early-access version 3447

This commit is contained in:
pineappleEA 2023-03-10 21:31:28 +01:00
parent 3100016035
commit f7cf0f6559
6 changed files with 157 additions and 58 deletions

View file

@ -1,7 +1,7 @@
yuzu emulator early access
=============
This is the source code for early-access 3446.
This is the source code for early-access 3447.
## Legal Notice

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@ -119,7 +119,7 @@ void Cabinet::DisplayCompleted(bool apply_changes, std::string_view amiibo_name)
case Service::NFP::CabinetMode::StartNicknameAndOwnerSettings: {
Service::NFP::AmiiboName name{};
std::memcpy(name.data(), amiibo_name.data(), std::min(amiibo_name.size(), name.size() - 1));
nfp_device->SetNicknameAndOwner(name);
nfp_device->SetRegisterInfoPrivate(name);
break;
}
case Service::NFP::CabinetMode::StartGameDataEraser:
@ -129,7 +129,7 @@ void Cabinet::DisplayCompleted(bool apply_changes, std::string_view amiibo_name)
nfp_device->RestoreAmiibo();
break;
case Service::NFP::CabinetMode::StartFormatter:
nfp_device->DeleteAllData();
nfp_device->Format();
break;
default:
UNIMPLEMENTED_MSG("Unknown CabinetMode={}", applet_input_common.applet_mode);

View file

@ -404,8 +404,8 @@ Result NfpDevice::GetAdminInfo(AdminInfo& admin_info) const {
// Restore application id to original value
if (application_id >> 0x38 != 0) {
const u8 application_byte = tag_data.application_id_byte & 0xf;
application_id &= ~(0xfULL << application_id_version_offset);
application_id |= static_cast<u64>(application_byte) << application_id_version_offset;
application_id = RemoveVersionByte(application_id) |
(static_cast<u64>(application_byte) << application_id_version_offset);
}
application_area_id = tag_data.application_area_id;
@ -424,7 +424,39 @@ Result NfpDevice::GetAdminInfo(AdminInfo& admin_info) const {
return ResultSuccess;
}
Result NfpDevice::SetNicknameAndOwner(const AmiiboName& amiibo_name) {
Result NfpDevice::DeleteRegisterInfo() {
if (device_state != DeviceState::TagMounted) {
LOG_ERROR(Service_NFC, "Wrong device state {}", device_state);
if (device_state == DeviceState::TagRemoved) {
return TagRemoved;
}
return WrongDeviceState;
}
if (mount_target == MountTarget::None || mount_target == MountTarget::Rom) {
LOG_ERROR(Service_NFC, "Amiibo is read only", device_state);
return WrongDeviceState;
}
if (tag_data.settings.settings.amiibo_initialized == 0) {
return RegistrationIsNotInitialized;
}
Common::TinyMT rng{};
rng.GenerateRandomBytes(&tag_data.owner_mii, sizeof(tag_data.owner_mii));
rng.GenerateRandomBytes(&tag_data.settings.amiibo_name, sizeof(tag_data.settings.amiibo_name));
rng.GenerateRandomBytes(&tag_data.unknown, sizeof(u8));
rng.GenerateRandomBytes(&tag_data.unknown2[0], sizeof(u32));
rng.GenerateRandomBytes(&tag_data.unknown2[1], sizeof(u32));
rng.GenerateRandomBytes(&tag_data.application_area_crc, sizeof(u32));
rng.GenerateRandomBytes(&tag_data.settings.init_date, sizeof(u32));
tag_data.settings.settings.font_region.Assign(0);
tag_data.settings.settings.amiibo_initialized.Assign(0);
return Flush();
}
Result NfpDevice::SetRegisterInfoPrivate(const AmiiboName& amiibo_name) {
if (device_state != DeviceState::TagMounted) {
LOG_ERROR(Service_NFP, "Wrong device state {}", device_state);
if (device_state == DeviceState::TagRemoved) {
@ -441,14 +473,23 @@ Result NfpDevice::SetNicknameAndOwner(const AmiiboName& amiibo_name) {
Service::Mii::MiiManager manager;
auto& settings = tag_data.settings;
if (tag_data.settings.settings.amiibo_initialized == 0) {
settings.init_date = GetAmiiboDate(current_posix_time);
settings.write_date = GetAmiiboDate(current_posix_time);
UpdateSettingsCrc();
settings.write_date.raw_date = 0;
}
SetAmiiboName(settings, amiibo_name);
tag_data.owner_mii = manager.ConvertCharInfoToV3(manager.BuildDefault(0));
tag_data.unknown = 0;
tag_data.unknown2[6] = 0;
settings.country_code_id = 0;
settings.settings.font_region.Assign(0);
settings.settings.amiibo_initialized.Assign(1);
// TODO: this is a mix of tag.file input
std::array<u8, 0x7e> unknown_input{};
tag_data.application_area_crc = CalculateCrc(unknown_input);
return Flush();
}
@ -471,23 +512,17 @@ Result NfpDevice::RestoreAmiibo() {
return ResultSuccess;
}
Result NfpDevice::DeleteAllData() {
const auto result = DeleteApplicationArea();
if (result.IsError()) {
return result;
Result NfpDevice::Format() {
auto result1 = DeleteApplicationArea();
auto result2 = DeleteRegisterInfo();
if (result1.IsError()) {
return result1;
}
if (device_state != DeviceState::TagMounted) {
LOG_ERROR(Service_NFP, "Wrong device state {}", device_state);
if (device_state == DeviceState::TagRemoved) {
return TagRemoved;
if (result2.IsError()) {
return result2;
}
return WrongDeviceState;
}
Common::TinyMT rng{};
rng.GenerateRandomBytes(&tag_data.owner_mii, sizeof(tag_data.owner_mii));
tag_data.settings.settings.amiibo_initialized.Assign(0);
return Flush();
}
@ -671,13 +706,11 @@ Result NfpDevice::RecreateApplicationArea(u32 access_id, std::span<const u8> dat
}
const u64 application_id = system.GetApplicationProcessProgramID();
const u64 application_id_without_version_byte =
application_id & ~(0xfULL << application_id_version_offset);
tag_data.application_id_byte =
static_cast<u8>(application_id >> application_id_version_offset & 0xf);
tag_data.application_id =
application_id_without_version_byte |
RemoveVersionByte(application_id) |
(static_cast<u64>(AppAreaVersion::NintendoSwitch) << application_id_version_offset);
tag_data.settings.settings.appdata_initialized.Assign(1);
tag_data.application_area_id = access_id;
@ -704,12 +737,20 @@ Result NfpDevice::DeleteApplicationArea() {
return WrongDeviceState;
}
if (tag_data.settings.settings.appdata_initialized == 0) {
return ApplicationAreaIsNotInitialized;
}
if (tag_data.application_write_counter != counter_limit) {
tag_data.application_write_counter++;
}
Common::TinyMT rng{};
rng.GenerateRandomBytes(tag_data.application_area.data(), sizeof(ApplicationArea));
rng.GenerateRandomBytes(&tag_data.application_id, sizeof(u64));
rng.GenerateRandomBytes(&tag_data.application_area_id, sizeof(u32));
rng.GenerateRandomBytes(&tag_data.application_id_byte, sizeof(u8));
tag_data.settings.settings.appdata_initialized.Assign(0);
tag_data.application_write_counter++;
tag_data.unknown = {};
return Flush();
@ -781,6 +822,10 @@ AmiiboDate NfpDevice::GetAmiiboDate(s64 posix_time) const {
return amiibo_date;
}
u64 NfpDevice::RemoveVersionByte(u64 application_id) const {
return application_id & ~(0xfULL << application_id_version_offset);
}
void NfpDevice::UpdateSettingsCrc() {
auto& settings = tag_data.settings;
@ -793,7 +838,7 @@ void NfpDevice::UpdateSettingsCrc() {
settings.crc = CalculateCrc(unknown_input);
}
u32 NfpDevice::CalculateCrc(std::span<u8> data) {
u32 NfpDevice::CalculateCrc(std::span<const u8> data) {
constexpr u32 magic = 0xedb88320;
u32 crc = 0xffffffff;

View file

@ -49,9 +49,10 @@ public:
Result GetRegisterInfo(RegisterInfo& register_info) const;
Result GetAdminInfo(AdminInfo& admin_info) const;
Result SetNicknameAndOwner(const AmiiboName& amiibo_name);
Result DeleteRegisterInfo();
Result SetRegisterInfoPrivate(const AmiiboName& amiibo_name);
Result RestoreAmiibo();
Result DeleteAllData();
Result Format();
Result OpenApplicationArea(u32 access_id);
Result GetApplicationAreaId(u32& application_area_id) const;
@ -77,8 +78,9 @@ private:
AmiiboName GetAmiiboName(const AmiiboSettings& settings) const;
void SetAmiiboName(AmiiboSettings& settings, const AmiiboName& amiibo_name);
AmiiboDate GetAmiiboDate(s64 posix_time) const;
u64 RemoveVersionByte(u64 application_id) const;
void UpdateSettingsCrc();
u32 CalculateCrc(std::span<u8> data);
u32 CalculateCrc(std::span<const u8>);
bool is_controller_set{};
int callback_key;

View file

@ -47,24 +47,41 @@ Scheduler::Scheduler(const Device& device_, StateTracker& state_tracker_)
Scheduler::~Scheduler() = default;
void Scheduler::Flush(VkSemaphore signal_semaphore, VkSemaphore wait_semaphore) {
// When flushing, we only send data to the worker thread; no waiting is necessary.
SubmitExecution(signal_semaphore, wait_semaphore);
AllocateNewContext();
}
void Scheduler::Finish(VkSemaphore signal_semaphore, VkSemaphore wait_semaphore) {
// When finishing, we need to wait for the submission to have executed on the device.
const u64 presubmit_tick = CurrentTick();
SubmitExecution(signal_semaphore, wait_semaphore);
WaitWorker();
DrainRequests();
Wait(presubmit_tick);
AllocateNewContext();
}
void Scheduler::DrainRequests() {
MICROPROFILE_SCOPE(Vulkan_WaitForWorker);
DispatchWork();
// Wait until the queue is empty and the queue lock can be held.
// This drains the queue.
std::unique_lock ql{queue_mutex};
event_cv.wait(ql, [this] { return work_queue.empty(); });
}
void Scheduler::WaitWorker() {
MICROPROFILE_SCOPE(Vulkan_WaitForWorker);
DispatchWork();
std::unique_lock lock{work_mutex};
wait_cv.wait(lock, [this] { return work_queue.empty(); });
// Wait until the queue is empty and the execution lock can be held.
// This ensures Vulkan is aware of everything we have done when we return.
std::unique_lock el{execution_mutex};
event_cv.wait(el, [this] {
std::scoped_lock ql{queue_mutex};
return work_queue.empty();
});
}
void Scheduler::DispatchWork() {
@ -72,10 +89,10 @@ void Scheduler::DispatchWork() {
return;
}
{
std::scoped_lock lock{work_mutex};
std::scoped_lock ql{queue_mutex};
work_queue.push(std::move(chunk));
}
work_cv.notify_one();
event_cv.notify_all();
AcquireNewChunk();
}
@ -137,30 +154,59 @@ bool Scheduler::UpdateRescaling(bool is_rescaling) {
void Scheduler::WorkerThread(std::stop_token stop_token) {
Common::SetCurrentThreadName("VulkanWorker");
do {
std::unique_ptr<CommandChunk> work;
bool has_submit{false};
{
std::unique_lock lock{work_mutex};
const auto TryPopQueue{[this](auto& work) -> bool {
std::scoped_lock ql{queue_mutex};
if (work_queue.empty()) {
wait_cv.notify_all();
}
Common::CondvarWait(work_cv, lock, stop_token, [&] { return !work_queue.empty(); });
if (stop_token.stop_requested()) {
continue;
return false;
}
work = std::move(work_queue.front());
work_queue.pop();
event_cv.notify_all();
return true;
}};
has_submit = work->HasSubmit();
work->ExecuteAll(current_cmdbuf);
while (!stop_token.stop_requested()) {
std::unique_ptr<CommandChunk> work;
{
std::unique_lock el{execution_mutex};
// Wait for work.
Common::CondvarWait(event_cv, el, stop_token, [&] {
std::scoped_lock ql{queue_mutex};
return !work_queue.empty();
});
// If we've been asked to stop, we're done.
if (stop_token.stop_requested()) {
return;
}
// If we don't have any work, restart from the top.
if (!TryPopQueue(work)) {
continue;
}
// Perform the work, tracking whether the chunk was a submission
// before executing.
const bool has_submit = work->HasSubmit();
work->ExecuteAll(current_cmdbuf);
// If the chunk was a submission, reallocate the command buffer.
if (has_submit) {
AllocateWorkerCommandBuffer();
}
std::scoped_lock reserve_lock{reserve_mutex};
chunk_reserve.push_back(std::move(work));
} while (!stop_token.stop_requested());
}
{
std::scoped_lock rl{reserve_mutex};
// Recycle the chunk back to the reserve.
chunk_reserve.emplace_back(std::move(work));
}
}
}
void Scheduler::AllocateWorkerCommandBuffer() {
@ -289,13 +335,16 @@ void Scheduler::EndRenderPass() {
}
void Scheduler::AcquireNewChunk() {
std::scoped_lock lock{reserve_mutex};
std::scoped_lock rl{reserve_mutex};
if (chunk_reserve.empty()) {
// If we don't have anything reserved, we need to make a new chunk.
chunk = std::make_unique<CommandChunk>();
} else {
// Otherwise, we can just take from the reserve.
chunk = std::make_unique<CommandChunk>();
return;
}
chunk = std::move(chunk_reserve.back());
chunk_reserve.pop_back();
}
}
} // namespace Vulkan

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@ -39,6 +39,9 @@ public:
/// Sends the current execution context to the GPU and waits for it to complete.
void Finish(VkSemaphore signal_semaphore = nullptr, VkSemaphore wait_semaphore = nullptr);
/// Waits for the worker thread to begin executing everything.
void DrainRequests();
/// Waits for the worker thread to finish executing everything. After this function returns it's
/// safe to touch worker resources.
void WaitWorker();
@ -232,10 +235,10 @@ private:
std::queue<std::unique_ptr<CommandChunk>> work_queue;
std::vector<std::unique_ptr<CommandChunk>> chunk_reserve;
std::mutex execution_mutex;
std::mutex reserve_mutex;
std::mutex work_mutex;
std::condition_variable_any work_cv;
std::condition_variable wait_cv;
std::mutex queue_mutex;
std::condition_variable_any event_cv;
std::jthread worker_thread;
};