ryujinx/Ryujinx.HLE/HOS/Horizon.cs
Thog 644de99e86
Implement GPU syncpoints (#980)
* Implement GPU syncpoints

This adds support for GPU syncpoints on the GPU backend & nvservices.

Everything that was implemented here is based on my researches,
hardware testing of the GM20B and reversing of nvservices (8.1.0).

Thanks to @fincs for the informations about some behaviours of the pusher
and for the initial informations about syncpoints.

* syncpoint: address gdkchan's comments

* Add some missing logic to handle SubmitGpfifo correctly

* Handle the NV event API correctly

* evnt => hostEvent

* Finish addressing gdkchan's comments

* nvservices: write the output buffer even when an error is returned

* dma pusher: Implemnet prefetch barrier

lso fix when the commands should be prefetch.

* Partially fix prefetch barrier

* Add a missing syncpoint check in QueryEvent of NvHostSyncPt

* Address Ac_K's comments and fix GetSyncpoint for ChannelResourcePolicy == Channel

* fix SyncptWait & SyncptWaitEx cmds logic

* Address ripinperi's comments

* Address gdkchan's comments

* Move user event management to the control channel

* Fix mm implementation, nvdec works again

* Address ripinperi's comments

* Address gdkchan's comments

* Implement nvhost-ctrl close accurately + make nvservices dispose channels when stopping the emulator

* Fix typo in MultiMediaOperationType
2020-04-19 11:25:57 +10:00

900 lines
32 KiB
C#

using LibHac;
using LibHac.Account;
using LibHac.Common;
using LibHac.Fs;
using LibHac.FsSystem;
using LibHac.FsSystem.NcaUtils;
using LibHac.Ncm;
using LibHac.Ns;
using LibHac.Spl;
using Ryujinx.Common.Configuration;
using Ryujinx.Common.Logging;
using Ryujinx.Configuration;
using Ryujinx.HLE.FileSystem.Content;
using Ryujinx.HLE.HOS.Font;
using Ryujinx.HLE.HOS.Kernel.Common;
using Ryujinx.HLE.HOS.Kernel.Memory;
using Ryujinx.HLE.HOS.Kernel.Process;
using Ryujinx.HLE.HOS.Kernel.Threading;
using Ryujinx.HLE.HOS.Services.Mii;
using Ryujinx.HLE.HOS.Services.Nv.NvDrvServices.NvHostCtrl;
using Ryujinx.HLE.HOS.Services.Pcv.Bpc;
using Ryujinx.HLE.HOS.Services.Settings;
using Ryujinx.HLE.HOS.Services.Sm;
using Ryujinx.HLE.HOS.Services.SurfaceFlinger;
using Ryujinx.HLE.HOS.Services.Time.Clock;
using Ryujinx.HLE.HOS.SystemState;
using Ryujinx.HLE.Loaders.Executables;
using Ryujinx.HLE.Loaders.Npdm;
using Ryujinx.HLE.Utilities;
using System;
using System.Collections.Concurrent;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using System.Reflection;
using System.Threading;
using Utf8Json;
using Utf8Json.Resolvers;
using TimeServiceManager = Ryujinx.HLE.HOS.Services.Time.TimeManager;
using NsoExecutable = Ryujinx.HLE.Loaders.Executables.NsoExecutable;
using static LibHac.Fs.ApplicationSaveDataManagement;
using Ryujinx.HLE.HOS.Services.Nv;
namespace Ryujinx.HLE.HOS
{
public class Horizon : IDisposable
{
internal const int InitialKipId = 1;
internal const int InitialProcessId = 0x51;
internal const int HidSize = 0x40000;
internal const int FontSize = 0x1100000;
internal const int IirsSize = 0x8000;
internal const int TimeSize = 0x1000;
private const int MemoryBlockAllocatorSize = 0x2710;
private const ulong UserSlabHeapBase = DramMemoryMap.SlabHeapBase;
private const ulong UserSlabHeapItemSize = KMemoryManager.PageSize;
private const ulong UserSlabHeapSize = 0x3de000;
internal long PrivilegedProcessLowestId { get; set; } = 1;
internal long PrivilegedProcessHighestId { get; set; } = 8;
internal Switch Device { get; private set; }
public SystemStateMgr State { get; private set; }
internal bool KernelInitialized { get; private set; }
internal KResourceLimit ResourceLimit { get; private set; }
internal KMemoryRegionManager[] MemoryRegions { get; private set; }
internal KMemoryBlockAllocator LargeMemoryBlockAllocator { get; private set; }
internal KMemoryBlockAllocator SmallMemoryBlockAllocator { get; private set; }
internal KSlabHeap UserSlabHeapPages { get; private set; }
internal KCriticalSection CriticalSection { get; private set; }
internal KScheduler Scheduler { get; private set; }
internal KTimeManager TimeManager { get; private set; }
internal KSynchronization Synchronization { get; private set; }
internal KContextIdManager ContextIdManager { get; private set; }
private long _kipId;
private long _processId;
private long _threadUid;
internal CountdownEvent ThreadCounter;
internal SortedDictionary<long, KProcess> Processes;
internal ConcurrentDictionary<string, KAutoObject> AutoObjectNames;
internal bool EnableVersionChecks { get; private set; }
internal AppletStateMgr AppletState { get; private set; }
internal KSharedMemory HidSharedMem { get; private set; }
internal KSharedMemory FontSharedMem { get; private set; }
internal KSharedMemory IirsSharedMem { get; private set; }
internal SharedFontManager Font { get; private set; }
internal ContentManager ContentManager { get; private set; }
internal KEvent VsyncEvent { get; private set; }
public Keyset KeySet => Device.FileSystem.KeySet;
private bool _hasStarted;
private bool _isDisposed;
public BlitStruct<ApplicationControlProperty> ControlData { get; set; }
public string TitleName { get; private set; }
public ulong TitleId { get; private set; }
public string TitleIdText => TitleId.ToString("x16");
public string TitleVersionString { get; private set; }
public bool TitleIs64Bit { get; private set; }
public IntegrityCheckLevel FsIntegrityCheckLevel { get; set; }
public int GlobalAccessLogMode { get; set; }
internal long HidBaseAddress { get; private set; }
internal NvHostSyncpt HostSyncpoint { get; private set; }
public Horizon(Switch device, ContentManager contentManager)
{
ControlData = new BlitStruct<ApplicationControlProperty>(1);
Device = device;
State = new SystemStateMgr();
ResourceLimit = new KResourceLimit(this);
KernelInit.InitializeResourceLimit(ResourceLimit);
MemoryRegions = KernelInit.GetMemoryRegions();
LargeMemoryBlockAllocator = new KMemoryBlockAllocator(MemoryBlockAllocatorSize * 2);
SmallMemoryBlockAllocator = new KMemoryBlockAllocator(MemoryBlockAllocatorSize);
UserSlabHeapPages = new KSlabHeap(
UserSlabHeapBase,
UserSlabHeapItemSize,
UserSlabHeapSize);
CriticalSection = new KCriticalSection(this);
Scheduler = new KScheduler(this);
TimeManager = new KTimeManager();
Synchronization = new KSynchronization(this);
ContextIdManager = new KContextIdManager();
_kipId = InitialKipId;
_processId = InitialProcessId;
Scheduler.StartAutoPreemptionThread();
KernelInitialized = true;
ThreadCounter = new CountdownEvent(1);
Processes = new SortedDictionary<long, KProcess>();
AutoObjectNames = new ConcurrentDictionary<string, KAutoObject>();
// Note: This is not really correct, but with HLE of services, the only memory
// region used that is used is Application, so we can use the other ones for anything.
KMemoryRegionManager region = MemoryRegions[(int)MemoryRegion.NvServices];
ulong hidPa = region.Address;
ulong fontPa = region.Address + HidSize;
ulong iirsPa = region.Address + HidSize + FontSize;
ulong timePa = region.Address + HidSize + FontSize + IirsSize;
HidBaseAddress = (long)(hidPa - DramMemoryMap.DramBase);
KPageList hidPageList = new KPageList();
KPageList fontPageList = new KPageList();
KPageList iirsPageList = new KPageList();
KPageList timePageList = new KPageList();
hidPageList .AddRange(hidPa, HidSize / KMemoryManager.PageSize);
fontPageList.AddRange(fontPa, FontSize / KMemoryManager.PageSize);
iirsPageList.AddRange(iirsPa, IirsSize / KMemoryManager.PageSize);
timePageList.AddRange(timePa, TimeSize / KMemoryManager.PageSize);
HidSharedMem = new KSharedMemory(this, hidPageList, 0, 0, MemoryPermission.Read);
FontSharedMem = new KSharedMemory(this, fontPageList, 0, 0, MemoryPermission.Read);
IirsSharedMem = new KSharedMemory(this, iirsPageList, 0, 0, MemoryPermission.Read);
KSharedMemory timeSharedMemory = new KSharedMemory(this, timePageList, 0, 0, MemoryPermission.Read);
TimeServiceManager.Instance.Initialize(device, this, timeSharedMemory, (long)(timePa - DramMemoryMap.DramBase), TimeSize);
AppletState = new AppletStateMgr(this);
AppletState.SetFocus(true);
Font = new SharedFontManager(device, (long)(fontPa - DramMemoryMap.DramBase));
IUserInterface.InitializePort(this);
VsyncEvent = new KEvent(this);
ContentManager = contentManager;
// TODO: use set:sys (and get external clock source id from settings)
// TODO: use "time!standard_steady_clock_rtc_update_interval_minutes" and implement a worker thread to be accurate.
UInt128 clockSourceId = new UInt128(Guid.NewGuid().ToByteArray());
IRtcManager.GetExternalRtcValue(out ulong rtcValue);
// We assume the rtc is system time.
TimeSpanType systemTime = TimeSpanType.FromSeconds((long)rtcValue);
// Configure and setup internal offset
TimeSpanType internalOffset = TimeSpanType.FromSeconds(ConfigurationState.Instance.System.SystemTimeOffset);
TimeSpanType systemTimeOffset = new TimeSpanType(systemTime.NanoSeconds + internalOffset.NanoSeconds);
if (systemTime.IsDaylightSavingTime() && !systemTimeOffset.IsDaylightSavingTime())
{
internalOffset = internalOffset.AddSeconds(3600L);
}
else if (!systemTime.IsDaylightSavingTime() && systemTimeOffset.IsDaylightSavingTime())
{
internalOffset = internalOffset.AddSeconds(-3600L);
}
internalOffset = new TimeSpanType(-internalOffset.NanoSeconds);
// First init the standard steady clock
TimeServiceManager.Instance.SetupStandardSteadyClock(null, clockSourceId, systemTime, internalOffset, TimeSpanType.Zero, false);
TimeServiceManager.Instance.SetupStandardLocalSystemClock(null, new SystemClockContext(), systemTime.ToSeconds());
if (NxSettings.Settings.TryGetValue("time!standard_network_clock_sufficient_accuracy_minutes", out object standardNetworkClockSufficientAccuracyMinutes))
{
TimeSpanType standardNetworkClockSufficientAccuracy = new TimeSpanType((int)standardNetworkClockSufficientAccuracyMinutes * 60000000000);
TimeServiceManager.Instance.SetupStandardNetworkSystemClock(new SystemClockContext(), standardNetworkClockSufficientAccuracy);
}
TimeServiceManager.Instance.SetupStandardUserSystemClock(null, false, SteadyClockTimePoint.GetRandom());
// FIXME: TimeZone shoud be init here but it's actually done in ContentManager
TimeServiceManager.Instance.SetupEphemeralNetworkSystemClock();
DatabaseImpl.Instance.InitializeDatabase(device);
HostSyncpoint = new NvHostSyncpt(device);
}
public void LoadCart(string exeFsDir, string romFsFile = null)
{
if (romFsFile != null)
{
Device.FileSystem.LoadRomFs(romFsFile);
}
LocalFileSystem codeFs = new LocalFileSystem(exeFsDir);
LoadExeFs(codeFs, out _);
if (TitleId != 0)
{
EnsureSaveData(new TitleId(TitleId));
}
}
public void LoadXci(string xciFile)
{
FileStream file = new FileStream(xciFile, FileMode.Open, FileAccess.Read);
Xci xci = new Xci(KeySet, file.AsStorage());
(Nca mainNca, Nca patchNca, Nca controlNca) = GetXciGameData(xci);
if (mainNca == null)
{
Logger.PrintError(LogClass.Loader, "Unable to load XCI");
return;
}
ContentManager.LoadEntries(Device);
LoadNca(mainNca, patchNca, controlNca);
}
public void LoadKip(string kipFile)
{
using (IStorage fs = new LocalStorage(kipFile, FileAccess.Read))
{
ProgramLoader.LoadKernelInitalProcess(this, new KipExecutable(fs));
}
}
private (Nca Main, Nca patch, Nca Control) GetXciGameData(Xci xci)
{
if (!xci.HasPartition(XciPartitionType.Secure))
{
throw new InvalidDataException("Could not find XCI secure partition");
}
Nca mainNca = null;
Nca patchNca = null;
Nca controlNca = null;
XciPartition securePartition = xci.OpenPartition(XciPartitionType.Secure);
foreach (DirectoryEntryEx ticketEntry in securePartition.EnumerateEntries("/", "*.tik"))
{
Result result = securePartition.OpenFile(out IFile ticketFile, ticketEntry.FullPath.ToU8Span(), OpenMode.Read);
if (result.IsSuccess())
{
Ticket ticket = new Ticket(ticketFile.AsStream());
KeySet.ExternalKeySet.Add(new RightsId(ticket.RightsId), new AccessKey(ticket.GetTitleKey(KeySet)));
}
}
foreach (DirectoryEntryEx fileEntry in securePartition.EnumerateEntries("/", "*.nca"))
{
Result result = securePartition.OpenFile(out IFile ncaFile, fileEntry.FullPath.ToU8Span(), OpenMode.Read);
if (result.IsFailure())
{
continue;
}
Nca nca = new Nca(KeySet, ncaFile.AsStorage());
if (nca.Header.ContentType == NcaContentType.Program)
{
int dataIndex = Nca.GetSectionIndexFromType(NcaSectionType.Data, NcaContentType.Program);
if (nca.Header.GetFsHeader(dataIndex).IsPatchSection())
{
patchNca = nca;
}
else
{
mainNca = nca;
}
}
else if (nca.Header.ContentType == NcaContentType.Control)
{
controlNca = nca;
}
}
if (mainNca == null)
{
Logger.PrintError(LogClass.Loader, "Could not find an Application NCA in the provided XCI file");
}
if (controlNca != null)
{
ReadControlData(controlNca);
}
else
{
ControlData.ByteSpan.Clear();
}
return (mainNca, patchNca, controlNca);
}
public void ReadControlData(Nca controlNca)
{
IFileSystem controlFs = controlNca.OpenFileSystem(NcaSectionType.Data, FsIntegrityCheckLevel);
Result result = controlFs.OpenFile(out IFile controlFile, "/control.nacp".ToU8Span(), OpenMode.Read);
if (result.IsSuccess())
{
result = controlFile.Read(out long bytesRead, 0, ControlData.ByteSpan, ReadOption.None);
if (result.IsSuccess() && bytesRead == ControlData.ByteSpan.Length)
{
TitleName = ControlData.Value
.Titles[(int) State.DesiredTitleLanguage].Name.ToString();
if (string.IsNullOrWhiteSpace(TitleName))
{
TitleName = ControlData.Value.Titles.ToArray()
.FirstOrDefault(x => x.Name[0] != 0).Name.ToString();
}
TitleVersionString = ControlData.Value.DisplayVersion.ToString();
}
}
else
{
ControlData.ByteSpan.Clear();
}
}
public void LoadNca(string ncaFile)
{
FileStream file = new FileStream(ncaFile, FileMode.Open, FileAccess.Read);
Nca nca = new Nca(KeySet, file.AsStorage(false));
LoadNca(nca, null, null);
}
public void LoadNsp(string nspFile)
{
FileStream file = new FileStream(nspFile, FileMode.Open, FileAccess.Read);
PartitionFileSystem nsp = new PartitionFileSystem(file.AsStorage());
foreach (DirectoryEntryEx ticketEntry in nsp.EnumerateEntries("/", "*.tik"))
{
Result result = nsp.OpenFile(out IFile ticketFile, ticketEntry.FullPath.ToU8Span(), OpenMode.Read);
if (result.IsSuccess())
{
Ticket ticket = new Ticket(ticketFile.AsStream());
KeySet.ExternalKeySet.Add(new RightsId(ticket.RightsId), new AccessKey(ticket.GetTitleKey(KeySet)));
}
}
Nca mainNca = null;
Nca patchNca = null;
Nca controlNca = null;
foreach (DirectoryEntryEx fileEntry in nsp.EnumerateEntries("/", "*.nca"))
{
nsp.OpenFile(out IFile ncaFile, fileEntry.FullPath.ToU8Span(), OpenMode.Read).ThrowIfFailure();
Nca nca = new Nca(KeySet, ncaFile.AsStorage());
if (nca.Header.ContentType == NcaContentType.Program)
{
int dataIndex = Nca.GetSectionIndexFromType(NcaSectionType.Data, NcaContentType.Program);
if (nca.Header.GetFsHeader(dataIndex).IsPatchSection())
{
patchNca = nca;
}
else
{
mainNca = nca;
}
}
else if (nca.Header.ContentType == NcaContentType.Control)
{
controlNca = nca;
}
}
if (mainNca != null)
{
LoadNca(mainNca, patchNca, controlNca);
return;
}
// This is not a normal NSP, it's actually a ExeFS as a NSP
LoadExeFs(nsp, out _);
}
public void LoadNca(Nca mainNca, Nca patchNca, Nca controlNca)
{
if (mainNca.Header.ContentType != NcaContentType.Program)
{
Logger.PrintError(LogClass.Loader, "Selected NCA is not a \"Program\" NCA");
return;
}
IStorage dataStorage = null;
IFileSystem codeFs = null;
if (File.Exists(Path.Combine(Device.FileSystem.GetBasePath(), "games", mainNca.Header.TitleId.ToString("x16"), "updates.json")))
{
using (Stream stream = File.OpenRead(Path.Combine(Device.FileSystem.GetBasePath(), "games", mainNca.Header.TitleId.ToString("x16"), "updates.json")))
{
IJsonFormatterResolver resolver = CompositeResolver.Create(StandardResolver.AllowPrivateSnakeCase);
string updatePath = JsonSerializer.Deserialize<TitleUpdateMetadata>(stream, resolver).Selected;
if (File.Exists(updatePath))
{
FileStream file = new FileStream(updatePath, FileMode.Open, FileAccess.Read);
PartitionFileSystem nsp = new PartitionFileSystem(file.AsStorage());
foreach (DirectoryEntryEx ticketEntry in nsp.EnumerateEntries("/", "*.tik"))
{
Result result = nsp.OpenFile(out IFile ticketFile, ticketEntry.FullPath.ToU8Span(), OpenMode.Read);
if (result.IsSuccess())
{
Ticket ticket = new Ticket(ticketFile.AsStream());
KeySet.ExternalKeySet.Add(new RightsId(ticket.RightsId), new AccessKey(ticket.GetTitleKey(KeySet)));
}
}
foreach (DirectoryEntryEx fileEntry in nsp.EnumerateEntries("/", "*.nca"))
{
nsp.OpenFile(out IFile ncaFile, fileEntry.FullPath.ToU8Span(), OpenMode.Read).ThrowIfFailure();
Nca nca = new Nca(KeySet, ncaFile.AsStorage());
if ($"{nca.Header.TitleId.ToString("x16")[..^3]}000" != mainNca.Header.TitleId.ToString("x16"))
{
break;
}
if (nca.Header.ContentType == NcaContentType.Program)
{
patchNca = nca;
}
else if (nca.Header.ContentType == NcaContentType.Control)
{
controlNca = nca;
}
}
}
}
}
if (patchNca == null)
{
if (mainNca.CanOpenSection(NcaSectionType.Data))
{
dataStorage = mainNca.OpenStorage(NcaSectionType.Data, FsIntegrityCheckLevel);
}
if (mainNca.CanOpenSection(NcaSectionType.Code))
{
codeFs = mainNca.OpenFileSystem(NcaSectionType.Code, FsIntegrityCheckLevel);
}
}
else
{
if (patchNca.CanOpenSection(NcaSectionType.Data))
{
dataStorage = mainNca.OpenStorageWithPatch(patchNca, NcaSectionType.Data, FsIntegrityCheckLevel);
}
if (patchNca.CanOpenSection(NcaSectionType.Code))
{
codeFs = mainNca.OpenFileSystemWithPatch(patchNca, NcaSectionType.Code, FsIntegrityCheckLevel);
}
}
if (codeFs == null)
{
Logger.PrintError(LogClass.Loader, "No ExeFS found in NCA");
return;
}
if (dataStorage == null)
{
Logger.PrintWarning(LogClass.Loader, "No RomFS found in NCA");
}
else
{
Device.FileSystem.SetRomFs(dataStorage.AsStream(FileAccess.Read));
}
LoadExeFs(codeFs, out Npdm metaData);
TitleId = metaData.Aci0.TitleId;
TitleIs64Bit = metaData.Is64Bit;
if (controlNca != null)
{
ReadControlData(controlNca);
}
else
{
ControlData.ByteSpan.Clear();
}
if (TitleId != 0)
{
EnsureSaveData(new TitleId(TitleId));
}
Logger.PrintInfo(LogClass.Loader, $"Application Loaded: {TitleName} v{TitleVersionString} [{TitleIdText}] [{(TitleIs64Bit ? "64-bit" : "32-bit")}]");
}
private void LoadExeFs(IFileSystem codeFs, out Npdm metaData)
{
Result result = codeFs.OpenFile(out IFile npdmFile, "/main.npdm".ToU8Span(), OpenMode.Read);
if (ResultFs.PathNotFound.Includes(result))
{
Logger.PrintWarning(LogClass.Loader, "NPDM file not found, using default values!");
metaData = GetDefaultNpdm();
}
else
{
metaData = new Npdm(npdmFile.AsStream());
}
List<IExecutable> staticObjects = new List<IExecutable>();
void LoadNso(string filename)
{
foreach (DirectoryEntryEx file in codeFs.EnumerateEntries("/", $"{filename}*"))
{
if (Path.GetExtension(file.Name) != string.Empty)
{
continue;
}
Logger.PrintInfo(LogClass.Loader, $"Loading {file.Name}...");
codeFs.OpenFile(out IFile nsoFile, file.FullPath.ToU8Span(), OpenMode.Read).ThrowIfFailure();
NsoExecutable staticObject = new NsoExecutable(nsoFile.AsStorage());
staticObjects.Add(staticObject);
}
}
TitleId = metaData.Aci0.TitleId;
TitleIs64Bit = metaData.Is64Bit;
LoadNso("rtld");
LoadNso("main");
LoadNso("subsdk");
LoadNso("sdk");
ContentManager.LoadEntries(Device);
ProgramLoader.LoadStaticObjects(this, metaData, staticObjects.ToArray());
}
public void LoadProgram(string filePath)
{
Npdm metaData = GetDefaultNpdm();
bool isNro = Path.GetExtension(filePath).ToLower() == ".nro";
IExecutable staticObject;
if (isNro)
{
FileStream input = new FileStream(filePath, FileMode.Open);
NroExecutable obj = new NroExecutable(input);
staticObject = obj;
// homebrew NRO can actually have some data after the actual NRO
if (input.Length > obj.FileSize)
{
input.Position = obj.FileSize;
BinaryReader reader = new BinaryReader(input);
uint asetMagic = reader.ReadUInt32();
if (asetMagic == 0x54455341)
{
uint asetVersion = reader.ReadUInt32();
if (asetVersion == 0)
{
ulong iconOffset = reader.ReadUInt64();
ulong iconSize = reader.ReadUInt64();
ulong nacpOffset = reader.ReadUInt64();
ulong nacpSize = reader.ReadUInt64();
ulong romfsOffset = reader.ReadUInt64();
ulong romfsSize = reader.ReadUInt64();
if (romfsSize != 0)
{
Device.FileSystem.SetRomFs(new HomebrewRomFsStream(input, obj.FileSize + (long)romfsOffset));
}
if (nacpSize != 0)
{
input.Seek(obj.FileSize + (long)nacpOffset, SeekOrigin.Begin);
reader.Read(ControlData.ByteSpan);
ref ApplicationControlProperty nacp = ref ControlData.Value;
metaData.TitleName = nacp.Titles[(int)State.DesiredTitleLanguage].Name.ToString();
if (string.IsNullOrWhiteSpace(metaData.TitleName))
{
metaData.TitleName = nacp.Titles.ToArray().FirstOrDefault(x => x.Name[0] != 0).Name.ToString();
}
if (nacp.PresenceGroupId != 0)
{
metaData.Aci0.TitleId = nacp.PresenceGroupId;
}
else if (nacp.SaveDataOwnerId.Value != 0)
{
metaData.Aci0.TitleId = nacp.SaveDataOwnerId.Value;
}
else if (nacp.AddOnContentBaseId != 0)
{
metaData.Aci0.TitleId = nacp.AddOnContentBaseId - 0x1000;
}
else
{
metaData.Aci0.TitleId = 0000000000000000;
}
}
}
else
{
Logger.PrintWarning(LogClass.Loader, $"Unsupported ASET header version found \"{asetVersion}\"");
}
}
}
}
else
{
staticObject = new NsoExecutable(new LocalStorage(filePath, FileAccess.Read));
}
ContentManager.LoadEntries(Device);
TitleName = metaData.TitleName;
TitleId = metaData.Aci0.TitleId;
TitleIs64Bit = metaData.Is64Bit;
ProgramLoader.LoadStaticObjects(this, metaData, new IExecutable[] { staticObject });
}
private Npdm GetDefaultNpdm()
{
Assembly asm = Assembly.GetCallingAssembly();
using (Stream npdmStream = asm.GetManifestResourceStream("Ryujinx.HLE.Homebrew.npdm"))
{
return new Npdm(npdmStream);
}
}
private Result EnsureSaveData(TitleId titleId)
{
Logger.PrintInfo(LogClass.Application, "Ensuring required savedata exists.");
Uid user = State.Account.LastOpenedUser.UserId.ToLibHacUid();
ref ApplicationControlProperty control = ref ControlData.Value;
if (LibHac.Util.IsEmpty(ControlData.ByteSpan))
{
// If the current application doesn't have a loaded control property, create a dummy one
// and set the savedata sizes so a user savedata will be created.
control = ref new BlitStruct<ApplicationControlProperty>(1).Value;
// The set sizes don't actually matter as long as they're non-zero because we use directory savedata.
control.UserAccountSaveDataSize = 0x4000;
control.UserAccountSaveDataJournalSize = 0x4000;
Logger.PrintWarning(LogClass.Application,
"No control file was found for this game. Using a dummy one instead. This may cause inaccuracies in some games.");
}
FileSystemClient fs = Device.FileSystem.FsClient;
Result rc = fs.EnsureApplicationCacheStorage(out _, titleId, ref control);
if (rc.IsFailure())
{
Logger.PrintError(LogClass.Application, $"Error calling EnsureApplicationCacheStorage. Result code {rc.ToStringWithName()}");
}
rc = EnsureApplicationSaveData(fs, out _, titleId, ref control, ref user);
if (rc.IsFailure())
{
Logger.PrintError(LogClass.Application, $"Error calling EnsureApplicationSaveData. Result code {rc.ToStringWithName()}");
}
return rc;
}
public void SignalVsync()
{
VsyncEvent.ReadableEvent.Signal();
}
internal long GetThreadUid()
{
return Interlocked.Increment(ref _threadUid) - 1;
}
internal long GetKipId()
{
return Interlocked.Increment(ref _kipId) - 1;
}
internal long GetProcessId()
{
return Interlocked.Increment(ref _processId) - 1;
}
public void EnableMultiCoreScheduling()
{
if (!_hasStarted)
{
Scheduler.MultiCoreScheduling = true;
}
}
public void DisableMultiCoreScheduling()
{
if (!_hasStarted)
{
Scheduler.MultiCoreScheduling = false;
}
}
public void Dispose()
{
Dispose(true);
}
protected virtual void Dispose(bool disposing)
{
if (!_isDisposed && disposing)
{
_isDisposed = true;
KProcess terminationProcess = new KProcess(this);
KThread terminationThread = new KThread(this);
terminationThread.Initialize(0, 0, 0, 3, 0, terminationProcess, ThreadType.Kernel, () =>
{
// Force all threads to exit.
lock (Processes)
{
foreach (KProcess process in Processes.Values)
{
process.Terminate();
}
}
// Exit ourself now!
Scheduler.ExitThread(terminationThread);
Scheduler.GetCurrentThread().Exit();
Scheduler.RemoveThread(terminationThread);
});
terminationThread.Start();
// Signal the vsync event to avoid issues of KThread waiting on it.
if (Device.EnableDeviceVsync)
{
Device.VsyncEvent.Set();
}
// Destroy nvservices channels as KThread could be waiting on some user events.
// This is safe as KThread that are likely to call ioctls are going to be terminated by the post handler hook on the SVC facade.
INvDrvServices.Destroy();
// This is needed as the IPC Dummy KThread is also counted in the ThreadCounter.
ThreadCounter.Signal();
// It's only safe to release resources once all threads
// have exited.
ThreadCounter.Signal();
ThreadCounter.Wait();
Scheduler.Dispose();
TimeManager.Dispose();
Device.Unload();
}
}
}
}