* Right() {
+    constexpr void SetRight(T* e) {
-        return rbe_right;
+        m_rbe_right = e;
    }
-    [[nodiscard]] const T* Right() const {
+    [[nodiscard]] constexpr T* Parent() {
-        return rbe_right;
+        return m_rbe_parent;
    }
    [[nodiscard]] constexpr const T* Parent() const {
        return m_rbe_parent;
    }
-    void SetRight(T* right) {
+    constexpr void SetParent(T* e) {
-        rbe_right = right;
+        m_rbe_parent = e;
    }
-    [[nodiscard]] T* Parent() {
+    [[nodiscard]] constexpr bool IsBlack() const {
-        return rbe_parent;
+        return m_rbe_color == RBColor::RB_BLACK;
    }
    [[nodiscard]] constexpr bool IsRed() const {
        return m_rbe_color == RBColor::RB_RED;
    }
    [[nodiscard]] constexpr RBColor Color() const {
        return m_rbe_color;
    }
-    [[nodiscard]] const T* Parent() const {
+    constexpr void SetColor(RBColor c) {
-        return rbe_parent;
+        m_rbe_color = c;
    }
    void SetParent(T* parent) {
        rbe_parent = parent;
    }
    [[nodiscard]] bool IsBlack() const {
        return rbe_color == EntryColor::Black;
    }
    [[nodiscard]] bool IsRed() const {
        return rbe_color == EntryColor::Red;
    }
    [[nodiscard]] EntryColor Color() const {
        return rbe_color;
    }
    void SetColor(EntryColor color) {
        rbe_color = color;
    }
 private:
-    T* rbe_left = nullptr;
+    T* m_rbe_left{};
-    T* rbe_right = nullptr;
+    T* m_rbe_right{};
-    T* rbe_parent = nullptr;
+    T* m_rbe_parent{};
-    EntryColor rbe_color{};
+    RBColor m_rbe_color{RBColor::RB_BLACK};
 };
 #pragma pack(pop)
 template <typename T>
 struct CheckRBEntry {
    static constexpr bool value = false;
 };
 template <typename T>
 struct CheckRBEntry<RBEntry<T>> {
    static constexpr bool value = true;
 };
-template <typename Node>
+template <typename T>
-[[nodiscard]] RBEntry<Node>& RB_ENTRY(Node* node) {
+concept IsRBEntry = CheckRBEntry<T>::value;
-    return node->GetEntry();
+
 template <typename T>
 concept HasRBEntry = requires(T& t, const T& ct) {
    { t.GetRBEntry() } -> std::same_as<RBEntry<T>&>;
    { ct.GetRBEntry() } -> std::same_as<const RBEntry<T>&>;
 };
 template <typename T>
 requires HasRBEntry<T>
 class RBHead {
 private:
    T* m_rbh_root = nullptr;
 public:
    [[nodiscard]] constexpr T* Root() {
        return m_rbh_root;
    }
    [[nodiscard]] constexpr const T* Root() const {
        return m_rbh_root;
    }
    constexpr void SetRoot(T* root) {
        m_rbh_root = root;
    }
    [[nodiscard]] constexpr bool IsEmpty() const {
        return this->Root() == nullptr;
    }
 };
 template <typename T>
 requires HasRBEntry<T>
 [[nodiscard]] constexpr RBEntry<T>& RB_ENTRY(T* t) {
    return t->GetRBEntry();
 }
 template <typename T>
 requires HasRBEntry<T>
 [[nodiscard]] constexpr const RBEntry<T>& RB_ENTRY(const T* t) {
    return t->GetRBEntry();
 }
-template <typename Node>
+template <typename T>
-[[nodiscard]] const RBEntry<Node>& RB_ENTRY(const Node* node) {
+requires HasRBEntry<T>
-    return node->GetEntry();
+[[nodiscard]] constexpr T* RB_LEFT(T* t) {
    return RB_ENTRY(t).Left();
 }
 template <typename T>
 requires HasRBEntry<T>
 [[nodiscard]] constexpr const T* RB_LEFT(const T* t) {
    return RB_ENTRY(t).Left();
 }
-template <typename Node>
+template <typename T>
-[[nodiscard]] Node* RB_PARENT(Node* node) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).Parent();
+[[nodiscard]] constexpr T* RB_RIGHT(T* t) {
    return RB_ENTRY(t).Right();
 }
 template <typename T>
 requires HasRBEntry<T>
 [[nodiscard]] constexpr const T* RB_RIGHT(const T* t) {
    return RB_ENTRY(t).Right();
 }
-template <typename Node>
+template <typename T>
-[[nodiscard]] const Node* RB_PARENT(const Node* node) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).Parent();
+[[nodiscard]] constexpr T* RB_PARENT(T* t) {
    return RB_ENTRY(t).Parent();
 }
 template <typename T>
 requires HasRBEntry<T>
 [[nodiscard]] constexpr const T* RB_PARENT(const T* t) {
    return RB_ENTRY(t).Parent();
 }
-template <typename Node>
+template <typename T>
-void RB_SET_PARENT(Node* node, Node* parent) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).SetParent(parent);
+constexpr void RB_SET_LEFT(T* t, T* e) {
    RB_ENTRY(t).SetLeft(e);
 }
 template <typename T>
 requires HasRBEntry<T>
 constexpr void RB_SET_RIGHT(T* t, T* e) {
    RB_ENTRY(t).SetRight(e);
 }
 template <typename T>
 requires HasRBEntry<T>
 constexpr void RB_SET_PARENT(T* t, T* e) {
    RB_ENTRY(t).SetParent(e);
 }
-template <typename Node>
+template <typename T>
-[[nodiscard]] Node* RB_LEFT(Node* node) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).Left();
+[[nodiscard]] constexpr bool RB_IS_BLACK(const T* t) {
    return RB_ENTRY(t).IsBlack();
 }
 template <typename T>
 requires HasRBEntry<T>
 [[nodiscard]] constexpr bool RB_IS_RED(const T* t) {
    return RB_ENTRY(t).IsRed();
 }
-template <typename Node>
+template <typename T>
-[[nodiscard]] const Node* RB_LEFT(const Node* node) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).Left();
+[[nodiscard]] constexpr RBColor RB_COLOR(const T* t) {
    return RB_ENTRY(t).Color();
 }
-template <typename Node>
+template <typename T>
-void RB_SET_LEFT(Node* node, Node* left) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).SetLeft(left);
+constexpr void RB_SET_COLOR(T* t, RBColor c) {
    RB_ENTRY(t).SetColor(c);
 }
-template <typename Node>
+template <typename T>
-[[nodiscard]] Node* RB_RIGHT(Node* node) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).Right();
+constexpr void RB_SET(T* elm, T* parent) {
    auto& rb_entry = RB_ENTRY(elm);
    rb_entry.SetParent(parent);
    rb_entry.SetLeft(nullptr);
    rb_entry.SetRight(nullptr);
    rb_entry.SetColor(RBColor::RB_RED);
 }
-template <typename Node>
+template <typename T>
-[[nodiscard]] const Node* RB_RIGHT(const Node* node) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).Right();
+constexpr void RB_SET_BLACKRED(T* black, T* red) {
    RB_SET_COLOR(black, RBColor::RB_BLACK);
    RB_SET_COLOR(red, RBColor::RB_RED);
 }
-template <typename Node>
+template <typename T>
-void RB_SET_RIGHT(Node* node, Node* right) {
+requires HasRBEntry<T>
-    return RB_ENTRY(node).SetRight(right);
+constexpr void RB_ROTATE_LEFT(RBHead<T>& head, T* elm, T*& tmp) {
 }
 template <typename Node>
 [[nodiscard]] bool RB_IS_BLACK(const Node* node) {
    return RB_ENTRY(node).IsBlack();
 }
 template <typename Node>
 [[nodiscard]] bool RB_IS_RED(const Node* node) {
    return RB_ENTRY(node).IsRed();
 }
 template <typename Node>
 [[nodiscard]] EntryColor RB_COLOR(const Node* node) {
    return RB_ENTRY(node).Color();
 }
 template <typename Node>
 void RB_SET_COLOR(Node* node, EntryColor color) {
    return RB_ENTRY(node).SetColor(color);
 }
 template <typename Node>
 void RB_SET(Node* node, Node* parent) {
    auto& entry = RB_ENTRY(node);
    entry.SetParent(parent);
    entry.SetLeft(nullptr);
    entry.SetRight(nullptr);
    entry.SetColor(EntryColor::Red);
 }
 template <typename Node>
 void RB_SET_BLACKRED(Node* black, Node* red) {
    RB_SET_COLOR(black, EntryColor::Black);
    RB_SET_COLOR(red, EntryColor::Red);
 }
 template <typename Node>
 void RB_ROTATE_LEFT(RBHead<Node>* head, Node* elm, Node*& tmp) {
    tmp = RB_RIGHT(elm);
-    RB_SET_RIGHT(elm, RB_LEFT(tmp));
+    if (RB_SET_RIGHT(elm, RB_LEFT(tmp)); RB_RIGHT(elm) != nullptr) {
    if (RB_RIGHT(elm) != nullptr) {
        RB_SET_PARENT(RB_LEFT(tmp), elm);
    }
-    RB_SET_PARENT(tmp, RB_PARENT(elm));
+    if (RB_SET_PARENT(tmp, RB_PARENT(elm)); RB_PARENT(tmp) != nullptr) {
    if (RB_PARENT(tmp) != nullptr) {
        if (elm == RB_LEFT(RB_PARENT(elm))) {
            RB_SET_LEFT(RB_PARENT(elm), tmp);
        } else {
            RB_SET_RIGHT(RB_PARENT(elm), tmp);
        }
    } else {
-        head->SetRoot(tmp);
+        head.SetRoot(tmp);
    }
    RB_SET_LEFT(tmp, elm);
    RB_SET_PARENT(elm, tmp);
 }
-template <typename Node>
+template <typename T>
-void RB_ROTATE_RIGHT(RBHead<Node>* head, Node* elm, Node*& tmp) {
+requires HasRBEntry<T>
 constexpr void RB_ROTATE_RIGHT(RBHead<T>& head, T* elm, T*& tmp) {
    tmp = RB_LEFT(elm);
-    RB_SET_LEFT(elm, RB_RIGHT(tmp));
+    if (RB_SET_LEFT(elm, RB_RIGHT(tmp)); RB_LEFT(elm) != nullptr) {
    if (RB_LEFT(elm) != nullptr) {
        RB_SET_PARENT(RB_RIGHT(tmp), elm);
    }
-    RB_SET_PARENT(tmp, RB_PARENT(elm));
+    if (RB_SET_PARENT(tmp, RB_PARENT(elm)); RB_PARENT(tmp) != nullptr) {
    if (RB_PARENT(tmp) != nullptr) {
        if (elm == RB_LEFT(RB_PARENT(elm))) {
            RB_SET_LEFT(RB_PARENT(elm), tmp);
        } else {
            RB_SET_RIGHT(RB_PARENT(elm), tmp);
        }
    } else {
-        head->SetRoot(tmp);
+        head.SetRoot(tmp);
    }
    RB_SET_RIGHT(tmp, elm);
    RB_SET_PARENT(elm, tmp);
 }
-template <typename Node>
+template <typename T>
-void RB_INSERT_COLOR(RBHead<Node>* head, Node* elm) {
+requires HasRBEntry<T>
-    Node* parent = nullptr;
+constexpr void RB_REMOVE_COLOR(RBHead<T>& head, T* parent, T* elm) {
-    Node* tmp = nullptr;
+    T* tmp;
    while ((elm == nullptr || RB_IS_BLACK(elm)) && elm != head.Root()) {
        if (RB_LEFT(parent) == elm) {
            tmp = RB_RIGHT(parent);
            if (RB_IS_RED(tmp)) {
                RB_SET_BLACKRED(tmp, parent);
                RB_ROTATE_LEFT(head, parent, tmp);
                tmp = RB_RIGHT(parent);
            }
            if ((RB_LEFT(tmp) == nullptr || RB_IS_BLACK(RB_LEFT(tmp))) &&
                (RB_RIGHT(tmp) == nullptr || RB_IS_BLACK(RB_RIGHT(tmp)))) {
                RB_SET_COLOR(tmp, RBColor::RB_RED);
                elm = parent;
                parent = RB_PARENT(elm);
            } else {
                if (RB_RIGHT(tmp) == nullptr || RB_IS_BLACK(RB_RIGHT(tmp))) {
                    T* oleft;
                    if ((oleft = RB_LEFT(tmp)) != nullptr) {
                        RB_SET_COLOR(oleft, RBColor::RB_BLACK);
                    }
                    RB_SET_COLOR(tmp, RBColor::RB_RED);
                    RB_ROTATE_RIGHT(head, tmp, oleft);
                    tmp = RB_RIGHT(parent);
                }
                RB_SET_COLOR(tmp, RB_COLOR(parent));
                RB_SET_COLOR(parent, RBColor::RB_BLACK);
                if (RB_RIGHT(tmp)) {
                    RB_SET_COLOR(RB_RIGHT(tmp), RBColor::RB_BLACK);
                }
                RB_ROTATE_LEFT(head, parent, tmp);
                elm = head.Root();
                break;
            }
        } else {
            tmp = RB_LEFT(parent);
            if (RB_IS_RED(tmp)) {
                RB_SET_BLACKRED(tmp, parent);
                RB_ROTATE_RIGHT(head, parent, tmp);
                tmp = RB_LEFT(parent);
            }
            if ((RB_LEFT(tmp) == nullptr || RB_IS_BLACK(RB_LEFT(tmp))) &&
                (RB_RIGHT(tmp) == nullptr || RB_IS_BLACK(RB_RIGHT(tmp)))) {
                RB_SET_COLOR(tmp, RBColor::RB_RED);
                elm = parent;
                parent = RB_PARENT(elm);
            } else {
                if (RB_LEFT(tmp) == nullptr || RB_IS_BLACK(RB_LEFT(tmp))) {
                    T* oright;
                    if ((oright = RB_RIGHT(tmp)) != nullptr) {
                        RB_SET_COLOR(oright, RBColor::RB_BLACK);
                    }
                    RB_SET_COLOR(tmp, RBColor::RB_RED);
                    RB_ROTATE_LEFT(head, tmp, oright);
                    tmp = RB_LEFT(parent);
                }
                RB_SET_COLOR(tmp, RB_COLOR(parent));
                RB_SET_COLOR(parent, RBColor::RB_BLACK);
                if (RB_LEFT(tmp)) {
                    RB_SET_COLOR(RB_LEFT(tmp), RBColor::RB_BLACK);
                }
                RB_ROTATE_RIGHT(head, parent, tmp);
                elm = head.Root();
                break;
            }
        }
    }
    if (elm) {
        RB_SET_COLOR(elm, RBColor::RB_BLACK);
    }
 }
 template <typename T>
 requires HasRBEntry<T>
 constexpr T* RB_REMOVE(RBHead<T>& head, T* elm) {
    T* child = nullptr;
    T* parent = nullptr;
    T* old = elm;
    RBColor color = RBColor::RB_BLACK;
    if (RB_LEFT(elm) == nullptr) {
        child = RB_RIGHT(elm);
    } else if (RB_RIGHT(elm) == nullptr) {
        child = RB_LEFT(elm);
    } else {
        T* left;
        elm = RB_RIGHT(elm);
        while ((left = RB_LEFT(elm)) != nullptr) {
            elm = left;
        }
        child = RB_RIGHT(elm);
        parent = RB_PARENT(elm);
        color = RB_COLOR(elm);
        if (child) {
            RB_SET_PARENT(child, parent);
        }
        if (parent) {
            if (RB_LEFT(parent) == elm) {
                RB_SET_LEFT(parent, child);
            } else {
                RB_SET_RIGHT(parent, child);
            }
        } else {
            head.SetRoot(child);
        }
        if (RB_PARENT(elm) == old) {
            parent = elm;
        }
        elm->SetRBEntry(old->GetRBEntry());
        if (RB_PARENT(old)) {
            if (RB_LEFT(RB_PARENT(old)) == old) {
                RB_SET_LEFT(RB_PARENT(old), elm);
            } else {
                RB_SET_RIGHT(RB_PARENT(old), elm);
            }
        } else {
            head.SetRoot(elm);
        }
        RB_SET_PARENT(RB_LEFT(old), elm);
        if (RB_RIGHT(old)) {
            RB_SET_PARENT(RB_RIGHT(old), elm);
        }
        if (parent) {
            left = parent;
        }
        if (color == RBColor::RB_BLACK) {
            RB_REMOVE_COLOR(head, parent, child);
        }
        return old;
    }
    parent = RB_PARENT(elm);
    color = RB_COLOR(elm);
    if (child) {
        RB_SET_PARENT(child, parent);
    }
    if (parent) {
        if (RB_LEFT(parent) == elm) {
            RB_SET_LEFT(parent, child);
        } else {
            RB_SET_RIGHT(parent, child);
        }
    } else {
        head.SetRoot(child);
    }
    if (color == RBColor::RB_BLACK) {
        RB_REMOVE_COLOR(head, parent, child);
    }
    return old;
 }
 template <typename T>
 requires HasRBEntry<T>
 constexpr void RB_INSERT_COLOR(RBHead<T>& head, T* elm) {
    T *parent = nullptr, *tmp = nullptr;
    while ((parent = RB_PARENT(elm)) != nullptr && RB_IS_RED(parent)) {
-        Node* gparent = RB_PARENT(parent);
+        T* gparent = RB_PARENT(parent);
        if (parent == RB_LEFT(gparent)) {
            tmp = RB_RIGHT(gparent);
            if (tmp && RB_IS_RED(tmp)) {
-                RB_SET_COLOR(tmp, EntryColor::Black);
+                RB_SET_COLOR(tmp, RBColor::RB_BLACK);
                RB_SET_BLACKRED(parent, gparent);
                elm = gparent;
                continue;
@ -300,7 +499,7 @@ void RB_INSERT_COLOR(RBHead<Node>* head, Node* elm) {
        } else {
            tmp = RB_LEFT(gparent);
            if (tmp && RB_IS_RED(tmp)) {
-                RB_SET_COLOR(tmp, EntryColor::Black);
+                RB_SET_COLOR(tmp, RBColor::RB_BLACK);
                RB_SET_BLACKRED(parent, gparent);
                elm = gparent;
                continue;
@ -318,194 +517,14 @@ void RB_INSERT_COLOR(RBHead<Node>* head, Node* elm) {
        }
    }
-    RB_SET_COLOR(head->Root(), EntryColor::Black);
+    RB_SET_COLOR(head.Root(), RBColor::RB_BLACK);
 }
-template <typename Node>
+template <typename T, typename Compare>
-void RB_REMOVE_COLOR(RBHead<Node>* head, Node* parent, Node* elm) {
+requires HasRBEntry<T>
-    Node* tmp;
+constexpr T* RB_INSERT(RBHead<T>& head, T* elm, Compare cmp) {
-    while ((elm == nullptr || RB_IS_BLACK(elm)) && elm != head->Root() && parent != nullptr) {
+    T* parent = nullptr;
-        if (RB_LEFT(parent) == elm) {
+    T* tmp = head.Root();
            tmp = RB_RIGHT(parent);
            if (!tmp) {
                ASSERT_MSG(false, "tmp is invalid!");
                break;
            }
            if (RB_IS_RED(tmp)) {
                RB_SET_BLACKRED(tmp, parent);
                RB_ROTATE_LEFT(head, parent, tmp);
                tmp = RB_RIGHT(parent);
            }
            if ((RB_LEFT(tmp) == nullptr || RB_IS_BLACK(RB_LEFT(tmp))) &&
                (RB_RIGHT(tmp) == nullptr || RB_IS_BLACK(RB_RIGHT(tmp)))) {
                RB_SET_COLOR(tmp, EntryColor::Red);
                elm = parent;
                parent = RB_PARENT(elm);
            } else {
                if (RB_RIGHT(tmp) == nullptr || RB_IS_BLACK(RB_RIGHT(tmp))) {
                    Node* oleft;
                    if ((oleft = RB_LEFT(tmp)) != nullptr) {
                        RB_SET_COLOR(oleft, EntryColor::Black);
                    }
                    RB_SET_COLOR(tmp, EntryColor::Red);
                    RB_ROTATE_RIGHT(head, tmp, oleft);
                    tmp = RB_RIGHT(parent);
                }
                RB_SET_COLOR(tmp, RB_COLOR(parent));
                RB_SET_COLOR(parent, EntryColor::Black);
                if (RB_RIGHT(tmp)) {
                    RB_SET_COLOR(RB_RIGHT(tmp), EntryColor::Black);
                }
                RB_ROTATE_LEFT(head, parent, tmp);
                elm = head->Root();
                break;
            }
        } else {
            tmp = RB_LEFT(parent);
            if (RB_IS_RED(tmp)) {
                RB_SET_BLACKRED(tmp, parent);
                RB_ROTATE_RIGHT(head, parent, tmp);
                tmp = RB_LEFT(parent);
            }
            if (!tmp) {
                ASSERT_MSG(false, "tmp is invalid!");
                break;
            }
            if ((RB_LEFT(tmp) == nullptr || RB_IS_BLACK(RB_LEFT(tmp))) &&
                (RB_RIGHT(tmp) == nullptr || RB_IS_BLACK(RB_RIGHT(tmp)))) {
                RB_SET_COLOR(tmp, EntryColor::Red);
                elm = parent;
                parent = RB_PARENT(elm);
            } else {
                if (RB_LEFT(tmp) == nullptr || RB_IS_BLACK(RB_LEFT(tmp))) {
                    Node* oright;
                    if ((oright = RB_RIGHT(tmp)) != nullptr) {
                        RB_SET_COLOR(oright, EntryColor::Black);
                    }
                    RB_SET_COLOR(tmp, EntryColor::Red);
                    RB_ROTATE_LEFT(head, tmp, oright);
                    tmp = RB_LEFT(parent);
                }
                RB_SET_COLOR(tmp, RB_COLOR(parent));
                RB_SET_COLOR(parent, EntryColor::Black);
                if (RB_LEFT(tmp)) {
                    RB_SET_COLOR(RB_LEFT(tmp), EntryColor::Black);
                }
                RB_ROTATE_RIGHT(head, parent, tmp);
                elm = head->Root();
                break;
            }
        }
    }
    if (elm) {
        RB_SET_COLOR(elm, EntryColor::Black);
    }
 }
 template <typename Node>
 Node* RB_REMOVE(RBHead<Node>* head, Node* elm) {
    Node* child = nullptr;
    Node* parent = nullptr;
    Node* old = elm;
    EntryColor color{};
    const auto finalize = [&] {
        if (color == EntryColor::Black) {
            RB_REMOVE_COLOR(head, parent, child);
        }
        return old;
    };
    if (RB_LEFT(elm) == nullptr) {
        child = RB_RIGHT(elm);
    } else if (RB_RIGHT(elm) == nullptr) {
        child = RB_LEFT(elm);
    } else {
        Node* left;
        elm = RB_RIGHT(elm);
        while ((left = RB_LEFT(elm)) != nullptr) {
            elm = left;
        }
        child = RB_RIGHT(elm);
        parent = RB_PARENT(elm);
        color = RB_COLOR(elm);
        if (child) {
            RB_SET_PARENT(child, parent);
        }
        if (parent) {
            if (RB_LEFT(parent) == elm) {
                RB_SET_LEFT(parent, child);
            } else {
                RB_SET_RIGHT(parent, child);
            }
        } else {
            head->SetRoot(child);
        }
        if (RB_PARENT(elm) == old) {
            parent = elm;
        }
        elm->SetEntry(old->GetEntry());
        if (RB_PARENT(old)) {
            if (RB_LEFT(RB_PARENT(old)) == old) {
                RB_SET_LEFT(RB_PARENT(old), elm);
            } else {
                RB_SET_RIGHT(RB_PARENT(old), elm);
            }
        } else {
            head->SetRoot(elm);
        }
        RB_SET_PARENT(RB_LEFT(old), elm);
        if (RB_RIGHT(old)) {
            RB_SET_PARENT(RB_RIGHT(old), elm);
        }
        if (parent) {
            left = parent;
        }
        return finalize();
    }
    parent = RB_PARENT(elm);
    color = RB_COLOR(elm);
    if (child) {
        RB_SET_PARENT(child, parent);
    }
    if (parent) {
        if (RB_LEFT(parent) == elm) {
            RB_SET_LEFT(parent, child);
        } else {
            RB_SET_RIGHT(parent, child);
        }
    } else {
        head->SetRoot(child);
    }
    return finalize();
 }
 // Inserts a node into the RB tree
 template <typename Node, typename CompareFunction>
 Node* RB_INSERT(RBHead<Node>* head, Node* elm, CompareFunction cmp) {
    Node* parent = nullptr;
    Node* tmp = head->Root();
    int comp = 0;
    while (tmp) {
@ -529,17 +548,17 @@ Node* RB_INSERT(RBHead<Node>* head, Node* elm, CompareFunction cmp) {
            RB_SET_RIGHT(parent, elm);
        }
    } else {
-        head->SetRoot(elm);
+        head.SetRoot(elm);
    }
    RB_INSERT_COLOR(head, elm);
    return nullptr;
 }
-// Finds the node with the same key as elm
+template <typename T, typename Compare>
-template <typename Node, typename CompareFunction>
+requires HasRBEntry<T>
-Node* RB_FIND(RBHead<Node>* head, Node* elm, CompareFunction cmp) {
+constexpr T* RB_FIND(RBHead<T>& head, T* elm, Compare cmp) {
-    Node* tmp = head->Root();
+    T* tmp = head.Root();
    while (tmp) {
        const int comp = cmp(elm, tmp);
@ -555,11 +574,11 @@ Node* RB_FIND(RBHead<Node>* head, Node* elm, CompareFunction cmp) {
    return nullptr;
 }
-// Finds the first node greater than or equal to the search key
+template <typename T, typename Compare>
-template <typename Node, typename CompareFunction>
+requires HasRBEntry<T>
-Node* RB_NFIND(RBHead<Node>* head, Node* elm, CompareFunction cmp) {
+constexpr T* RB_NFIND(RBHead<T>& head, T* elm, Compare cmp) {
-    Node* tmp = head->Root();
+    T* tmp = head.Root();
-    Node* res = nullptr;
+    T* res = nullptr;
    while (tmp) {
        const int comp = cmp(elm, tmp);
@ -576,13 +595,13 @@ Node* RB_NFIND(RBHead<Node>* head, Node* elm, CompareFunction cmp) {
    return res;
 }
-// Finds the node with the same key as lelm
+template <typename T, typename U, typename Compare>
-template <typename Node, typename CompareFunction>
+requires HasRBEntry<T>
-Node* RB_FIND_LIGHT(RBHead<Node>* head, const void* lelm, CompareFunction lcmp) {
+constexpr T* RB_FIND_KEY(RBHead<T>& head, const U& key, Compare cmp) {
-    Node* tmp = head->Root();
+    T* tmp = head.Root();
    while (tmp) {
-        const int comp = lcmp(lelm, tmp);
+        const int comp = cmp(key, tmp);
        if (comp < 0) {
            tmp = RB_LEFT(tmp);
        } else if (comp > 0) {
@ -595,14 +614,14 @@ Node* RB_FIND_LIGHT(RBHead<Node>* head, const void* lelm, CompareFunction lcmp)
    return nullptr;
 }
-// Finds the first node greater than or equal to the search key
+template <typename T, typename U, typename Compare>
-template <typename Node, typename CompareFunction>
+requires HasRBEntry<T>
-Node* RB_NFIND_LIGHT(RBHead<Node>* head, const void* lelm, CompareFunction lcmp) {
+constexpr T* RB_NFIND_KEY(RBHead<T>& head, const U& key, Compare cmp) {
-    Node* tmp = head->Root();
+    T* tmp = head.Root();
-    Node* res = nullptr;
+    T* res = nullptr;
    while (tmp) {
-        const int comp = lcmp(lelm, tmp);
+        const int comp = cmp(key, tmp);
        if (comp < 0) {
            res = tmp;
            tmp = RB_LEFT(tmp);
@ -616,8 +635,43 @@ Node* RB_NFIND_LIGHT(RBHead<Node>* head, const void* lelm, CompareFunction lcmp)
    return res;
 }
-template <typename Node>
+template <typename T, typename Compare>
-Node* RB_NEXT(Node* elm) {
+requires HasRBEntry<T>
 constexpr T* RB_FIND_EXISTING(RBHead<T>& head, T* elm, Compare cmp) {
    T* tmp = head.Root();
    while (true) {
        const int comp = cmp(elm, tmp);
        if (comp < 0) {
            tmp = RB_LEFT(tmp);
        } else if (comp > 0) {
            tmp = RB_RIGHT(tmp);
        } else {
            return tmp;
        }
    }
 }
 template <typename T, typename U, typename Compare>
 requires HasRBEntry<T>
 constexpr T* RB_FIND_EXISTING_KEY(RBHead<T>& head, const U& key, Compare cmp) {
    T* tmp = head.Root();
    while (true) {
        const int comp = cmp(key, tmp);
        if (comp < 0) {
            tmp = RB_LEFT(tmp);
        } else if (comp > 0) {
            tmp = RB_RIGHT(tmp);
        } else {
            return tmp;
        }
    }
 }
 template <typename T>
 requires HasRBEntry<T>
 constexpr T* RB_NEXT(T* elm) {
    if (RB_RIGHT(elm)) {
        elm = RB_RIGHT(elm);
        while (RB_LEFT(elm)) {
@ -636,8 +690,9 @@ Node* RB_NEXT(Node* elm) {
    return elm;
 }
-template <typename Node>
+template <typename T>
-Node* RB_PREV(Node* elm) {
+requires HasRBEntry<T>
 constexpr T* RB_PREV(T* elm) {
    if (RB_LEFT(elm)) {
        elm = RB_LEFT(elm);
        while (RB_RIGHT(elm)) {
@ -656,30 +711,32 @@ Node* RB_PREV(Node* elm) {
    return elm;
 }
-template <typename Node>
+template <typename T>
-Node* RB_MINMAX(RBHead<Node>* head, bool is_min) {
+requires HasRBEntry<T>
-    Node* tmp = head->Root();
+constexpr T* RB_MIN(RBHead<T>& head) {
-    Node* parent = nullptr;
+    T* tmp = head.Root();
    T* parent = nullptr;
    while (tmp) {
        parent = tmp;
-        if (is_min) {
+        tmp = RB_LEFT(tmp);
            tmp = RB_LEFT(tmp);
        } else {
            tmp = RB_RIGHT(tmp);
        }
    }
    return parent;
 }
-template <typename Node>
+template <typename T>
-Node* RB_MIN(RBHead<Node>* head) {
+requires HasRBEntry<T>
-    return RB_MINMAX(head, true);
+constexpr T* RB_MAX(RBHead<T>& head) {
    T* tmp = head.Root();
    T* parent = nullptr;
    while (tmp) {
        parent = tmp;
        tmp = RB_RIGHT(tmp);
    }
    return parent;
 }
-template <typename Node>
+} // namespace Common::freebsd
 Node* RB_MAX(RBHead<Node>* head) {
    return RB_MINMAX(head, false);
 }
 } // namespace Common
--- a/src/core/CMakeLists.txt
+++ b/src/core/CMakeLists.txt
@ -207,6 +207,7 @@ add_library(core STATIC
    hle/kernel/k_memory_region.h
    hle/kernel/k_memory_region_type.h
    hle/kernel/k_page_bitmap.h
    hle/kernel/k_page_buffer.h
    hle/kernel/k_page_heap.cpp
    hle/kernel/k_page_heap.h
    hle/kernel/k_page_linked_list.h
@ -244,6 +245,8 @@ add_library(core STATIC
    hle/kernel/k_system_control.h
    hle/kernel/k_thread.cpp
    hle/kernel/k_thread.h
    hle/kernel/k_thread_local_page.cpp
    hle/kernel/k_thread_local_page.h
    hle/kernel/k_thread_queue.cpp
    hle/kernel/k_thread_queue.h
    hle/kernel/k_trace.h
--- a/src/core/hle/ipc_helpers.h
+++ b/src/core/hle/ipc_helpers.h
@ -385,7 +385,7 @@ public:
    T PopRaw();
    template <class T>
-    std::shared_ptr<T> PopIpcInterface() {
+    std::weak_ptr<T> PopIpcInterface() {
        ASSERT(context->Session()->IsDomain());
        ASSERT(context->GetDomainMessageHeader().input_object_count > 0);
        return context->GetDomainHandler<T>(Pop<u32>() - 1);
--- a/src/core/hle/kernel/hle_ipc.cpp
+++ b/src/core/hle/kernel/hle_ipc.cpp
@ -45,7 +45,7 @@ bool SessionRequestManager::HasSessionRequestHandler(const HLERequestContext& co
            LOG_CRITICAL(IPC, "object_id {} is too big!", object_id);
            return false;
        }
-        return DomainHandler(object_id - 1) != nullptr;
+        return DomainHandler(object_id - 1).lock() != nullptr;
    } else {
        return session_handler != nullptr;
    }
@ -53,9 +53,6 @@ bool SessionRequestManager::HasSessionRequestHandler(const HLERequestContext& co
 void SessionRequestHandler::ClientConnected(KServerSession* session) {
    session->ClientConnected(shared_from_this());
    // Ensure our server session is tracked globally.
    kernel.RegisterServerSession(session);
 }
 void SessionRequestHandler::ClientDisconnected(KServerSession* session) {
--- a/src/core/hle/kernel/hle_ipc.h
+++ b/src/core/hle/kernel/hle_ipc.h
@ -94,6 +94,7 @@ protected:
    std::weak_ptr<ServiceThread> service_thread;
 };
 using SessionRequestHandlerWeakPtr = std::weak_ptr<SessionRequestHandler>;
 using SessionRequestHandlerPtr = std::shared_ptr<SessionRequestHandler>;
 /**
@ -139,7 +140,7 @@ public:
        }
    }
-    SessionRequestHandlerPtr DomainHandler(std::size_t index) const {
+    SessionRequestHandlerWeakPtr DomainHandler(std::size_t index) const {
        ASSERT_MSG(index < DomainHandlerCount(), "Unexpected handler index {}", index);
        return domain_handlers.at(index);
    }
@ -328,10 +329,10 @@ public:
    template <typename T>
    std::shared_ptr<T> GetDomainHandler(std::size_t index) const {
-        return std::static_pointer_cast<T>(manager->DomainHandler(index));
+        return std::static_pointer_cast<T>(manager.lock()->DomainHandler(index).lock());
    }
-    void SetSessionRequestManager(std::shared_ptr<SessionRequestManager> manager_) {
+    void SetSessionRequestManager(std::weak_ptr<SessionRequestManager> manager_) {
        manager = std::move(manager_);
    }
@ -374,7 +375,7 @@ private:
    u32 handles_offset{};
    u32 domain_offset{};
-    std::shared_ptr<SessionRequestManager> manager;
+    std::weak_ptr<SessionRequestManager> manager;
    KernelCore& kernel;
    Core::Memory::Memory& memory;
--- a/src/core/hle/kernel/init/init_slab_setup.cpp
+++ b/src/core/hle/kernel/init/init_slab_setup.cpp
@ -7,19 +7,23 @@
 #include "common/common_funcs.h"
 #include "common/common_types.h"
 #include "core/core.h"
 #include "core/device_memory.h"
 #include "core/hardware_properties.h"
 #include "core/hle/kernel/init/init_slab_setup.h"
 #include "core/hle/kernel/k_code_memory.h"
 #include "core/hle/kernel/k_event.h"
 #include "core/hle/kernel/k_memory_layout.h"
 #include "core/hle/kernel/k_memory_manager.h"
 #include "core/hle/kernel/k_page_buffer.h"
 #include "core/hle/kernel/k_port.h"
 #include "core/hle/kernel/k_process.h"
 #include "core/hle/kernel/k_resource_limit.h"
 #include "core/hle/kernel/k_session.h"
 #include "core/hle/kernel/k_shared_memory.h"
 #include "core/hle/kernel/k_shared_memory_info.h"
 #include "core/hle/kernel/k_system_control.h"
 #include "core/hle/kernel/k_thread.h"
 #include "core/hle/kernel/k_thread_local_page.h"
 #include "core/hle/kernel/k_transfer_memory.h"
 namespace Kernel::Init {
@ -32,9 +36,13 @@ namespace Kernel::Init {
    HANDLER(KEvent, (SLAB_COUNT(KEvent)), ##__VA_ARGS__)                                           \
    HANDLER(KPort, (SLAB_COUNT(KPort)), ##__VA_ARGS__)                                             \
    HANDLER(KSharedMemory, (SLAB_COUNT(KSharedMemory)), ##__VA_ARGS__)                             \
    HANDLER(KSharedMemoryInfo, (SLAB_COUNT(KSharedMemory) * 8), ##__VA_ARGS__)                     \
    HANDLER(KTransferMemory, (SLAB_COUNT(KTransferMemory)), ##__VA_ARGS__)                         \
    HANDLER(KCodeMemory, (SLAB_COUNT(KCodeMemory)), ##__VA_ARGS__)                                 \
    HANDLER(KSession, (SLAB_COUNT(KSession)), ##__VA_ARGS__)                                       \
    HANDLER(KThreadLocalPage,                                                                      \
            (SLAB_COUNT(KProcess) + (SLAB_COUNT(KProcess) + SLAB_COUNT(KThread)) / 8),             \
            ##__VA_ARGS__)                                                                         \
    HANDLER(KResourceLimit, (SLAB_COUNT(KResourceLimit)), ##__VA_ARGS__)
 namespace {
@ -50,38 +58,46 @@ enum KSlabType : u32 {
 // Constexpr counts.
 constexpr size_t SlabCountKProcess = 80;
 constexpr size_t SlabCountKThread = 800;
-constexpr size_t SlabCountKEvent = 700;
+constexpr size_t SlabCountKEvent = 900;
 constexpr size_t SlabCountKInterruptEvent = 100;
-constexpr size_t SlabCountKPort = 256 + 0x20; // Extra 0x20 ports over Nintendo for homebrew.
+constexpr size_t SlabCountKPort = 384;
 constexpr size_t SlabCountKSharedMemory = 80;
 constexpr size_t SlabCountKTransferMemory = 200;
 constexpr size_t SlabCountKCodeMemory = 10;
 constexpr size_t SlabCountKDeviceAddressSpace = 300;
-constexpr size_t SlabCountKSession = 933;
+constexpr size_t SlabCountKSession = 1133;
 constexpr size_t SlabCountKLightSession = 100;
 constexpr size_t SlabCountKObjectName = 7;
 constexpr size_t SlabCountKResourceLimit = 5;
 constexpr size_t SlabCountKDebug = Core::Hardware::NUM_CPU_CORES;
-constexpr size_t SlabCountKAlpha = 1;
+constexpr size_t SlabCountKIoPool = 1;
-constexpr size_t SlabCountKBeta = 6;
+constexpr size_t SlabCountKIoRegion = 6;
 constexpr size_t SlabCountExtraKThread = 160;
 /// Helper function to translate from the slab virtual address to the reserved location in physical
 /// memory.
 static PAddr TranslateSlabAddrToPhysical(KMemoryLayout& memory_layout, VAddr slab_addr) {
    slab_addr -= memory_layout.GetSlabRegionAddress();
    return slab_addr + Core::DramMemoryMap::SlabHeapBase;
 }
 template <typename T>
 VAddr InitializeSlabHeap(Core::System& system, KMemoryLayout& memory_layout, VAddr address,
                         size_t num_objects) {
    // TODO(bunnei): This is just a place holder. We should initialize the appropriate KSlabHeap for
    // kernel object type T with the backing kernel memory pointer once we emulate kernel memory.
    const size_t size = Common::AlignUp(sizeof(T) * num_objects, alignof(void*));
    VAddr start = Common::AlignUp(address, alignof(T));
-    // This is intentionally empty. Once KSlabHeap is fully implemented, we can replace this with
+    // This should use the virtual memory address passed in, but currently, we do not setup the
-    // the pointer to emulated memory to pass along. Until then, KSlabHeap will just allocate/free
+    // kernel virtual memory layout. Instead, we simply map these at a region of physical memory
-    // host memory.
+    // that we reserve for the slab heaps.
-    void* backing_kernel_memory{};
+    // TODO(bunnei): Fix this once we support the kernel virtual memory layout.
    if (size > 0) {
        void* backing_kernel_memory{
            system.DeviceMemory().GetPointer(TranslateSlabAddrToPhysical(memory_layout, start))};
        const KMemoryRegion* region = memory_layout.FindVirtual(start + size - 1);
        ASSERT(region != nullptr);
        ASSERT(region->IsDerivedFrom(KMemoryRegionType_KernelSlab));
@ -91,6 +107,12 @@ VAddr InitializeSlabHeap(Core::System& system, KMemoryLayout& memory_layout, VAd
    return start + size;
 }
 size_t CalculateSlabHeapGapSize() {
    constexpr size_t KernelSlabHeapGapSize = 2_MiB - 296_KiB;
    static_assert(KernelSlabHeapGapSize <= KernelSlabHeapGapsSizeMax);
    return KernelSlabHeapGapSize;
 }
 } // namespace
 KSlabResourceCounts KSlabResourceCounts::CreateDefault() {
@ -109,8 +131,8 @@ KSlabResourceCounts KSlabResourceCounts::CreateDefault() {
        .num_KObjectName = SlabCountKObjectName,
        .num_KResourceLimit = SlabCountKResourceLimit,
        .num_KDebug = SlabCountKDebug,
-        .num_KAlpha = SlabCountKAlpha,
+        .num_KIoPool = SlabCountKIoPool,
-        .num_KBeta = SlabCountKBeta,
+        .num_KIoRegion = SlabCountKIoRegion,
    };
 }
@ -136,11 +158,34 @@ size_t CalculateTotalSlabHeapSize(const KernelCore& kernel) {
 #undef ADD_SLAB_SIZE
    // Add the reserved size.
-    size += KernelSlabHeapGapsSize;
+    size += CalculateSlabHeapGapSize();
    return size;
 }
 void InitializeKPageBufferSlabHeap(Core::System& system) {
    auto& kernel = system.Kernel();
    const auto& counts = kernel.SlabResourceCounts();
    const size_t num_pages =
        counts.num_KProcess + counts.num_KThread + (counts.num_KProcess + counts.num_KThread) / 8;
    const size_t slab_size = num_pages * PageSize;
    // Reserve memory from the system resource limit.
    ASSERT(kernel.GetSystemResourceLimit()->Reserve(LimitableResource::PhysicalMemory, slab_size));
    // Allocate memory for the slab.
    constexpr auto AllocateOption = KMemoryManager::EncodeOption(
        KMemoryManager::Pool::System, KMemoryManager::Direction::FromFront);
    const PAddr slab_address =
        kernel.MemoryManager().AllocateAndOpenContinuous(num_pages, 1, AllocateOption);
    ASSERT(slab_address != 0);
    // Initialize the slabheap.
    KPageBuffer::InitializeSlabHeap(kernel, system.DeviceMemory().GetPointer(slab_address),
                                    slab_size);
 }
 void InitializeSlabHeaps(Core::System& system, KMemoryLayout& memory_layout) {
    auto& kernel = system.Kernel();
@ -160,13 +205,13 @@ void InitializeSlabHeaps(Core::System& system, KMemoryLayout& memory_layout) {
    }
    // Create an array to represent the gaps between the slabs.
-    const size_t total_gap_size = KernelSlabHeapGapsSize;
+    const size_t total_gap_size = CalculateSlabHeapGapSize();
    std::array<size_t, slab_types.size()> slab_gaps;
-    for (size_t i = 0; i < slab_gaps.size(); i++) {
+    for (auto& slab_gap : slab_gaps) {
        // Note: This is an off-by-one error from Nintendo's intention, because GenerateRandomRange
        // is inclusive. However, Nintendo also has the off-by-one error, and it's "harmless", so we
        // will include it ourselves.
-        slab_gaps[i] = KSystemControl::GenerateRandomRange(0, total_gap_size);
+        slab_gap = KSystemControl::GenerateRandomRange(0, total_gap_size);
    }
    // Sort the array, so that we can treat differences between values as offsets to the starts of
@ -177,13 +222,21 @@ void InitializeSlabHeaps(Core::System& system, KMemoryLayout& memory_layout) {
        }
    }
-    for (size_t i = 0; i < slab_types.size(); i++) {
+    // Track the gaps, so that we can free them to the unused slab tree.
    VAddr gap_start = address;
    size_t gap_size = 0;
    for (size_t i = 0; i < slab_gaps.size(); i++) {
        // Add the random gap to the address.
-        address += (i == 0) ? slab_gaps[0] : slab_gaps[i] - slab_gaps[i - 1];
+        const auto cur_gap = (i == 0) ? slab_gaps[0] : slab_gaps[i] - slab_gaps[i - 1];
        address += cur_gap;
        gap_size += cur_gap;
 #define INITIALIZE_SLAB_HEAP(NAME, COUNT, ...)                                                     \
    case KSlabType_##NAME:                                                                         \
-        address = InitializeSlabHeap<NAME>(system, memory_layout, address, COUNT);                 \
+        if (COUNT > 0) {                                                                           \
            address = InitializeSlabHeap<NAME>(system, memory_layout, address, COUNT);             \
        }                                                                                          \
        break;
        // Initialize the slabheap.
@ -192,7 +245,13 @@ void InitializeSlabHeaps(Core::System& system, KMemoryLayout& memory_layout) {
            FOREACH_SLAB_TYPE(INITIALIZE_SLAB_HEAP)
            // If we somehow get an invalid type, abort.
        default:
-            UNREACHABLE();
+            UNREACHABLE_MSG("Unknown slab type: {}", slab_types[i]);
        }
        // If we've hit the end of a gap, free it.
        if (gap_start + gap_size != address) {
            gap_start = address;
            gap_size = 0;
        }
    }
 }
--- a/src/core/hle/kernel/init/init_slab_setup.h
+++ b/src/core/hle/kernel/init/init_slab_setup.h
@ -32,12 +32,13 @@ struct KSlabResourceCounts {
    size_t num_KObjectName;
    size_t num_KResourceLimit;
    size_t num_KDebug;
-    size_t num_KAlpha;
+    size_t num_KIoPool;
-    size_t num_KBeta;
+    size_t num_KIoRegion;
 };
 void InitializeSlabResourceCounts(KernelCore& kernel);
 size_t CalculateTotalSlabHeapSize(const KernelCore& kernel);
 void InitializeKPageBufferSlabHeap(Core::System& system);
 void InitializeSlabHeaps(Core::System& system, KMemoryLayout& memory_layout);
 } // namespace Kernel::Init
--- a/src/core/hle/kernel/k_address_arbiter.cpp
+++ b/src/core/hle/kernel/k_address_arbiter.cpp
@ -115,7 +115,7 @@ ResultCode KAddressArbiter::Signal(VAddr addr, s32 count) {
    {
        KScopedSchedulerLock sl(kernel);
-        auto it = thread_tree.nfind_light({addr, -1});
+        auto it = thread_tree.nfind_key({addr, -1});
        while ((it != thread_tree.end()) && (count <= 0 || num_waiters < count) &&
               (it->GetAddressArbiterKey() == addr)) {
            // End the thread's wait.
@ -148,7 +148,7 @@ ResultCode KAddressArbiter::SignalAndIncrementIfEqual(VAddr addr, s32 value, s32
            return ResultInvalidState;
        }
-        auto it = thread_tree.nfind_light({addr, -1});
+        auto it = thread_tree.nfind_key({addr, -1});
        while ((it != thread_tree.end()) && (count <= 0 || num_waiters < count) &&
               (it->GetAddressArbiterKey() == addr)) {
            // End the thread's wait.
@ -171,7 +171,7 @@ ResultCode KAddressArbiter::SignalAndModifyByWaitingCountIfEqual(VAddr addr, s32
    {
        [[maybe_unused]] const KScopedSchedulerLock sl(kernel);
-        auto it = thread_tree.nfind_light({addr, -1});
+        auto it = thread_tree.nfind_key({addr, -1});
        // Determine the updated value.
        s32 new_value{};
        if (count <= 0) {
--- a/src/core/hle/kernel/k_condition_variable.cpp
+++ b/src/core/hle/kernel/k_condition_variable.cpp
@ -244,7 +244,7 @@ void KConditionVariable::Signal(u64 cv_key, s32 count) {
    {
        KScopedSchedulerLock sl(kernel);
-        auto it = thread_tree.nfind_light({cv_key, -1});
+        auto it = thread_tree.nfind_key({cv_key, -1});
        while ((it != thread_tree.end()) && (count <= 0 || num_waiters < count) &&
               (it->GetConditionVariableKey() == cv_key)) {
            KThread* target_thread = std::addressof(*it);
--- a/src/core/hle/kernel/k_memory_layout.h
+++ b/src/core/hle/kernel/k_memory_layout.h
@ -57,11 +57,11 @@ constexpr std::size_t KernelPageTableHeapSize = GetMaximumOverheadSize(MainMemor
 constexpr std::size_t KernelInitialPageHeapSize = 128_KiB;
 constexpr std::size_t KernelSlabHeapDataSize = 5_MiB;
-constexpr std::size_t KernelSlabHeapGapsSize = 2_MiB - 64_KiB;
+constexpr std::size_t KernelSlabHeapGapsSizeMax = 2_MiB - 64_KiB;
-constexpr std::size_t KernelSlabHeapSize = KernelSlabHeapDataSize + KernelSlabHeapGapsSize;
+constexpr std::size_t KernelSlabHeapSize = KernelSlabHeapDataSize + KernelSlabHeapGapsSizeMax;
 // NOTE: This is calculated from KThread slab counts, assuming KThread size <= 0x860.
-constexpr std::size_t KernelSlabHeapAdditionalSize = 416_KiB;
+constexpr std::size_t KernelSlabHeapAdditionalSize = 0x68000;
 constexpr std::size_t KernelResourceSize =
    KernelPageTableHeapSize + KernelInitialPageHeapSize + KernelSlabHeapSize;
--- a/src/core/hle/kernel/k_page_buffer.h
+++ b/src/core/hle/kernel/k_page_buffer.h
@ -0,0 +1,34 @@
 // Copyright 2022 yuzu Emulator Project
 // Licensed under GPLv2 or any later version
 // Refer to the license.txt file included.
 #pragma once
 #include <array>
 #include "common/alignment.h"
 #include "common/assert.h"
 #include "common/common_types.h"
 #include "core/core.h"
 #include "core/device_memory.h"
 #include "core/hle/kernel/memory_types.h"
 namespace Kernel {
 class KPageBuffer final : public KSlabAllocated<KPageBuffer> {
 public:
    KPageBuffer() = default;
    static KPageBuffer* FromPhysicalAddress(Core::System& system, PAddr phys_addr) {
        ASSERT(Common::IsAligned(phys_addr, PageSize));
        return reinterpret_cast<KPageBuffer*>(system.DeviceMemory().GetPointer(phys_addr));
    }
 private:
    [[maybe_unused]] alignas(PageSize) std::array<u8, PageSize> m_buffer{};
 };
 static_assert(sizeof(KPageBuffer) == PageSize);
 static_assert(alignof(KPageBuffer) == PageSize);
 } // namespace Kernel
--- a/src/core/hle/kernel/k_page_table.cpp
+++ b/src/core/hle/kernel/k_page_table.cpp
@ -424,6 +424,68 @@ ResultCode KPageTable::UnmapCodeMemory(VAddr dst_address, VAddr src_address, std
    return ResultSuccess;
 }
 VAddr KPageTable::FindFreeArea(VAddr region_start, std::size_t region_num_pages,
                               std::size_t num_pages, std::size_t alignment, std::size_t offset,
                               std::size_t guard_pages) {
    VAddr address = 0;
    if (num_pages <= region_num_pages) {
        if (this->IsAslrEnabled()) {
            // Try to directly find a free area up to 8 times.
            for (std::size_t i = 0; i < 8; i++) {
                const std::size_t random_offset =
                    KSystemControl::GenerateRandomRange(
                        0, (region_num_pages - num_pages - guard_pages) * PageSize / alignment) *
                    alignment;
                const VAddr candidate =
                    Common::AlignDown((region_start + random_offset), alignment) + offset;
                KMemoryInfo info = this->QueryInfoImpl(candidate);
                if (info.state != KMemoryState::Free) {
                    continue;
                }
                if (region_start > candidate) {
                    continue;
                }
                if (info.GetAddress() + guard_pages * PageSize > candidate) {
                    continue;
                }
                const VAddr candidate_end = candidate + (num_pages + guard_pages) * PageSize - 1;
                if (candidate_end > info.GetLastAddress()) {
                    continue;
                }
                if (candidate_end > region_start + region_num_pages * PageSize - 1) {
                    continue;
                }
                address = candidate;
                break;
            }
            // Fall back to finding the first free area with a random offset.
            if (address == 0) {
                // NOTE: Nintendo does not account for guard pages here.
                // This may theoretically cause an offset to be chosen that cannot be mapped. We
                // will account for guard pages.
                const std::size_t offset_pages = KSystemControl::GenerateRandomRange(
                    0, region_num_pages - num_pages - guard_pages);
                address = block_manager->FindFreeArea(region_start + offset_pages * PageSize,
                                                      region_num_pages - offset_pages, num_pages,
                                                      alignment, offset, guard_pages);
            }
        }
        // Find the first free area.
        if (address == 0) {
            address = block_manager->FindFreeArea(region_start, region_num_pages, num_pages,
                                                  alignment, offset, guard_pages);
        }
    }
    return address;
 }
 ResultCode KPageTable::UnmapProcessMemory(VAddr dst_addr, std::size_t size,
                                          KPageTable& src_page_table, VAddr src_addr) {
    KScopedLightLock lk(general_lock);
@ -1055,6 +1117,46 @@ ResultCode KPageTable::MapPages(VAddr address, KPageLinkedList& page_linked_list
    return ResultSuccess;
 }
 ResultCode KPageTable::MapPages(VAddr* out_addr, std::size_t num_pages, std::size_t alignment,
                                PAddr phys_addr, bool is_pa_valid, VAddr region_start,
                                std::size_t region_num_pages, KMemoryState state,
                                KMemoryPermission perm) {
    ASSERT(Common::IsAligned(alignment, PageSize) && alignment >= PageSize);
    // Ensure this is a valid map request.
    R_UNLESS(this->CanContain(region_start, region_num_pages * PageSize, state),
             ResultInvalidCurrentMemory);
    R_UNLESS(num_pages < region_num_pages, ResultOutOfMemory);
    // Lock the table.
    KScopedLightLock lk(general_lock);
    // Find a random address to map at.
    VAddr addr = this->FindFreeArea(region_start, region_num_pages, num_pages, alignment, 0,
                                    this->GetNumGuardPages());
    R_UNLESS(addr != 0, ResultOutOfMemory);
    ASSERT(Common::IsAligned(addr, alignment));
    ASSERT(this->CanContain(addr, num_pages * PageSize, state));
    ASSERT(this->CheckMemoryState(addr, num_pages * PageSize, KMemoryState::All, KMemoryState::Free,
                                  KMemoryPermission::None, KMemoryPermission::None,
                                  KMemoryAttribute::None, KMemoryAttribute::None)
               .IsSuccess());
    // Perform mapping operation.
    if (is_pa_valid) {
        R_TRY(this->Operate(addr, num_pages, perm, OperationType::Map, phys_addr));
    } else {
        UNIMPLEMENTED();
    }
    // Update the blocks.
    block_manager->Update(addr, num_pages, state, perm);
    // We successfully mapped the pages.
    *out_addr = addr;
    return ResultSuccess;
 }
 ResultCode KPageTable::UnmapPages(VAddr addr, const KPageLinkedList& page_linked_list) {
    ASSERT(this->IsLockedByCurrentThread());
@ -1097,6 +1199,30 @@ ResultCode KPageTable::UnmapPages(VAddr addr, KPageLinkedList& page_linked_list,
    return ResultSuccess;
 }
 ResultCode KPageTable::UnmapPages(VAddr address, std::size_t num_pages, KMemoryState state) {
    // Check that the unmap is in range.
    const std::size_t size = num_pages * PageSize;
    R_UNLESS(this->Contains(address, size), ResultInvalidCurrentMemory);
    // Lock the table.
    KScopedLightLock lk(general_lock);
    // Check the memory state.
    std::size_t num_allocator_blocks{};
    R_TRY(this->CheckMemoryState(std::addressof(num_allocator_blocks), address, size,
                                 KMemoryState::All, state, KMemoryPermission::None,
                                 KMemoryPermission::None, KMemoryAttribute::All,
                                 KMemoryAttribute::None));
    // Perform the unmap.
    R_TRY(Operate(address, num_pages, KMemoryPermission::None, OperationType::Unmap));
    // Update the blocks.
    block_manager->Update(address, num_pages, KMemoryState::Free, KMemoryPermission::None);
    return ResultSuccess;
 }
 ResultCode KPageTable::SetProcessMemoryPermission(VAddr addr, std::size_t size,
                                                  Svc::MemoryPermission svc_perm) {
    const size_t num_pages = size / PageSize;
--- a/src/core/hle/kernel/k_page_table.h
+++ b/src/core/hle/kernel/k_page_table.h
@ -46,7 +46,14 @@ public:
    ResultCode UnmapMemory(VAddr dst_addr, VAddr src_addr, std::size_t size);
    ResultCode MapPages(VAddr addr, KPageLinkedList& page_linked_list, KMemoryState state,
                        KMemoryPermission perm);
    ResultCode MapPages(VAddr* out_addr, std::size_t num_pages, std::size_t alignment,
                        PAddr phys_addr, KMemoryState state, KMemoryPermission perm) {
        return this->MapPages(out_addr, num_pages, alignment, phys_addr, true,
                              this->GetRegionAddress(state), this->GetRegionSize(state) / PageSize,
                              state, perm);
    }
    ResultCode UnmapPages(VAddr addr, KPageLinkedList& page_linked_list, KMemoryState state);
    ResultCode UnmapPages(VAddr address, std::size_t num_pages, KMemoryState state);
    ResultCode SetProcessMemoryPermission(VAddr addr, std::size_t size,
                                          Svc::MemoryPermission svc_perm);
    KMemoryInfo QueryInfo(VAddr addr);
@ -91,6 +98,9 @@ private:
    ResultCode InitializeMemoryLayout(VAddr start, VAddr end);
    ResultCode MapPages(VAddr addr, const KPageLinkedList& page_linked_list,
                        KMemoryPermission perm);
    ResultCode MapPages(VAddr* out_addr, std::size_t num_pages, std::size_t alignment,
                        PAddr phys_addr, bool is_pa_valid, VAddr region_start,
                        std::size_t region_num_pages, KMemoryState state, KMemoryPermission perm);
    ResultCode UnmapPages(VAddr addr, const KPageLinkedList& page_linked_list);
    bool IsRegionMapped(VAddr address, u64 size);
    bool IsRegionContiguous(VAddr addr, u64 size) const;
@ -105,6 +115,9 @@ private:
    VAddr GetRegionAddress(KMemoryState state) const;
    std::size_t GetRegionSize(KMemoryState state) const;
    VAddr FindFreeArea(VAddr region_start, std::size_t region_num_pages, std::size_t num_pages,
                       std::size_t alignment, std::size_t offset, std::size_t guard_pages);
    ResultCode CheckMemoryStateContiguous(std::size_t* out_blocks_needed, VAddr addr,
                                          std::size_t size, KMemoryState state_mask,
                                          KMemoryState state, KMemoryPermission perm_mask,
@ -137,7 +150,7 @@ private:
        return CheckMemoryState(nullptr, nullptr, nullptr, out_blocks_needed, addr, size,
                                state_mask, state, perm_mask, perm, attr_mask, attr, ignore_attr);
    }
-    ResultCode CheckMemoryState(VAddr addr, size_t size, KMemoryState state_mask,
+    ResultCode CheckMemoryState(VAddr addr, std::size_t size, KMemoryState state_mask,
                                KMemoryState state, KMemoryPermission perm_mask,
                                KMemoryPermission perm, KMemoryAttribute attr_mask,
                                KMemoryAttribute attr,
@ -210,7 +223,7 @@ public:
    constexpr VAddr GetAliasCodeRegionSize() const {
        return alias_code_region_end - alias_code_region_start;
    }
-    size_t GetNormalMemorySize() {
+    std::size_t GetNormalMemorySize() {
        KScopedLightLock lk(general_lock);
        return GetHeapSize() + mapped_physical_memory_size;
    }
--- a/src/core/hle/kernel/k_port.cpp
+++ b/src/core/hle/kernel/k_port.cpp
@ -57,7 +57,12 @@ ResultCode KPort::EnqueueSession(KServerSession* session) {
    R_UNLESS(state == State::Normal, ResultPortClosed);
    server.EnqueueSession(session);
-    server.GetSessionRequestHandler()->ClientConnected(server.AcceptSession());
+
    if (auto session_ptr = server.GetSessionRequestHandler().lock()) {
        session_ptr->ClientConnected(server.AcceptSession());
    } else {
        UNREACHABLE();
    }
    return ResultSuccess;
 }
--- a/src/core/hle/kernel/k_process.cpp
+++ b/src/core/hle/kernel/k_process.cpp
@ -70,58 +70,6 @@ void SetupMainThread(Core::System& system, KProcess& owner_process, u32 priority
 }
 } // Anonymous namespace
 // Represents a page used for thread-local storage.
 //
 // Each TLS page contains slots that may be used by processes and threads.
 // Every process and thread is created with a slot in some arbitrary page
 // (whichever page happens to have an available slot).
 class TLSPage {
 public:
    static constexpr std::size_t num_slot_entries =
        Core::Memory::PAGE_SIZE / Core::Memory::TLS_ENTRY_SIZE;
    explicit TLSPage(VAddr address) : base_address{address} {}
    bool HasAvailableSlots() const {
        return !is_slot_used.all();
    }
    VAddr GetBaseAddress() const {
        return base_address;
    }
    std::optional<VAddr> ReserveSlot() {
        for (std::size_t i = 0; i < is_slot_used.size(); i++) {
            if (is_slot_used[i]) {
                continue;
            }
            is_slot_used[i] = true;
            return base_address + (i * Core::Memory::TLS_ENTRY_SIZE);
        }
        return std::nullopt;
    }
    void ReleaseSlot(VAddr address) {
        // Ensure that all given addresses are consistent with how TLS pages
        // are intended to be used when releasing slots.
        ASSERT(IsWithinPage(address));
        ASSERT((address % Core::Memory::TLS_ENTRY_SIZE) == 0);
        const std::size_t index = (address - base_address) / Core::Memory::TLS_ENTRY_SIZE;
        is_slot_used[index] = false;
    }
 private:
    bool IsWithinPage(VAddr address) const {
        return base_address <= address && address < base_address + Core::Memory::PAGE_SIZE;
    }
    VAddr base_address;
    std::bitset<num_slot_entries> is_slot_used;
 };
 ResultCode KProcess::Initialize(KProcess* process, Core::System& system, std::string process_name,
                                ProcessType type, KResourceLimit* res_limit) {
    auto& kernel = system.Kernel();
@ -404,7 +352,7 @@ ResultCode KProcess::LoadFromMetadata(const FileSys::ProgramMetadata& metadata,
    }
    // Create TLS region
-    tls_region_address = CreateTLSRegion();
+    R_TRY(this->CreateThreadLocalRegion(std::addressof(tls_region_address)));
    memory_reservation.Commit();
    return handle_table.Initialize(capabilities.GetHandleTableSize());
@ -444,7 +392,7 @@ void KProcess::PrepareForTermination() {
    stop_threads(kernel.System().GlobalSchedulerContext().GetThreadList());
-    FreeTLSRegion(tls_region_address);
+    this->DeleteThreadLocalRegion(tls_region_address);
    tls_region_address = 0;
    if (resource_limit) {
@ -456,9 +404,6 @@ void KProcess::PrepareForTermination() {
 }
 void KProcess::Finalize() {
    // Finalize the handle table and close any open handles.
    handle_table.Finalize();
    // Free all shared memory infos.
    {
        auto it = shared_memory_list.begin();
@ -483,67 +428,110 @@ void KProcess::Finalize() {
        resource_limit = nullptr;
    }
    // Finalize the page table.
    page_table.reset();
    // Perform inherited finalization.
    KAutoObjectWithSlabHeapAndContainer<KProcess, KWorkerTask>::Finalize();
 }
-/**
+ResultCode KProcess::CreateThreadLocalRegion(VAddr* out) {
- * Attempts to find a TLS page that contains a free slot for
+    KThreadLocalPage* tlp = nullptr;
- * use by a thread.
+    VAddr tlr = 0;
 *
 * @returns If a page with an available slot is found, then an iterator
 *          pointing to the page is returned. Otherwise the end iterator
 *          is returned instead.
 */
 static auto FindTLSPageWithAvailableSlots(std::vector<TLSPage>& tls_pages) {
    return std::find_if(tls_pages.begin(), tls_pages.end(),
                        [](const auto& page) { return page.HasAvailableSlots(); });
 }
-VAddr KProcess::CreateTLSRegion() {
+    // See if we can get a region from a partially used TLP.
-    KScopedSchedulerLock lock(kernel);
+    {
-    if (auto tls_page_iter{FindTLSPageWithAvailableSlots(tls_pages)};
+        KScopedSchedulerLock sl{kernel};
-        tls_page_iter != tls_pages.cend()) {
+
-        return *tls_page_iter->ReserveSlot();
+        if (auto it = partially_used_tlp_tree.begin(); it != partially_used_tlp_tree.end()) {
            tlr = it->Reserve();
            ASSERT(tlr != 0);
            if (it->IsAllUsed()) {
                tlp = std::addressof(*it);
                partially_used_tlp_tree.erase(it);
                fully_used_tlp_tree.insert(*tlp);
            }
            *out = tlr;
            return ResultSuccess;
        }
    }
-    Page* const tls_page_ptr{kernel.GetUserSlabHeapPages().Allocate()};
+    // Allocate a new page.
-    ASSERT(tls_page_ptr);
+    tlp = KThreadLocalPage::Allocate(kernel);
    R_UNLESS(tlp != nullptr, ResultOutOfMemory);
    auto tlp_guard = SCOPE_GUARD({ KThreadLocalPage::Free(kernel, tlp); });
-    const VAddr start{page_table->GetKernelMapRegionStart()};
+    // Initialize the new page.
-    const VAddr size{page_table->GetKernelMapRegionEnd() - start};
+    R_TRY(tlp->Initialize(kernel, this));
    const PAddr tls_map_addr{kernel.System().DeviceMemory().GetPhysicalAddr(tls_page_ptr)};
    const VAddr tls_page_addr{page_table
                                  ->AllocateAndMapMemory(1, PageSize, true, start, size / PageSize,
                                                         KMemoryState::ThreadLocal,
                                                         KMemoryPermission::UserReadWrite,
                                                         tls_map_addr)
                                  .ValueOr(0)};
-    ASSERT(tls_page_addr);
+    // Reserve a TLR.
    tlr = tlp->Reserve();
    ASSERT(tlr != 0);
-    std::memset(tls_page_ptr, 0, PageSize);
+    // Insert into our tree.
-    tls_pages.emplace_back(tls_page_addr);
+    {
        KScopedSchedulerLock sl{kernel};
        if (tlp->IsAllUsed()) {
            fully_used_tlp_tree.insert(*tlp);
        } else {
            partially_used_tlp_tree.insert(*tlp);
        }
    }
-    const auto reserve_result{tls_pages.back().ReserveSlot()};
+    // We succeeded!
-    ASSERT(reserve_result.has_value());
+    tlp_guard.Cancel();
-
+    *out = tlr;
-    return *reserve_result;
+    return ResultSuccess;
 }
-void KProcess::FreeTLSRegion(VAddr tls_address) {
+ResultCode KProcess::DeleteThreadLocalRegion(VAddr addr) {
-    KScopedSchedulerLock lock(kernel);
+    KThreadLocalPage* page_to_free = nullptr;
    const VAddr aligned_address = Common::AlignDown(tls_address, Core::Memory::PAGE_SIZE);
    auto iter =
        std::find_if(tls_pages.begin(), tls_pages.end(), [aligned_address](const auto& page) {
            return page.GetBaseAddress() == aligned_address;
        });
-    // Something has gone very wrong if we're freeing a region
+    // Release the region.
-    // with no actual page available.
+    {
-    ASSERT(iter != tls_pages.cend());
+        KScopedSchedulerLock sl{kernel};
-    iter->ReleaseSlot(tls_address);
+        // Try to find the page in the partially used list.
        auto it = partially_used_tlp_tree.find_key(Common::AlignDown(addr, PageSize));
        if (it == partially_used_tlp_tree.end()) {
            // If we don't find it, it has to be in the fully used list.
            it = fully_used_tlp_tree.find_key(Common::AlignDown(addr, PageSize));
            R_UNLESS(it != fully_used_tlp_tree.end(), ResultInvalidAddress);
            // Release the region.
            it->Release(addr);
            // Move the page out of the fully used list.
            KThreadLocalPage* tlp = std::addressof(*it);
            fully_used_tlp_tree.erase(it);
            if (tlp->IsAllFree()) {
                page_to_free = tlp;
            } else {
                partially_used_tlp_tree.insert(*tlp);
            }
        } else {
            // Release the region.
            it->Release(addr);
            // Handle the all-free case.
            KThreadLocalPage* tlp = std::addressof(*it);
            if (tlp->IsAllFree()) {
                partially_used_tlp_tree.erase(it);
                page_to_free = tlp;
            }
        }
    }
    // If we should free the page it was in, do so.
    if (page_to_free != nullptr) {
        page_to_free->Finalize();
        KThreadLocalPage::Free(kernel, page_to_free);
    }
    return ResultSuccess;
 }
 void KProcess::LoadModule(CodeSet code_set, VAddr base_addr) {
--- a/src/core/hle/kernel/k_process.h
+++ b/src/core/hle/kernel/k_process.h
@ -15,6 +15,7 @@
 #include "core/hle/kernel/k_condition_variable.h"
 #include "core/hle/kernel/k_handle_table.h"
 #include "core/hle/kernel/k_synchronization_object.h"
 #include "core/hle/kernel/k_thread_local_page.h"
 #include "core/hle/kernel/k_worker_task.h"
 #include "core/hle/kernel/process_capability.h"
 #include "core/hle/kernel/slab_helpers.h"
@ -362,10 +363,10 @@ public:
    // Thread-local storage management
    // Marks the next available region as used and returns the address of the slot.
-    [[nodiscard]] VAddr CreateTLSRegion();
+    [[nodiscard]] ResultCode CreateThreadLocalRegion(VAddr* out);
    // Frees a used TLS slot identified by the given address
-    void FreeTLSRegion(VAddr tls_address);
+    ResultCode DeleteThreadLocalRegion(VAddr addr);
 private:
    void PinThread(s32 core_id, KThread* thread) {
@ -413,13 +414,6 @@ private:
    /// The ideal CPU core for this process, threads are scheduled on this core by default.
    u8 ideal_core = 0;
    /// The Thread Local Storage area is allocated as processes create threads,
    /// each TLS area is 0x200 bytes, so one page (0x1000) is split up in 8 parts, and each part
    /// holds the TLS for a specific thread. This vector contains which parts are in use for each
    /// page as a bitmask.
    /// This vector will grow as more pages are allocated for new threads.
    std::vector<TLSPage> tls_pages;
    /// Contains the parsed process capability descriptors.
    ProcessCapabilities capabilities;
@ -482,6 +476,12 @@ private:
    KThread* exception_thread{};
    KLightLock state_lock;
    using TLPTree =
        Common::IntrusiveRedBlackTreeBaseTraits<KThreadLocalPage>::TreeType<KThreadLocalPage>;
    using TLPIterator = TLPTree::iterator;
    TLPTree fully_used_tlp_tree;
    TLPTree partially_used_tlp_tree;
 };
 } // namespace Kernel
--- a/src/core/hle/kernel/k_server_port.h
+++ b/src/core/hle/kernel/k_server_port.h
@ -30,11 +30,11 @@ public:
    /// Whether or not this server port has an HLE handler available.
    bool HasSessionRequestHandler() const {
-        return session_handler != nullptr;
+        return !session_handler.expired();
    }
    /// Gets the HLE handler for this port.
-    SessionRequestHandlerPtr GetSessionRequestHandler() const {
+    SessionRequestHandlerWeakPtr GetSessionRequestHandler() const {
        return session_handler;
    }
@ -42,7 +42,7 @@ public:
     * Sets the HLE handler template for the port. ServerSessions crated by connecting to this port
     * will inherit a reference to this handler.
     */
-    void SetSessionHandler(SessionRequestHandlerPtr&& handler) {
+    void SetSessionHandler(SessionRequestHandlerWeakPtr&& handler) {
        session_handler = std::move(handler);
    }
@ -66,7 +66,7 @@ private:
    void CleanupSessions();
    SessionList session_list;
-    SessionRequestHandlerPtr session_handler;
+    SessionRequestHandlerWeakPtr session_handler;
    KPort* parent{};
 };
--- a/src/core/hle/kernel/k_server_session.cpp
+++ b/src/core/hle/kernel/k_server_session.cpp
@ -27,10 +27,7 @@ namespace Kernel {
 KServerSession::KServerSession(KernelCore& kernel_) : KSynchronizationObject{kernel_} {}
-KServerSession::~KServerSession() {
+KServerSession::~KServerSession() = default;
    // Ensure that the global list tracking server sessions does not hold on to a reference.
    kernel.UnregisterServerSession(this);
 }
 void KServerSession::Initialize(KSession* parent_session_, std::string&& name_,
                                std::shared_ptr<SessionRequestManager> manager_) {
@ -49,6 +46,9 @@ void KServerSession::Destroy() {
    parent->OnServerClosed();
    parent->Close();
    // Release host emulation members.
    manager.reset();
 }
 void KServerSession::OnClientClosed() {
@ -98,7 +98,12 @@ ResultCode KServerSession::HandleDomainSyncRequest(Kernel::HLERequestContext& co
            UNREACHABLE();
            return ResultSuccess; // Ignore error if asserts are off
        }
-        return manager->DomainHandler(object_id - 1)->HandleSyncRequest(*this, context);
+        if (auto strong_ptr = manager->DomainHandler(object_id - 1).lock()) {
            return strong_ptr->HandleSyncRequest(*this, context);
        } else {
            UNREACHABLE();
            return ResultSuccess;
        }
    case IPC::DomainMessageHeader::CommandType::CloseVirtualHandle: {
        LOG_DEBUG(IPC, "CloseVirtualHandle, object_id=0x{:08X}", object_id);
--- a/src/core/hle/kernel/k_slab_heap.h
+++ b/src/core/hle/kernel/k_slab_heap.h
@ -16,39 +16,34 @@ class KernelCore;
 namespace impl {
-class KSlabHeapImpl final {
+class KSlabHeapImpl {
 public:
    YUZU_NON_COPYABLE(KSlabHeapImpl);
    YUZU_NON_MOVEABLE(KSlabHeapImpl);
 public:
    struct Node {
        Node* next{};
    };
 public:
    constexpr KSlabHeapImpl() = default;
    constexpr ~KSlabHeapImpl() = default;
-    void Initialize(std::size_t size) {
+    void Initialize() {
-        ASSERT(head == nullptr);
+        ASSERT(m_head == nullptr);
        obj_size = size;
    }
    constexpr std::size_t GetObjectSize() const {
        return obj_size;
    }
    Node* GetHead() const {
-        return head;
+        return m_head;
    }
    void* Allocate() {
-        Node* ret = head.load();
+        Node* ret = m_head.load();
        do {
            if (ret == nullptr) {
                break;
            }
-        } while (!head.compare_exchange_weak(ret, ret->next));
+        } while (!m_head.compare_exchange_weak(ret, ret->next));
        return ret;
    }
@ -56,170 +51,157 @@ public:
    void Free(void* obj) {
        Node* node = static_cast<Node*>(obj);
-        Node* cur_head = head.load();
+        Node* cur_head = m_head.load();
        do {
            node->next = cur_head;
-        } while (!head.compare_exchange_weak(cur_head, node));
+        } while (!m_head.compare_exchange_weak(cur_head, node));
    }
 private:
-    std::atomic<Node*> head{};
+    std::atomic<Node*> m_head{};
    std::size_t obj_size{};
 };
 } // namespace impl
-class KSlabHeapBase {
+template <bool SupportDynamicExpansion>
-public:
+class KSlabHeapBase : protected impl::KSlabHeapImpl {
    YUZU_NON_COPYABLE(KSlabHeapBase);
    YUZU_NON_MOVEABLE(KSlabHeapBase);
 private:
    size_t m_obj_size{};
    uintptr_t m_peak{};
    uintptr_t m_start{};
    uintptr_t m_end{};
 private:
    void UpdatePeakImpl(uintptr_t obj) {
        static_assert(std::atomic_ref<uintptr_t>::is_always_lock_free);
        std::atomic_ref<uintptr_t> peak_ref(m_peak);
        const uintptr_t alloc_peak = obj + this->GetObjectSize();
        uintptr_t cur_peak = m_peak;
        do {
            if (alloc_peak <= cur_peak) {
                break;
            }
        } while (!peak_ref.compare_exchange_strong(cur_peak, alloc_peak));
    }
 public:
    constexpr KSlabHeapBase() = default;
    constexpr ~KSlabHeapBase() = default;
-    constexpr bool Contains(uintptr_t addr) const {
+    bool Contains(uintptr_t address) const {
-        return start <= addr && addr < end;
+        return m_start <= address && address < m_end;
    }
-    constexpr std::size_t GetSlabHeapSize() const {
+    void Initialize(size_t obj_size, void* memory, size_t memory_size) {
-        return (end - start) / GetObjectSize();
+        // Ensure we don't initialize a slab using null memory.
    }
    constexpr std::size_t GetObjectSize() const {
        return impl.GetObjectSize();
    }
    constexpr uintptr_t GetSlabHeapAddress() const {
        return start;
    }
    std::size_t GetObjectIndexImpl(const void* obj) const {
        return (reinterpret_cast<uintptr_t>(obj) - start) / GetObjectSize();
    }
    std::size_t GetPeakIndex() const {
        return GetObjectIndexImpl(reinterpret_cast<const void*>(peak));
    }
    void* AllocateImpl() {
        return impl.Allocate();
    }
    void FreeImpl(void* obj) {
        // Don't allow freeing an object that wasn't allocated from this heap
        ASSERT(Contains(reinterpret_cast<uintptr_t>(obj)));
        impl.Free(obj);
    }
    void InitializeImpl(std::size_t obj_size, void* memory, std::size_t memory_size) {
        // Ensure we don't initialize a slab using null memory
        ASSERT(memory != nullptr);
-        // Initialize the base allocator
+        // Set our object size.
-        impl.Initialize(obj_size);
+        m_obj_size = obj_size;
-        // Set our tracking variables
+        // Initialize the base allocator.
-        const std::size_t num_obj = (memory_size / obj_size);
+        KSlabHeapImpl::Initialize();
        start = reinterpret_cast<uintptr_t>(memory);
        end = start + num_obj * obj_size;
        peak = start;
-        // Free the objects
+        // Set our tracking variables.
-        u8* cur = reinterpret_cast<u8*>(end);
+        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;
-        for (std::size_t i{}; i < num_obj; i++) {
+        // Free the objects.
        u8* cur = reinterpret_cast<u8*>(m_end);
        for (size_t i = 0; i < num_obj; i++) {
            cur -= obj_size;
-            impl.Free(cur);
+            KSlabHeapImpl::Free(cur);
        }
    }
-private:
+    size_t GetSlabHeapSize() const {
-    using Impl = impl::KSlabHeapImpl;
+        return (m_end - m_start) / this->GetObjectSize();
    }
-    Impl impl;
+    size_t GetObjectSize() const {
-    uintptr_t peak{};
+        return m_obj_size;
-    uintptr_t start{};
+    }
-    uintptr_t end{};
+
    void* Allocate() {
        void* obj = KSlabHeapImpl::Allocate();
        return obj;
    }
    void Free(void* obj) {
        // Don't allow freeing an object that wasn't allocated from this heap.
        const bool contained = this->Contains(reinterpret_cast<uintptr_t>(obj));
        ASSERT(contained);
        KSlabHeapImpl::Free(obj);
    }
    size_t GetObjectIndex(const void* obj) const {
        if constexpr (SupportDynamicExpansion) {
            if (!this->Contains(reinterpret_cast<uintptr_t>(obj))) {
                return std::numeric_limits<size_t>::max();
            }
        }
        return (reinterpret_cast<uintptr_t>(obj) - m_start) / this->GetObjectSize();
    }
    size_t GetPeakIndex() const {
        return this->GetObjectIndex(reinterpret_cast<const void*>(m_peak));
    }
    uintptr_t GetSlabHeapAddress() const {
        return m_start;
    }
    size_t GetNumRemaining() const {
        // Only calculate the number of remaining objects under debug configuration.
        return 0;
    }
 };
 template <typename T>
-class KSlabHeap final : public KSlabHeapBase {
+class KSlabHeap final : public KSlabHeapBase<false> {
 private:
    using BaseHeap = KSlabHeapBase<false>;
 public:
-    enum class AllocationType {
+    constexpr KSlabHeap() = default;
        Host,
        Guest,
    };
-    explicit constexpr KSlabHeap(AllocationType allocation_type_ = AllocationType::Host)
+    void Initialize(void* memory, size_t memory_size) {
-        : KSlabHeapBase(), allocation_type{allocation_type_} {}
+        BaseHeap::Initialize(sizeof(T), memory, memory_size);
    void Initialize(void* memory, std::size_t memory_size) {
        if (allocation_type == AllocationType::Guest) {
            InitializeImpl(sizeof(T), memory, memory_size);
        }
    }
    T* Allocate() {
-        switch (allocation_type) {
+        T* obj = static_cast<T*>(BaseHeap::Allocate());
        case AllocationType::Host:
            // Fallback for cases where we do not yet support allocating guest memory from the slab
            // heap, such as for kernel memory regions.
            return new T;
-        case AllocationType::Guest:
+        if (obj != nullptr) [[likely]] {
-            T* obj = static_cast<T*>(AllocateImpl());
+            std::construct_at(obj);
            if (obj != nullptr) {
                new (obj) T();
            }
            return obj;
        }
-
+        return obj;
        UNREACHABLE_MSG("Invalid AllocationType {}", allocation_type);
        return nullptr;
    }
-    T* AllocateWithKernel(KernelCore& kernel) {
+    T* Allocate(KernelCore& kernel) {
-        switch (allocation_type) {
+        T* obj = static_cast<T*>(BaseHeap::Allocate());
        case AllocationType::Host:
            // Fallback for cases where we do not yet support allocating guest memory from the slab
            // heap, such as for kernel memory regions.
            return new T(kernel);
-        case AllocationType::Guest:
+        if (obj != nullptr) [[likely]] {
-            T* obj = static_cast<T*>(AllocateImpl());
+            std::construct_at(obj, kernel);
            if (obj != nullptr) {
                new (obj) T(kernel);
            }
            return obj;
        }
-
+        return obj;
        UNREACHABLE_MSG("Invalid AllocationType {}", allocation_type);
        return nullptr;
    }
    void Free(T* obj) {
-        switch (allocation_type) {
+        BaseHeap::Free(obj);
        case AllocationType::Host:
            // Fallback for cases where we do not yet support allocating guest memory from the slab
            // heap, such as for kernel memory regions.
            delete obj;
            return;
        case AllocationType::Guest:
            FreeImpl(obj);
            return;
        }
        UNREACHABLE_MSG("Invalid AllocationType {}", allocation_type);
    }
-    constexpr std::size_t GetObjectIndex(const T* obj) const {
+    size_t GetObjectIndex(const T* obj) const {
-        return GetObjectIndexImpl(obj);
+        return BaseHeap::GetObjectIndex(obj);
    }
 private:
    const AllocationType allocation_type;
 };
 } // namespace Kernel
--- a/src/core/hle/kernel/k_thread.cpp
+++ b/src/core/hle/kernel/k_thread.cpp
@ -210,7 +210,7 @@ ResultCode KThread::Initialize(KThreadFunction func, uintptr_t arg, VAddr user_s
    if (owner != nullptr) {
        // Setup the TLS, if needed.
        if (type == ThreadType::User) {
-            tls_address = owner->CreateTLSRegion();
+            R_TRY(owner->CreateThreadLocalRegion(std::addressof(tls_address)));
        }
        parent = owner;
@ -305,7 +305,7 @@ void KThread::Finalize() {
    // If the thread has a local region, delete it.
    if (tls_address != 0) {
-        parent->FreeTLSRegion(tls_address);
+        ASSERT(parent->DeleteThreadLocalRegion(tls_address).IsSuccess());
    }
    // Release any waiters.
@ -326,6 +326,9 @@ void KThread::Finalize() {
        }
    }
    // Release host emulation members.
    host_context.reset();
    // Perform inherited finalization.
    KSynchronizationObject::Finalize();
 }
--- a/src/core/hle/kernel/k_thread.h
+++ b/src/core/hle/kernel/k_thread.h
@ -656,7 +656,7 @@ private:
    static_assert(sizeof(SyncObjectBuffer::sync_objects) == sizeof(SyncObjectBuffer::handles));
    struct ConditionVariableComparator {
-        struct LightCompareType {
+        struct RedBlackKeyType {
            u64 cv_key{};
            s32 priority{};
@ -672,8 +672,8 @@ private:
        template <typename T>
        requires(
            std::same_as<T, KThread> ||
-            std::same_as<T, LightCompareType>) static constexpr int Compare(const T& lhs,
+            std::same_as<T, RedBlackKeyType>) static constexpr int Compare(const T& lhs,
-                                                                            const KThread& rhs) {
+                                                                           const KThread& rhs) {
            const u64 l_key = lhs.GetConditionVariableKey();
            const u64 r_key = rhs.GetConditionVariableKey();
--- a/src/core/hle/kernel/k_thread_local_page.cpp
+++ b/src/core/hle/kernel/k_thread_local_page.cpp
@ -0,0 +1,65 @@
 // Copyright 2022 yuzu Emulator Project
 // Licensed under GPLv2 or any later version
 // Refer to the license.txt file included.
 #include "common/scope_exit.h"
 #include "core/hle/kernel/k_memory_block.h"
 #include "core/hle/kernel/k_page_table.h"
 #include "core/hle/kernel/k_process.h"
 #include "core/hle/kernel/k_thread_local_page.h"
 #include "core/hle/kernel/kernel.h"
 namespace Kernel {
 ResultCode KThreadLocalPage::Initialize(KernelCore& kernel, KProcess* process) {
    // Set that this process owns us.
    m_owner = process;
    m_kernel = &kernel;
    // Allocate a new page.
    KPageBuffer* page_buf = KPageBuffer::Allocate(kernel);
    R_UNLESS(page_buf != nullptr, ResultOutOfMemory);
    auto page_buf_guard = SCOPE_GUARD({ KPageBuffer::Free(kernel, page_buf); });
    // Map the address in.
    const auto phys_addr = kernel.System().DeviceMemory().GetPhysicalAddr(page_buf);
    R_TRY(m_owner->PageTable().MapPages(std::addressof(m_virt_addr), 1, PageSize, phys_addr,
                                        KMemoryState::ThreadLocal,
                                        KMemoryPermission::UserReadWrite));
    // We succeeded.
    page_buf_guard.Cancel();
    return ResultSuccess;
 }
 ResultCode KThreadLocalPage::Finalize() {
    // Get the physical address of the page.
    const PAddr phys_addr = m_owner->PageTable().GetPhysicalAddr(m_virt_addr);
    ASSERT(phys_addr);
    // Unmap the page.
    R_TRY(m_owner->PageTable().UnmapPages(this->GetAddress(), 1, KMemoryState::ThreadLocal));
    // Free the page.
    KPageBuffer::Free(*m_kernel, KPageBuffer::FromPhysicalAddress(m_kernel->System(), phys_addr));
    return ResultSuccess;
 }
 VAddr KThreadLocalPage::Reserve() {
    for (size_t i = 0; i < m_is_region_free.size(); i++) {
        if (m_is_region_free[i]) {
            m_is_region_free[i] = false;
            return this->GetRegionAddress(i);
        }
    }
    return 0;
 }
 void KThreadLocalPage::Release(VAddr addr) {
    m_is_region_free[this->GetRegionIndex(addr)] = true;
 }
 } // namespace Kernel
--- a/src/core/hle/kernel/k_thread_local_page.h
+++ b/src/core/hle/kernel/k_thread_local_page.h
@ -0,0 +1,112 @@
 // Copyright 2022 yuzu Emulator Project
 // Licensed under GPLv2 or any later version
 // Refer to the license.txt file included.
 #pragma once
 #include <algorithm>
 #include <array>
 #include "common/alignment.h"
 #include "common/assert.h"
 #include "common/common_types.h"
 #include "common/intrusive_red_black_tree.h"
 #include "core/hle/kernel/k_page_buffer.h"
 #include "core/hle/kernel/memory_types.h"
 #include "core/hle/kernel/slab_helpers.h"
 #include "core/hle/result.h"
 namespace Kernel {
 class KernelCore;
 class KProcess;
 class KThreadLocalPage final : public Common::IntrusiveRedBlackTreeBaseNode<KThreadLocalPage>,
                               public KSlabAllocated<KThreadLocalPage> {
 public:
    static constexpr size_t RegionsPerPage = PageSize / Svc::ThreadLocalRegionSize;
    static_assert(RegionsPerPage > 0);
 public:
    constexpr explicit KThreadLocalPage(VAddr addr = {}) : m_virt_addr(addr) {
        m_is_region_free.fill(true);
    }
    constexpr VAddr GetAddress() const {
        return m_virt_addr;
    }
    ResultCode Initialize(KernelCore& kernel, KProcess* process);
    ResultCode Finalize();
    VAddr Reserve();
    void Release(VAddr addr);
    bool IsAllUsed() const {
        return std::ranges::all_of(m_is_region_free.begin(), m_is_region_free.end(),
                                   [](bool is_free) { return !is_free; });
    }
    bool IsAllFree() const {
        return std::ranges::all_of(m_is_region_free.begin(), m_is_region_free.end(),
                                   [](bool is_free) { return is_free; });
    }
    bool IsAnyUsed() const {
        return !this->IsAllFree();
    }
    bool IsAnyFree() const {
        return !this->IsAllUsed();
    }
 public:
    using RedBlackKeyType = VAddr;
    static constexpr RedBlackKeyType GetRedBlackKey(const RedBlackKeyType& v) {
        return v;
    }
    static constexpr RedBlackKeyType GetRedBlackKey(const KThreadLocalPage& v) {
        return v.GetAddress();
    }
    template <typename T>
    requires(std::same_as<T, KThreadLocalPage> ||
             std::same_as<T, RedBlackKeyType>) static constexpr int Compare(const T& lhs,
                                                                            const KThreadLocalPage&
                                                                                rhs) {
        const VAddr lval = GetRedBlackKey(lhs);
        const VAddr rval = GetRedBlackKey(rhs);
        if (lval < rval) {
            return -1;
        } else if (lval == rval) {
            return 0;
        } else {
            return 1;
        }
    }
 private:
    constexpr VAddr GetRegionAddress(size_t i) const {
        return this->GetAddress() + i * Svc::ThreadLocalRegionSize;
    }
    constexpr bool Contains(VAddr addr) const {
        return this->GetAddress() <= addr && addr < this->GetAddress() + PageSize;
    }
    constexpr size_t GetRegionIndex(VAddr addr) const {
        ASSERT(Common::IsAligned(addr, Svc::ThreadLocalRegionSize));
        ASSERT(this->Contains(addr));
        return (addr - this->GetAddress()) / Svc::ThreadLocalRegionSize;
    }
 private:
    VAddr m_virt_addr{};
    KProcess* m_owner{};
    KernelCore* m_kernel{};
    std::array<bool, RegionsPerPage> m_is_region_free{};
 };
 } // namespace Kernel
--- a/src/core/hle/kernel/kernel.cpp
+++ b/src/core/hle/kernel/kernel.cpp
@ -52,7 +52,7 @@ namespace Kernel {
 struct KernelCore::Impl {
    explicit Impl(Core::System& system_, KernelCore& kernel_)
-        : time_manager{system_}, object_list_container{kernel_},
+        : time_manager{system_},
          service_threads_manager{1, "yuzu:ServiceThreadsManager"}, system{system_} {}
    void SetMulticore(bool is_multi) {
@ -60,6 +60,7 @@ struct KernelCore::Impl {
    }
    void Initialize(KernelCore& kernel) {
        global_object_list_container = std::make_unique<KAutoObjectWithListContainer>(kernel);
        global_scheduler_context = std::make_unique<Kernel::GlobalSchedulerContext>(kernel);
        global_handle_table = std::make_unique<Kernel::KHandleTable>(kernel);
        global_handle_table->Initialize(KHandleTable::MaxTableSize);
@ -76,7 +77,7 @@ struct KernelCore::Impl {
        // Initialize kernel memory and resources.
        InitializeSystemResourceLimit(kernel, system.CoreTiming());
        InitializeMemoryLayout();
-        InitializePageSlab();
+        Init::InitializeKPageBufferSlabHeap(system);
        InitializeSchedulers();
        InitializeSuspendThreads();
        InitializePreemption(kernel);
@ -107,19 +108,6 @@ struct KernelCore::Impl {
        for (auto* server_port : server_ports_) {
            server_port->Close();
        }
        // Close all open server sessions.
        std::unordered_set<KServerSession*> server_sessions_;
        {
            std::lock_guard lk(server_sessions_lock);
            server_sessions_ = server_sessions;
            server_sessions.clear();
        }
        for (auto* server_session : server_sessions_) {
            server_session->Close();
        }
        // Ensure that the object list container is finalized and properly shutdown.
        object_list_container.Finalize();
        // Ensures all service threads gracefully shutdown.
        ClearServiceThreads();
@ -194,11 +182,15 @@ struct KernelCore::Impl {
        {
            std::lock_guard lk(registered_objects_lock);
            if (registered_objects.size()) {
-                LOG_WARNING(Kernel, "{} kernel objects were dangling on shutdown!",
+                LOG_DEBUG(Kernel, "{} kernel objects were dangling on shutdown!",
-                            registered_objects.size());
+                          registered_objects.size());
                registered_objects.clear();
            }
        }
        // Ensure that the object list container is finalized and properly shutdown.
        global_object_list_container->Finalize();
        global_object_list_container.reset();
    }
    void InitializePhysicalCores() {
@ -291,15 +283,16 @@ struct KernelCore::Impl {
    // Gets the dummy KThread for the caller, allocating a new one if this is the first time
    KThread* GetHostDummyThread() {
-        auto make_thread = [this]() {
+        auto initialize = [this](KThread* thread) {
            KThread* thread = KThread::Create(system.Kernel());
            ASSERT(KThread::InitializeDummyThread(thread).IsSuccess());
            thread->SetName(fmt::format("DummyThread:{}", GetHostThreadId()));
            return thread;
        };
-        thread_local KThread* saved_thread = make_thread();
+        thread_local auto raw_thread = KThread(system.Kernel());
-        return saved_thread;
+        thread_local auto thread = initialize(&raw_thread);
        return thread;
    }
    /// Registers a CPU core thread by allocating a host thread ID for it
@ -660,22 +653,6 @@ struct KernelCore::Impl {
                                    time_phys_addr, time_size, "Time:SharedMemory");
    }
    void InitializePageSlab() {
        // Allocate slab heaps
        user_slab_heap_pages =
            std::make_unique<KSlabHeap<Page>>(KSlabHeap<Page>::AllocationType::Guest);
        // TODO(ameerj): This should be derived, not hardcoded within the kernel
        constexpr u64 user_slab_heap_size{0x3de000};
        // Reserve slab heaps
        ASSERT(
            system_resource_limit->Reserve(LimitableResource::PhysicalMemory, user_slab_heap_size));
        // Initialize slab heap
        user_slab_heap_pages->Initialize(
            system.DeviceMemory().GetPointer(Core::DramMemoryMap::SlabHeapBase),
            user_slab_heap_size);
    }
    KClientPort* CreateNamedServicePort(std::string name) {
        auto search = service_interface_factory.find(name);
        if (search == service_interface_factory.end()) {
@ -713,7 +690,6 @@ struct KernelCore::Impl {
    }
    std::mutex server_ports_lock;
    std::mutex server_sessions_lock;
    std::mutex registered_objects_lock;
    std::mutex registered_in_use_objects_lock;
@ -737,14 +713,13 @@ struct KernelCore::Impl {
    // stores all the objects in place.
    std::unique_ptr<KHandleTable> global_handle_table;
-    KAutoObjectWithListContainer object_list_container;
+    std::unique_ptr<KAutoObjectWithListContainer> global_object_list_container;
    /// Map of named ports managed by the kernel, which can be retrieved using
    /// the ConnectToPort SVC.
    std::unordered_map<std::string, ServiceInterfaceFactory> service_interface_factory;
    NamedPortTable named_ports;
    std::unordered_set<KServerPort*> server_ports;
    std::unordered_set<KServerSession*> server_sessions;
    std::unordered_set<KAutoObject*> registered_objects;
    std::unordered_set<KAutoObject*> registered_in_use_objects;
@ -756,7 +731,6 @@ struct KernelCore::Impl {
    // Kernel memory management
    std::unique_ptr<KMemoryManager> memory_manager;
    std::unique_ptr<KSlabHeap<Page>> user_slab_heap_pages;
    // Shared memory for services
    Kernel::KSharedMemory* hid_shared_mem{};
@ -915,11 +889,11 @@ const Core::ExclusiveMonitor& KernelCore::GetExclusiveMonitor() const {
 }
 KAutoObjectWithListContainer& KernelCore::ObjectListContainer() {
-    return impl->object_list_container;
+    return *impl->global_object_list_container;
 }
 const KAutoObjectWithListContainer& KernelCore::ObjectListContainer() const {
-    return impl->object_list_container;
+    return *impl->global_object_list_container;
 }
 void KernelCore::InvalidateAllInstructionCaches() {
@ -949,16 +923,6 @@ KClientPort* KernelCore::CreateNamedServicePort(std::string name) {
    return impl->CreateNamedServicePort(std::move(name));
 }
 void KernelCore::RegisterServerSession(KServerSession* server_session) {
    std::lock_guard lk(impl->server_sessions_lock);
    impl->server_sessions.insert(server_session);
 }
 void KernelCore::UnregisterServerSession(KServerSession* server_session) {
    std::lock_guard lk(impl->server_sessions_lock);
    impl->server_sessions.erase(server_session);
 }
 void KernelCore::RegisterKernelObject(KAutoObject* object) {
    std::lock_guard lk(impl->registered_objects_lock);
    impl->registered_objects.insert(object);
@ -1031,14 +995,6 @@ const KMemoryManager& KernelCore::MemoryManager() const {
    return *impl->memory_manager;
 }
 KSlabHeap<Page>& KernelCore::GetUserSlabHeapPages() {
    return *impl->user_slab_heap_pages;
 }
 const KSlabHeap<Page>& KernelCore::GetUserSlabHeapPages() const {
    return *impl->user_slab_heap_pages;
 }
 Kernel::KSharedMemory& KernelCore::GetHidSharedMem() {
    return *impl->hid_shared_mem;
 }
--- a/src/core/hle/kernel/kernel.h
+++ b/src/core/hle/kernel/kernel.h
@ -43,6 +43,7 @@ class KHandleTable;
 class KLinkedListNode;
 class KMemoryLayout;
 class KMemoryManager;
 class KPageBuffer;
 class KPort;
 class KProcess;
 class KResourceLimit;
@ -52,6 +53,7 @@ class KSession;
 class KSharedMemory;
 class KSharedMemoryInfo;
 class KThread;
 class KThreadLocalPage;
 class KTransferMemory;
 class KWorkerTaskManager;
 class KWritableEvent;
@ -194,14 +196,6 @@ public:
    /// Opens a port to a service previously registered with RegisterNamedService.
    KClientPort* CreateNamedServicePort(std::string name);
    /// Registers a server session with the gobal emulation state, to be freed on shutdown. This is
    /// necessary because we do not emulate processes for HLE sessions.
    void RegisterServerSession(KServerSession* server_session);
    /// Unregisters a server session previously registered with RegisterServerSession when it was
    /// destroyed during the current emulation session.
    void UnregisterServerSession(KServerSession* server_session);
    /// Registers all kernel objects with the global emulation state, this is purely for tracking
    /// leaks after emulation has been shutdown.
    void RegisterKernelObject(KAutoObject* object);
@ -239,12 +233,6 @@ public:
    /// Gets the virtual memory manager for the kernel.
    const KMemoryManager& MemoryManager() const;
    /// Gets the slab heap allocated for user space pages.
    KSlabHeap<Page>& GetUserSlabHeapPages();
    /// Gets the slab heap allocated for user space pages.
    const KSlabHeap<Page>& GetUserSlabHeapPages() const;
    /// Gets the shared memory object for HID services.
    Kernel::KSharedMemory& GetHidSharedMem();
@ -336,6 +324,10 @@ public:
            return slab_heap_container->writeable_event;
        } else if constexpr (std::is_same_v<T, KCodeMemory>) {
            return slab_heap_container->code_memory;
        } else if constexpr (std::is_same_v<T, KPageBuffer>) {
            return slab_heap_container->page_buffer;
        } else if constexpr (std::is_same_v<T, KThreadLocalPage>) {
            return slab_heap_container->thread_local_page;
        }
    }
@ -397,6 +389,8 @@ private:
        KSlabHeap<KTransferMemory> transfer_memory;
        KSlabHeap<KWritableEvent> writeable_event;
        KSlabHeap<KCodeMemory> code_memory;
        KSlabHeap<KPageBuffer> page_buffer;
        KSlabHeap<KThreadLocalPage> thread_local_page;
    };
    std::unique_ptr<SlabHeapContainer> slab_heap_container;
--- a/src/core/hle/kernel/service_thread.cpp
+++ b/src/core/hle/kernel/service_thread.cpp
@ -49,12 +49,9 @@ ServiceThread::Impl::Impl(KernelCore& kernel, std::size_t num_threads, const std
                return;
            }
            // Allocate a dummy guest thread for this host thread.
            kernel.RegisterHostThread();
            // Ensure the dummy thread allocated for this host thread is closed on exit.
            auto* dummy_thread = kernel.GetCurrentEmuThread();
            SCOPE_EXIT({ dummy_thread->Close(); });
            while (true) {
                std::function<void()> task;
--- a/src/core/hle/kernel/slab_helpers.h
+++ b/src/core/hle/kernel/slab_helpers.h
@ -59,7 +59,7 @@ class KAutoObjectWithSlabHeapAndContainer : public Base {
 private:
    static Derived* Allocate(KernelCore& kernel) {
-        return kernel.SlabHeap<Derived>().AllocateWithKernel(kernel);
+        return kernel.SlabHeap<Derived>().Allocate(kernel);
    }
    static void Free(KernelCore& kernel, Derived* obj) {
--- a/src/core/hle/kernel/svc_types.h
+++ b/src/core/hle/kernel/svc_types.h
@ -96,4 +96,6 @@ constexpr inline s32 IdealCoreNoUpdate = -3;
 constexpr inline s32 LowestThreadPriority = 63;
 constexpr inline s32 HighestThreadPriority = 0;
 constexpr inline size_t ThreadLocalRegionSize = 0x200;
 } // namespace Kernel::Svc
--- a/src/core/hle/service/am/am.cpp
+++ b/src/core/hle/service/am/am.cpp
@ -980,7 +980,7 @@ private:
        LOG_DEBUG(Service_AM, "called");
        IPC::RequestParser rp{ctx};
-        applet->GetBroker().PushNormalDataFromGame(rp.PopIpcInterface<IStorage>());
+        applet->GetBroker().PushNormalDataFromGame(rp.PopIpcInterface<IStorage>().lock());
        IPC::ResponseBuilder rb{ctx, 2};
        rb.Push(ResultSuccess);
@ -1007,7 +1007,7 @@ private:
        LOG_DEBUG(Service_AM, "called");
        IPC::RequestParser rp{ctx};
-        applet->GetBroker().PushInteractiveDataFromGame(rp.PopIpcInterface<IStorage>());
+        applet->GetBroker().PushInteractiveDataFromGame(rp.PopIpcInterface<IStorage>().lock());
        ASSERT(applet->IsInitialized());
        applet->ExecuteInteractive();
--- a/src/core/hle/service/kernel_helpers.cpp
+++ b/src/core/hle/service/kernel_helpers.cpp
@ -17,21 +17,12 @@ namespace Service::KernelHelpers {
 ServiceContext::ServiceContext(Core::System& system_, std::string name_)
    : kernel(system_.Kernel()) {
    // Create a resource limit for the process.
    const auto physical_memory_size =
        kernel.MemoryManager().GetSize(Kernel::KMemoryManager::Pool::System);
    auto* resource_limit = Kernel::CreateResourceLimitForProcess(system_, physical_memory_size);
    // Create the process.
    process = Kernel::KProcess::Create(kernel);
    ASSERT(Kernel::KProcess::Initialize(process, system_, std::move(name_),
                                        Kernel::KProcess::ProcessType::KernelInternal,
-                                        resource_limit)
+                                        kernel.GetSystemResourceLimit())
               .IsSuccess());
    // Close reference to our resource limit, as the process opens one.
    resource_limit->Close();
 }
 ServiceContext::~ServiceContext() {
--- a/src/core/hle/service/sm/sm.cpp
+++ b/src/core/hle/service/sm/sm.cpp
@ -81,6 +81,8 @@ ResultVal<Kernel::KPort*> ServiceManager::GetServicePort(const std::string& name
    }
    auto* port = Kernel::KPort::Create(kernel);
    SCOPE_EXIT({ port->Close(); });
    port->Initialize(ServerSessionCountMax, false, name);
    auto handler = it->second;
    port->GetServerPort().SetSessionHandler(std::move(handler));