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Merge pull request #12579 from FernandoS27/smmu

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Core: Implement Device Mapping & GPU SMMU
This commit is contained in:
liamwhite
2024-01-22 10:55:39 -05:00
committed by GitHub
parent 8d708b0c79 748465f5a5
commit 8bd10473d6
121 changed files with 2742 additions and 1415 deletions
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4
src/core/CMakeLists.txt
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@ -37,6 +37,8 @@ add_library(core STATIC
debugger/gdbstub_arch.h
debugger/gdbstub.cpp
debugger/gdbstub.h
device_memory_manager.h
device_memory_manager.inc
device_memory.cpp
device_memory.h
file_sys/fssystem/fs_i_storage.h
@ -609,6 +611,8 @@ add_library(core STATIC
hle/service/ns/pdm_qry.h
hle/service/nvdrv/core/container.cpp
hle/service/nvdrv/core/container.h
hle/service/nvdrv/core/heap_mapper.cpp
hle/service/nvdrv/core/heap_mapper.h
hle/service/nvdrv/core/nvmap.cpp
hle/service/nvdrv/core/nvmap.h
hle/service/nvdrv/core/syncpoint_manager.cpp

14
src/core/core.cpp
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@ -28,6 +28,7 @@
#include "core/file_sys/savedata_factory.h"
#include "core/file_sys/vfs_concat.h"
#include "core/file_sys/vfs_real.h"
#include "core/gpu_dirty_memory_manager.h"
#include "core/hle/kernel/k_memory_manager.h"
#include "core/hle/kernel/k_process.h"
#include "core/hle/kernel/k_resource_limit.h"
@ -565,6 +566,9 @@ struct System::Impl {
std::array<u64, Core::Hardware::NUM_CPU_CORES> dynarmic_ticks{};
std::array<MicroProfileToken, Core::Hardware::NUM_CPU_CORES> microprofile_cpu{};
std::array<Core::GPUDirtyMemoryManager, Core::Hardware::NUM_CPU_CORES>
gpu_dirty_memory_managers;
std::deque<std::vector<u8>> user_channel;
};
@ -651,8 +655,14 @@ size_t System::GetCurrentHostThreadID() const {
return impl->kernel.GetCurrentHostThreadID();
}
void System::GatherGPUDirtyMemory(std::function<void(VAddr, size_t)>& callback) {
return this->ApplicationProcess()->GatherGPUDirtyMemory(callback);
std::span<GPUDirtyMemoryManager> System::GetGPUDirtyMemoryManager() {
return impl->gpu_dirty_memory_managers;
}
void System::GatherGPUDirtyMemory(std::function<void(PAddr, size_t)>& callback) {
for (auto& manager : impl->gpu_dirty_memory_managers) {
manager.Gather(callback);
}
}
PerfStatsResults System::GetAndResetPerfStats() {

6
src/core/core.h
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@ -8,6 +8,7 @@
#include <functional>
#include <memory>
#include <mutex>
#include <span>
#include <string>
#include <vector>
@ -116,6 +117,7 @@ class CpuManager;
class Debugger;
class DeviceMemory;
class ExclusiveMonitor;
class GPUDirtyMemoryManager;
class PerfStats;
class Reporter;
class SpeedLimiter;
@ -224,7 +226,9 @@ public:
/// Prepare the core emulation for a reschedule
void PrepareReschedule(u32 core_index);
void GatherGPUDirtyMemory(std::function<void(VAddr, size_t)>& callback);
std::span<GPUDirtyMemoryManager> GetGPUDirtyMemoryManager();
void GatherGPUDirtyMemory(std::function<void(PAddr, size_t)>& callback);
[[nodiscard]] size_t GetCurrentHostThreadID() const;

16
src/core/device_memory.h
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@ -31,6 +31,12 @@ public:
DramMemoryMap::Base;
}
template <typename T>
PAddr GetRawPhysicalAddr(const T* ptr) const {
return static_cast<PAddr>(reinterpret_cast<uintptr_t>(ptr) -
reinterpret_cast<uintptr_t>(buffer.BackingBasePointer()));
}
template <typename T>
T* GetPointer(Common::PhysicalAddress addr) {
return reinterpret_cast<T*>(buffer.BackingBasePointer() +
@ -43,6 +49,16 @@ public:
(GetInteger(addr) - DramMemoryMap::Base));
}
template <typename T>
T* GetPointerFromRaw(PAddr addr) {
return reinterpret_cast<T*>(buffer.BackingBasePointer() + addr);
}
template <typename T>
const T* GetPointerFromRaw(PAddr addr) const {
return reinterpret_cast<T*>(buffer.BackingBasePointer() + addr);
}
Common::HostMemory buffer;
};

211
src/core/device_memory_manager.h Normal file
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@ -0,0 +1,211 @@
// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#pragma once
#include <array>
#include <atomic>
#include <deque>
#include <memory>
#include <mutex>
#include "common/common_types.h"
#include "common/scratch_buffer.h"
#include "common/virtual_buffer.h"
namespace Core {
constexpr size_t DEVICE_PAGEBITS = 12ULL;
constexpr size_t DEVICE_PAGESIZE = 1ULL << DEVICE_PAGEBITS;
constexpr size_t DEVICE_PAGEMASK = DEVICE_PAGESIZE - 1ULL;
class DeviceMemory;
namespace Memory {
class Memory;
}
template <typename DTraits>
struct DeviceMemoryManagerAllocator;
struct Asid {
size_t id;
};
template <typename Traits>
class DeviceMemoryManager {
using DeviceInterface = typename Traits::DeviceInterface;
using DeviceMethods = typename Traits::DeviceMethods;
public:
DeviceMemoryManager(const DeviceMemory& device_memory);
~DeviceMemoryManager();
void BindInterface(DeviceInterface* device_inter);
DAddr Allocate(size_t size);
void AllocateFixed(DAddr start, size_t size);
void Free(DAddr start, size_t size);
void Map(DAddr address, VAddr virtual_address, size_t size, Asid asid, bool track = false);
void Unmap(DAddr address, size_t size);
void TrackContinuityImpl(DAddr address, VAddr virtual_address, size_t size, Asid asid);
void TrackContinuity(DAddr address, VAddr virtual_address, size_t size, Asid asid) {
std::scoped_lock lk(mapping_guard);
TrackContinuityImpl(address, virtual_address, size, asid);
}
// Write / Read
template <typename T>
T* GetPointer(DAddr address);
template <typename T>
const T* GetPointer(DAddr address) const;
template <typename Func>
void ApplyOpOnPAddr(PAddr address, Common::ScratchBuffer<u32>& buffer, Func&& operation) {
DAddr subbits = static_cast<DAddr>(address & page_mask);
const u32 base = compressed_device_addr[(address >> page_bits)];
if ((base >> MULTI_FLAG_BITS) == 0) [[likely]] {
const DAddr d_address = (static_cast<DAddr>(base) << page_bits) + subbits;
operation(d_address);
return;
}
InnerGatherDeviceAddresses(buffer, address);
for (u32 value : buffer) {
operation((static_cast<DAddr>(value) << page_bits) + subbits);
}
}
template <typename Func>
void ApplyOpOnPointer(const u8* p, Common::ScratchBuffer<u32>& buffer, Func&& operation) {
PAddr address = GetRawPhysicalAddr<u8>(p);
ApplyOpOnPAddr(address, buffer, operation);
}
PAddr GetPhysicalRawAddressFromDAddr(DAddr address) const {
PAddr subbits = static_cast<PAddr>(address & page_mask);
auto paddr = compressed_physical_ptr[(address >> page_bits)];
if (paddr == 0) {
return 0;
}
return (static_cast<PAddr>(paddr - 1) << page_bits) + subbits;
}
template <typename T>
void Write(DAddr address, T value);
template <typename T>
T Read(DAddr address) const;
u8* GetSpan(const DAddr src_addr, const std::size_t size);
const u8* GetSpan(const DAddr src_addr, const std::size_t size) const;
void ReadBlock(DAddr address, void* dest_pointer, size_t size);
void ReadBlockUnsafe(DAddr address, void* dest_pointer, size_t size);
void WriteBlock(DAddr address, const void* src_pointer, size_t size);
void WriteBlockUnsafe(DAddr address, const void* src_pointer, size_t size);
Asid RegisterProcess(Memory::Memory* memory);
void UnregisterProcess(Asid id);
void UpdatePagesCachedCount(DAddr addr, size_t size, s32 delta);
static constexpr size_t AS_BITS = Traits::device_virtual_bits;
private:
static constexpr size_t device_virtual_bits = Traits::device_virtual_bits;
static constexpr size_t device_as_size = 1ULL << device_virtual_bits;
static constexpr size_t physical_min_bits = 32;
static constexpr size_t physical_max_bits = 33;
static constexpr size_t page_bits = 12;
static constexpr size_t page_size = 1ULL << page_bits;
static constexpr size_t page_mask = page_size - 1ULL;
static constexpr u32 physical_address_base = 1U << page_bits;
static constexpr u32 MULTI_FLAG_BITS = 31;
static constexpr u32 MULTI_FLAG = 1U << MULTI_FLAG_BITS;
static constexpr u32 MULTI_MASK = ~MULTI_FLAG;
template <typename T>
T* GetPointerFromRaw(PAddr addr) {
return reinterpret_cast<T*>(physical_base + addr);
}
template <typename T>
const T* GetPointerFromRaw(PAddr addr) const {
return reinterpret_cast<T*>(physical_base + addr);
}
template <typename T>
PAddr GetRawPhysicalAddr(const T* ptr) const {
return static_cast<PAddr>(reinterpret_cast<uintptr_t>(ptr) - physical_base);
}
void WalkBlock(const DAddr addr, const std::size_t size, auto on_unmapped, auto on_memory,
auto increment);
void InnerGatherDeviceAddresses(Common::ScratchBuffer<u32>& buffer, PAddr address);
std::unique_ptr<DeviceMemoryManagerAllocator<Traits>> impl;
const uintptr_t physical_base;
DeviceInterface* device_inter;
Common::VirtualBuffer<u32> compressed_physical_ptr;
Common::VirtualBuffer<u32> compressed_device_addr;
Common::VirtualBuffer<u32> continuity_tracker;
// Process memory interfaces
std::deque<size_t> id_pool;
std::deque<Memory::Memory*> registered_processes;
// Memory protection management
static constexpr size_t guest_max_as_bits = 39;
static constexpr size_t guest_as_size = 1ULL << guest_max_as_bits;
static constexpr size_t guest_mask = guest_as_size - 1ULL;
static constexpr size_t asid_start_bit = guest_max_as_bits;
std::pair<Asid, VAddr> ExtractCPUBacking(size_t page_index) {
auto content = cpu_backing_address[page_index];
const VAddr address = content & guest_mask;
const Asid asid{static_cast<size_t>(content >> asid_start_bit)};
return std::make_pair(asid, address);
}
void InsertCPUBacking(size_t page_index, VAddr address, Asid asid) {
cpu_backing_address[page_index] = address | (asid.id << asid_start_bit);
}
Common::VirtualBuffer<VAddr> cpu_backing_address;
static constexpr size_t subentries = 8 / sizeof(u8);
static constexpr size_t subentries_mask = subentries - 1;
class CounterEntry final {
public:
CounterEntry() = default;
std::atomic_uint8_t& Count(std::size_t page) {
return values[page & subentries_mask];
}
const std::atomic_uint8_t& Count(std::size_t page) const {
return values[page & subentries_mask];
}
private:
std::array<std::atomic_uint8_t, subentries> values{};
};
static_assert(sizeof(CounterEntry) == subentries * sizeof(u8),
"CounterEntry should be 8 bytes!");
static constexpr size_t num_counter_entries =
(1ULL << (device_virtual_bits - page_bits)) / subentries;
using CachedPages = std::array<CounterEntry, num_counter_entries>;
std::unique_ptr<CachedPages> cached_pages;
std::mutex counter_guard;
std::mutex mapping_guard;
};
} // namespace Core

582
src/core/device_memory_manager.inc Normal file
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@ -0,0 +1,582 @@
// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#include <atomic>
#include <limits>
#include <memory>
#include <type_traits>
#include "common/address_space.h"
#include "common/address_space.inc"
#include "common/alignment.h"
#include "common/assert.h"
#include "common/div_ceil.h"
#include "common/scope_exit.h"
#include "common/settings.h"
#include "core/device_memory.h"
#include "core/device_memory_manager.h"
#include "core/memory.h"
namespace Core {
namespace {
class MultiAddressContainer {
public:
MultiAddressContainer() = default;
~MultiAddressContainer() = default;
void GatherValues(u32 start_entry, Common::ScratchBuffer<u32>& buffer) {
buffer.resize(8);
buffer.resize(0);
size_t index = 0;
const auto add_value = [&](u32 value) {
buffer[index] = value;
index++;
buffer.resize(index);
};
u32 iter_entry = start_entry;
Entry* current = &storage[iter_entry - 1];
add_value(current->value);
while (current->next_entry != 0) {
iter_entry = current->next_entry;
current = &storage[iter_entry - 1];
add_value(current->value);
}
}
u32 Register(u32 value) {
return RegisterImplementation(value);
}
void Register(u32 value, u32 start_entry) {
auto entry_id = RegisterImplementation(value);
u32 iter_entry = start_entry;
Entry* current = &storage[iter_entry - 1];
while (current->next_entry != 0) {
iter_entry = current->next_entry;
current = &storage[iter_entry - 1];
}
current->next_entry = entry_id;
}
std::pair<bool, u32> Unregister(u32 value, u32 start_entry) {
u32 iter_entry = start_entry;
Entry* previous{};
Entry* current = &storage[iter_entry - 1];
Entry* next{};
bool more_than_one_remaining = false;
u32 result_start{start_entry};
size_t count = 0;
while (current->value != value) {
count++;
previous = current;
iter_entry = current->next_entry;
current = &storage[iter_entry - 1];
}
// Find next
u32 next_entry = current->next_entry;
if (next_entry != 0) {
next = &storage[next_entry - 1];
more_than_one_remaining = next->next_entry != 0 || previous != nullptr;
}
if (previous) {
previous->next_entry = next_entry;
} else {
result_start = next_entry;
}
free_entries.emplace_back(iter_entry);
return std::make_pair(more_than_one_remaining || count > 1, result_start);
}
u32 ReleaseEntry(u32 start_entry) {
Entry* current = &storage[start_entry - 1];
free_entries.emplace_back(start_entry);
return current->value;
}
private:
u32 RegisterImplementation(u32 value) {
auto entry_id = GetNewEntry();
auto& entry = storage[entry_id - 1];
entry.next_entry = 0;
entry.value = value;
return entry_id;
}
u32 GetNewEntry() {
if (!free_entries.empty()) {
u32 result = free_entries.front();
free_entries.pop_front();
return result;
}
storage.emplace_back();
u32 new_entry = static_cast<u32>(storage.size());
return new_entry;
}
struct Entry {
u32 next_entry{};
u32 value{};
};
std::deque<Entry> storage;
std::deque<u32> free_entries;
};
struct EmptyAllocator {
EmptyAllocator([[maybe_unused]] DAddr address) {}
};
} // namespace
template <typename DTraits>
struct DeviceMemoryManagerAllocator {
static constexpr size_t device_virtual_bits = DTraits::device_virtual_bits;
static constexpr DAddr first_address = 1ULL << Memory::YUZU_PAGEBITS;
static constexpr DAddr max_device_area = 1ULL << device_virtual_bits;
DeviceMemoryManagerAllocator() : main_allocator(first_address) {}
Common::FlatAllocator<DAddr, 0, device_virtual_bits> main_allocator;
MultiAddressContainer multi_dev_address;
/// Returns true when vaddr -> vaddr+size is fully contained in the buffer
template <bool pin_area>
[[nodiscard]] bool IsInBounds(VAddr addr, u64 size) const noexcept {
return addr >= 0 && addr + size <= max_device_area;
}
DAddr Allocate(size_t size) {
return main_allocator.Allocate(size);
}
void AllocateFixed(DAddr b_address, size_t b_size) {
main_allocator.AllocateFixed(b_address, b_size);
}
void Free(DAddr b_address, size_t b_size) {
main_allocator.Free(b_address, b_size);
}
};
template <typename Traits>
DeviceMemoryManager<Traits>::DeviceMemoryManager(const DeviceMemory& device_memory_)
: physical_base{reinterpret_cast<const uintptr_t>(device_memory_.buffer.BackingBasePointer())},
device_inter{nullptr}, compressed_physical_ptr(device_as_size >> Memory::YUZU_PAGEBITS),
compressed_device_addr(1ULL << ((Settings::values.memory_layout_mode.GetValue() ==
Settings::MemoryLayout::Memory_4Gb
? physical_min_bits
: physical_max_bits) -
Memory::YUZU_PAGEBITS)),
continuity_tracker(device_as_size >> Memory::YUZU_PAGEBITS),
cpu_backing_address(device_as_size >> Memory::YUZU_PAGEBITS) {
impl = std::make_unique<DeviceMemoryManagerAllocator<Traits>>();
cached_pages = std::make_unique<CachedPages>();
const size_t total_virtual = device_as_size >> Memory::YUZU_PAGEBITS;
for (size_t i = 0; i < total_virtual; i++) {
compressed_physical_ptr[i] = 0;
continuity_tracker[i] = 1;
cpu_backing_address[i] = 0;
}
const size_t total_phys = 1ULL << ((Settings::values.memory_layout_mode.GetValue() ==
Settings::MemoryLayout::Memory_4Gb
? physical_min_bits
: physical_max_bits) -
Memory::YUZU_PAGEBITS);
for (size_t i = 0; i < total_phys; i++) {
compressed_device_addr[i] = 0;
}
}
template <typename Traits>
DeviceMemoryManager<Traits>::~DeviceMemoryManager() = default;
template <typename Traits>
void DeviceMemoryManager<Traits>::BindInterface(DeviceInterface* device_inter_) {
device_inter = device_inter_;
}
template <typename Traits>
DAddr DeviceMemoryManager<Traits>::Allocate(size_t size) {
return impl->Allocate(size);
}
template <typename Traits>
void DeviceMemoryManager<Traits>::AllocateFixed(DAddr start, size_t size) {
return impl->AllocateFixed(start, size);
}
template <typename Traits>
void DeviceMemoryManager<Traits>::Free(DAddr start, size_t size) {
impl->Free(start, size);
}
template <typename Traits>
void DeviceMemoryManager<Traits>::Map(DAddr address, VAddr virtual_address, size_t size,
Asid asid, bool track) {
Core::Memory::Memory* process_memory = registered_processes[asid.id];
size_t start_page_d = address >> Memory::YUZU_PAGEBITS;
size_t num_pages = Common::AlignUp(size, Memory::YUZU_PAGESIZE) >> Memory::YUZU_PAGEBITS;
std::scoped_lock lk(mapping_guard);
for (size_t i = 0; i < num_pages; i++) {
const VAddr new_vaddress = virtual_address + i * Memory::YUZU_PAGESIZE;
auto* ptr = process_memory->GetPointerSilent(Common::ProcessAddress(new_vaddress));
if (ptr == nullptr) [[unlikely]] {
compressed_physical_ptr[start_page_d + i] = 0;
continue;
}
auto phys_addr = static_cast<u32>(GetRawPhysicalAddr(ptr) >> Memory::YUZU_PAGEBITS) + 1U;
compressed_physical_ptr[start_page_d + i] = phys_addr;
InsertCPUBacking(start_page_d + i, new_vaddress, asid);
const u32 base_dev = compressed_device_addr[phys_addr - 1U];
const u32 new_dev = static_cast<u32>(start_page_d + i);
if (base_dev == 0) [[likely]] {
compressed_device_addr[phys_addr - 1U] = new_dev;
continue;
}
u32 start_id = base_dev & MULTI_MASK;
if ((base_dev >> MULTI_FLAG_BITS) == 0) {
start_id = impl->multi_dev_address.Register(base_dev);
compressed_device_addr[phys_addr - 1U] = MULTI_FLAG | start_id;
}
impl->multi_dev_address.Register(new_dev, start_id);
}
if (track) {
TrackContinuityImpl(address, virtual_address, size, asid);
}
}
template <typename Traits>
void DeviceMemoryManager<Traits>::Unmap(DAddr address, size_t size) {
size_t start_page_d = address >> Memory::YUZU_PAGEBITS;
size_t num_pages = Common::AlignUp(size, Memory::YUZU_PAGESIZE) >> Memory::YUZU_PAGEBITS;
device_inter->InvalidateRegion(address, size);
std::scoped_lock lk(mapping_guard);
for (size_t i = 0; i < num_pages; i++) {
auto phys_addr = compressed_physical_ptr[start_page_d + i];
compressed_physical_ptr[start_page_d + i] = 0;
cpu_backing_address[start_page_d + i] = 0;
if (phys_addr != 0) [[likely]] {
const u32 base_dev = compressed_device_addr[phys_addr - 1U];
if ((base_dev >> MULTI_FLAG_BITS) == 0) [[likely]] {
compressed_device_addr[phys_addr - 1] = 0;
continue;
}
const auto [more_entries, new_start] = impl->multi_dev_address.Unregister(
static_cast<u32>(start_page_d + i), base_dev & MULTI_MASK);
if (!more_entries) {
compressed_device_addr[phys_addr - 1] =
impl->multi_dev_address.ReleaseEntry(new_start);
continue;
}
compressed_device_addr[phys_addr - 1] = new_start | MULTI_FLAG;
}
}
}
template <typename Traits>
void DeviceMemoryManager<Traits>::TrackContinuityImpl(DAddr address, VAddr virtual_address,
size_t size, Asid asid) {
Core::Memory::Memory* process_memory = registered_processes[asid.id];
size_t start_page_d = address >> Memory::YUZU_PAGEBITS;
size_t num_pages = Common::AlignUp(size, Memory::YUZU_PAGESIZE) >> Memory::YUZU_PAGEBITS;
uintptr_t last_ptr = 0;
size_t page_count = 1;
for (size_t i = num_pages; i > 0; i--) {
size_t index = i - 1;
const VAddr new_vaddress = virtual_address + index * Memory::YUZU_PAGESIZE;
const uintptr_t new_ptr = reinterpret_cast<uintptr_t>(
process_memory->GetPointerSilent(Common::ProcessAddress(new_vaddress)));
if (new_ptr + page_size == last_ptr) {
page_count++;
} else {
page_count = 1;
}
last_ptr = new_ptr;
continuity_tracker[start_page_d + index] = static_cast<u32>(page_count);
}
}
template <typename Traits>
u8* DeviceMemoryManager<Traits>::GetSpan(const DAddr src_addr, const std::size_t size) {
size_t page_index = src_addr >> page_bits;
size_t subbits = src_addr & page_mask;
if ((static_cast<size_t>(continuity_tracker[page_index]) << page_bits) >= size + subbits) {
return GetPointer<u8>(src_addr);
}
return nullptr;
}
template <typename Traits>
const u8* DeviceMemoryManager<Traits>::GetSpan(const DAddr src_addr, const std::size_t size) const {
size_t page_index = src_addr >> page_bits;
size_t subbits = src_addr & page_mask;
if ((static_cast<size_t>(continuity_tracker[page_index]) << page_bits) >= size + subbits) {
return GetPointer<u8>(src_addr);
}
return nullptr;
}
template <typename Traits>
void DeviceMemoryManager<Traits>::InnerGatherDeviceAddresses(Common::ScratchBuffer<u32>& buffer,
PAddr address) {
size_t phys_addr = address >> page_bits;
std::scoped_lock lk(mapping_guard);
u32 backing = compressed_device_addr[phys_addr];
if ((backing >> MULTI_FLAG_BITS) != 0) {
impl->multi_dev_address.GatherValues(backing & MULTI_MASK, buffer);
return;
}
buffer.resize(1);
buffer[0] = backing;
}
template <typename Traits>
template <typename T>
T* DeviceMemoryManager<Traits>::GetPointer(DAddr address) {
const size_t index = address >> Memory::YUZU_PAGEBITS;
const size_t offset = address & Memory::YUZU_PAGEMASK;
auto phys_addr = compressed_physical_ptr[index];
if (phys_addr == 0) [[unlikely]] {
return nullptr;
}
return GetPointerFromRaw<T>((static_cast<PAddr>(phys_addr - 1) << Memory::YUZU_PAGEBITS) +
offset);
}
template <typename Traits>
template <typename T>
const T* DeviceMemoryManager<Traits>::GetPointer(DAddr address) const {
const size_t index = address >> Memory::YUZU_PAGEBITS;
const size_t offset = address & Memory::YUZU_PAGEMASK;
auto phys_addr = compressed_physical_ptr[index];
if (phys_addr == 0) [[unlikely]] {
return nullptr;
}
return GetPointerFromRaw<T>((static_cast<PAddr>(phys_addr - 1) << Memory::YUZU_PAGEBITS) +
offset);
}
template <typename Traits>
template <typename T>
void DeviceMemoryManager<Traits>::Write(DAddr address, T value) {
T* ptr = GetPointer<T>(address);
if (!ptr) [[unlikely]] {
return;
}
std::memcpy(ptr, &value, sizeof(T));
}
template <typename Traits>
template <typename T>
T DeviceMemoryManager<Traits>::Read(DAddr address) const {
const T* ptr = GetPointer<T>(address);
T result{};
if (!ptr) [[unlikely]] {
return result;
}
std::memcpy(&result, ptr, sizeof(T));
return result;
}
template <typename Traits>
void DeviceMemoryManager<Traits>::WalkBlock(DAddr addr, std::size_t size, auto on_unmapped,
auto on_memory, auto increment) {
std::size_t remaining_size = size;
std::size_t page_index = addr >> Memory::YUZU_PAGEBITS;
std::size_t page_offset = addr & Memory::YUZU_PAGEMASK;
while (remaining_size) {
const size_t next_pages = static_cast<std::size_t>(continuity_tracker[page_index]);
const std::size_t copy_amount =
std::min((next_pages << Memory::YUZU_PAGEBITS) - page_offset, remaining_size);
const auto current_vaddr =
static_cast<u64>((page_index << Memory::YUZU_PAGEBITS) + page_offset);
SCOPE_EXIT({
page_index += next_pages;
page_offset = 0;
increment(copy_amount);
remaining_size -= copy_amount;
});
auto phys_addr = compressed_physical_ptr[page_index];
if (phys_addr == 0) {
on_unmapped(copy_amount, current_vaddr);
continue;
}
auto* mem_ptr = GetPointerFromRaw<u8>(
(static_cast<PAddr>(phys_addr - 1) << Memory::YUZU_PAGEBITS) + page_offset);
on_memory(copy_amount, mem_ptr);
}
}
template <typename Traits>
void DeviceMemoryManager<Traits>::ReadBlock(DAddr address, void* dest_pointer, size_t size) {
device_inter->FlushRegion(address, size);
WalkBlock(
address, size,
[&](size_t copy_amount, DAddr current_vaddr) {
LOG_ERROR(
HW_Memory,
"Unmapped Device ReadBlock @ 0x{:016X} (start address = 0x{:016X}, size = {})",
current_vaddr, address, size);
std::memset(dest_pointer, 0, copy_amount);
},
[&](size_t copy_amount, const u8* const src_ptr) {
std::memcpy(dest_pointer, src_ptr, copy_amount);
},
[&](const std::size_t copy_amount) {
dest_pointer = static_cast<u8*>(dest_pointer) + copy_amount;
});
}
template <typename Traits>
void DeviceMemoryManager<Traits>::WriteBlock(DAddr address, const void* src_pointer, size_t size) {
WalkBlock(
address, size,
[&](size_t copy_amount, DAddr current_vaddr) {
LOG_ERROR(
HW_Memory,
"Unmapped Device WriteBlock @ 0x{:016X} (start address = 0x{:016X}, size = {})",
current_vaddr, address, size);
},
[&](size_t copy_amount, u8* const dst_ptr) {
std::memcpy(dst_ptr, src_pointer, copy_amount);
},
[&](const std::size_t copy_amount) {
src_pointer = static_cast<const u8*>(src_pointer) + copy_amount;
});
device_inter->InvalidateRegion(address, size);
}
template <typename Traits>
void DeviceMemoryManager<Traits>::ReadBlockUnsafe(DAddr address, void* dest_pointer, size_t size) {
WalkBlock(
address, size,
[&](size_t copy_amount, DAddr current_vaddr) {
LOG_ERROR(
HW_Memory,
"Unmapped Device ReadBlock @ 0x{:016X} (start address = 0x{:016X}, size = {})",
current_vaddr, address, size);
std::memset(dest_pointer, 0, copy_amount);
},
[&](size_t copy_amount, const u8* const src_ptr) {
std::memcpy(dest_pointer, src_ptr, copy_amount);
},
[&](const std::size_t copy_amount) {
dest_pointer = static_cast<u8*>(dest_pointer) + copy_amount;
});
}
template <typename Traits>
void DeviceMemoryManager<Traits>::WriteBlockUnsafe(DAddr address, const void* src_pointer,
size_t size) {
WalkBlock(
address, size,
[&](size_t copy_amount, DAddr current_vaddr) {
LOG_ERROR(
HW_Memory,
"Unmapped Device WriteBlock @ 0x{:016X} (start address = 0x{:016X}, size = {})",
current_vaddr, address, size);
},
[&](size_t copy_amount, u8* const dst_ptr) {
std::memcpy(dst_ptr, src_pointer, copy_amount);
},
[&](const std::size_t copy_amount) {
src_pointer = static_cast<const u8*>(src_pointer) + copy_amount;
});
}
template <typename Traits>
Asid DeviceMemoryManager<Traits>::RegisterProcess(Memory::Memory* memory_device_inter) {
size_t new_id{};
if (!id_pool.empty()) {
new_id = id_pool.front();
id_pool.pop_front();
registered_processes[new_id] = memory_device_inter;
} else {
registered_processes.emplace_back(memory_device_inter);
new_id = registered_processes.size() - 1U;
}
return Asid{new_id};
}
template <typename Traits>
void DeviceMemoryManager<Traits>::UnregisterProcess(Asid asid) {
registered_processes[asid.id] = nullptr;
id_pool.push_front(asid.id);
}
template <typename Traits>
void DeviceMemoryManager<Traits>::UpdatePagesCachedCount(DAddr addr, size_t size, s32 delta) {
std::unique_lock<std::mutex> lk(counter_guard, std::defer_lock);
const auto Lock = [&] {
if (!lk) {
lk.lock();
}
};
u64 uncache_begin = 0;
u64 cache_begin = 0;
u64 uncache_bytes = 0;
u64 cache_bytes = 0;
const auto MarkRegionCaching = &DeviceMemoryManager<Traits>::DeviceMethods::MarkRegionCaching;
std::atomic_thread_fence(std::memory_order_acquire);
const size_t page_end = Common::DivCeil(addr + size, Memory::YUZU_PAGESIZE);
size_t page = addr >> Memory::YUZU_PAGEBITS;
auto [asid, base_vaddress] = ExtractCPUBacking(page);
size_t vpage = base_vaddress >> Memory::YUZU_PAGEBITS;
auto* memory_device_inter = registered_processes[asid.id];
for (; page != page_end; ++page) {
std::atomic_uint8_t& count = cached_pages->at(page >> 3).Count(page);
if (delta > 0) {
ASSERT_MSG(count.load(std::memory_order::relaxed) < std::numeric_limits<u8>::max(),
"Count may overflow!");
} else if (delta < 0) {
ASSERT_MSG(count.load(std::memory_order::relaxed) > 0, "Count may underflow!");
} else {
ASSERT_MSG(false, "Delta must be non-zero!");
}
// Adds or subtracts 1, as count is a unsigned 8-bit value
count.fetch_add(static_cast<u8>(delta), std::memory_order_release);
// Assume delta is either -1 or 1
if (count.load(std::memory_order::relaxed) == 0) {
if (uncache_bytes == 0) {
uncache_begin = vpage;
}
uncache_bytes += Memory::YUZU_PAGESIZE;
} else if (uncache_bytes > 0) {
Lock();
MarkRegionCaching(memory_device_inter, uncache_begin << Memory::YUZU_PAGEBITS,
uncache_bytes, false);
uncache_bytes = 0;
}
if (count.load(std::memory_order::relaxed) == 1 && delta > 0) {
if (cache_bytes == 0) {
cache_begin = vpage;
}
cache_bytes += Memory::YUZU_PAGESIZE;
} else if (cache_bytes > 0) {
Lock();
MarkRegionCaching(memory_device_inter, cache_begin << Memory::YUZU_PAGEBITS, cache_bytes,
true);
cache_bytes = 0;
}
vpage++;
}
if (uncache_bytes > 0) {
Lock();
MarkRegionCaching(memory_device_inter, uncache_begin << Memory::YUZU_PAGEBITS, uncache_bytes,
false);
}
if (cache_bytes > 0) {
Lock();
MarkRegionCaching(memory_device_inter, cache_begin << Memory::YUZU_PAGEBITS, cache_bytes,
true);
}
}
} // namespace Core

14
src/core/gpu_dirty_memory_manager.h
View File

@ -10,7 +10,7 @@
#include <utility>
#include <vector>
#include "core/memory.h"
#include "core/device_memory_manager.h"
namespace Core {
@ -23,7 +23,7 @@ public:
~GPUDirtyMemoryManager() = default;
void Collect(VAddr address, size_t size) {
void Collect(PAddr address, size_t size) {
TransformAddress t = BuildTransform(address, size);
TransformAddress tmp, original;
do {
@ -47,7 +47,7 @@ public:
std::memory_order_relaxed));
}
void Gather(std::function<void(VAddr, size_t)>& callback) {
void Gather(std::function<void(PAddr, size_t)>& callback) {
{
std::scoped_lock lk(guard);
TransformAddress t = current.exchange(default_transform, std::memory_order_relaxed);
@ -65,7 +65,7 @@ public:
mask = mask >> empty_bits;
const size_t continuous_bits = std::countr_one(mask);
callback((static_cast<VAddr>(transform.address) << page_bits) + offset,
callback((static_cast<PAddr>(transform.address) << page_bits) + offset,
continuous_bits << align_bits);
mask = continuous_bits < align_size ? (mask >> continuous_bits) : 0;
offset += continuous_bits << align_bits;
@ -80,7 +80,7 @@ private:
u32 mask;
};
constexpr static size_t page_bits = Memory::YUZU_PAGEBITS - 1;
constexpr static size_t page_bits = DEVICE_PAGEBITS - 1;
constexpr static size_t page_size = 1ULL << page_bits;
constexpr static size_t page_mask = page_size - 1;
@ -89,7 +89,7 @@ private:
constexpr static size_t align_mask = align_size - 1;
constexpr static TransformAddress default_transform = {.address = ~0U, .mask = 0U};
bool IsValid(VAddr address) {
bool IsValid(PAddr address) {
return address < (1ULL << 39);
}
@ -103,7 +103,7 @@ private:
return mask;
}
TransformAddress BuildTransform(VAddr address, size_t size) {
TransformAddress BuildTransform(PAddr address, size_t size) {
const size_t minor_address = address & page_mask;
const size_t minor_bit = minor_address >> align_bits;
const size_t top_bit = (minor_address + size + align_mask) >> align_bits;

214
src/core/guest_memory.h Normal file
View File

@ -0,0 +1,214 @@
// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#pragma once
#include <iterator>
#include <memory>
#include <optional>
#include <span>
#include <vector>
#include "common/assert.h"
#include "common/scratch_buffer.h"
namespace Core::Memory {
enum GuestMemoryFlags : u32 {
Read = 1 << 0,
Write = 1 << 1,
Safe = 1 << 2,
Cached = 1 << 3,
SafeRead = Read | Safe,
SafeWrite = Write | Safe,
SafeReadWrite = SafeRead | SafeWrite,
SafeReadCachedWrite = SafeReadWrite | Cached,
UnsafeRead = Read,
UnsafeWrite = Write,
UnsafeReadWrite = UnsafeRead | UnsafeWrite,
UnsafeReadCachedWrite = UnsafeReadWrite | Cached,
};
namespace {
template <typename M, typename T, GuestMemoryFlags FLAGS>
class GuestMemory {
using iterator = T*;
using const_iterator = const T*;
using value_type = T;
using element_type = T;
using iterator_category = std::contiguous_iterator_tag;
public:
GuestMemory() = delete;
explicit GuestMemory(M& memory, u64 addr, std::size_t size,
Common::ScratchBuffer<T>* backup = nullptr)
: m_memory{memory}, m_addr{addr}, m_size{size} {
static_assert(FLAGS & GuestMemoryFlags::Read || FLAGS & GuestMemoryFlags::Write);
if constexpr (FLAGS & GuestMemoryFlags::Read) {
Read(addr, size, backup);
}
}
~GuestMemory() = default;
T* data() noexcept {
return m_data_span.data();
}
const T* data() const noexcept {
return m_data_span.data();
}
size_t size() const noexcept {
return m_size;
}
size_t size_bytes() const noexcept {
return this->size() * sizeof(T);
}
[[nodiscard]] T* begin() noexcept {
return this->data();
}
[[nodiscard]] const T* begin() const noexcept {
return this->data();
}
[[nodiscard]] T* end() noexcept {
return this->data() + this->size();
}
[[nodiscard]] const T* end() const noexcept {
return this->data() + this->size();
}
T& operator[](size_t index) noexcept {
return m_data_span[index];
}
const T& operator[](size_t index) const noexcept {
return m_data_span[index];
}
void SetAddressAndSize(u64 addr, std::size_t size) noexcept {
m_addr = addr;
m_size = size;
m_addr_changed = true;
}
std::span<T> Read(u64 addr, std::size_t size,
Common::ScratchBuffer<T>* backup = nullptr) noexcept {
m_addr = addr;
m_size = size;
if (m_size == 0) {
m_is_data_copy = true;
return {};
}
if (this->TrySetSpan()) {
if constexpr (FLAGS & GuestMemoryFlags::Safe) {
m_memory.FlushRegion(m_addr, this->size_bytes());
}
} else {
if (backup) {
backup->resize_destructive(this->size());
m_data_span = *backup;
} else {
m_data_copy.resize(this->size());
m_data_span = std::span(m_data_copy);
}
m_is_data_copy = true;
m_span_valid = true;
if constexpr (FLAGS & GuestMemoryFlags::Safe) {
m_memory.ReadBlock(m_addr, this->data(), this->size_bytes());
} else {
m_memory.ReadBlockUnsafe(m_addr, this->data(), this->size_bytes());
}
}
return m_data_span;
}
void Write(std::span<T> write_data) noexcept {
if constexpr (FLAGS & GuestMemoryFlags::Cached) {
m_memory.WriteBlockCached(m_addr, write_data.data(), this->size_bytes());
} else if constexpr (FLAGS & GuestMemoryFlags::Safe) {
m_memory.WriteBlock(m_addr, write_data.data(), this->size_bytes());
} else {
m_memory.WriteBlockUnsafe(m_addr, write_data.data(), this->size_bytes());
}
}
bool TrySetSpan() noexcept {
if (u8* ptr = m_memory.GetSpan(m_addr, this->size_bytes()); ptr) {
m_data_span = {reinterpret_cast<T*>(ptr), this->size()};
m_span_valid = true;
return true;
}
return false;
}
protected:
bool IsDataCopy() const noexcept {
return m_is_data_copy;
}
bool AddressChanged() const noexcept {
return m_addr_changed;
}
M& m_memory;
u64 m_addr{};
size_t m_size{};
std::span<T> m_data_span{};
std::vector<T> m_data_copy{};
bool m_span_valid{false};
bool m_is_data_copy{false};
bool m_addr_changed{false};
};
template <typename M, typename T, GuestMemoryFlags FLAGS>
class GuestMemoryScoped : public GuestMemory<M, T, FLAGS> {
public:
GuestMemoryScoped() = delete;
explicit GuestMemoryScoped(M& memory, u64 addr, std::size_t size,
Common::ScratchBuffer<T>* backup = nullptr)
: GuestMemory<M, T, FLAGS>(memory, addr, size, backup) {
if constexpr (!(FLAGS & GuestMemoryFlags::Read)) {
if (!this->TrySetSpan()) {
if (backup) {
this->m_data_span = *backup;
this->m_span_valid = true;
this->m_is_data_copy = true;
}
}
}
}
~GuestMemoryScoped() {
if constexpr (FLAGS & GuestMemoryFlags::Write) {
if (this->size() == 0) [[unlikely]] {
return;
}
if (this->AddressChanged() || this->IsDataCopy()) {
ASSERT(this->m_span_valid);
if constexpr (FLAGS & GuestMemoryFlags::Cached) {
this->m_memory.WriteBlockCached(this->m_addr, this->data(), this->size_bytes());
} else if constexpr (FLAGS & GuestMemoryFlags::Safe) {
this->m_memory.WriteBlock(this->m_addr, this->data(), this->size_bytes());
} else {
this->m_memory.WriteBlockUnsafe(this->m_addr, this->data(), this->size_bytes());
}
} else if constexpr ((FLAGS & GuestMemoryFlags::Safe) ||
(FLAGS & GuestMemoryFlags::Cached)) {
this->m_memory.InvalidateRegion(this->m_addr, this->size_bytes());
}
}
}
};
} // namespace
} // namespace Core::Memory

14
src/core/hle/kernel/k_process.cpp
View File

@ -5,6 +5,7 @@
#include "common/scope_exit.h"
#include "common/settings.h"
#include "core/core.h"
#include "core/gpu_dirty_memory_manager.h"
#include "core/hle/kernel/k_process.h"
#include "core/hle/kernel/k_scoped_resource_reservation.h"
#include "core/hle/kernel/k_shared_memory.h"
@ -320,7 +321,7 @@ Result KProcess::Initialize(const Svc::CreateProcessParameter& params, const KPa
// Ensure our memory is initialized.
m_memory.SetCurrentPageTable(*this);
m_memory.SetGPUDirtyManagers(m_dirty_memory_managers);
m_memory.SetGPUDirtyManagers(m_kernel.System().GetGPUDirtyMemoryManager());
// Ensure we can insert the code region.
R_UNLESS(m_page_table.CanContain(params.code_address, params.code_num_pages * PageSize,
@ -417,7 +418,7 @@ Result KProcess::Initialize(const Svc::CreateProcessParameter& params,
// Ensure our memory is initialized.
m_memory.SetCurrentPageTable(*this);
m_memory.SetGPUDirtyManagers(m_dirty_memory_managers);
m_memory.SetGPUDirtyManagers(m_kernel.System().GetGPUDirtyMemoryManager());
// Ensure we can insert the code region.
R_UNLESS(m_page_table.CanContain(params.code_address, code_size, KMemoryState::Code),
@ -1141,8 +1142,7 @@ void KProcess::Switch(KProcess* cur_process, KProcess* next_process) {}
KProcess::KProcess(KernelCore& kernel)
: KAutoObjectWithSlabHeapAndContainer(kernel), m_page_table{kernel}, m_state_lock{kernel},
m_list_lock{kernel}, m_cond_var{kernel.System()}, m_address_arbiter{kernel.System()},
m_handle_table{kernel}, m_dirty_memory_managers{},
m_exclusive_monitor{}, m_memory{kernel.System()} {}
m_handle_table{kernel}, m_exclusive_monitor{}, m_memory{kernel.System()} {}
KProcess::~KProcess() = default;
Result KProcess::LoadFromMetadata(const FileSys::ProgramMetadata& metadata, std::size_t code_size,
@ -1324,10 +1324,4 @@ bool KProcess::RemoveWatchpoint(KProcessAddress addr, u64 size, DebugWatchpointT
return true;
}
void KProcess::GatherGPUDirtyMemory(std::function<void(VAddr, size_t)>& callback) {
for (auto& manager : m_dirty_memory_managers) {
manager.Gather(callback);
}
}
} // namespace Kernel

4
src/core/hle/kernel/k_process.h
View File

@ -7,7 +7,6 @@
#include "core/arm/arm_interface.h"
#include "core/file_sys/program_metadata.h"
#include "core/gpu_dirty_memory_manager.h"
#include "core/hle/kernel/code_set.h"
#include "core/hle/kernel/k_address_arbiter.h"
#include "core/hle/kernel/k_capabilities.h"
@ -128,7 +127,6 @@ private:
#ifdef HAS_NCE
std::unordered_map<u64, u64> m_post_handlers{};
#endif
std::array<Core::GPUDirtyMemoryManager, Core::Hardware::NUM_CPU_CORES> m_dirty_memory_managers;
std::unique_ptr<Core::ExclusiveMonitor> m_exclusive_monitor;
Core::Memory::Memory m_memory;
@ -511,8 +509,6 @@ public:
return m_memory;
}
void GatherGPUDirtyMemory(std::function<void(VAddr, size_t)>& callback);
Core::ExclusiveMonitor& GetExclusiveMonitor() const {
return *m_exclusive_monitor;
}

61
src/core/hle/service/hle_ipc.cpp
View File

@ -12,6 +12,7 @@
#include "common/common_types.h"
#include "common/logging/log.h"
#include "common/scratch_buffer.h"
#include "core/guest_memory.h"
#include "core/hle/kernel/k_auto_object.h"
#include "core/hle/kernel/k_handle_table.h"
#include "core/hle/kernel/k_process.h"
@ -23,19 +24,6 @@
#include "core/hle/service/ipc_helpers.h"
#include "core/memory.h"
namespace {
static thread_local std::array read_buffer_data_a{
Common::ScratchBuffer<u8>(),
Common::ScratchBuffer<u8>(),
Common::ScratchBuffer<u8>(),
};
static thread_local std::array read_buffer_data_x{
Common::ScratchBuffer<u8>(),
Common::ScratchBuffer<u8>(),
Common::ScratchBuffer<u8>(),
};
} // Anonymous namespace
namespace Service {
SessionRequestHandler::SessionRequestHandler(Kernel::KernelCore& kernel_, const char* service_name_)
@ -343,48 +331,27 @@ std::vector<u8> HLERequestContext::ReadBufferCopy(std::size_t buffer_index) cons
}
std::span<const u8> HLERequestContext::ReadBufferA(std::size_t buffer_index) const {
static thread_local std::array read_buffer_a{
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
};
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::UnsafeRead> gm(memory, 0, 0);
ASSERT_OR_EXECUTE_MSG(
BufferDescriptorA().size() > buffer_index, { return {}; },
"BufferDescriptorA invalid buffer_index {}", buffer_index);
auto& read_buffer = read_buffer_a[buffer_index];
return read_buffer.Read(BufferDescriptorA()[buffer_index].Address(),
BufferDescriptorA()[buffer_index].Size(),
&read_buffer_data_a[buffer_index]);
return gm.Read(BufferDescriptorA()[buffer_index].Address(),
BufferDescriptorA()[buffer_index].Size(), &read_buffer_data_a[buffer_index]);
}
std::span<const u8> HLERequestContext::ReadBufferX(std::size_t buffer_index) const {
static thread_local std::array read_buffer_x{
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
};
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::UnsafeRead> gm(memory, 0, 0);
ASSERT_OR_EXECUTE_MSG(
BufferDescriptorX().size() > buffer_index, { return {}; },
"BufferDescriptorX invalid buffer_index {}", buffer_index);
auto& read_buffer = read_buffer_x[buffer_index];
return read_buffer.Read(BufferDescriptorX()[buffer_index].Address(),
BufferDescriptorX()[buffer_index].Size(),
&read_buffer_data_x[buffer_index]);
return gm.Read(BufferDescriptorX()[buffer_index].Address(),
BufferDescriptorX()[buffer_index].Size(), &read_buffer_data_x[buffer_index]);
}
std::span<const u8> HLERequestContext::ReadBuffer(std::size_t buffer_index) const {
static thread_local std::array read_buffer_a{
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
};
static thread_local std::array read_buffer_x{
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::SafeRead>(memory, 0, 0),
};
Core::Memory::CpuGuestMemory<u8, Core::Memory::GuestMemoryFlags::UnsafeRead> gm(memory, 0, 0);
const bool is_buffer_a{BufferDescriptorA().size() > buffer_index &&
BufferDescriptorA()[buffer_index].Size()};
@ -401,18 +368,14 @@ std::span<const u8> HLERequestContext::ReadBuffer(std::size_t buffer_index) cons
ASSERT_OR_EXECUTE_MSG(
BufferDescriptorA().size() > buffer_index, { return {}; },
"BufferDescriptorA invalid buffer_index {}", buffer_index);
auto& read_buffer = read_buffer_a[buffer_index];
return read_buffer.Read(BufferDescriptorA()[buffer_index].Address(),
BufferDescriptorA()[buffer_index].Size(),
&read_buffer_data_a[buffer_index]);
return gm.Read(BufferDescriptorA()[buffer_index].Address(),
BufferDescriptorA()[buffer_index].Size(), &read_buffer_data_a[buffer_index]);
} else {
ASSERT_OR_EXECUTE_MSG(
BufferDescriptorX().size() > buffer_index, { return {}; },
"BufferDescriptorX invalid buffer_index {}", buffer_index);
auto& read_buffer = read_buffer_x[buffer_index];
return read_buffer.Read(BufferDescriptorX()[buffer_index].Address(),
BufferDescriptorX()[buffer_index].Size(),
&read_buffer_data_x[buffer_index]);
return gm.Read(BufferDescriptorX()[buffer_index].Address(),
BufferDescriptorX()[buffer_index].Size(), &read_buffer_data_x[buffer_index]);
}
}

5
src/core/hle/service/hle_ipc.h
View File

@ -41,6 +41,8 @@ class KernelCore;
class KHandleTable;
class KProcess;
class KServerSession;
template <typename T>
class KScopedAutoObject;
class KThread;
} // namespace Kernel
@ -424,6 +426,9 @@ private:
Kernel::KernelCore& kernel;
Core::Memory::Memory& memory;
mutable std::array<Common::ScratchBuffer<u8>, 3> read_buffer_data_a{};
mutable std::array<Common::ScratchBuffer<u8>, 3> read_buffer_data_x{};
};
} // namespace Service

114
src/core/hle/service/nvdrv/core/container.cpp
View File

@ -2,27 +2,135 @@
// SPDX-FileCopyrightText: 2022 Skyline Team and Contributors
// SPDX-License-Identifier: GPL-3.0-or-later
#include <atomic>
#include <deque>
#include <mutex>
#include "core/hle/kernel/k_process.h"
#include "core/hle/service/nvdrv/core/container.h"
#include "core/hle/service/nvdrv/core/heap_mapper.h"
#include "core/hle/service/nvdrv/core/nvmap.h"
#include "core/hle/service/nvdrv/core/syncpoint_manager.h"
#include "core/memory.h"
#include "video_core/host1x/host1x.h"
namespace Service::Nvidia::NvCore {
Session::Session(SessionId id_, Kernel::KProcess* process_, Core::Asid asid_)
: id{id_}, process{process_}, asid{asid_}, has_preallocated_area{}, mapper{}, is_active{} {}
Session::~Session() = default;
struct ContainerImpl {
explicit ContainerImpl(Tegra::Host1x::Host1x& host1x_)
: file{host1x_}, manager{host1x_}, device_file_data{} {}
explicit ContainerImpl(Container& core, Tegra::Host1x::Host1x& host1x_)
: host1x{host1x_}, file{core, host1x_}, manager{host1x_}, device_file_data{} {}
Tegra::Host1x::Host1x& host1x;
NvMap file;
SyncpointManager manager;
Container::Host1xDeviceFileData device_file_data;
std::deque<Session> sessions;
size_t new_ids{};
std::deque<size_t> id_pool;
std::mutex session_guard;
};
Container::Container(Tegra::Host1x::Host1x& host1x_) {
impl = std::make_unique<ContainerImpl>(host1x_);
impl = std::make_unique<ContainerImpl>(*this, host1x_);
}
Container::~Container() = default;
SessionId Container::OpenSession(Kernel::KProcess* process) {
using namespace Common::Literals;
std::scoped_lock lk(impl->session_guard);
for (auto& session : impl->sessions) {
if (!session.is_active) {
continue;
}
if (session.process == process) {
return session.id;
}
}
size_t new_id{};
auto* memory_interface = &process->GetMemory();
auto& smmu = impl->host1x.MemoryManager();
auto asid = smmu.RegisterProcess(memory_interface);
if (!impl->id_pool.empty()) {
new_id = impl->id_pool.front();
impl->id_pool.pop_front();
impl->sessions[new_id] = Session{SessionId{new_id}, process, asid};
} else {
new_id = impl->new_ids++;
impl->sessions.emplace_back(SessionId{new_id}, process, asid);
}
auto& session = impl->sessions[new_id];
session.is_active = true;
// Optimization
if (process->IsApplication()) {
auto& page_table = process->GetPageTable().GetBasePageTable();
auto heap_start = page_table.GetHeapRegionStart();
Kernel::KProcessAddress cur_addr = heap_start;
size_t region_size = 0;
VAddr region_start = 0;
while (true) {
Kernel::KMemoryInfo mem_info{};
Kernel::Svc::PageInfo page_info{};
R_ASSERT(page_table.QueryInfo(std::addressof(mem_info), std::addressof(page_info),
cur_addr));
auto svc_mem_info = mem_info.GetSvcMemoryInfo();
// Check if this memory block is heap.
if (svc_mem_info.state == Kernel::Svc::MemoryState::Normal) {
if (svc_mem_info.size > region_size) {
region_size = svc_mem_info.size;
region_start = svc_mem_info.base_address;
}
}
// Check if we're done.
const uintptr_t next_address = svc_mem_info.base_address + svc_mem_info.size;
if (next_address <= GetInteger(cur_addr)) {
break;
}
cur_addr = next_address;
}
session.has_preallocated_area = false;
auto start_region = region_size >= 32_MiB ? smmu.Allocate(region_size) : 0;
if (start_region != 0) {
session.mapper = std::make_unique<HeapMapper>(region_start, start_region, region_size,
asid, impl->host1x);
smmu.TrackContinuity(start_region, region_start, region_size, asid);
session.has_preallocated_area = true;
LOG_DEBUG(Debug, "Preallocation created!");
}
}
return SessionId{new_id};
}
void Container::CloseSession(SessionId session_id) {
std::scoped_lock lk(impl->session_guard);
auto& session = impl->sessions[session_id.id];
auto& smmu = impl->host1x.MemoryManager();
if (session.has_preallocated_area) {
const DAddr region_start = session.mapper->GetRegionStart();
const size_t region_size = session.mapper->GetRegionSize();
session.mapper.reset();
smmu.Free(region_start, region_size);
session.has_preallocated_area = false;
}
session.is_active = false;
smmu.UnregisterProcess(impl->sessions[session_id.id].asid);
impl->id_pool.emplace_front(session_id.id);
}
Session* Container::GetSession(SessionId session_id) {
std::atomic_thread_fence(std::memory_order_acquire);
return &impl->sessions[session_id.id];
}
NvMap& Container::GetNvMapFile() {
return impl->file;
}

32
src/core/hle/service/nvdrv/core/container.h
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@ -8,24 +8,56 @@
#include <memory>
#include <unordered_map>
#include "core/device_memory_manager.h"
#include "core/hle/service/nvdrv/nvdata.h"
namespace Kernel {
class KProcess;
}
namespace Tegra::Host1x {
class Host1x;
} // namespace Tegra::Host1x
namespace Service::Nvidia::NvCore {
class HeapMapper;
class NvMap;
class SyncpointManager;
struct ContainerImpl;
struct SessionId {
size_t id;
};
struct Session {
Session(SessionId id_, Kernel::KProcess* process_, Core::Asid asid_);
~Session();
Session(const Session&) = delete;
Session& operator=(const Session&) = delete;
Session(Session&&) = default;
Session& operator=(Session&&) = default;
SessionId id;
Kernel::KProcess* process;
Core::Asid asid;
bool has_preallocated_area{};
std::unique_ptr<HeapMapper> mapper{};
bool is_active{};
};
class Container {
public:
explicit Container(Tegra::Host1x::Host1x& host1x);
~Container();
SessionId OpenSession(Kernel::KProcess* process);
void CloseSession(SessionId id);
Session* GetSession(SessionId id);
NvMap& GetNvMapFile();
const NvMap& GetNvMapFile() const;

175
src/core/hle/service/nvdrv/core/heap_mapper.cpp Normal file
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@ -0,0 +1,175 @@
// SPDX-FileCopyrightText: 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-3.0-or-later
#include <mutex>
#include <boost/container/small_vector.hpp>
#define BOOST_NO_MT
#include <boost/pool/detail/mutex.hpp>
#undef BOOST_NO_MT
#include <boost/icl/interval.hpp>
#include <boost/icl/interval_base_set.hpp>
#include <boost/icl/interval_set.hpp>
#include <boost/icl/split_interval_map.hpp>
#include <boost/pool/pool.hpp>
#include <boost/pool/pool_alloc.hpp>
#include <boost/pool/poolfwd.hpp>
#include "core/hle/service/nvdrv/core/heap_mapper.h"
#include "video_core/host1x/host1x.h"
namespace boost {
template <typename T>
class fast_pool_allocator<T, default_user_allocator_new_delete, details::pool::null_mutex, 4096, 0>;
}
namespace Service::Nvidia::NvCore {
using IntervalCompare = std::less<DAddr>;
using IntervalInstance = boost::icl::interval_type_default<DAddr, std::less>;
using IntervalAllocator = boost::fast_pool_allocator<DAddr>;
using IntervalSet = boost::icl::interval_set<DAddr>;
using IntervalType = typename IntervalSet::interval_type;
template <typename Type>
struct counter_add_functor : public boost::icl::identity_based_inplace_combine<Type> {
// types
typedef counter_add_functor<Type> type;
typedef boost::icl::identity_based_inplace_combine<Type> base_type;
// public member functions
void operator()(Type& current, const Type& added) const {
current += added;
if (current < base_type::identity_element()) {
current = base_type::identity_element();
}
}
// public static functions
static void version(Type&){};
};
using OverlapCombine = counter_add_functor<int>;
using OverlapSection = boost::icl::inter_section<int>;
using OverlapCounter = boost::icl::split_interval_map<DAddr, int>;
struct HeapMapper::HeapMapperInternal {
HeapMapperInternal(Tegra::Host1x::Host1x& host1x) : device_memory{host1x.MemoryManager()} {}
~HeapMapperInternal() = default;
template <typename Func>
void ForEachInOverlapCounter(OverlapCounter& current_range, VAddr cpu_addr, u64 size,
Func&& func) {
const DAddr start_address = cpu_addr;
const DAddr end_address = start_address + size;
const IntervalType search_interval{start_address, end_address};
auto it = current_range.lower_bound(search_interval);
if (it == current_range.end()) {
return;
}
auto end_it = current_range.upper_bound(search_interval);
for (; it != end_it; it++) {
auto& inter = it->first;
DAddr inter_addr_end = inter.upper();
DAddr inter_addr = inter.lower();
if (inter_addr_end > end_address) {
inter_addr_end = end_address;
}
if (inter_addr < start_address) {
inter_addr = start_address;
}
func(inter_addr, inter_addr_end, it->second);
}
}
void RemoveEachInOverlapCounter(OverlapCounter& current_range,
const IntervalType search_interval, int subtract_value) {
bool any_removals = false;
current_range.add(std::make_pair(search_interval, subtract_value));
do {
any_removals = false;
auto it = current_range.lower_bound(search_interval);
if (it == current_range.end()) {
return;
}
auto end_it = current_range.upper_bound(search_interval);
for (; it != end_it; it++) {
if (it->second <= 0) {
any_removals = true;
current_range.erase(it);
break;
}
}
} while (any_removals);
}
IntervalSet base_set;
OverlapCounter mapping_overlaps;
Tegra::MaxwellDeviceMemoryManager& device_memory;
std::mutex guard;
};
HeapMapper::HeapMapper(VAddr start_vaddress, DAddr start_daddress, size_t size, Core::Asid asid,
Tegra::Host1x::Host1x& host1x)
: m_vaddress{start_vaddress}, m_daddress{start_daddress}, m_size{size}, m_asid{asid} {
m_internal = std::make_unique<HeapMapperInternal>(host1x);
}
HeapMapper::~HeapMapper() {
m_internal->device_memory.Unmap(m_daddress, m_size);
}
DAddr HeapMapper::Map(VAddr start, size_t size) {
std::scoped_lock lk(m_internal->guard);
m_internal->base_set.clear();
const IntervalType interval{start, start + size};
m_internal->base_set.insert(interval);
m_internal->ForEachInOverlapCounter(m_internal->mapping_overlaps, start, size,
[this](VAddr start_addr, VAddr end_addr, int) {
const IntervalType other{start_addr, end_addr};
m_internal->base_set.subtract(other);
});
if (!m_internal->base_set.empty()) {
auto it = m_internal->base_set.begin();
auto end_it = m_internal->base_set.end();
for (; it != end_it; it++) {
const VAddr inter_addr_end = it->upper();
const VAddr inter_addr = it->lower();
const size_t offset = inter_addr - m_vaddress;
const size_t sub_size = inter_addr_end - inter_addr;
m_internal->device_memory.Map(m_daddress + offset, m_vaddress + offset, sub_size,
m_asid);
}
}
m_internal->mapping_overlaps += std::make_pair(interval, 1);
m_internal->base_set.clear();
return m_daddress + (start - m_vaddress);
}
void HeapMapper::Unmap(VAddr start, size_t size) {
std::scoped_lock lk(m_internal->guard);
m_internal->base_set.clear();
m_internal->ForEachInOverlapCounter(m_internal->mapping_overlaps, start, size,
[this](VAddr start_addr, VAddr end_addr, int value) {
if (value <= 1) {
const IntervalType other{start_addr, end_addr};
m_internal->base_set.insert(other);
}
});
if (!m_internal->base_set.empty()) {
auto it = m_internal->base_set.begin();
auto end_it = m_internal->base_set.end();
for (; it != end_it; it++) {
const VAddr inter_addr_end = it->upper();
const VAddr inter_addr = it->lower();
const size_t offset = inter_addr - m_vaddress;
const size_t sub_size = inter_addr_end - inter_addr;
m_internal->device_memory.Unmap(m_daddress + offset, sub_size);
}
}
const IntervalType to_remove{start, start + size};
m_internal->RemoveEachInOverlapCounter(m_internal->mapping_overlaps, to_remove, -1);
m_internal->base_set.clear();
}
} // namespace Service::Nvidia::NvCore

49
src/core/hle/service/nvdrv/core/heap_mapper.h Normal file
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@ -0,0 +1,49 @@
// SPDX-FileCopyrightText: 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-3.0-or-later
#pragma once
#include <memory>
#include "common/common_types.h"
#include "core/device_memory_manager.h"
namespace Tegra::Host1x {
class Host1x;
} // namespace Tegra::Host1x
namespace Service::Nvidia::NvCore {
class HeapMapper {
public:
HeapMapper(VAddr start_vaddress, DAddr start_daddress, size_t size, Core::Asid asid,
Tegra::Host1x::Host1x& host1x);
~HeapMapper();
bool IsInBounds(VAddr start, size_t size) const {
VAddr end = start + size;
return start >= m_vaddress && end <= (m_vaddress + m_size);
}
DAddr Map(VAddr start, size_t size);
void Unmap(VAddr start, size_t size);
DAddr GetRegionStart() const {
return m_daddress;
}
size_t GetRegionSize() const {
return m_size;
}
private:
struct HeapMapperInternal;
VAddr m_vaddress;
DAddr m_daddress;
size_t m_size;
Core::Asid m_asid;
std::unique_ptr<HeapMapperInternal> m_internal;
};
} // namespace Service::Nvidia::NvCore

122
src/core/hle/service/nvdrv/core/nvmap.cpp
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@ -2,14 +2,19 @@
// SPDX-FileCopyrightText: 2022 Skyline Team and Contributors
// SPDX-License-Identifier: GPL-3.0-or-later
#include <functional>
#include "common/alignment.h"
#include "common/assert.h"
#include "common/logging/log.h"
#include "core/hle/service/nvdrv/core/container.h"
#include "core/hle/service/nvdrv/core/heap_mapper.h"
#include "core/hle/service/nvdrv/core/nvmap.h"
#include "core/memory.h"
#include "video_core/host1x/host1x.h"
using Core::Memory::YUZU_PAGESIZE;
constexpr size_t BIG_PAGE_SIZE = YUZU_PAGESIZE * 16;
namespace Service::Nvidia::NvCore {
NvMap::Handle::Handle(u64 size_, Id id_)
@ -17,9 +22,9 @@ NvMap::Handle::Handle(u64 size_, Id id_)
flags.raw = 0;
}
NvResult NvMap::Handle::Alloc(Flags pFlags, u32 pAlign, u8 pKind, u64 pAddress) {
NvResult NvMap::Handle::Alloc(Flags pFlags, u32 pAlign, u8 pKind, u64 pAddress,
NvCore::SessionId pSessionId) {
std::scoped_lock lock(mutex);
// Handles cannot be allocated twice
if (allocated) {
return NvResult::AccessDenied;
@ -28,6 +33,7 @@ NvResult NvMap::Handle::Alloc(Flags pFlags, u32 pAlign, u8 pKind, u64 pAddress)
flags = pFlags;
kind = pKind;
align = pAlign < YUZU_PAGESIZE ? YUZU_PAGESIZE : pAlign;
session_id = pSessionId;
// This flag is only applicable for handles with an address passed
if (pAddress) {
@ -63,7 +69,7 @@ NvResult NvMap::Handle::Duplicate(bool internal_session) {
return NvResult::Success;
}
NvMap::NvMap(Tegra::Host1x::Host1x& host1x_) : host1x{host1x_} {}
NvMap::NvMap(Container& core_, Tegra::Host1x::Host1x& host1x_) : host1x{host1x_}, core{core_} {}
void NvMap::AddHandle(std::shared_ptr<Handle> handle_description) {
std::scoped_lock lock(handles_lock);
@ -78,12 +84,30 @@ void NvMap::UnmapHandle(Handle& handle_description) {
handle_description.unmap_queue_entry.reset();
}
// Free and unmap the handle from Host1x GMMU
if (handle_description.pin_virt_address) {
host1x.GMMU().Unmap(static_cast<GPUVAddr>(handle_description.pin_virt_address),
handle_description.aligned_size);
host1x.Allocator().Free(handle_description.pin_virt_address,
static_cast<u32>(handle_description.aligned_size));
handle_description.pin_virt_address = 0;
}
// Free and unmap the handle from the SMMU
host1x.MemoryManager().Unmap(static_cast<GPUVAddr>(handle_description.pin_virt_address),
handle_description.aligned_size);
host1x.Allocator().Free(handle_description.pin_virt_address,
static_cast<u32>(handle_description.aligned_size));
handle_description.pin_virt_address = 0;
const size_t map_size = handle_description.aligned_size;
if (!handle_description.in_heap) {
auto& smmu = host1x.MemoryManager();
size_t aligned_up = Common::AlignUp(map_size, BIG_PAGE_SIZE);
smmu.Unmap(handle_description.d_address, map_size);
smmu.Free(handle_description.d_address, static_cast<size_t>(aligned_up));
handle_description.d_address = 0;
return;
}
const VAddr vaddress = handle_description.address;
auto* session = core.GetSession(handle_description.session_id);
session->mapper->Unmap(vaddress, map_size);
handle_description.d_address = 0;
handle_description.in_heap = false;
}
bool NvMap::TryRemoveHandle(const Handle& handle_description) {
@ -124,22 +148,33 @@ std::shared_ptr<NvMap::Handle> NvMap::GetHandle(Handle::Id handle) {
}
}
VAddr NvMap::GetHandleAddress(Handle::Id handle) {
DAddr NvMap::GetHandleAddress(Handle::Id handle) {
std::scoped_lock lock(handles_lock);
try {
return handles.at(handle)->address;
return handles.at(handle)->d_address;
} catch (std::out_of_range&) {
return 0;
}
}
u32 NvMap::PinHandle(NvMap::Handle::Id handle) {
DAddr NvMap::PinHandle(NvMap::Handle::Id handle, bool low_area_pin) {
auto handle_description{GetHandle(handle)};
if (!handle_description) [[unlikely]] {
return 0;
}
std::scoped_lock lock(handle_description->mutex);
const auto map_low_area = [&] {
if (handle_description->pin_virt_address == 0) {
auto& gmmu_allocator = host1x.Allocator();
auto& gmmu = host1x.GMMU();
u32 address =
gmmu_allocator.Allocate(static_cast<u32>(handle_description->aligned_size));
gmmu.Map(static_cast<GPUVAddr>(address), handle_description->d_address,
handle_description->aligned_size);
handle_description->pin_virt_address = address;
}
};
if (!handle_description->pins) {
// If we're in the unmap queue we can just remove ourselves and return since we're already
// mapped
@ -151,37 +186,58 @@ u32 NvMap::PinHandle(NvMap::Handle::Id handle) {
unmap_queue.erase(*handle_description->unmap_queue_entry);
handle_description->unmap_queue_entry.reset();
if (low_area_pin) {
map_low_area();
handle_description->pins++;
return static_cast<DAddr>(handle_description->pin_virt_address);
}
handle_description->pins++;
return handle_description->pin_virt_address;
return handle_description->d_address;
}
}
using namespace std::placeholders;
// If not then allocate some space and map it
u32 address{};
auto& smmu_allocator = host1x.Allocator();
auto& smmu_memory_manager = host1x.MemoryManager();
while ((address = smmu_allocator.Allocate(
static_cast<u32>(handle_description->aligned_size))) == 0) {
// Free handles until the allocation succeeds
std::scoped_lock queueLock(unmap_queue_lock);
if (auto freeHandleDesc{unmap_queue.front()}) {
// Handles in the unmap queue are guaranteed not to be pinned so don't bother
// checking if they are before unmapping
std::scoped_lock freeLock(freeHandleDesc->mutex);
if (handle_description->pin_virt_address)
UnmapHandle(*freeHandleDesc);
} else {
LOG_CRITICAL(Service_NVDRV, "Ran out of SMMU address space!");
DAddr address{};
auto& smmu = host1x.MemoryManager();
auto* session = core.GetSession(handle_description->session_id);
const VAddr vaddress = handle_description->address;
const size_t map_size = handle_description->aligned_size;
if (session->has_preallocated_area && session->mapper->IsInBounds(vaddress, map_size)) {
handle_description->d_address = session->mapper->Map(vaddress, map_size);
handle_description->in_heap = true;
} else {
size_t aligned_up = Common::AlignUp(map_size, BIG_PAGE_SIZE);
while ((address = smmu.Allocate(aligned_up)) == 0) {
// Free handles until the allocation succeeds
std::scoped_lock queueLock(unmap_queue_lock);
if (auto freeHandleDesc{unmap_queue.front()}) {
// Handles in the unmap queue are guaranteed not to be pinned so don't bother
// checking if they are before unmapping
std::scoped_lock freeLock(freeHandleDesc->mutex);
if (handle_description->d_address)
UnmapHandle(*freeHandleDesc);
} else {
LOG_CRITICAL(Service_NVDRV, "Ran out of SMMU address space!");
}
}
}
smmu_memory_manager.Map(static_cast<GPUVAddr>(address), handle_description->address,
handle_description->aligned_size);
handle_description->pin_virt_address = address;
handle_description->d_address = address;
smmu.Map(address, vaddress, map_size, session->asid, true);
handle_description->in_heap = false;
}
}
if (low_area_pin) {
map_low_area();
}
handle_description->pins++;
return handle_description->pin_virt_address;
if (low_area_pin) {
return static_cast<DAddr>(handle_description->pin_virt_address);
}
return handle_description->d_address;
}
void NvMap::UnpinHandle(Handle::Id handle) {
@ -232,7 +288,7 @@ std::optional<NvMap::FreeInfo> NvMap::FreeHandle(Handle::Id handle, bool interna
LOG_WARNING(Service_NVDRV, "User duplicate count imbalance detected!");
} else if (handle_description->dupes == 0) {
// Force unmap the handle
if (handle_description->pin_virt_address) {
if (handle_description->d_address) {
std::scoped_lock queueLock(unmap_queue_lock);
UnmapHandle(*handle_description);
}

25
src/core/hle/service/nvdrv/core/nvmap.h
View File

@ -14,6 +14,7 @@
#include "common/bit_field.h"
#include "common/common_types.h"
#include "core/hle/service/nvdrv/core/container.h"
#include "core/hle/service/nvdrv/nvdata.h"
namespace Tegra {
@ -25,6 +26,8 @@ class Host1x;
} // namespace Tegra
namespace Service::Nvidia::NvCore {
class Container;
/**
* @brief The nvmap core class holds the global state for nvmap and provides methods to manage
* handles
@ -48,7 +51,7 @@ public:
using Id = u32;
Id id; //!< A globally unique identifier for this handle
s32 pins{};
s64 pins{};
u32 pin_virt_address{};
std::optional<typename std::list<std::shared_ptr<Handle>>::iterator> unmap_queue_entry{};
@ -61,15 +64,18 @@ public:
} flags{};
static_assert(sizeof(Flags) == sizeof(u32));
u64 address{}; //!< The memory location in the guest's AS that this handle corresponds to,
//!< this can also be in the nvdrv tmem
VAddr address{}; //!< The memory location in the guest's AS that this handle corresponds to,
//!< this can also be in the nvdrv tmem
bool is_shared_mem_mapped{}; //!< If this nvmap has been mapped with the MapSharedMem IPC
//!< call
u8 kind{}; //!< Used for memory compression
bool allocated{}; //!< If the handle has been allocated with `Alloc`
bool in_heap{};
NvCore::SessionId session_id{};
u64 dma_map_addr{}; //! remove me after implementing pinning.
DAddr d_address{}; //!< The memory location in the device's AS that this handle corresponds
//!< to, this can also be in the nvdrv tmem
Handle(u64 size, Id id);
@ -77,7 +83,8 @@ public:
* @brief Sets up the handle with the given memory config, can allocate memory from the tmem
* if a 0 address is passed
*/
[[nodiscard]] NvResult Alloc(Flags pFlags, u32 pAlign, u8 pKind, u64 pAddress);
[[nodiscard]] NvResult Alloc(Flags pFlags, u32 pAlign, u8 pKind, u64 pAddress,
NvCore::SessionId pSessionId);
/**
* @brief Increases the dupe counter of the handle for the given session
@ -108,7 +115,7 @@ public:
bool can_unlock; //!< If the address region is ready to be unlocked
};
explicit NvMap(Tegra::Host1x::Host1x& host1x);
explicit NvMap(Container& core, Tegra::Host1x::Host1x& host1x);
/**
* @brief Creates an unallocated handle of the given size
@ -117,7 +124,7 @@ public:
std::shared_ptr<Handle> GetHandle(Handle::Id handle);
VAddr GetHandleAddress(Handle::Id handle);
DAddr GetHandleAddress(Handle::Id handle);
/**
* @brief Maps a handle into the SMMU address space
@ -125,7 +132,7 @@ public:
* number of calls to `UnpinHandle`
* @return The SMMU virtual address that the handle has been mapped to
*/
u32 PinHandle(Handle::Id handle);
DAddr PinHandle(Handle::Id handle, bool low_area_pin);
/**
* @brief When this has been called an equal number of times to `PinHandle` for the supplied
@ -172,5 +179,7 @@ private:
* @return If the handle was removed from the map
*/
bool TryRemoveHandle(const Handle& handle_description);
Container& core;
};
} // namespace Service::Nvidia::NvCore

3
src/core/hle/service/nvdrv/devices/nvdevice.h
View File

@ -7,6 +7,7 @@
#include <vector>
#include "common/common_types.h"
#include "core/hle/service/nvdrv/core/container.h"
#include "core/hle/service/nvdrv/nvdata.h"
namespace Core {
@ -62,7 +63,7 @@ public:
* Called once a device is opened
* @param fd The device fd
*/
virtual void OnOpen(DeviceFD fd) = 0;
virtual void OnOpen(NvCore::SessionId session_id, DeviceFD fd) = 0;
/**
* Called once a device is closed

4
src/core/hle/service/nvdrv/devices/nvdisp_disp0.cpp
View File

@ -35,14 +35,14 @@ NvResult nvdisp_disp0::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> in
return NvResult::NotImplemented;
}
void nvdisp_disp0::OnOpen(DeviceFD fd) {}
void nvdisp_disp0::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {}
void nvdisp_disp0::OnClose(DeviceFD fd) {}
void nvdisp_disp0::flip(u32 buffer_handle, u32 offset, android::PixelFormat format, u32 width,
u32 height, u32 stride, android::BufferTransformFlags transform,
const Common::Rectangle<int>& crop_rect,
std::array<Service::Nvidia::NvFence, 4>& fences, u32 num_fences) {
const VAddr addr = nvmap.GetHandleAddress(buffer_handle);
const DAddr addr = nvmap.GetHandleAddress(buffer_handle);
LOG_TRACE(Service,
"Drawing from address {:X} offset {:08X} Width {} Height {} Stride {} Format {}",
addr, offset, width, height, stride, format);

2
src/core/hle/service/nvdrv/devices/nvdisp_disp0.h
View File

@ -32,7 +32,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
/// Performs a screen flip, drawing the buffer pointed to by the handle.

36
src/core/hle/service/nvdrv/devices/nvhost_as_gpu.cpp
View File

@ -86,7 +86,7 @@ NvResult nvhost_as_gpu::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> i
return NvResult::NotImplemented;
}
void nvhost_as_gpu::OnOpen(DeviceFD fd) {}
void nvhost_as_gpu::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {}
void nvhost_as_gpu::OnClose(DeviceFD fd) {}
NvResult nvhost_as_gpu::AllocAsEx(IoctlAllocAsEx& params) {
@ -206,6 +206,8 @@ void nvhost_as_gpu::FreeMappingLocked(u64 offset) {
static_cast<u32>(aligned_size >> page_size_bits));
}
nvmap.UnpinHandle(mapping->handle);
// Sparse mappings shouldn't be fully unmapped, just returned to their sparse state
// Only FreeSpace can unmap them fully
if (mapping->sparse_alloc) {
@ -293,12 +295,12 @@ NvResult nvhost_as_gpu::Remap(std::span<IoctlRemapEntry> entries) {
return NvResult::BadValue;
}
VAddr cpu_address{static_cast<VAddr>(
handle->address +
(static_cast<u64>(entry.handle_offset_big_pages) << vm.big_page_size_bits))};
DAddr base = nvmap.PinHandle(entry.handle, false);
DAddr device_address{static_cast<DAddr>(
base + (static_cast<u64>(entry.handle_offset_big_pages) << vm.big_page_size_bits))};
gmmu->Map(virtual_address, cpu_address, size, static_cast<Tegra::PTEKind>(entry.kind),
use_big_pages);
gmmu->Map(virtual_address, device_address, size,
static_cast<Tegra::PTEKind>(entry.kind), use_big_pages);
}
}
@ -331,9 +333,9 @@ NvResult nvhost_as_gpu::MapBufferEx(IoctlMapBufferEx& params) {
}
u64 gpu_address{static_cast<u64>(params.offset + params.buffer_offset)};
VAddr cpu_address{mapping->ptr + params.buffer_offset};
VAddr device_address{mapping->ptr + params.buffer_offset};
gmmu->Map(gpu_address, cpu_address, params.mapping_size,
gmmu->Map(gpu_address, device_address, params.mapping_size,
static_cast<Tegra::PTEKind>(params.kind), mapping->big_page);
return NvResult::Success;
@ -349,7 +351,8 @@ NvResult nvhost_as_gpu::MapBufferEx(IoctlMapBufferEx& params) {
return NvResult::BadValue;
}
VAddr cpu_address{static_cast<VAddr>(handle->address + params.buffer_offset)};
DAddr device_address{
static_cast<DAddr>(nvmap.PinHandle(params.handle, false) + params.buffer_offset)};
u64 size{params.mapping_size ? params.mapping_size : handle->orig_size};
bool big_page{[&]() {
@ -373,15 +376,14 @@ NvResult nvhost_as_gpu::MapBufferEx(IoctlMapBufferEx& params) {
}
const bool use_big_pages = alloc->second.big_pages && big_page;
gmmu->Map(params.offset, cpu_address, size, static_cast<Tegra::PTEKind>(params.kind),
gmmu->Map(params.offset, device_address, size, static_cast<Tegra::PTEKind>(params.kind),
use_big_pages);
auto mapping{std::make_shared<Mapping>(cpu_address, params.offset, size, true,
use_big_pages, alloc->second.sparse)};
auto mapping{std::make_shared<Mapping>(params.handle, device_address, params.offset, size,
true, use_big_pages, alloc->second.sparse)};
alloc->second.mappings.push_back(mapping);
mapping_map[params.offset] = mapping;
} else {
auto& allocator{big_page ? *vm.big_page_allocator : *vm.small_page_allocator};
u32 page_size{big_page ? vm.big_page_size : VM::YUZU_PAGESIZE};
u32 page_size_bits{big_page ? vm.big_page_size_bits : VM::PAGE_SIZE_BITS};
@ -394,11 +396,11 @@ NvResult nvhost_as_gpu::MapBufferEx(IoctlMapBufferEx& params) {
return NvResult::InsufficientMemory;
}
gmmu->Map(params.offset, cpu_address, Common::AlignUp(size, page_size),
gmmu->Map(params.offset, device_address, Common::AlignUp(size, page_size),
static_cast<Tegra::PTEKind>(params.kind), big_page);
auto mapping{
std::make_shared<Mapping>(cpu_address, params.offset, size, false, big_page, false)};
auto mapping{std::make_shared<Mapping>(params.handle, device_address, params.offset, size,
false, big_page, false)};
mapping_map[params.offset] = mapping;
}
@ -433,6 +435,8 @@ NvResult nvhost_as_gpu::UnmapBuffer(IoctlUnmapBuffer& params) {
gmmu->Unmap(params.offset, mapping->size);
}
nvmap.UnpinHandle(mapping->handle);
mapping_map.erase(params.offset);
} catch (const std::out_of_range&) {
LOG_WARNING(Service_NVDRV, "Couldn't find region to unmap at 0x{:X}", params.offset);

15
src/core/hle/service/nvdrv/devices/nvhost_as_gpu.h
View File

@ -55,7 +55,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
Kernel::KEvent* QueryEvent(u32 event_id) override;
@ -159,16 +159,18 @@ private:
NvCore::NvMap& nvmap;
struct Mapping {
VAddr ptr;
NvCore::NvMap::Handle::Id handle;
DAddr ptr;
u64 offset;
u64 size;
bool fixed;
bool big_page; // Only valid if fixed == false
bool sparse_alloc;
Mapping(VAddr ptr_, u64 offset_, u64 size_, bool fixed_, bool big_page_, bool sparse_alloc_)
: ptr(ptr_), offset(offset_), size(size_), fixed(fixed_), big_page(big_page_),
sparse_alloc(sparse_alloc_) {}
Mapping(NvCore::NvMap::Handle::Id handle_, DAddr ptr_, u64 offset_, u64 size_, bool fixed_,
bool big_page_, bool sparse_alloc_)
: handle(handle_), ptr(ptr_), offset(offset_), size(size_), fixed(fixed_),
big_page(big_page_), sparse_alloc(sparse_alloc_) {}
};
struct Allocation {
@ -212,9 +214,6 @@ private:
bool initialised{};
} vm;
std::shared_ptr<Tegra::MemoryManager> gmmu;
// s32 channel{};
// u32 big_page_size{VM::DEFAULT_BIG_PAGE_SIZE};
};
} // namespace Service::Nvidia::Devices

2
src/core/hle/service/nvdrv/devices/nvhost_ctrl.cpp
View File

@ -76,7 +76,7 @@ NvResult nvhost_ctrl::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> inp
return NvResult::NotImplemented;
}
void nvhost_ctrl::OnOpen(DeviceFD fd) {}
void nvhost_ctrl::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {}
void nvhost_ctrl::OnClose(DeviceFD fd) {}

2
src/core/hle/service/nvdrv/devices/nvhost_ctrl.h
View File

@ -32,7 +32,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
Kernel::KEvent* QueryEvent(u32 event_id) override;

2
src/core/hle/service/nvdrv/devices/nvhost_ctrl_gpu.cpp
View File

@ -82,7 +82,7 @@ NvResult nvhost_ctrl_gpu::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8>
return NvResult::NotImplemented;
}
void nvhost_ctrl_gpu::OnOpen(DeviceFD fd) {}
void nvhost_ctrl_gpu::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {}
void nvhost_ctrl_gpu::OnClose(DeviceFD fd) {}
NvResult nvhost_ctrl_gpu::GetCharacteristics1(IoctlCharacteristics& params) {

2
src/core/hle/service/nvdrv/devices/nvhost_ctrl_gpu.h
View File

@ -28,7 +28,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
Kernel::KEvent* QueryEvent(u32 event_id) override;

2
src/core/hle/service/nvdrv/devices/nvhost_gpu.cpp
View File

@ -120,7 +120,7 @@ NvResult nvhost_gpu::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> inpu
return NvResult::NotImplemented;
}
void nvhost_gpu::OnOpen(DeviceFD fd) {}
void nvhost_gpu::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {}
void nvhost_gpu::OnClose(DeviceFD fd) {}
NvResult nvhost_gpu::SetNVMAPfd(IoctlSetNvmapFD& params) {

2
src/core/hle/service/nvdrv/devices/nvhost_gpu.h
View File

@ -47,7 +47,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
Kernel::KEvent* QueryEvent(u32 event_id) override;

9
src/core/hle/service/nvdrv/devices/nvhost_nvdec.cpp
View File

@ -35,7 +35,7 @@ NvResult nvhost_nvdec::Ioctl1(DeviceFD fd, Ioctl command, std::span<const u8> in
case 0x7:
return WrapFixed(this, &nvhost_nvdec::SetSubmitTimeout, input, output);
case 0x9:
return WrapFixedVariable(this, &nvhost_nvdec::MapBuffer, input, output);
return WrapFixedVariable(this, &nvhost_nvdec::MapBuffer, input, output, fd);
case 0xa:
return WrapFixedVariable(this, &nvhost_nvdec::UnmapBuffer, input, output);
default:
@ -68,9 +68,10 @@ NvResult nvhost_nvdec::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> in
return NvResult::NotImplemented;
}
void nvhost_nvdec::OnOpen(DeviceFD fd) {
void nvhost_nvdec::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {
LOG_INFO(Service_NVDRV, "NVDEC video stream started");
system.SetNVDECActive(true);
sessions[fd] = session_id;
}
void nvhost_nvdec::OnClose(DeviceFD fd) {
@ -81,6 +82,10 @@ void nvhost_nvdec::OnClose(DeviceFD fd) {
system.GPU().ClearCdmaInstance(iter->second);
}
system.SetNVDECActive(false);
auto it = sessions.find(fd);
if (it != sessions.end()) {
sessions.erase(it);
}
}
} // namespace Service::Nvidia::Devices

2
src/core/hle/service/nvdrv/devices/nvhost_nvdec.h
View File

@ -20,7 +20,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
};

13
src/core/hle/service/nvdrv/devices/nvhost_nvdec_common.cpp
View File

@ -8,6 +8,7 @@
#include "common/common_types.h"
#include "common/logging/log.h"
#include "core/core.h"
#include "core/hle/kernel/k_process.h"
#include "core/hle/service/nvdrv/core/container.h"
#include "core/hle/service/nvdrv/core/nvmap.h"
#include "core/hle/service/nvdrv/core/syncpoint_manager.h"
@ -95,6 +96,8 @@ NvResult nvhost_nvdec_common::Submit(IoctlSubmit& params, std::span<u8> data, De
offset += SliceVectors(data, fence_thresholds, params.fence_count, offset);
auto& gpu = system.GPU();
auto* session = core.GetSession(sessions[fd]);
if (gpu.UseNvdec()) {
for (std::size_t i = 0; i < syncpt_increments.size(); i++) {
const SyncptIncr& syncpt_incr = syncpt_increments[i];
@ -106,8 +109,8 @@ NvResult nvhost_nvdec_common::Submit(IoctlSubmit& params, std::span<u8> data, De
const auto object = nvmap.GetHandle(cmd_buffer.memory_id);
ASSERT_OR_EXECUTE(object, return NvResult::InvalidState;);
Tegra::ChCommandHeaderList cmdlist(cmd_buffer.word_count);
system.ApplicationMemory().ReadBlock(object->address + cmd_buffer.offset, cmdlist.data(),
cmdlist.size() * sizeof(u32));
session->process->GetMemory().ReadBlock(object->address + cmd_buffer.offset, cmdlist.data(),
cmdlist.size() * sizeof(u32));
gpu.PushCommandBuffer(core.Host1xDeviceFile().fd_to_id[fd], cmdlist);
}
// Some games expect command_buffers to be written back
@ -133,10 +136,12 @@ NvResult nvhost_nvdec_common::GetWaitbase(IoctlGetWaitbase& params) {
return NvResult::Success;
}
NvResult nvhost_nvdec_common::MapBuffer(IoctlMapBuffer& params, std::span<MapBufferEntry> entries) {
NvResult nvhost_nvdec_common::MapBuffer(IoctlMapBuffer& params, std::span<MapBufferEntry> entries,
DeviceFD fd) {
const size_t num_entries = std::min(params.num_entries, static_cast<u32>(entries.size()));
for (size_t i = 0; i < num_entries; i++) {
entries[i].map_address = nvmap.PinHandle(entries[i].map_handle);
DAddr pin_address = nvmap.PinHandle(entries[i].map_handle, true);
entries[i].map_address = static_cast<u32>(pin_address);
}
return NvResult::Success;

5
src/core/hle/service/nvdrv/devices/nvhost_nvdec_common.h
View File

@ -4,7 +4,9 @@
#pragma once
#include <deque>
#include <unordered_map>
#include <vector>
#include "common/common_types.h"
#include "common/swap.h"
#include "core/hle/service/nvdrv/core/syncpoint_manager.h"
@ -111,7 +113,7 @@ protected:
NvResult Submit(IoctlSubmit& params, std::span<u8> input, DeviceFD fd);
NvResult GetSyncpoint(IoctlGetSyncpoint& params);
NvResult GetWaitbase(IoctlGetWaitbase& params);
NvResult MapBuffer(IoctlMapBuffer& params, std::span<MapBufferEntry> entries);
NvResult MapBuffer(IoctlMapBuffer& params, std::span<MapBufferEntry> entries, DeviceFD fd);
NvResult UnmapBuffer(IoctlMapBuffer& params, std::span<MapBufferEntry> entries);
NvResult SetSubmitTimeout(u32 timeout);
@ -125,6 +127,7 @@ protected:
NvCore::NvMap& nvmap;
NvCore::ChannelType channel_type;
std::array<u32, MaxSyncPoints> device_syncpoints{};
std::unordered_map<DeviceFD, NvCore::SessionId> sessions;
};
}; // namespace Devices
} // namespace Service::Nvidia

2
src/core/hle/service/nvdrv/devices/nvhost_nvjpg.cpp
View File

@ -44,7 +44,7 @@ NvResult nvhost_nvjpg::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> in
return NvResult::NotImplemented;
}
void nvhost_nvjpg::OnOpen(DeviceFD fd) {}
void nvhost_nvjpg::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {}
void nvhost_nvjpg::OnClose(DeviceFD fd) {}
NvResult nvhost_nvjpg::SetNVMAPfd(IoctlSetNvmapFD& params) {

2
src/core/hle/service/nvdrv/devices/nvhost_nvjpg.h
View File

@ -22,7 +22,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
private:

7
src/core/hle/service/nvdrv/devices/nvhost_vic.cpp
View File

@ -33,7 +33,7 @@ NvResult nvhost_vic::Ioctl1(DeviceFD fd, Ioctl command, std::span<const u8> inpu
case 0x3:
return WrapFixed(this, &nvhost_vic::GetWaitbase, input, output);
case 0x9:
return WrapFixedVariable(this, &nvhost_vic::MapBuffer, input, output);
return WrapFixedVariable(this, &nvhost_vic::MapBuffer, input, output, fd);
case 0xa:
return WrapFixedVariable(this, &nvhost_vic::UnmapBuffer, input, output);
default:
@ -68,7 +68,9 @@ NvResult nvhost_vic::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> inpu
return NvResult::NotImplemented;
}
void nvhost_vic::OnOpen(DeviceFD fd) {}
void nvhost_vic::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {
sessions[fd] = session_id;
}
void nvhost_vic::OnClose(DeviceFD fd) {
auto& host1x_file = core.Host1xDeviceFile();
@ -76,6 +78,7 @@ void nvhost_vic::OnClose(DeviceFD fd) {
if (iter != host1x_file.fd_to_id.end()) {
system.GPU().ClearCdmaInstance(iter->second);
}
sessions.erase(fd);
}
} // namespace Service::Nvidia::Devices

2
src/core/hle/service/nvdrv/devices/nvhost_vic.h
View File

@ -19,7 +19,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
};
} // namespace Service::Nvidia::Devices

31
src/core/hle/service/nvdrv/devices/nvmap.cpp
View File

@ -36,9 +36,9 @@ NvResult nvmap::Ioctl1(DeviceFD fd, Ioctl command, std::span<const u8> input,
case 0x3:
return WrapFixed(this, &nvmap::IocFromId, input, output);
case 0x4:
return WrapFixed(this, &nvmap::IocAlloc, input, output);
return WrapFixed(this, &nvmap::IocAlloc, input, output, fd);
case 0x5:
return WrapFixed(this, &nvmap::IocFree, input, output);
return WrapFixed(this, &nvmap::IocFree, input, output, fd);
case 0x9:
return WrapFixed(this, &nvmap::IocParam, input, output);
case 0xe:
@ -67,8 +67,15 @@ NvResult nvmap::Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, st
return NvResult::NotImplemented;
}
void nvmap::OnOpen(DeviceFD fd) {}
void nvmap::OnClose(DeviceFD fd) {}
void nvmap::OnOpen(NvCore::SessionId session_id, DeviceFD fd) {
sessions[fd] = session_id;
}
void nvmap::OnClose(DeviceFD fd) {
auto it = sessions.find(fd);
if (it != sessions.end()) {
sessions.erase(it);
}
}
NvResult nvmap::IocCreate(IocCreateParams& params) {
LOG_DEBUG(Service_NVDRV, "called, size=0x{:08X}", params.size);
@ -87,7 +94,7 @@ NvResult nvmap::IocCreate(IocCreateParams& params) {
return NvResult::Success;
}
NvResult nvmap::IocAlloc(IocAllocParams& params) {
NvResult nvmap::IocAlloc(IocAllocParams& params, DeviceFD fd) {
LOG_DEBUG(Service_NVDRV, "called, addr={:X}", params.address);
if (!params.handle) {
@ -116,15 +123,15 @@ NvResult nvmap::IocAlloc(IocAllocParams& params) {
return NvResult::InsufficientMemory;
}
const auto result =
handle_description->Alloc(params.flags, params.align, params.kind, params.address);
const auto result = handle_description->Alloc(params.flags, params.align, params.kind,
params.address, sessions[fd]);
if (result != NvResult::Success) {
LOG_CRITICAL(Service_NVDRV, "Object failed to allocate, handle={:08X}", params.handle);
return result;
}
bool is_out_io{};
ASSERT(system.ApplicationProcess()
->GetPageTable()
auto process = container.GetSession(sessions[fd])->process;
ASSERT(process->GetPageTable()
.LockForMapDeviceAddressSpace(&is_out_io, handle_description->address,
handle_description->size,
Kernel::KMemoryPermission::None, true, false)
@ -224,7 +231,7 @@ NvResult nvmap::IocParam(IocParamParams& params) {
return NvResult::Success;
}
NvResult nvmap::IocFree(IocFreeParams& params) {
NvResult nvmap::IocFree(IocFreeParams& params, DeviceFD fd) {
LOG_DEBUG(Service_NVDRV, "called");
if (!params.handle) {
@ -233,9 +240,9 @@ NvResult nvmap::IocFree(IocFreeParams& params) {
}
if (auto freeInfo{file.FreeHandle(params.handle, false)}) {
auto process = container.GetSession(sessions[fd])->process;
if (freeInfo->can_unlock) {
ASSERT(system.ApplicationProcess()
->GetPageTable()
ASSERT(process->GetPageTable()
.UnlockForDeviceAddressSpace(freeInfo->address, freeInfo->size)
.IsSuccess());
}

7
src/core/hle/service/nvdrv/devices/nvmap.h
View File

@ -33,7 +33,7 @@ public:
NvResult Ioctl3(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output,
std::span<u8> inline_output) override;
void OnOpen(DeviceFD fd) override;
void OnOpen(NvCore::SessionId session_id, DeviceFD fd) override;
void OnClose(DeviceFD fd) override;
enum class HandleParameterType : u32_le {
@ -100,11 +100,11 @@ public:
static_assert(sizeof(IocGetIdParams) == 8, "IocGetIdParams has wrong size");
NvResult IocCreate(IocCreateParams& params);
NvResult IocAlloc(IocAllocParams& params);
NvResult IocAlloc(IocAllocParams& params, DeviceFD fd);
NvResult IocGetId(IocGetIdParams& params);
NvResult IocFromId(IocFromIdParams& params);
NvResult IocParam(IocParamParams& params);
NvResult IocFree(IocFreeParams& params);
NvResult IocFree(IocFreeParams& params, DeviceFD fd);
private:
/// Id to use for the next handle that is created.
@ -115,6 +115,7 @@ private:
NvCore::Container& container;
NvCore::NvMap& file;
std::unordered_map<DeviceFD, NvCore::SessionId> sessions;
};
} // namespace Service::Nvidia::Devices

27
src/core/hle/service/nvdrv/nvdrv.cpp
View File

@ -45,13 +45,22 @@ void EventInterface::FreeEvent(Kernel::KEvent* event) {
void LoopProcess(Nvnflinger::Nvnflinger& nvnflinger, Core::System& system) {
auto server_manager = std::make_unique<ServerManager>(system);
auto module = std::make_shared<Module>(system);
server_manager->RegisterNamedService("nvdrv", std::make_shared<NVDRV>(system, module, "nvdrv"));
server_manager->RegisterNamedService("nvdrv:a",
std::make_shared<NVDRV>(system, module, "nvdrv:a"));
server_manager->RegisterNamedService("nvdrv:s",
std::make_shared<NVDRV>(system, module, "nvdrv:s"));
server_manager->RegisterNamedService("nvdrv:t",
std::make_shared<NVDRV>(system, module, "nvdrv:t"));
const auto NvdrvInterfaceFactoryForApplication = [&, module] {
return std::make_shared<NVDRV>(system, module, "nvdrv");
};
const auto NvdrvInterfaceFactoryForApplets = [&, module] {
return std::make_shared<NVDRV>(system, module, "nvdrv:a");
};
const auto NvdrvInterfaceFactoryForSysmodules = [&, module] {
return std::make_shared<NVDRV>(system, module, "nvdrv:s");
};
const auto NvdrvInterfaceFactoryForTesting = [&, module] {
return std::make_shared<NVDRV>(system, module, "nvdrv:t");
};
server_manager->RegisterNamedService("nvdrv", NvdrvInterfaceFactoryForApplication);
server_manager->RegisterNamedService("nvdrv:a", NvdrvInterfaceFactoryForApplets);
server_manager->RegisterNamedService("nvdrv:s", NvdrvInterfaceFactoryForSysmodules);
server_manager->RegisterNamedService("nvdrv:t", NvdrvInterfaceFactoryForTesting);
server_manager->RegisterNamedService("nvmemp", std::make_shared<NVMEMP>(system));
nvnflinger.SetNVDrvInstance(module);
ServerManager::RunServer(std::move(server_manager));
@ -113,7 +122,7 @@ NvResult Module::VerifyFD(DeviceFD fd) const {
return NvResult::Success;
}
DeviceFD Module::Open(const std::string& device_name) {
DeviceFD Module::Open(const std::string& device_name, NvCore::SessionId session_id) {
auto it = builders.find(device_name);
if (it == builders.end()) {
LOG_ERROR(Service_NVDRV, "Trying to open unknown device {}", device_name);
@ -124,7 +133,7 @@ DeviceFD Module::Open(const std::string& device_name) {
auto& builder = it->second;
auto device = builder(fd)->second;
device->OnOpen(fd);
device->OnOpen(session_id, fd);
return fd;
}

6
src/core/hle/service/nvdrv/nvdrv.h
View File

@ -77,7 +77,7 @@ public:
NvResult VerifyFD(DeviceFD fd) const;
/// Opens a device node and returns a file descriptor to it.
DeviceFD Open(const std::string& device_name);
DeviceFD Open(const std::string& device_name, NvCore::SessionId session_id);
/// Sends an ioctl command to the specified file descriptor.
NvResult Ioctl1(DeviceFD fd, Ioctl command, std::span<const u8> input, std::span<u8> output);
@ -93,6 +93,10 @@ public:
NvResult QueryEvent(DeviceFD fd, u32 event_id, Kernel::KEvent*& event);
NvCore::Container& GetContainer() {
return container;
}
private:
friend class EventInterface;
friend class Service::Nvnflinger::Nvnflinger;

34
src/core/hle/service/nvdrv/nvdrv_interface.cpp
View File

@ -3,8 +3,10 @@
// SPDX-License-Identifier: GPL-3.0-or-later
#include "common/logging/log.h"
#include "common/scope_exit.h"
#include "core/core.h"
#include "core/hle/kernel/k_event.h"
#include "core/hle/kernel/k_process.h"
#include "core/hle/kernel/k_readable_event.h"
#include "core/hle/service/ipc_helpers.h"
#include "core/hle/service/nvdrv/nvdata.h"
@ -37,7 +39,7 @@ void NVDRV::Open(HLERequestContext& ctx) {
return;
}
DeviceFD fd = nvdrv->Open(device_name);
DeviceFD fd = nvdrv->Open(device_name, session_id);
rb.Push<DeviceFD>(fd);
rb.PushEnum(fd != INVALID_NVDRV_FD ? NvResult::Success : NvResult::FileOperationFailed);
@ -150,12 +152,29 @@ void NVDRV::Close(HLERequestContext& ctx) {
void NVDRV::Initialize(HLERequestContext& ctx) {
LOG_WARNING(Service_NVDRV, "(STUBBED) called");
IPC::ResponseBuilder rb{ctx, 3};
SCOPE_EXIT({
rb.Push(ResultSuccess);
rb.PushEnum(NvResult::Success);
});
if (is_initialized) {
// No need to initialize again
return;
}
IPC::RequestParser rp{ctx};
const auto process_handle{ctx.GetCopyHandle(0)};
// The transfer memory is lent to nvdrv as a work buffer since nvdrv is
// unable to allocate as much memory on its own. For HLE it's unnecessary to handle it
[[maybe_unused]] const auto transfer_memory_handle{ctx.GetCopyHandle(1)};
[[maybe_unused]] const auto transfer_memory_size = rp.Pop<u32>();
auto& container = nvdrv->GetContainer();
auto process = ctx.GetObjectFromHandle<Kernel::KProcess>(process_handle);
session_id = container.OpenSession(process.GetPointerUnsafe());
is_initialized = true;
IPC::ResponseBuilder rb{ctx, 3};
rb.Push(ResultSuccess);
rb.PushEnum(NvResult::Success);
}
void NVDRV::QueryEvent(HLERequestContext& ctx) {
@ -242,6 +261,9 @@ NVDRV::NVDRV(Core::System& system_, std::shared_ptr<Module> nvdrv_, const char*
RegisterHandlers(functions);
}
NVDRV::~NVDRV() = default;
NVDRV::~NVDRV() {
auto& container = nvdrv->GetContainer();
container.CloseSession(session_id);
}
} // namespace Service::Nvidia

1
src/core/hle/service/nvdrv/nvdrv_interface.h
View File

@ -35,6 +35,7 @@ private:
u64 pid{};
bool is_initialized{};
NvCore::SessionId session_id{};
Common::ScratchBuffer<u8> output_buffer;
Common::ScratchBuffer<u8> inline_output_buffer;
};

25
src/core/hle/service/nvnflinger/fb_share_buffer_manager.cpp
View File

@ -87,19 +87,20 @@ Result CreateNvMapHandle(u32* out_nv_map_handle, Nvidia::Devices::nvmap& nvmap,
R_SUCCEED();
}
Result FreeNvMapHandle(Nvidia::Devices::nvmap& nvmap, u32 handle) {
Result FreeNvMapHandle(Nvidia::Devices::nvmap& nvmap, u32 handle, Nvidia::DeviceFD nvmap_fd) {
// Free the handle.
Nvidia::Devices::nvmap::IocFreeParams free_params{
.handle = handle,
};
R_UNLESS(nvmap.IocFree(free_params) == Nvidia::NvResult::Success, VI::ResultOperationFailed);
R_UNLESS(nvmap.IocFree(free_params, nvmap_fd) == Nvidia::NvResult::Success,
VI::ResultOperationFailed);
// We succeeded.
R_SUCCEED();
}
Result AllocNvMapHandle(Nvidia::Devices::nvmap& nvmap, u32 handle, Common::ProcessAddress buffer,
u32 size) {
u32 size, Nvidia::DeviceFD nvmap_fd) {
// Assign the allocated memory to the handle.
Nvidia::Devices::nvmap::IocAllocParams alloc_params{
.handle = handle,
@ -109,16 +110,16 @@ Result AllocNvMapHandle(Nvidia::Devices::nvmap& nvmap, u32 handle, Common::Proce
.kind = 0,
.address = GetInteger(buffer),
};
R_UNLESS(nvmap.IocAlloc(alloc_params) == Nvidia::NvResult::Success, VI::ResultOperationFailed);
R_UNLESS(nvmap.IocAlloc(alloc_params, nvmap_fd) == Nvidia::NvResult::Success,
VI::ResultOperationFailed);
// We succeeded.
R_SUCCEED();
}
Result AllocateHandleForBuffer(u32* out_handle, Nvidia::Module& nvdrv,
Result AllocateHandleForBuffer(u32* out_handle, Nvidia::Module& nvdrv, Nvidia::DeviceFD nvmap_fd,
Common::ProcessAddress buffer, u32 size) {
// Get the nvmap device.
auto nvmap_fd = nvdrv.Open("/dev/nvmap");
auto nvmap = nvdrv.GetDevice<Nvidia::Devices::nvmap>(nvmap_fd);
ASSERT(nvmap != nullptr);
@ -127,11 +128,11 @@ Result AllocateHandleForBuffer(u32* out_handle, Nvidia::Module& nvdrv,
// Ensure we maintain a clean state on failure.
ON_RESULT_FAILURE {
ASSERT(R_SUCCEEDED(FreeNvMapHandle(*nvmap, *out_handle)));
ASSERT(R_SUCCEEDED(FreeNvMapHandle(*nvmap, *out_handle, nvmap_fd)));
};
// Assign the allocated memory to the handle.
R_RETURN(AllocNvMapHandle(*nvmap, *out_handle, buffer, size));
R_RETURN(AllocNvMapHandle(*nvmap, *out_handle, buffer, size, nvmap_fd));
}
constexpr auto SharedBufferBlockLinearFormat = android::PixelFormat::Rgba8888;
@ -197,9 +198,13 @@ Result FbShareBufferManager::Initialize(u64* out_buffer_id, u64* out_layer_id, u
std::addressof(m_buffer_page_group), m_system,
SharedBufferSize));
auto& container = m_nvdrv->GetContainer();
m_session_id = container.OpenSession(m_system.ApplicationProcess());
m_nvmap_fd = m_nvdrv->Open("/dev/nvmap", m_session_id);
// Create an nvmap handle for the buffer and assign the memory to it.
R_TRY(AllocateHandleForBuffer(std::addressof(m_buffer_nvmap_handle), *m_nvdrv, map_address,
SharedBufferSize));
R_TRY(AllocateHandleForBuffer(std::addressof(m_buffer_nvmap_handle), *m_nvdrv, m_nvmap_fd,
map_address, SharedBufferSize));
// Record the display id.
m_display_id = display_id;

5
src/core/hle/service/nvnflinger/fb_share_buffer_manager.h
View File

@ -4,6 +4,8 @@
#pragma once
#include "common/math_util.h"
#include "core/hle/service/nvdrv/core/container.h"
#include "core/hle/service/nvdrv/nvdata.h"
#include "core/hle/service/nvnflinger/nvnflinger.h"
#include "core/hle/service/nvnflinger/ui/fence.h"
@ -53,7 +55,8 @@ private:
u64 m_layer_id = 0;
u32 m_buffer_nvmap_handle = 0;
SharedMemoryPoolLayout m_pool_layout = {};
Nvidia::DeviceFD m_nvmap_fd = {};
Nvidia::NvCore::SessionId m_session_id = {};
std::unique_ptr<Kernel::KPageGroup> m_buffer_page_group;
std::mutex m_guard;

2
src/core/hle/service/nvnflinger/nvnflinger.cpp
View File

@ -124,7 +124,7 @@ void Nvnflinger::ShutdownLayers() {
void Nvnflinger::SetNVDrvInstance(std::shared_ptr<Nvidia::Module> instance) {
nvdrv = std::move(instance);
disp_fd = nvdrv->Open("/dev/nvdisp_disp0");
disp_fd = nvdrv->Open("/dev/nvdisp_disp0", {});
}
std::optional<u64> Nvnflinger::OpenDisplay(std::string_view name) {

2
src/core/hle/service/nvnflinger/ui/graphic_buffer.cpp
View File

@ -22,11 +22,13 @@ GraphicBuffer::GraphicBuffer(Service::Nvidia::NvCore::NvMap& nvmap,
: NvGraphicBuffer(GetBuffer(buffer)), m_nvmap(std::addressof(nvmap)) {
if (this->BufferId() > 0) {
m_nvmap->DuplicateHandle(this->BufferId(), true);
m_nvmap->PinHandle(this->BufferId(), false);
}
}
GraphicBuffer::~GraphicBuffer() {
if (m_nvmap != nullptr && this->BufferId() > 0) {
m_nvmap->UnpinHandle(this->BufferId());
m_nvmap->FreeHandle(this->BufferId(), true);
}
}

108
src/core/memory.cpp
View File

@ -24,6 +24,8 @@
#include "core/hle/kernel/k_process.h"
#include "core/memory.h"
#include "video_core/gpu.h"
#include "video_core/host1x/gpu_device_memory_manager.h"
#include "video_core/host1x/host1x.h"
#include "video_core/rasterizer_download_area.h"
namespace Core::Memory {
@ -637,17 +639,6 @@ struct Memory::Impl {
LOG_DEBUG(HW_Memory, "Mapping {:016X} onto {:016X}-{:016X}", GetInteger(target),
base * YUZU_PAGESIZE, (base + size) * YUZU_PAGESIZE);
// During boot, current_page_table might not be set yet, in which case we need not flush
if (system.IsPoweredOn()) {
auto& gpu = system.GPU();
for (u64 i = 0; i < size; i++) {
const auto page = base + i;
if (page_table.pointers[page].Type() == Common::PageType::RasterizerCachedMemory) {
gpu.FlushAndInvalidateRegion(page << YUZU_PAGEBITS, YUZU_PAGESIZE);
}
}
}
const auto end = base + size;
ASSERT_MSG(end <= page_table.pointers.size(), "out of range mapping at {:016X}",
base + page_table.pointers.size());
@ -811,21 +802,33 @@ struct Memory::Impl {
return true;
}
void HandleRasterizerDownload(VAddr address, size_t size) {
void HandleRasterizerDownload(VAddr v_address, size_t size) {
const auto* p = GetPointerImpl(
v_address, []() {}, []() {});
if (!gpu_device_memory) [[unlikely]] {
gpu_device_memory = &system.Host1x().MemoryManager();
}
const size_t core = system.GetCurrentHostThreadID();
auto& current_area = rasterizer_read_areas[core];
const VAddr end_address = address + size;
if (current_area.start_address <= address && end_address <= current_area.end_address)
[[likely]] {
return;
}
current_area = system.GPU().OnCPURead(address, size);
gpu_device_memory->ApplyOpOnPointer(p, scratch_buffers[core], [&](DAddr address) {
const DAddr end_address = address + size;
if (current_area.start_address <= address && end_address <= current_area.end_address)
[[likely]] {
return;
}
current_area = system.GPU().OnCPURead(address, size);
});
}
void HandleRasterizerWrite(VAddr address, size_t size) {
void HandleRasterizerWrite(VAddr v_address, size_t size) {
const auto* p = GetPointerImpl(
v_address, []() {}, []() {});
constexpr size_t sys_core = Core::Hardware::NUM_CPU_CORES - 1;
const size_t core = std::min(system.GetCurrentHostThreadID(),
sys_core); // any other calls threads go to syscore.
if (!gpu_device_memory) [[unlikely]] {
gpu_device_memory = &system.Host1x().MemoryManager();
}
// Guard on sys_core;
if (core == sys_core) [[unlikely]] {
sys_core_guard.lock();
@ -835,36 +838,53 @@ struct Memory::Impl {
sys_core_guard.unlock();
}
});
auto& current_area = rasterizer_write_areas[core];
VAddr subaddress = address >> YUZU_PAGEBITS;
bool do_collection = current_area.last_address == subaddress;
if (!do_collection) [[unlikely]] {
do_collection = system.GPU().OnCPUWrite(address, size);
if (!do_collection) {
return;
gpu_device_memory->ApplyOpOnPointer(p, scratch_buffers[core], [&](DAddr address) {
auto& current_area = rasterizer_write_areas[core];
PAddr subaddress = address >> YUZU_PAGEBITS;
bool do_collection = current_area.last_address == subaddress;
if (!do_collection) [[unlikely]] {
do_collection = system.GPU().OnCPUWrite(address, size);
if (!do_collection) {
return;
}
current_area.last_address = subaddress;
}
current_area.last_address = subaddress;
}
gpu_dirty_managers[core].Collect(address, size);
gpu_dirty_managers[core].Collect(address, size);
});
}
struct GPUDirtyState {
VAddr last_address;
PAddr last_address;
};
void InvalidateRegion(Common::ProcessAddress dest_addr, size_t size) {
system.GPU().InvalidateRegion(GetInteger(dest_addr), size);
}
void FlushRegion(Common::ProcessAddress dest_addr, size_t size) {
system.GPU().FlushRegion(GetInteger(dest_addr), size);
void InvalidateGPUMemory(u8* p, size_t size) {
constexpr size_t sys_core = Core::Hardware::NUM_CPU_CORES - 1;
const size_t core = std::min(system.GetCurrentHostThreadID(),
sys_core); // any other calls threads go to syscore.
if (!gpu_device_memory) [[unlikely]] {
gpu_device_memory = &system.Host1x().MemoryManager();
}
// Guard on sys_core;
if (core == sys_core) [[unlikely]] {
sys_core_guard.lock();
}
SCOPE_EXIT({
if (core == sys_core) [[unlikely]] {
sys_core_guard.unlock();
}
});
auto& gpu = system.GPU();
gpu_device_memory->ApplyOpOnPointer(
p, scratch_buffers[core], [&](DAddr address) { gpu.InvalidateRegion(address, size); });
}
Core::System& system;
Tegra::MaxwellDeviceMemoryManager* gpu_device_memory{};
Common::PageTable* current_page_table = nullptr;
std::array<VideoCore::RasterizerDownloadArea, Core::Hardware::NUM_CPU_CORES>
rasterizer_read_areas{};
std::array<GPUDirtyState, Core::Hardware::NUM_CPU_CORES> rasterizer_write_areas{};
std::array<Common::ScratchBuffer<u32>, Core::Hardware::NUM_CPU_CORES> scratch_buffers{};
std::span<Core::GPUDirtyMemoryManager> gpu_dirty_managers;
std::mutex sys_core_guard;
@ -1059,14 +1079,6 @@ void Memory::MarkRegionDebug(Common::ProcessAddress vaddr, u64 size, bool debug)
impl->MarkRegionDebug(GetInteger(vaddr), size, debug);
}
void Memory::InvalidateRegion(Common::ProcessAddress dest_addr, size_t size) {
impl->InvalidateRegion(dest_addr, size);
}
void Memory::FlushRegion(Common::ProcessAddress dest_addr, size_t size) {
impl->FlushRegion(dest_addr, size);
}
bool Memory::InvalidateNCE(Common::ProcessAddress vaddr, size_t size) {
[[maybe_unused]] bool mapped = true;
[[maybe_unused]] bool rasterizer = false;
@ -1078,10 +1090,10 @@ bool Memory::InvalidateNCE(Common::ProcessAddress vaddr, size_t size) {
GetInteger(vaddr));
mapped = false;
},
[&] {
impl->system.GPU().InvalidateRegion(GetInteger(vaddr), size);
rasterizer = true;
});
[&] { rasterizer = true; });
if (rasterizer) {
impl->InvalidateGPUMemory(ptr, size);
}
#ifdef __linux__
if (!rasterizer && mapped) {

211
src/core/memory.h
View File

@ -12,6 +12,7 @@
#include "common/scratch_buffer.h"
#include "common/typed_address.h"
#include "core/guest_memory.h"
#include "core/hle/result.h"
namespace Common {
@ -486,10 +487,10 @@ public:
void MarkRegionDebug(Common::ProcessAddress vaddr, u64 size, bool debug);
void SetGPUDirtyManagers(std::span<Core::GPUDirtyMemoryManager> managers);
void InvalidateRegion(Common::ProcessAddress dest_addr, size_t size);
bool InvalidateNCE(Common::ProcessAddress vaddr, size_t size);
bool InvalidateSeparateHeap(void* fault_address);
void FlushRegion(Common::ProcessAddress dest_addr, size_t size);
private:
Core::System& system;
@ -498,209 +499,9 @@ private:
std::unique_ptr<Impl> impl;
};
enum GuestMemoryFlags : u32 {
Read = 1 << 0,
Write = 1 << 1,
Safe = 1 << 2,
Cached = 1 << 3,
SafeRead = Read | Safe,
SafeWrite = Write | Safe,
SafeReadWrite = SafeRead | SafeWrite,
SafeReadCachedWrite = SafeReadWrite | Cached,
UnsafeRead = Read,
UnsafeWrite = Write,
UnsafeReadWrite = UnsafeRead | UnsafeWrite,
UnsafeReadCachedWrite = UnsafeReadWrite | Cached,
};
namespace {
template <typename M, typename T, GuestMemoryFlags FLAGS>
class GuestMemory {
using iterator = T*;
using const_iterator = const T*;
using value_type = T;
using element_type = T;
using iterator_category = std::contiguous_iterator_tag;
public:
GuestMemory() = delete;
explicit GuestMemory(M& memory, u64 addr, std::size_t size,
Common::ScratchBuffer<T>* backup = nullptr)
: m_memory{memory}, m_addr{addr}, m_size{size} {
static_assert(FLAGS & GuestMemoryFlags::Read || FLAGS & GuestMemoryFlags::Write);
if constexpr (FLAGS & GuestMemoryFlags::Read) {
Read(addr, size, backup);
}
}
~GuestMemory() = default;
T* data() noexcept {
return m_data_span.data();
}
const T* data() const noexcept {
return m_data_span.data();
}
size_t size() const noexcept {
return m_size;
}
size_t size_bytes() const noexcept {
return this->size() * sizeof(T);
}
[[nodiscard]] T* begin() noexcept {
return this->data();
}
[[nodiscard]] const T* begin() const noexcept {
return this->data();
}
[[nodiscard]] T* end() noexcept {
return this->data() + this->size();
}
[[nodiscard]] const T* end() const noexcept {
return this->data() + this->size();
}
T& operator[](size_t index) noexcept {
return m_data_span[index];
}
const T& operator[](size_t index) const noexcept {
return m_data_span[index];
}
void SetAddressAndSize(u64 addr, std::size_t size) noexcept {
m_addr = addr;
m_size = size;
m_addr_changed = true;
}
std::span<T> Read(u64 addr, std::size_t size,
Common::ScratchBuffer<T>* backup = nullptr) noexcept {
m_addr = addr;
m_size = size;
if (m_size == 0) {
m_is_data_copy = true;
return {};
}
if (this->TrySetSpan()) {
if constexpr (FLAGS & GuestMemoryFlags::Safe) {
m_memory.FlushRegion(m_addr, this->size_bytes());
}
} else {
if (backup) {
backup->resize_destructive(this->size());
m_data_span = *backup;
} else {
m_data_copy.resize(this->size());
m_data_span = std::span(m_data_copy);
}
m_is_data_copy = true;
m_span_valid = true;
if constexpr (FLAGS & GuestMemoryFlags::Safe) {
m_memory.ReadBlock(m_addr, this->data(), this->size_bytes());
} else {
m_memory.ReadBlockUnsafe(m_addr, this->data(), this->size_bytes());
}
}
return m_data_span;
}
void Write(std::span<T> write_data) noexcept {
if constexpr (FLAGS & GuestMemoryFlags::Cached) {
m_memory.WriteBlockCached(m_addr, write_data.data(), this->size_bytes());
} else if constexpr (FLAGS & GuestMemoryFlags::Safe) {
m_memory.WriteBlock(m_addr, write_data.data(), this->size_bytes());
} else {
m_memory.WriteBlockUnsafe(m_addr, write_data.data(), this->size_bytes());
}
}
bool TrySetSpan() noexcept {
if (u8* ptr = m_memory.GetSpan(m_addr, this->size_bytes()); ptr) {
m_data_span = {reinterpret_cast<T*>(ptr), this->size()};
m_span_valid = true;
return true;
}
return false;
}
protected:
bool IsDataCopy() const noexcept {
return m_is_data_copy;
}
bool AddressChanged() const noexcept {
return m_addr_changed;
}
M& m_memory;
u64 m_addr{};
size_t m_size{};
std::span<T> m_data_span{};
std::vector<T> m_data_copy{};
bool m_span_valid{false};
bool m_is_data_copy{false};
bool m_addr_changed{false};
};
template <typename M, typename T, GuestMemoryFlags FLAGS>
class GuestMemoryScoped : public GuestMemory<M, T, FLAGS> {
public:
GuestMemoryScoped() = delete;
explicit GuestMemoryScoped(M& memory, u64 addr, std::size_t size,
Common::ScratchBuffer<T>* backup = nullptr)
: GuestMemory<M, T, FLAGS>(memory, addr, size, backup) {
if constexpr (!(FLAGS & GuestMemoryFlags::Read)) {
if (!this->TrySetSpan()) {
if (backup) {
this->m_data_span = *backup;
this->m_span_valid = true;
this->m_is_data_copy = true;
}
}
}
}
~GuestMemoryScoped() {
if constexpr (FLAGS & GuestMemoryFlags::Write) {
if (this->size() == 0) [[unlikely]] {
return;
}
if (this->AddressChanged() || this->IsDataCopy()) {
ASSERT(this->m_span_valid);
if constexpr (FLAGS & GuestMemoryFlags::Cached) {
this->m_memory.WriteBlockCached(this->m_addr, this->data(), this->size_bytes());
} else if constexpr (FLAGS & GuestMemoryFlags::Safe) {
this->m_memory.WriteBlock(this->m_addr, this->data(), this->size_bytes());
} else {
this->m_memory.WriteBlockUnsafe(this->m_addr, this->data(), this->size_bytes());
}
} else if constexpr ((FLAGS & GuestMemoryFlags::Safe) ||
(FLAGS & GuestMemoryFlags::Cached)) {
this->m_memory.InvalidateRegion(this->m_addr, this->size_bytes());
}
}
}
};
} // namespace
template <typename T, GuestMemoryFlags FLAGS>
using CpuGuestMemory = GuestMemory<Memory, T, FLAGS>;
using CpuGuestMemory = GuestMemory<Core::Memory::Memory, T, FLAGS>;
template <typename T, GuestMemoryFlags FLAGS>
using CpuGuestMemoryScoped = GuestMemoryScoped<Memory, T, FLAGS>;
template <typename T, GuestMemoryFlags FLAGS>
using GpuGuestMemory = GuestMemory<Tegra::MemoryManager, T, FLAGS>;
template <typename T, GuestMemoryFlags FLAGS>
using GpuGuestMemoryScoped = GuestMemoryScoped<Tegra::MemoryManager, T, FLAGS>;
using CpuGuestMemoryScoped = GuestMemoryScoped<Core::Memory::Memory, T, FLAGS>;
} // namespace Core::Memory