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jinx/Ryujinx.HLE/HOS/Services/ServerBase.cs
Mary 20ce37dee6
kernel: A bit of refactoring and fix GetThreadContext3 correctness (#3042)
* Start refactoring kernel a bit and import some changes from kernel decoupling PR

* kernel: Put output always at the start in Syscall functions

* kernel: Rewrite GetThreadContext3 to use a structure and to be accurate

* kernel: make KernelTransfer use generic types and simplify

* Fix some warning and do not use getters on MemoryInfo

* Address gdkchan's comment

* GetThreadContext3: use correct pause flag
2022-01-29 22:18:03 +01:00

380 lines
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14 KiB
C#

using Ryujinx.HLE.HOS.Ipc;
using Ryujinx.HLE.HOS.Kernel;
using Ryujinx.HLE.HOS.Kernel.Common;
using Ryujinx.HLE.HOS.Kernel.Ipc;
using Ryujinx.HLE.HOS.Kernel.Process;
using Ryujinx.HLE.HOS.Kernel.Threading;
using Ryujinx.HLE.HOS.Services.Sm;
using System;
using System.Buffers.Binary;
using System.Collections.Generic;
using System.IO;
using System.Threading;
namespace Ryujinx.HLE.HOS.Services
{
class ServerBase : IDisposable
{
// Must be the maximum value used by services (highest one know is the one used by nvservices = 0x8000).
// Having a size that is too low will cause failures as data copy will fail if the receiving buffer is
// not large enough.
private const int PointerBufferSize = 0x8000;
private readonly static int[] DefaultCapabilities = new int[]
{
0x030363F7,
0x1FFFFFCF,
0x207FFFEF,
0x47E0060F,
0x0048BFFF,
0x01007FFF
};
private readonly KernelContext _context;
private KProcess _selfProcess;
private readonly List<int> _sessionHandles = new List<int>();
private readonly List<int> _portHandles = new List<int>();
private readonly Dictionary<int, IpcService> _sessions = new Dictionary<int, IpcService>();
private readonly Dictionary<int, Func<IpcService>> _ports = new Dictionary<int, Func<IpcService>>();
public ManualResetEvent InitDone { get; }
public Func<IpcService> SmObjectFactory { get; }
public string Name { get; }
public ServerBase(KernelContext context, string name, Func<IpcService> smObjectFactory = null)
{
InitDone = new ManualResetEvent(false);
Name = name;
SmObjectFactory = smObjectFactory;
_context = context;
const ProcessCreationFlags flags =
ProcessCreationFlags.EnableAslr |
ProcessCreationFlags.AddressSpace64Bit |
ProcessCreationFlags.Is64Bit |
ProcessCreationFlags.PoolPartitionSystem;
ProcessCreationInfo creationInfo = new ProcessCreationInfo("Service", 1, 0, 0x8000000, 1, flags, 0, 0);
KernelStatic.StartInitialProcess(context, creationInfo, DefaultCapabilities, 44, ServerLoop);
}
private void AddPort(int serverPortHandle, Func<IpcService> objectFactory)
{
_portHandles.Add(serverPortHandle);
_ports.Add(serverPortHandle, objectFactory);
}
public void AddSessionObj(KServerSession serverSession, IpcService obj)
{
// Ensure that the sever loop is running.
InitDone.WaitOne();
_selfProcess.HandleTable.GenerateHandle(serverSession, out int serverSessionHandle);
AddSessionObj(serverSessionHandle, obj);
}
public void AddSessionObj(int serverSessionHandle, IpcService obj)
{
_sessionHandles.Add(serverSessionHandle);
_sessions.Add(serverSessionHandle, obj);
}
private void ServerLoop()
{
_selfProcess = KernelStatic.GetCurrentProcess();
if (SmObjectFactory != null)
{
_context.Syscall.ManageNamedPort(out int serverPortHandle, "sm:", 50);
AddPort(serverPortHandle, SmObjectFactory);
}
InitDone.Set();
KThread thread = KernelStatic.GetCurrentThread();
ulong messagePtr = thread.TlsAddress;
_context.Syscall.SetHeapSize(out ulong heapAddr, 0x200000);
_selfProcess.CpuMemory.Write(messagePtr + 0x0, 0);
_selfProcess.CpuMemory.Write(messagePtr + 0x4, 2 << 10);
_selfProcess.CpuMemory.Write(messagePtr + 0x8, heapAddr | ((ulong)PointerBufferSize << 48));
int replyTargetHandle = 0;
while (true)
{
int[] portHandles = _portHandles.ToArray();
int[] sessionHandles = _sessionHandles.ToArray();
int[] handles = new int[portHandles.Length + sessionHandles.Length];
portHandles.CopyTo(handles, 0);
sessionHandles.CopyTo(handles, portHandles.Length);
// We still need a timeout here to allow the service to pick up and listen new sessions...
var rc = _context.Syscall.ReplyAndReceive(out int signaledIndex, handles, replyTargetHandle, 1000000L);
thread.HandlePostSyscall();
if (!thread.Context.Running)
{
break;
}
replyTargetHandle = 0;
if (rc == KernelResult.Success && signaledIndex >= portHandles.Length)
{
// We got a IPC request, process it, pass to the appropriate service if needed.
int signaledHandle = handles[signaledIndex];
if (Process(signaledHandle, heapAddr))
{
replyTargetHandle = signaledHandle;
}
}
else
{
if (rc == KernelResult.Success)
{
// We got a new connection, accept the session to allow servicing future requests.
if (_context.Syscall.AcceptSession(out int serverSessionHandle, handles[signaledIndex]) == KernelResult.Success)
{
IpcService obj = _ports[handles[signaledIndex]].Invoke();
AddSessionObj(serverSessionHandle, obj);
}
}
_selfProcess.CpuMemory.Write(messagePtr + 0x0, 0);
_selfProcess.CpuMemory.Write(messagePtr + 0x4, 2 << 10);
_selfProcess.CpuMemory.Write(messagePtr + 0x8, heapAddr | ((ulong)PointerBufferSize << 48));
}
}
Dispose();
}
private bool Process(int serverSessionHandle, ulong recvListAddr)
{
KProcess process = KernelStatic.GetCurrentProcess();
KThread thread = KernelStatic.GetCurrentThread();
ulong messagePtr = thread.TlsAddress;
ulong messageSize = 0x100;
byte[] reqData = new byte[messageSize];
process.CpuMemory.Read(messagePtr, reqData);
IpcMessage request = new IpcMessage(reqData, (long)messagePtr);
IpcMessage response = new IpcMessage();
ulong tempAddr = recvListAddr;
int sizesOffset = request.RawData.Length - ((request.RecvListBuff.Count * 2 + 3) & ~3);
bool noReceive = true;
for (int i = 0; i < request.ReceiveBuff.Count; i++)
{
noReceive &= (request.ReceiveBuff[i].Position == 0);
}
if (noReceive)
{
for (int i = 0; i < request.RecvListBuff.Count; i++)
{
ulong size = (ulong)BinaryPrimitives.ReadInt16LittleEndian(request.RawData.AsSpan().Slice(sizesOffset + i * 2, 2));
response.PtrBuff.Add(new IpcPtrBuffDesc(tempAddr, (uint)i, size));
request.RecvListBuff[i] = new IpcRecvListBuffDesc(tempAddr, size);
tempAddr += size;
}
}
bool shouldReply = true;
bool isTipcCommunication = false;
using (MemoryStream raw = new MemoryStream(request.RawData))
{
BinaryReader reqReader = new BinaryReader(raw);
if (request.Type == IpcMessageType.HipcRequest ||
request.Type == IpcMessageType.HipcRequestWithContext)
{
response.Type = IpcMessageType.HipcResponse;
using (MemoryStream resMs = new MemoryStream())
{
BinaryWriter resWriter = new BinaryWriter(resMs);
ServiceCtx context = new ServiceCtx(
_context.Device,
process,
process.CpuMemory,
thread,
request,
response,
reqReader,
resWriter);
_sessions[serverSessionHandle].CallHipcMethod(context);
response.RawData = resMs.ToArray();
}
}
else if (request.Type == IpcMessageType.HipcControl ||
request.Type == IpcMessageType.HipcControlWithContext)
{
uint magic = (uint)reqReader.ReadUInt64();
uint cmdId = (uint)reqReader.ReadUInt64();
switch (cmdId)
{
case 0:
request = FillResponse(response, 0, _sessions[serverSessionHandle].ConvertToDomain());
break;
case 3:
request = FillResponse(response, 0, PointerBufferSize);
break;
// TODO: Whats the difference between IpcDuplicateSession/Ex?
case 2:
case 4:
int unknown = reqReader.ReadInt32();
_context.Syscall.CreateSession(out int dupServerSessionHandle, out int dupClientSessionHandle, false, 0);
AddSessionObj(dupServerSessionHandle, _sessions[serverSessionHandle]);
response.HandleDesc = IpcHandleDesc.MakeMove(dupClientSessionHandle);
request = FillResponse(response, 0);
break;
default: throw new NotImplementedException(cmdId.ToString());
}
}
else if (request.Type == IpcMessageType.HipcCloseSession || request.Type == IpcMessageType.TipcCloseSession)
{
_context.Syscall.CloseHandle(serverSessionHandle);
_sessionHandles.Remove(serverSessionHandle);
IpcService service = _sessions[serverSessionHandle];
if (service is IDisposable disposableObj)
{
disposableObj.Dispose();
}
_sessions.Remove(serverSessionHandle);
shouldReply = false;
}
// If the type is past 0xF, we are using TIPC
else if (request.Type > IpcMessageType.TipcCloseSession)
{
isTipcCommunication = true;
// Response type is always the same as request on TIPC.
response.Type = request.Type;
using (MemoryStream resMs = new MemoryStream())
{
BinaryWriter resWriter = new BinaryWriter(resMs);
ServiceCtx context = new ServiceCtx(
_context.Device,
process,
process.CpuMemory,
thread,
request,
response,
reqReader,
resWriter);
_sessions[serverSessionHandle].CallTipcMethod(context);
response.RawData = resMs.ToArray();
}
process.CpuMemory.Write(messagePtr, response.GetBytesTipc());
}
else
{
throw new NotImplementedException(request.Type.ToString());
}
if (!isTipcCommunication)
{
process.CpuMemory.Write(messagePtr, response.GetBytes((long)messagePtr, recvListAddr | ((ulong)PointerBufferSize << 48)));
}
return shouldReply;
}
}
private static IpcMessage FillResponse(IpcMessage response, long result, params int[] values)
{
using (MemoryStream ms = new MemoryStream())
{
BinaryWriter writer = new BinaryWriter(ms);
foreach (int value in values)
{
writer.Write(value);
}
return FillResponse(response, result, ms.ToArray());
}
}
private static IpcMessage FillResponse(IpcMessage response, long result, byte[] data = null)
{
response.Type = IpcMessageType.HipcResponse;
using (MemoryStream ms = new MemoryStream())
{
BinaryWriter writer = new BinaryWriter(ms);
writer.Write(IpcMagic.Sfco);
writer.Write(result);
if (data != null)
{
writer.Write(data);
}
response.RawData = ms.ToArray();
}
return response;
}
protected virtual void Dispose(bool disposing)
{
if (disposing)
{
foreach (IpcService service in _sessions.Values)
{
if (service is IDisposable disposableObj)
{
disposableObj.Dispose();
}
service.DestroyAtExit();
}
_sessions.Clear();
InitDone.Dispose();
}
}
public void Dispose()
{
Dispose(true);
}
}
}