hle: kernel: Use host memory allocations for KSlabMemory.

- There are some issues with the current workaround, we will just use host memory until we have a complete kernel memory implementation.
2021-05-20 18:15:59 -07:00 · 2021-05-20 18:15:59 -07:00 · b4fc2e52a2
parent 7331bb9d8d
commit b4fc2e52a2
4 changed files with 20 additions and 174 deletions
--- a/src/core/hle/kernel/init/init_slab_setup.cpp
+++ b/src/core/hle/kernel/init/init_slab_setup.cpp
@ -70,14 +70,22 @@ constexpr size_t SlabCountExtraKThread = 160;
 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
    // the pointer to emulated memory to pass along. Until then, KSlabHeap will just allocate/free
    // host memory.
    void* backing_kernel_memory{};
    if (size > 0) {
        const KMemoryRegion* region = memory_layout.FindVirtual(start + size - 1);
        ASSERT(region != nullptr);
        ASSERT(region->IsDerivedFrom(KMemoryRegionType_KernelSlab));
-        T::InitializeSlabHeap(system.Kernel(), system.Memory().GetKernelBuffer(start, size), size);
+        T::InitializeSlabHeap(system.Kernel(), backing_kernel_memory, size);
    }
    return start + size;
--- a/src/core/hle/kernel/k_slab_heap.h
+++ b/src/core/hle/kernel/k_slab_heap.h
@ -4,165 +4,33 @@
 #pragma once
 #include <atomic>
 #include "common/assert.h"
 #include "common/common_types.h"
 namespace Kernel {
-namespace impl {
+class KernelCore;
-class KSlabHeapImpl final : NonCopyable {
+/// This is a placeholder class to manage slab heaps for kernel objects. For now, we just allocate
-public:
+/// these with new/delete, but this can be re-implemented later to allocate these in emulated
-    struct Node {
+/// memory.
        Node* next{};
    };
    constexpr KSlabHeapImpl() = default;
    void Initialize(std::size_t size) {
        ASSERT(head == nullptr);
        obj_size = size;
    }
    constexpr std::size_t GetObjectSize() const {
        return obj_size;
    }
    Node* GetHead() const {
        return head;
    }
    void* Allocate() {
        Node* ret = head.load();
        do {
            if (ret == nullptr) {
                break;
            }
        } while (!head.compare_exchange_weak(ret, ret->next));
        return ret;
    }
    void Free(void* obj) {
        Node* node = static_cast<Node*>(obj);
        Node* cur_head = head.load();
        do {
            node->next = cur_head;
        } while (!head.compare_exchange_weak(cur_head, node));
    }
 private:
    std::atomic<Node*> head{};
    std::size_t obj_size{};
 };
 } // namespace impl
 class KSlabHeapBase : NonCopyable {
 public:
    constexpr KSlabHeapBase() = default;
    constexpr bool Contains(uintptr_t addr) const {
        return start <= addr && addr < end;
    }
    constexpr std::size_t GetSlabHeapSize() const {
        return (end - start) / GetObjectSize();
    }
    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
        impl.Initialize(obj_size);
        // Set our tracking variables
        const std::size_t num_obj = (memory_size / obj_size);
        start = reinterpret_cast<uintptr_t>(memory);
        end = start + num_obj * obj_size;
        peak = start;
        // Free the objects
        u8* cur = reinterpret_cast<u8*>(end);
        for (std::size_t i{}; i < num_obj; i++) {
            cur -= obj_size;
            impl.Free(cur);
        }
    }
 private:
    using Impl = impl::KSlabHeapImpl;
    Impl impl;
    uintptr_t peak{};
    uintptr_t start{};
    uintptr_t end{};
 };
 template <typename T>
-class KSlabHeap final : public KSlabHeapBase {
+class KSlabHeap final : NonCopyable {
 public:
-    constexpr KSlabHeap() : KSlabHeapBase() {}
+    KSlabHeap() = default;
-    void Initialize(void* memory, std::size_t memory_size) {
+    void Initialize([[maybe_unused]] void* memory, [[maybe_unused]] std::size_t memory_size) {
-        InitializeImpl(sizeof(T), memory, memory_size);
+        // Placeholder that should initialize the backing slab heap implementation.
    }
    T* Allocate() {
-        T* obj = static_cast<T*>(AllocateImpl());
+        return new T();
        if (obj != nullptr) {
            new (obj) T();
        }
        return obj;
    }
    T* AllocateWithKernel(KernelCore& kernel) {
-        T* obj = static_cast<T*>(AllocateImpl());
+        return new T(kernel);
        if (obj != nullptr) {
            new (obj) T(kernel);
        }
        return obj;
    }
    void Free(T* obj) {
-        FreeImpl(obj);
+        delete obj;
    }
    constexpr std::size_t GetObjectIndex(const T* obj) const {
        return GetObjectIndexImpl(obj);
    }
 };
--- a/src/core/memory.cpp
+++ b/src/core/memory.cpp
@ -82,22 +82,6 @@ struct Memory::Impl {
        return nullptr;
    }
    u8* GetKernelBuffer(VAddr start_vaddr, size_t size) {
        // TODO(bunnei): This is just a workaround until we have kernel memory layout mapped &
        // managed. Until then, we use this to allocate and access kernel memory regions.
        auto search = kernel_memory_regions.find(start_vaddr);
        if (search != kernel_memory_regions.end()) {
            return search->second.get();
        }
        std::unique_ptr<u8[]> new_memory_region{new u8[size]};
        u8* raw_ptr = new_memory_region.get();
        kernel_memory_regions[start_vaddr] = std::move(new_memory_region);
        return raw_ptr;
    }
    u8 Read8(const VAddr addr) {
        return Read<u8>(addr);
    }
@ -727,7 +711,6 @@ struct Memory::Impl {
    }
    Common::PageTable* current_page_table = nullptr;
    std::unordered_map<VAddr, std::unique_ptr<u8[]>> kernel_memory_regions;
    Core::System& system;
 };
@ -765,10 +748,6 @@ u8* Memory::GetPointer(VAddr vaddr) {
    return impl->GetPointer(vaddr);
 }
 u8* Memory::GetKernelBuffer(VAddr start_vaddr, size_t size) {
    return impl->GetKernelBuffer(start_vaddr, size);
 }
 const u8* Memory::GetPointer(VAddr vaddr) const {
    return impl->GetPointer(vaddr);
 }
--- a/src/core/memory.h
+++ b/src/core/memory.h
@ -121,15 +121,6 @@ public:
     */
    u8* GetPointer(VAddr vaddr);
    /**
     * Gets a pointer to the start of a kernel heap allocated memory region. Will allocate one if it
     * does not already exist.
     *
     * @param start_vaddr Start virtual address for the memory region.
     * @param size Size of the memory region.
     */
    u8* GetKernelBuffer(VAddr start_vaddr, size_t size);
    template <typename T>
    T* GetPointer(VAddr vaddr) {
        return reinterpret_cast<T*>(GetPointer(vaddr));