ryujinx-mirror/Ryujinx.HLE/HOS/Services/Time/ITimeServiceManager.cs

224 lines
9 KiB
C#
Raw Normal View History

using Ryujinx.Common;
using Ryujinx.HLE.Exceptions;
using Ryujinx.HLE.HOS.Ipc;
using Ryujinx.HLE.HOS.Kernel.Common;
using Ryujinx.HLE.HOS.Services.Time.Clock;
using Ryujinx.HLE.Utilities;
using System;
using System.IO;
using System.Text;
namespace Ryujinx.HLE.HOS.Services.Time
{
[Service("time:m")] // 9.0.0+
class ITimeServiceManager : IpcService
{
private TimeManager _timeManager;
private int _automaticCorrectionEvent;
public ITimeServiceManager(ServiceCtx context)
{
_timeManager = TimeManager.Instance;
_automaticCorrectionEvent = 0;
}
[CommandHipc(0)]
// GetUserStaticService() -> object<nn::timesrv::detail::service::IStaticService>
public ResultCode GetUserStaticService(ServiceCtx context)
{
MakeObject(context, new IStaticServiceForPsc(_timeManager, TimePermissions.User));
return ResultCode.Success;
}
[CommandHipc(5)]
// GetAdminStaticService() -> object<nn::timesrv::detail::service::IStaticService>
public ResultCode GetAdminStaticService(ServiceCtx context)
{
MakeObject(context, new IStaticServiceForPsc(_timeManager, TimePermissions.Admin));
return ResultCode.Success;
}
[CommandHipc(6)]
// GetRepairStaticService() -> object<nn::timesrv::detail::service::IStaticService>
public ResultCode GetRepairStaticService(ServiceCtx context)
{
MakeObject(context, new IStaticServiceForPsc(_timeManager, TimePermissions.Repair));
return ResultCode.Success;
}
[CommandHipc(9)]
// GetManufactureStaticService() -> object<nn::timesrv::detail::service::IStaticService>
public ResultCode GetManufactureStaticService(ServiceCtx context)
{
MakeObject(context, new IStaticServiceForPsc(_timeManager, TimePermissions.Manufacture));
return ResultCode.Success;
}
[CommandHipc(10)]
// SetupStandardSteadyClock(nn::util::Uuid clock_source_id, nn::TimeSpanType setup_value, nn::TimeSpanType internal_offset, nn::TimeSpanType test_offset, bool is_rtc_reset_detected)
public ResultCode SetupStandardSteadyClock(ServiceCtx context)
{
UInt128 clockSourceId = context.RequestData.ReadStruct<UInt128>();
TimeSpanType setupValue = context.RequestData.ReadStruct<TimeSpanType>();
TimeSpanType internalOffset = context.RequestData.ReadStruct<TimeSpanType>();
TimeSpanType testOffset = context.RequestData.ReadStruct<TimeSpanType>();
bool isRtcResetDetected = context.RequestData.ReadBoolean();
_timeManager.SetupStandardSteadyClock(context.Thread, clockSourceId, setupValue, internalOffset, testOffset, isRtcResetDetected);
return ResultCode.Success;
}
[CommandHipc(11)]
// SetupStandardLocalSystemClock(nn::time::SystemClockContext context, nn::time::PosixTime posix_time)
public ResultCode SetupStandardLocalSystemClock(ServiceCtx context)
{
SystemClockContext clockContext = context.RequestData.ReadStruct<SystemClockContext>();
long posixTime = context.RequestData.ReadInt64();
_timeManager.SetupStandardLocalSystemClock(context.Thread, clockContext, posixTime);
return ResultCode.Success;
}
[CommandHipc(12)]
// SetupStandardNetworkSystemClock(nn::time::SystemClockContext context, nn::TimeSpanType sufficient_accuracy)
public ResultCode SetupStandardNetworkSystemClock(ServiceCtx context)
{
SystemClockContext clockContext = context.RequestData.ReadStruct<SystemClockContext>();
TimeSpanType sufficientAccuracy = context.RequestData.ReadStruct<TimeSpanType>();
_timeManager.SetupStandardNetworkSystemClock(clockContext, sufficientAccuracy);
return ResultCode.Success;
}
[CommandHipc(13)]
// SetupStandardUserSystemClock(bool automatic_correction_enabled, nn::time::SteadyClockTimePoint steady_clock_timepoint)
public ResultCode SetupStandardUserSystemClock(ServiceCtx context)
{
bool isAutomaticCorrectionEnabled = context.RequestData.ReadBoolean();
context.RequestData.BaseStream.Position += 7;
SteadyClockTimePoint steadyClockTimePoint = context.RequestData.ReadStruct<SteadyClockTimePoint>();
_timeManager.SetupStandardUserSystemClock(context.Thread, isAutomaticCorrectionEnabled, steadyClockTimePoint);
return ResultCode.Success;
}
[CommandHipc(14)]
// SetupTimeZoneManager(nn::time::LocationName location_name, nn::time::SteadyClockTimePoint timezone_update_timepoint, u32 total_location_name_count, nn::time::TimeZoneRuleVersion timezone_rule_version, buffer<nn::time::TimeZoneBinary, 0x21> timezone_binary)
public ResultCode SetupTimeZoneManager(ServiceCtx context)
{
string locationName = Encoding.ASCII.GetString(context.RequestData.ReadBytes(0x24)).TrimEnd('\0');
SteadyClockTimePoint timeZoneUpdateTimePoint = context.RequestData.ReadStruct<SteadyClockTimePoint>();
uint totalLocationNameCount = context.RequestData.ReadUInt32();
UInt128 timeZoneRuleVersion = context.RequestData.ReadStruct<UInt128>();
(ulong bufferPosition, ulong bufferSize) = context.Request.GetBufferType0x21();
byte[] temp = new byte[bufferSize];
context.Memory.Read(bufferPosition, temp);
using (MemoryStream timeZoneBinaryStream = new MemoryStream(temp))
{
_timeManager.SetupTimeZoneManager(locationName, timeZoneUpdateTimePoint, totalLocationNameCount, timeZoneRuleVersion, timeZoneBinaryStream);
}
return ResultCode.Success;
}
[CommandHipc(15)]
// SetupEphemeralNetworkSystemClock()
public ResultCode SetupEphemeralNetworkSystemClock(ServiceCtx context)
{
_timeManager.SetupEphemeralNetworkSystemClock();
return ResultCode.Success;
}
[CommandHipc(50)]
// Unknown50() -> handle<copy>
public ResultCode Unknown50(ServiceCtx context)
{
// TODO: figure out the usage of this event
throw new ServiceNotImplementedException(this, context, false);
}
[CommandHipc(51)]
// Unknown51() -> handle<copy>
public ResultCode Unknown51(ServiceCtx context)
{
// TODO: figure out the usage of this event
throw new ServiceNotImplementedException(this, context, false);
}
[CommandHipc(52)]
// Unknown52() -> handle<copy>
public ResultCode Unknown52(ServiceCtx context)
{
// TODO: figure out the usage of this event
throw new ServiceNotImplementedException(this, context, false);
}
[CommandHipc(60)]
// GetStandardUserSystemClockAutomaticCorrectionEvent() -> handle<copy>
public ResultCode GetStandardUserSystemClockAutomaticCorrectionEvent(ServiceCtx context)
{
if (_automaticCorrectionEvent == 0)
{
if (context.Process.HandleTable.GenerateHandle(_timeManager.StandardUserSystemClock.GetAutomaticCorrectionReadableEvent(), out _automaticCorrectionEvent) != KernelResult.Success)
{
throw new InvalidOperationException("Out of handles!");
}
}
context.Response.HandleDesc = IpcHandleDesc.MakeCopy(_automaticCorrectionEvent);
return ResultCode.Success;
}
[CommandHipc(100)]
// SetStandardSteadyClockRtcOffset(nn::TimeSpanType rtc_offset)
public ResultCode SetStandardSteadyClockRtcOffset(ServiceCtx context)
{
TimeSpanType rtcOffset = context.RequestData.ReadStruct<TimeSpanType>();
_timeManager.SetStandardSteadyClockRtcOffset(context.Thread, rtcOffset);
return ResultCode.Success;
}
[CommandHipc(200)]
// GetAlarmRegistrationEvent() -> handle<copy>
public ResultCode GetAlarmRegistrationEvent(ServiceCtx context)
{
// TODO
throw new ServiceNotImplementedException(this, context, false);
}
[CommandHipc(201)]
// UpdateSteadyAlarms()
public ResultCode UpdateSteadyAlarms(ServiceCtx context)
{
// TODO
throw new ServiceNotImplementedException(this, context, false);
}
[CommandHipc(202)]
// TryGetNextSteadyClockAlarmSnapshot() -> (bool, nn::time::SteadyClockAlarmSnapshot)
public ResultCode TryGetNextSteadyClockAlarmSnapshot(ServiceCtx context)
{
// TODO
throw new ServiceNotImplementedException(this, context, false);
}
}
}