// Copyright 2014 Citra Emulator Project // Licensed under GPLv2 or any later version // Refer to the license.txt file included. #include #include #include #include #include "audio_core/dsp_interface.h" #include "audio_core/hle/hle.h" #include "audio_core/lle/lle.h" #include "common/arch.h" #include "common/logging/log.h" #include "common/settings.h" #include "common/texture.h" #include "core/arm/arm_interface.h" #include "core/arm/exclusive_monitor.h" #if CITRA_ARCH(x86_64) || CITRA_ARCH(arm64) #include "core/arm/dynarmic/arm_dynarmic.h" #endif #include "core/arm/dyncom/arm_dyncom.h" #include "core/cheats/cheats.h" #include "core/core.h" #include "core/core_timing.h" #include "core/dumping/backend.h" #include "core/dumping/ffmpeg_backend.h" #include "core/frontend/image_interface.h" #include "core/gdbstub/gdbstub.h" #include "core/global.h" #include "core/hle/kernel/client_port.h" #include "core/hle/kernel/kernel.h" #include "core/hle/kernel/process.h" #include "core/hle/kernel/thread.h" #include "core/hle/service/apt/applet_manager.h" #include "core/hle/service/apt/apt.h" #include "core/hle/service/fs/archive.h" #include "core/hle/service/gsp/gsp.h" #include "core/hle/service/pm/pm_app.h" #include "core/hle/service/service.h" #include "core/hle/service/sm/sm.h" #include "core/hw/gpu.h" #include "core/hw/hw.h" #include "core/hw/lcd.h" #include "core/loader/loader.h" #include "core/movie.h" #include "core/rpc/rpc_server.h" #include "network/network.h" #include "video_core/custom_textures/custom_tex_manager.h" #include "video_core/renderer_base.h" #include "video_core/video_core.h" namespace Core { template <> Core::System& Global() { return System::GetInstance(); } template <> Kernel::KernelSystem& Global() { return System::GetInstance().Kernel(); } template <> Core::Timing& Global() { return System::GetInstance().CoreTiming(); } System::~System() = default; void System::InitializeGlobalInstance() { if (s_instance) { std::abort(); } s_instance = std::unique_ptr(new System); } System::ResultStatus System::RunLoop(bool tight_loop) { status = ResultStatus::Success; if (!IsPoweredOn()) { return ResultStatus::ErrorNotInitialized; } if (GDBStub::IsServerEnabled()) { Kernel::Thread* thread = kernel->GetCurrentThreadManager().GetCurrentThread(); if (thread && running_core) { running_core->SaveContext(thread->context); } GDBStub::HandlePacket(); // If the loop is halted and we want to step, use a tiny (1) number of instructions to // execute. Otherwise, get out of the loop function. if (GDBStub::GetCpuHaltFlag()) { if (GDBStub::GetCpuStepFlag()) { tight_loop = false; } else { return ResultStatus::Success; } } } Signal signal{Signal::None}; u32 param{}; { std::lock_guard lock{signal_mutex}; if (current_signal != Signal::None) { signal = current_signal; param = signal_param; current_signal = Signal::None; } } switch (signal) { case Signal::Reset: Reset(); return ResultStatus::Success; case Signal::Shutdown: return ResultStatus::ShutdownRequested; case Signal::Load: { const u32 slot = param; LOG_INFO(Core, "Begin load of slot {}", slot); try { System::LoadState(slot); LOG_INFO(Core, "Load completed"); } catch (const std::exception& e) { LOG_ERROR(Core, "Error loading: {}", e.what()); status_details = e.what(); return ResultStatus::ErrorSavestate; } frame_limiter.WaitOnce(); return ResultStatus::Success; } case Signal::Save: { const u32 slot = param; LOG_INFO(Core, "Begin save to slot {}", slot); try { System::SaveState(slot); LOG_INFO(Core, "Save completed"); } catch (const std::exception& e) { LOG_ERROR(Core, "Error saving: {}", e.what()); status_details = e.what(); return ResultStatus::ErrorSavestate; } frame_limiter.WaitOnce(); return ResultStatus::Success; } default: break; } // All cores should have executed the same amount of ticks. If this is not the case an event was // scheduled with a cycles_into_future smaller then the current downcount. // So we have to get those cores to the same global time first u64 global_ticks = timing->GetGlobalTicks(); s64 max_delay = 0; ARM_Interface* current_core_to_execute = nullptr; for (auto& cpu_core : cpu_cores) { if (cpu_core->GetTimer().GetTicks() < global_ticks) { s64 delay = global_ticks - cpu_core->GetTimer().GetTicks(); kernel->SetRunningCPU(cpu_core.get()); cpu_core->GetTimer().Advance(); cpu_core->PrepareReschedule(); kernel->GetThreadManager(cpu_core->GetID()).Reschedule(); cpu_core->GetTimer().SetNextSlice(delay); if (max_delay < delay) { max_delay = delay; current_core_to_execute = cpu_core.get(); } } } // jit sometimes overshoot by a few ticks which might lead to a minimal desync in the cores. // This small difference shouldn't make it necessary to sync the cores and would only cost // performance. Thus we don't sync delays below min_delay static constexpr s64 min_delay = 100; if (max_delay > min_delay) { LOG_TRACE(Core_ARM11, "Core {} running (delayed) for {} ticks", current_core_to_execute->GetID(), current_core_to_execute->GetTimer().GetDowncount()); if (running_core != current_core_to_execute) { running_core = current_core_to_execute; kernel->SetRunningCPU(running_core); } if (kernel->GetCurrentThreadManager().GetCurrentThread() == nullptr) { LOG_TRACE(Core_ARM11, "Core {} idling", current_core_to_execute->GetID()); current_core_to_execute->GetTimer().Idle(); PrepareReschedule(); } else { if (tight_loop) { current_core_to_execute->Run(); } else { current_core_to_execute->Step(); } } } else { // Now all cores are at the same global time. So we will run them one after the other // with a max slice that is the minimum of all max slices of all cores // TODO: Make special check for idle since we can easily revert the time of idle cores s64 max_slice = Timing::MAX_SLICE_LENGTH; for (const auto& cpu_core : cpu_cores) { kernel->SetRunningCPU(cpu_core.get()); cpu_core->GetTimer().Advance(); cpu_core->PrepareReschedule(); kernel->GetThreadManager(cpu_core->GetID()).Reschedule(); max_slice = std::min(max_slice, cpu_core->GetTimer().GetMaxSliceLength()); } for (auto& cpu_core : cpu_cores) { cpu_core->GetTimer().SetNextSlice(max_slice); auto start_ticks = cpu_core->GetTimer().GetTicks(); LOG_TRACE(Core_ARM11, "Core {} running for {} ticks", cpu_core->GetID(), cpu_core->GetTimer().GetDowncount()); running_core = cpu_core.get(); kernel->SetRunningCPU(running_core); // If we don't have a currently active thread then don't execute instructions, // instead advance to the next event and try to yield to the next thread if (kernel->GetCurrentThreadManager().GetCurrentThread() == nullptr) { LOG_TRACE(Core_ARM11, "Core {} idling", cpu_core->GetID()); cpu_core->GetTimer().Idle(); PrepareReschedule(); } else { if (tight_loop) { cpu_core->Run(); } else { cpu_core->Step(); } } max_slice = cpu_core->GetTimer().GetTicks() - start_ticks; } } if (GDBStub::IsServerEnabled()) { GDBStub::SetCpuStepFlag(false); } HW::Update(); Reschedule(); return status; } bool System::SendSignal(System::Signal signal, u32 param) { std::lock_guard lock{signal_mutex}; if (current_signal != signal && current_signal != Signal::None) { LOG_ERROR(Core, "Unable to {} as {} is ongoing", signal, current_signal); return false; } current_signal = signal; signal_param = param; return true; } System::ResultStatus System::SingleStep() { return RunLoop(false); } System::ResultStatus System::Load(Frontend::EmuWindow& emu_window, const std::string& filepath, Frontend::EmuWindow* secondary_window) { FileUtil::SetCurrentRomPath(filepath); app_loader = Loader::GetLoader(filepath); if (!app_loader) { LOG_CRITICAL(Core, "Failed to obtain loader for {}!", filepath); return ResultStatus::ErrorGetLoader; } std::pair, Loader::ResultStatus> system_mode = app_loader->LoadKernelSystemMode(); if (system_mode.second != Loader::ResultStatus::Success) { LOG_CRITICAL(Core, "Failed to determine system mode (Error {})!", static_cast(system_mode.second)); switch (system_mode.second) { case Loader::ResultStatus::ErrorEncrypted: return ResultStatus::ErrorLoader_ErrorEncrypted; case Loader::ResultStatus::ErrorInvalidFormat: return ResultStatus::ErrorLoader_ErrorInvalidFormat; case Loader::ResultStatus::ErrorGbaTitle: return ResultStatus::ErrorLoader_ErrorGbaTitle; default: return ResultStatus::ErrorSystemMode; } } ASSERT(system_mode.first); auto n3ds_mode = app_loader->LoadKernelN3dsMode(); ASSERT(n3ds_mode.first); u32 num_cores = 2; if (Settings::values.is_new_3ds) { num_cores = 4; } ResultStatus init_result{ Init(emu_window, secondary_window, *system_mode.first, *n3ds_mode.first, num_cores)}; if (init_result != ResultStatus::Success) { LOG_CRITICAL(Core, "Failed to initialize system (Error {})!", static_cast(init_result)); System::Shutdown(); return init_result; } telemetry_session->AddInitialInfo(*app_loader); std::shared_ptr process; const Loader::ResultStatus load_result{app_loader->Load(process)}; if (Loader::ResultStatus::Success != load_result) { LOG_CRITICAL(Core, "Failed to load ROM (Error {})!", load_result); System::Shutdown(); switch (load_result) { case Loader::ResultStatus::ErrorEncrypted: return ResultStatus::ErrorLoader_ErrorEncrypted; case Loader::ResultStatus::ErrorInvalidFormat: return ResultStatus::ErrorLoader_ErrorInvalidFormat; case Loader::ResultStatus::ErrorGbaTitle: return ResultStatus::ErrorLoader_ErrorGbaTitle; default: return ResultStatus::ErrorLoader; } } kernel->SetCurrentProcess(process); title_id = 0; if (app_loader->ReadProgramId(title_id) != Loader::ResultStatus::Success) { LOG_ERROR(Core, "Failed to find title id for ROM (Error {})", static_cast(load_result)); } cheat_engine = std::make_unique(title_id, *this); perf_stats = std::make_unique(title_id); if (Settings::values.custom_textures) { custom_tex_manager->FindCustomTextures(); } if (Settings::values.dump_textures) { custom_tex_manager->WriteConfig(); } status = ResultStatus::Success; m_emu_window = &emu_window; m_secondary_window = secondary_window; m_filepath = filepath; self_delete_pending = false; // Reset counters and set time origin to current frame [[maybe_unused]] const PerfStats::Results result = GetAndResetPerfStats(); perf_stats->BeginSystemFrame(); return status; } void System::PrepareReschedule() { running_core->PrepareReschedule(); reschedule_pending = true; } PerfStats::Results System::GetAndResetPerfStats() { return (perf_stats && timing) ? perf_stats->GetAndResetStats(timing->GetGlobalTimeUs()) : PerfStats::Results{}; } void System::Reschedule() { if (!reschedule_pending) { return; } reschedule_pending = false; for (const auto& core : cpu_cores) { LOG_TRACE(Core_ARM11, "Reschedule core {}", core->GetID()); kernel->GetThreadManager(core->GetID()).Reschedule(); } } System::ResultStatus System::Init(Frontend::EmuWindow& emu_window, Frontend::EmuWindow* secondary_window, u32 system_mode, u8 n3ds_mode, u32 num_cores) { LOG_DEBUG(HW_Memory, "initialized OK"); memory = std::make_unique(); timing = std::make_unique(num_cores, Settings::values.cpu_clock_percentage.GetValue()); kernel = std::make_unique( *memory, *timing, [this] { PrepareReschedule(); }, system_mode, num_cores, n3ds_mode); exclusive_monitor = MakeExclusiveMonitor(*memory, num_cores); cpu_cores.reserve(num_cores); if (Settings::values.use_cpu_jit) { #if CITRA_ARCH(x86_64) || CITRA_ARCH(arm64) for (u32 i = 0; i < num_cores; ++i) { cpu_cores.push_back(std::make_shared( this, *memory, i, timing->GetTimer(i), *exclusive_monitor)); } #else for (u32 i = 0; i < num_cores; ++i) { cpu_cores.push_back( std::make_shared(this, *memory, USER32MODE, i, timing->GetTimer(i))); } LOG_WARNING(Core, "CPU JIT requested, but Dynarmic not available"); #endif } else { for (u32 i = 0; i < num_cores; ++i) { cpu_cores.push_back( std::make_shared(this, *memory, USER32MODE, i, timing->GetTimer(i))); } } running_core = cpu_cores[0].get(); kernel->SetCPUs(cpu_cores); kernel->SetRunningCPU(cpu_cores[0].get()); const auto audio_emulation = Settings::values.audio_emulation.GetValue(); if (audio_emulation == Settings::AudioEmulation::HLE) { dsp_core = std::make_unique(*memory, *timing); } else { const bool multithread = audio_emulation == Settings::AudioEmulation::LLEMultithreaded; dsp_core = std::make_unique(*memory, *timing, multithread); } memory->SetDSP(*dsp_core); dsp_core->SetSink(Settings::values.output_type.GetValue(), Settings::values.output_device.GetValue()); dsp_core->EnableStretching(Settings::values.enable_audio_stretching.GetValue()); telemetry_session = std::make_unique(); rpc_server = std::make_unique(); service_manager = std::make_unique(*this); archive_manager = std::make_unique(*this); HW::Init(*memory); Service::Init(*this); GDBStub::DeferStart(); if (!registered_image_interface) { registered_image_interface = std::make_shared(); } custom_tex_manager = std::make_unique(*this); VideoCore::Init(emu_window, secondary_window, *this); LOG_DEBUG(Core, "Initialized OK"); is_powered_on = true; return ResultStatus::Success; } VideoCore::RendererBase& System::Renderer() { return *VideoCore::g_renderer; } Service::SM::ServiceManager& System::ServiceManager() { return *service_manager; } const Service::SM::ServiceManager& System::ServiceManager() const { return *service_manager; } Service::FS::ArchiveManager& System::ArchiveManager() { return *archive_manager; } const Service::FS::ArchiveManager& System::ArchiveManager() const { return *archive_manager; } Kernel::KernelSystem& System::Kernel() { return *kernel; } const Kernel::KernelSystem& System::Kernel() const { return *kernel; } bool System::KernelRunning() { return kernel != nullptr; } Timing& System::CoreTiming() { return *timing; } const Timing& System::CoreTiming() const { return *timing; } Memory::MemorySystem& System::Memory() { return *memory; } const Memory::MemorySystem& System::Memory() const { return *memory; } Cheats::CheatEngine& System::CheatEngine() { return *cheat_engine; } const Cheats::CheatEngine& System::CheatEngine() const { return *cheat_engine; } void System::RegisterVideoDumper(std::shared_ptr dumper) { video_dumper = std::move(dumper); } VideoCore::CustomTexManager& System::CustomTexManager() { return *custom_tex_manager; } const VideoCore::CustomTexManager& System::CustomTexManager() const { return *custom_tex_manager; } void System::RegisterMiiSelector(std::shared_ptr mii_selector) { registered_mii_selector = std::move(mii_selector); } void System::RegisterSoftwareKeyboard(std::shared_ptr swkbd) { registered_swkbd = std::move(swkbd); } void System::RegisterImageInterface(std::shared_ptr image_interface) { registered_image_interface = std::move(image_interface); } void System::Shutdown(bool is_deserializing) { // Log last frame performance stats const auto perf_results = GetAndResetPerfStats(); constexpr auto performance = Common::Telemetry::FieldType::Performance; telemetry_session->AddField(performance, "Shutdown_EmulationSpeed", perf_results.emulation_speed * 100.0); telemetry_session->AddField(performance, "Shutdown_Framerate", perf_results.game_fps); telemetry_session->AddField(performance, "Shutdown_Frametime", perf_results.frametime * 1000.0); telemetry_session->AddField(performance, "Mean_Frametime_MS", perf_stats ? perf_stats->GetMeanFrametime() : 0); // Shutdown emulation session is_powered_on = false; VideoCore::Shutdown(); HW::Shutdown(); if (!is_deserializing) { GDBStub::Shutdown(); perf_stats.reset(); cheat_engine.reset(); app_loader.reset(); } custom_tex_manager.reset(); telemetry_session.reset(); rpc_server.reset(); archive_manager.reset(); service_manager.reset(); dsp_core.reset(); kernel.reset(); cpu_cores.clear(); exclusive_monitor.reset(); timing.reset(); if (video_dumper && video_dumper->IsDumping()) { video_dumper->StopDumping(); } if (auto room_member = Network::GetRoomMember().lock()) { Network::GameInfo game_info{}; room_member->SendGameInfo(game_info); } memory.reset(); if (self_delete_pending) FileUtil::Delete(m_filepath); self_delete_pending = false; LOG_DEBUG(Core, "Shutdown OK"); } void System::Reset() { // This is NOT a proper reset, but a temporary workaround by shutting down the system and // reloading. // TODO: Properly implement the reset // Since the system is completely reinitialized, we'll have to store the deliver arg manually. boost::optional deliver_arg; if (auto apt = Service::APT::GetModule(*this)) { deliver_arg = apt->GetAppletManager()->ReceiveDeliverArg(); } Shutdown(); if (!m_chainloadpath.empty()) { m_filepath = m_chainloadpath; m_chainloadpath.clear(); } // Reload the system with the same setting [[maybe_unused]] const System::ResultStatus result = Load(*m_emu_window, m_filepath, m_secondary_window); // Restore the deliver arg. if (auto apt = Service::APT::GetModule(*this)) { apt->GetAppletManager()->SetDeliverArg(std::move(deliver_arg)); } } template void System::serialize(Archive& ar, const unsigned int file_version) { u32 num_cores; if (Archive::is_saving::value) { num_cores = this->GetNumCores(); } ar& num_cores; if (Archive::is_loading::value) { // When loading, we want to make sure any lingering state gets cleared out before we begin. // Shutdown, but persist a few things between loads... Shutdown(true); // Re-initialize everything like it was before auto system_mode = this->app_loader->LoadKernelSystemMode(); auto n3ds_mode = this->app_loader->LoadKernelN3dsMode(); [[maybe_unused]] const System::ResultStatus result = Init( *m_emu_window, m_secondary_window, *system_mode.first, *n3ds_mode.first, num_cores); } // flush on save, don't flush on load bool should_flush = !Archive::is_loading::value; Memory::RasterizerClearAll(should_flush); ar&* timing.get(); for (u32 i = 0; i < num_cores; i++) { ar&* cpu_cores[i].get(); } ar&* service_manager.get(); ar&* archive_manager.get(); ar& GPU::g_regs; ar& LCD::g_regs; // NOTE: DSP doesn't like being destroyed and recreated. So instead we do an inline // serialization; this means that the DSP Settings need to match for loading to work. auto dsp_hle = dynamic_cast(dsp_core.get()); if (dsp_hle) { ar&* dsp_hle; } else { throw std::runtime_error("LLE audio not supported for save states"); } ar&* memory.get(); ar&* kernel.get(); VideoCore::serialize(ar, file_version); if (file_version >= 1) { ar& Movie::GetInstance(); } // This needs to be set from somewhere - might as well be here! if (Archive::is_loading::value) { timing->UnlockEventQueue(); Service::GSP::SetGlobalModule(*this); memory->SetDSP(*dsp_core); cheat_engine->Connect(); VideoCore::g_renderer->Sync(); } } SERIALIZE_IMPL(System) } // namespace Core