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326749498bed4360e5a4b11fc67d5ec7cb9a3076
ryujinx/src/Ryujinx.HLE/HOS/Services/Time/IStaticServiceForPsc.cs
TSRBerry 326749498b [Ryujinx.HLE] Address dotnet-format issues (#5380) 
* dotnet format style --severity info

Some changes were manually reverted.

* dotnet format analyzers --serverity info

Some changes have been minimally adapted.

* Restore a few unused methods and variables

* Silence dotnet format IDE0060 warnings

* Silence dotnet format IDE0052 warnings

* Address or silence dotnet format IDE1006 warnings

* Address dotnet format CA1816 warnings

* Address or silence dotnet format CA2208 warnings

* Address or silence dotnet format CA1806 and a few CA1854 warnings

* Address dotnet format CA2211 warnings

* Address dotnet format CA1822 warnings

* Address or silence dotnet format CA1069 warnings

* Make dotnet format succeed in style mode

* Address or silence dotnet format CA2211 warnings

* Address review comments

* Address dotnet format CA2208 warnings properly

* Make ProcessResult readonly

* Address most dotnet format whitespace warnings

* Apply dotnet format whitespace formatting

A few of them have been manually reverted and the corresponding warning was silenced

* Add previously silenced warnings back

I have no clue how these disappeared

* Revert formatting changes for while and for-loops

* Format if-blocks correctly

* Run dotnet format style after rebase

* Run dotnet format whitespace after rebase

* Run dotnet format style after rebase

* Run dotnet format analyzers after rebase

* Run dotnet format after rebase and remove unused usings

- analyzers
- style
- whitespace

* Disable 'prefer switch expression' rule

* Add comments to disabled warnings

* Fix a few disabled warnings

* Fix naming rule violation, Convert shader properties to auto-property and convert values to const

* Simplify properties and array initialization, Use const when possible, Remove trailing commas

* Start working on disabled warnings

* Fix and silence a few dotnet-format warnings again

* Run dotnet format after rebase

* Use using declaration instead of block syntax

* Address IDE0251 warnings

* Address a few disabled IDE0060 warnings

* Silence IDE0060 in .editorconfig

* Revert "Simplify properties and array initialization, Use const when possible, Remove trailing commas"

This reverts commit 9462e4136c0a2100dc28b20cf9542e06790aa67e.

* dotnet format whitespace after rebase

* First dotnet format pass

* Fix naming rule violations

* Fix typo

* Add trailing commas, use targeted new and use array initializer

* Fix build issues

* Fix remaining build issues

* Remove SuppressMessage for CA1069 where possible

* Address dotnet format issues

* Address formatting issues

Co-authored-by: Ac_K <acoustik666@gmail.com>

* Add GetHashCode implementation for RenderingSurfaceInfo

* Explicitly silence CA1822 for every affected method in Syscall

* Address formatting issues in Demangler.cs

* Address review feedback

Co-authored-by: Ac_K <acoustik666@gmail.com>

* Revert marking service methods as static

* Next dotnet format pass

* Address review feedback

---------

Co-authored-by: Ac_K <acoustik666@gmail.com>
2023-07-16 19:31:14 +02:00

433 lines
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using Ryujinx.Common;
using Ryujinx.Cpu;
using Ryujinx.HLE.HOS.Ipc;
using Ryujinx.HLE.HOS.Services.Time.Clock;
using Ryujinx.HLE.HOS.Services.Time.StaticService;
using Ryujinx.HLE.HOS.Services.Time.TimeZone;
using Ryujinx.Horizon.Common;
using System;
using System.Diagnostics;
using System.IO;
using System.Runtime.CompilerServices;
using System.Runtime.InteropServices;
using System.Text;
namespace Ryujinx.HLE.HOS.Services.Time
{
[Service("time:s", TimePermissions.System)]
[Service("time:su", TimePermissions.SystemUpdate)]
class IStaticServiceForPsc : IpcService
{
private readonly TimeManager _timeManager;
private readonly TimePermissions _permissions;
private int _timeSharedMemoryNativeHandle = 0;
public IStaticServiceForPsc(ServiceCtx context, TimePermissions permissions) : this(TimeManager.Instance, permissions) { }
public IStaticServiceForPsc(TimeManager manager, TimePermissions permissions)
{
_permissions = permissions;
_timeManager = manager;
}
[CommandCmif(0)]
// GetStandardUserSystemClock() -> object<nn::timesrv::detail::service::ISystemClock>
public ResultCode GetStandardUserSystemClock(ServiceCtx context)
{
MakeObject(context, new ISystemClock(_timeManager.StandardUserSystemClock,
(_permissions & TimePermissions.UserSystemClockWritableMask) != 0,
(_permissions & TimePermissions.BypassUninitialized) != 0));
return ResultCode.Success;
}
[CommandCmif(1)]
// GetStandardNetworkSystemClock() -> object<nn::timesrv::detail::service::ISystemClock>
public ResultCode GetStandardNetworkSystemClock(ServiceCtx context)
{
MakeObject(context, new ISystemClock(_timeManager.StandardNetworkSystemClock,
(_permissions & TimePermissions.NetworkSystemClockWritableMask) != 0,
(_permissions & TimePermissions.BypassUninitialized) != 0));
return ResultCode.Success;
}
[CommandCmif(2)]
// GetStandardSteadyClock() -> object<nn::timesrv::detail::service::ISteadyClock>
public ResultCode GetStandardSteadyClock(ServiceCtx context)
{
MakeObject(context, new ISteadyClock(_timeManager.StandardSteadyClock,
(_permissions & TimePermissions.SteadyClockWritableMask) != 0,
(_permissions & TimePermissions.BypassUninitialized) != 0));
return ResultCode.Success;
}
[CommandCmif(3)]
// GetTimeZoneService() -> object<nn::timesrv::detail::service::ITimeZoneService>
public ResultCode GetTimeZoneService(ServiceCtx context)
{
MakeObject(context, new ITimeZoneServiceForPsc(_timeManager.TimeZone.Manager,
(_permissions & TimePermissions.TimeZoneWritableMask) != 0));
return ResultCode.Success;
}
[CommandCmif(4)]
// GetStandardLocalSystemClock() -> object<nn::timesrv::detail::service::ISystemClock>
public ResultCode GetStandardLocalSystemClock(ServiceCtx context)
{
MakeObject(context, new ISystemClock(_timeManager.StandardLocalSystemClock,
(_permissions & TimePermissions.LocalSystemClockWritableMask) != 0,
(_permissions & TimePermissions.BypassUninitialized) != 0));
return ResultCode.Success;
}
[CommandCmif(5)] // 4.0.0+
// GetEphemeralNetworkSystemClock() -> object<nn::timesrv::detail::service::ISystemClock>
public ResultCode GetEphemeralNetworkSystemClock(ServiceCtx context)
{
MakeObject(context, new ISystemClock(_timeManager.StandardNetworkSystemClock,
(_permissions & TimePermissions.NetworkSystemClockWritableMask) != 0,
(_permissions & TimePermissions.BypassUninitialized) != 0));
return ResultCode.Success;
}
[CommandCmif(20)] // 6.0.0+
// GetSharedMemoryNativeHandle() -> handle<copy>
public ResultCode GetSharedMemoryNativeHandle(ServiceCtx context)
{
if (_timeSharedMemoryNativeHandle == 0)
{
if (context.Process.HandleTable.GenerateHandle(_timeManager.SharedMemory.GetSharedMemory(), out _timeSharedMemoryNativeHandle) != Result.Success)
{
throw new InvalidOperationException("Out of handles!");
}
}
context.Response.HandleDesc = IpcHandleDesc.MakeCopy(_timeSharedMemoryNativeHandle);
return ResultCode.Success;
}
[CommandCmif(50)] // 4.0.0+
// SetStandardSteadyClockInternalOffset(nn::TimeSpanType internal_offset)
public ResultCode SetStandardSteadyClockInternalOffset(ServiceCtx context)
{
// This is only implemented in glue's StaticService.
return ResultCode.NotImplemented;
}
[CommandCmif(51)] // 9.0.0+
// GetStandardSteadyClockRtcValue() -> u64
public ResultCode GetStandardSteadyClockRtcValue(ServiceCtx context)
{
// This is only implemented in glue's StaticService.
return ResultCode.NotImplemented;
}
[CommandCmif(100)]
// IsStandardUserSystemClockAutomaticCorrectionEnabled() -> bool
public ResultCode IsStandardUserSystemClockAutomaticCorrectionEnabled(ServiceCtx context)
{
StandardUserSystemClockCore userClock = _timeManager.StandardUserSystemClock;
if (!userClock.IsInitialized())
{
return ResultCode.UninitializedClock;
}
context.ResponseData.Write(userClock.IsAutomaticCorrectionEnabled());
return ResultCode.Success;
}
[CommandCmif(101)]
// SetStandardUserSystemClockAutomaticCorrectionEnabled(b8)
public ResultCode SetStandardUserSystemClockAutomaticCorrectionEnabled(ServiceCtx context)
{
SteadyClockCore steadyClock = _timeManager.StandardSteadyClock;
StandardUserSystemClockCore userClock = _timeManager.StandardUserSystemClock;
if (!userClock.IsInitialized() || !steadyClock.IsInitialized())
{
return ResultCode.UninitializedClock;
}
if ((_permissions & TimePermissions.UserSystemClockWritableMask) == 0)
{
return ResultCode.PermissionDenied;
}
bool autoCorrectionEnabled = context.RequestData.ReadBoolean();
ITickSource tickSource = context.Device.System.TickSource;
ResultCode result = userClock.SetAutomaticCorrectionEnabled(tickSource, autoCorrectionEnabled);
if (result == ResultCode.Success)
{
_timeManager.SharedMemory.SetAutomaticCorrectionEnabled(autoCorrectionEnabled);
SteadyClockTimePoint currentTimePoint = userClock.GetSteadyClockCore().GetCurrentTimePoint(tickSource);
userClock.SetAutomaticCorrectionUpdatedTime(currentTimePoint);
userClock.SignalAutomaticCorrectionEvent();
}
return result;
}
[CommandCmif(102)] // 5.0.0+
// GetStandardUserSystemClockInitialYear() -> u32
public ResultCode GetStandardUserSystemClockInitialYear(ServiceCtx context)
{
// This is only implemented in glue's StaticService.
return ResultCode.NotImplemented;
}
[CommandCmif(200)] // 3.0.0+
// IsStandardNetworkSystemClockAccuracySufficient() -> bool
public ResultCode IsStandardNetworkSystemClockAccuracySufficient(ServiceCtx context)
{
ITickSource tickSource = context.Device.System.TickSource;
context.ResponseData.Write(_timeManager.StandardNetworkSystemClock.IsStandardNetworkSystemClockAccuracySufficient(tickSource));
return ResultCode.Success;
}
[CommandCmif(201)] // 6.0.0+
// GetStandardUserSystemClockAutomaticCorrectionUpdatedTime() -> nn::time::SteadyClockTimePoint
public ResultCode GetStandardUserSystemClockAutomaticCorrectionUpdatedTime(ServiceCtx context)
{
StandardUserSystemClockCore userClock = _timeManager.StandardUserSystemClock;
if (!userClock.IsInitialized())
{
return ResultCode.UninitializedClock;
}
context.ResponseData.WriteStruct(userClock.GetAutomaticCorrectionUpdatedTime());
return ResultCode.Success;
}
[CommandCmif(300)] // 4.0.0+
// CalculateMonotonicSystemClockBaseTimePoint(nn::time::SystemClockContext) -> s64
public ResultCode CalculateMonotonicSystemClockBaseTimePoint(ServiceCtx context)
{
SteadyClockCore steadyClock = _timeManager.StandardSteadyClock;
if (!steadyClock.IsInitialized())
{
return ResultCode.UninitializedClock;
}
ITickSource tickSource = context.Device.System.TickSource;
SystemClockContext otherContext = context.RequestData.ReadStruct<SystemClockContext>();
SteadyClockTimePoint currentTimePoint = steadyClock.GetCurrentTimePoint(tickSource);
ResultCode result = ResultCode.TimeMismatch;
if (currentTimePoint.ClockSourceId == otherContext.SteadyTimePoint.ClockSourceId)
{
TimeSpanType ticksTimeSpan = TimeSpanType.FromTicks(tickSource.Counter, tickSource.Frequency);
long baseTimePoint = otherContext.Offset + currentTimePoint.TimePoint - ticksTimeSpan.ToSeconds();
context.ResponseData.Write(baseTimePoint);
result = ResultCode.Success;
}
return result;
}
[CommandCmif(400)] // 4.0.0+
// GetClockSnapshot(u8) -> buffer<nn::time::sf::ClockSnapshot, 0x1a>
public ResultCode GetClockSnapshot(ServiceCtx context)
{
byte type = context.RequestData.ReadByte();
context.Response.PtrBuff[0] = context.Response.PtrBuff[0].WithSize((uint)Marshal.SizeOf<ClockSnapshot>());
ITickSource tickSource = context.Device.System.TickSource;
ResultCode result = _timeManager.StandardUserSystemClock.GetClockContext(tickSource, out SystemClockContext userContext);
if (result == ResultCode.Success)
{
result = _timeManager.StandardNetworkSystemClock.GetClockContext(tickSource, out SystemClockContext networkContext);
if (result == ResultCode.Success)
{
result = GetClockSnapshotFromSystemClockContextInternal(tickSource, userContext, networkContext, type, out ClockSnapshot clockSnapshot);
if (result == ResultCode.Success)
{
WriteClockSnapshotFromBuffer(context, context.Request.RecvListBuff[0], clockSnapshot);
}
}
}
return result;
}
[CommandCmif(401)] // 4.0.0+
// GetClockSnapshotFromSystemClockContext(u8, nn::time::SystemClockContext, nn::time::SystemClockContext) -> buffer<nn::time::sf::ClockSnapshot, 0x1a>
public ResultCode GetClockSnapshotFromSystemClockContext(ServiceCtx context)
{
byte type = context.RequestData.ReadByte();
context.Response.PtrBuff[0] = context.Response.PtrBuff[0].WithSize((uint)Unsafe.SizeOf<ClockSnapshot>());
context.RequestData.BaseStream.Position += 7;
SystemClockContext userContext = context.RequestData.ReadStruct<SystemClockContext>();
SystemClockContext networkContext = context.RequestData.ReadStruct<SystemClockContext>();
ITickSource tickSource = context.Device.System.TickSource;
ResultCode result = GetClockSnapshotFromSystemClockContextInternal(tickSource, userContext, networkContext, type, out ClockSnapshot clockSnapshot);
if (result == ResultCode.Success)
{
WriteClockSnapshotFromBuffer(context, context.Request.RecvListBuff[0], clockSnapshot);
}
return result;
}
[CommandCmif(500)] // 4.0.0+
// CalculateStandardUserSystemClockDifferenceByUser(buffer<nn::time::sf::ClockSnapshot, 0x19>, buffer<nn::time::sf::ClockSnapshot, 0x19>) -> nn::TimeSpanType
public ResultCode CalculateStandardUserSystemClockDifferenceByUser(ServiceCtx context)
{
ClockSnapshot clockSnapshotA = ReadClockSnapshotFromBuffer(context, context.Request.PtrBuff[0]);
ClockSnapshot clockSnapshotB = ReadClockSnapshotFromBuffer(context, context.Request.PtrBuff[1]);
TimeSpanType difference = TimeSpanType.FromSeconds(clockSnapshotB.UserContext.Offset - clockSnapshotA.UserContext.Offset);
if (clockSnapshotB.UserContext.SteadyTimePoint.ClockSourceId != clockSnapshotA.UserContext.SteadyTimePoint.ClockSourceId || (clockSnapshotB.IsAutomaticCorrectionEnabled && clockSnapshotA.IsAutomaticCorrectionEnabled))
{
difference = new TimeSpanType(0);
}
context.ResponseData.Write(difference.NanoSeconds);
return ResultCode.Success;
}
[CommandCmif(501)] // 4.0.0+
// CalculateSpanBetween(buffer<nn::time::sf::ClockSnapshot, 0x19>, buffer<nn::time::sf::ClockSnapshot, 0x19>) -> nn::TimeSpanType
public ResultCode CalculateSpanBetween(ServiceCtx context)
{
ClockSnapshot clockSnapshotA = ReadClockSnapshotFromBuffer(context, context.Request.PtrBuff[0]);
ClockSnapshot clockSnapshotB = ReadClockSnapshotFromBuffer(context, context.Request.PtrBuff[1]);
TimeSpanType result;
ResultCode resultCode = clockSnapshotA.SteadyClockTimePoint.GetSpanBetween(clockSnapshotB.SteadyClockTimePoint, out long timeSpan);
if (resultCode != ResultCode.Success)
{
resultCode = ResultCode.TimeNotFound;
if (clockSnapshotA.NetworkTime != 0 && clockSnapshotB.NetworkTime != 0)
{
result = TimeSpanType.FromSeconds(clockSnapshotB.NetworkTime - clockSnapshotA.NetworkTime);
resultCode = ResultCode.Success;
}
else
{
return resultCode;
}
}
else
{
result = TimeSpanType.FromSeconds(timeSpan);
}
context.ResponseData.Write(result.NanoSeconds);
return resultCode;
}
private ResultCode GetClockSnapshotFromSystemClockContextInternal(ITickSource tickSource, SystemClockContext userContext, SystemClockContext networkContext, byte type, out ClockSnapshot clockSnapshot)
{
clockSnapshot = new ClockSnapshot();
SteadyClockCore steadyClockCore = _timeManager.StandardSteadyClock;
SteadyClockTimePoint currentTimePoint = steadyClockCore.GetCurrentTimePoint(tickSource);
clockSnapshot.IsAutomaticCorrectionEnabled = _timeManager.StandardUserSystemClock.IsAutomaticCorrectionEnabled();
clockSnapshot.UserContext = userContext;
clockSnapshot.NetworkContext = networkContext;
clockSnapshot.SteadyClockTimePoint = currentTimePoint;
ResultCode result = _timeManager.TimeZone.Manager.GetDeviceLocationName(out string deviceLocationName);
if (result != ResultCode.Success)
{
return result;
}
ReadOnlySpan<byte> tzName = Encoding.ASCII.GetBytes(deviceLocationName);
tzName.CopyTo(clockSnapshot.LocationName);
result = ClockSnapshot.GetCurrentTime(out clockSnapshot.UserTime, currentTimePoint, clockSnapshot.UserContext);
if (result == ResultCode.Success)
{
result = _timeManager.TimeZone.Manager.ToCalendarTimeWithMyRules(clockSnapshot.UserTime, out CalendarInfo userCalendarInfo);
if (result == ResultCode.Success)
{
clockSnapshot.UserCalendarTime = userCalendarInfo.Time;
clockSnapshot.UserCalendarAdditionalTime = userCalendarInfo.AdditionalInfo;
if (ClockSnapshot.GetCurrentTime(out clockSnapshot.NetworkTime, currentTimePoint, clockSnapshot.NetworkContext) != ResultCode.Success)
{
clockSnapshot.NetworkTime = 0;
}
result = _timeManager.TimeZone.Manager.ToCalendarTimeWithMyRules(clockSnapshot.NetworkTime, out CalendarInfo networkCalendarInfo);
if (result == ResultCode.Success)
{
clockSnapshot.NetworkCalendarTime = networkCalendarInfo.Time;
clockSnapshot.NetworkCalendarAdditionalTime = networkCalendarInfo.AdditionalInfo;
clockSnapshot.Type = type;
// Probably a version field?
clockSnapshot.Unknown = 0;
}
}
}
return result;
}
private ClockSnapshot ReadClockSnapshotFromBuffer(ServiceCtx context, IpcPtrBuffDesc ipcDesc)
{
Debug.Assert(ipcDesc.Size == (ulong)Unsafe.SizeOf<ClockSnapshot>());
byte[] temp = new byte[ipcDesc.Size];
context.Memory.Read(ipcDesc.Position, temp);
using BinaryReader bufferReader = new(new MemoryStream(temp));
return bufferReader.ReadStruct<ClockSnapshot>();
}
private void WriteClockSnapshotFromBuffer(ServiceCtx context, IpcRecvListBuffDesc ipcDesc, ClockSnapshot clockSnapshot)
{
MemoryHelper.Write(context.Memory, ipcDesc.Position, clockSnapshot);
}
}
}
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