Ryujinx/Ryujinx.HLE/HOS/Kernel/SupervisorCall/Syscall32.cs
Mary c94d47cc40
kernel: Implement SetMemoryPermission syscall (#2772)
* kernel: Implement SetMemoryPermission syscall

This commit implement the SetMemoryPermission syscall accurately.
This also fix KMemoryPermission not being an unsigned 32 bits type and
add the "DontCare" bit (used by shared memory, currently unused in
Ryujinx)

* Update MemoryPermission mask

* Address gdkchan's comments

* Fix a nit

* Address gdkchan's comment
2021-10-24 01:24:49 +02:00

454 lines
16 KiB
C#

using Ryujinx.HLE.HOS.Kernel.Common;
using Ryujinx.HLE.HOS.Kernel.Memory;
using Ryujinx.HLE.HOS.Kernel.Threading;
namespace Ryujinx.HLE.HOS.Kernel.SupervisorCall
{
class Syscall32
{
private readonly Syscall _syscall;
public Syscall32(Syscall syscall)
{
_syscall = syscall;
}
// IPC
public KernelResult ConnectToNamedPort32([R(1)] uint namePtr, [R(1)] out int handle)
{
return _syscall.ConnectToNamedPort(namePtr, out handle);
}
public KernelResult SendSyncRequest32([R(0)] int handle)
{
return _syscall.SendSyncRequest(handle);
}
public KernelResult SendSyncRequestWithUserBuffer32([R(0)] uint messagePtr, [R(1)] uint messageSize, [R(2)] int handle)
{
return _syscall.SendSyncRequestWithUserBuffer(messagePtr, messageSize, handle);
}
public KernelResult CreateSession32(
[R(2)] bool isLight,
[R(3)] uint namePtr,
[R(1)] out int serverSessionHandle,
[R(2)] out int clientSessionHandle)
{
return _syscall.CreateSession(isLight, namePtr, out serverSessionHandle, out clientSessionHandle);
}
public KernelResult AcceptSession32([R(1)] int portHandle, [R(1)] out int sessionHandle)
{
return _syscall.AcceptSession(portHandle, out sessionHandle);
}
public KernelResult ReplyAndReceive32(
[R(0)] uint timeoutLow,
[R(1)] ulong handlesPtr,
[R(2)] int handlesCount,
[R(3)] int replyTargetHandle,
[R(4)] uint timeoutHigh,
[R(1)] out int handleIndex)
{
long timeout = (long)(timeoutLow | ((ulong)timeoutHigh << 32));
return _syscall.ReplyAndReceive(handlesPtr, handlesCount, replyTargetHandle, timeout, out handleIndex);
}
public KernelResult CreatePort32(
[R(0)] uint namePtr,
[R(2)] int maxSessions,
[R(3)] bool isLight,
[R(1)] out int serverPortHandle,
[R(2)] out int clientPortHandle)
{
return _syscall.CreatePort(maxSessions, isLight, namePtr, out serverPortHandle, out clientPortHandle);
}
public KernelResult ManageNamedPort32([R(1)] uint namePtr, [R(2)] int maxSessions, [R(1)] out int handle)
{
return _syscall.ManageNamedPort(namePtr, maxSessions, out handle);
}
public KernelResult ConnectToPort32([R(1)] int clientPortHandle, [R(1)] out int clientSessionHandle)
{
return _syscall.ConnectToPort(clientPortHandle, out clientSessionHandle);
}
// Memory
public KernelResult SetHeapSize32([R(1)] uint size, [R(1)] out uint position)
{
KernelResult result = _syscall.SetHeapSize(size, out ulong temporaryPosition);
position = (uint)temporaryPosition;
return result;
}
public KernelResult SetMemoryPermission32(
[R(0)] ulong position,
[R(1)] ulong size,
[R(2)] KMemoryPermission permission)
{
return _syscall.SetMemoryPermission(position, size, permission);
}
public KernelResult SetMemoryAttribute32(
[R(0)] uint position,
[R(1)] uint size,
[R(2)] MemoryAttribute attributeMask,
[R(3)] MemoryAttribute attributeValue)
{
return _syscall.SetMemoryAttribute(position, size, attributeMask, attributeValue);
}
public KernelResult MapMemory32([R(0)] uint dst, [R(1)] uint src, [R(2)] uint size)
{
return _syscall.MapMemory(dst, src, size);
}
public KernelResult UnmapMemory32([R(0)] uint dst, [R(1)] uint src, [R(2)] uint size)
{
return _syscall.UnmapMemory(dst, src, size);
}
public KernelResult QueryMemory32([R(0)] uint infoPtr, [R(1)] uint r1, [R(2)] uint position, [R(1)] out uint pageInfo)
{
KernelResult result = _syscall.QueryMemory(infoPtr, position, out ulong pageInfo64);
pageInfo = (uint)pageInfo64;
return result;
}
public KernelResult MapSharedMemory32([R(0)] int handle, [R(1)] uint address, [R(2)] uint size, [R(3)] KMemoryPermission permission)
{
return _syscall.MapSharedMemory(handle, address, size, permission);
}
public KernelResult UnmapSharedMemory32([R(0)] int handle, [R(1)] uint address, [R(2)] uint size)
{
return _syscall.UnmapSharedMemory(handle, address, size);
}
public KernelResult CreateTransferMemory32(
[R(1)] uint address,
[R(2)] uint size,
[R(3)] KMemoryPermission permission,
[R(1)] out int handle)
{
return _syscall.CreateTransferMemory(address, size, permission, out handle);
}
public KernelResult MapTransferMemory32([R(0)] int handle, [R(1)] uint address, [R(2)] uint size, [R(3)] KMemoryPermission permission)
{
return _syscall.MapTransferMemory(handle, address, size, permission);
}
public KernelResult UnmapTransferMemory32([R(0)] int handle, [R(1)] uint address, [R(2)] uint size)
{
return _syscall.UnmapTransferMemory(handle, address, size);
}
public KernelResult MapPhysicalMemory32([R(0)] uint address, [R(1)] uint size)
{
return _syscall.MapPhysicalMemory(address, size);
}
public KernelResult UnmapPhysicalMemory32([R(0)] uint address, [R(1)] uint size)
{
return _syscall.UnmapPhysicalMemory(address, size);
}
public KernelResult MapProcessCodeMemory32([R(0)] int handle, [R(1)] uint srcLow, [R(2)] uint dstLow, [R(3)] uint dstHigh, [R(4)] uint srcHigh, [R(5)] uint sizeLow, [R(6)] uint sizeHigh)
{
ulong src = srcLow | ((ulong)srcHigh << 32);
ulong dst = dstLow | ((ulong)dstHigh << 32);
ulong size = sizeLow | ((ulong)sizeHigh << 32);
return _syscall.MapProcessCodeMemory(handle, dst, src, size);
}
public KernelResult UnmapProcessCodeMemory32([R(0)] int handle, [R(1)] uint srcLow, [R(2)] uint dstLow, [R(3)] uint dstHigh, [R(4)] uint srcHigh, [R(5)] uint sizeLow, [R(6)] uint sizeHigh)
{
ulong src = srcLow | ((ulong)srcHigh << 32);
ulong dst = dstLow | ((ulong)dstHigh << 32);
ulong size = sizeLow | ((ulong)sizeHigh << 32);
return _syscall.UnmapProcessCodeMemory(handle, dst, src, size);
}
public KernelResult SetProcessMemoryPermission32(
[R(0)] int handle,
[R(1)] uint sizeLow,
[R(2)] uint srcLow,
[R(3)] uint srcHigh,
[R(4)] uint sizeHigh,
[R(5)] KMemoryPermission permission)
{
ulong src = srcLow | ((ulong)srcHigh << 32);
ulong size = sizeLow | ((ulong)sizeHigh << 32);
return _syscall.SetProcessMemoryPermission(handle, src, size, permission);
}
// System
public void ExitProcess32()
{
_syscall.ExitProcess();
}
public KernelResult TerminateProcess32([R(0)] int handle)
{
return _syscall.TerminateProcess(handle);
}
public KernelResult SignalEvent32([R(0)] int handle)
{
return _syscall.SignalEvent(handle);
}
public KernelResult ClearEvent32([R(0)] int handle)
{
return _syscall.ClearEvent(handle);
}
public KernelResult CloseHandle32([R(0)] int handle)
{
return _syscall.CloseHandle(handle);
}
public KernelResult ResetSignal32([R(0)] int handle)
{
return _syscall.ResetSignal(handle);
}
public void GetSystemTick32([R(0)] out uint resultLow, [R(1)] out uint resultHigh)
{
ulong result = _syscall.GetSystemTick();
resultLow = (uint)(result & uint.MaxValue);
resultHigh = (uint)(result >> 32);
}
public KernelResult GetProcessId32([R(1)] int handle, [R(1)] out int pidLow, [R(2)] out int pidHigh)
{
KernelResult result = _syscall.GetProcessId(handle, out long pid);
pidLow = (int)(pid & uint.MaxValue);
pidHigh = (int)(pid >> 32);
return result;
}
public void Break32([R(0)] uint reason, [R(1)] uint r1, [R(2)] uint info)
{
_syscall.Break(reason);
}
public void OutputDebugString32([R(0)] uint strPtr, [R(1)] uint size)
{
_syscall.OutputDebugString(strPtr, size);
}
public KernelResult GetInfo32(
[R(0)] uint subIdLow,
[R(1)] uint id,
[R(2)] int handle,
[R(3)] uint subIdHigh,
[R(1)] out uint valueLow,
[R(2)] out uint valueHigh)
{
long subId = (long)(subIdLow | ((ulong)subIdHigh << 32));
KernelResult result = _syscall.GetInfo(id, handle, subId, out long value);
valueHigh = (uint)(value >> 32);
valueLow = (uint)(value & uint.MaxValue);
return result;
}
public KernelResult CreateEvent32([R(1)] out int wEventHandle, [R(2)] out int rEventHandle)
{
return _syscall.CreateEvent(out wEventHandle, out rEventHandle);
}
public KernelResult GetProcessList32([R(1)] ulong address, [R(2)] int maxCount, [R(1)] out int count)
{
return _syscall.GetProcessList(address, maxCount, out count);
}
public KernelResult GetSystemInfo32([R(1)] uint subIdLow, [R(2)] uint id, [R(3)] int handle, [R(3)] uint subIdHigh, [R(1)] out int valueLow, [R(2)] out int valueHigh)
{
long subId = (long)(subIdLow | ((ulong)subIdHigh << 32));
KernelResult result = _syscall.GetSystemInfo(id, handle, subId, out long value);
valueHigh = (int)(value >> 32);
valueLow = (int)(value & uint.MaxValue);
return result;
}
public KernelResult FlushProcessDataCache32(
[R(0)] uint processHandle,
[R(2)] uint addressLow,
[R(3)] uint addressHigh,
[R(1)] uint sizeLow,
[R(4)] uint sizeHigh)
{
// FIXME: This needs to be implemented as ARMv7 doesn't have any way to do cache maintenance operations on EL0.
// As we don't support (and don't actually need) to flush the cache, this is stubbed.
return KernelResult.Success;
}
// Thread
public KernelResult CreateThread32(
[R(1)] uint entrypoint,
[R(2)] uint argsPtr,
[R(3)] uint stackTop,
[R(0)] int priority,
[R(4)] int cpuCore,
[R(1)] out int handle)
{
return _syscall.CreateThread(entrypoint, argsPtr, stackTop, priority, cpuCore, out handle);
}
public KernelResult StartThread32([R(0)] int handle)
{
return _syscall.StartThread(handle);
}
public void ExitThread32()
{
_syscall.ExitThread();
}
public void SleepThread32([R(0)] uint timeoutLow, [R(1)] uint timeoutHigh)
{
long timeout = (long)(timeoutLow | ((ulong)timeoutHigh << 32));
_syscall.SleepThread(timeout);
}
public KernelResult GetThreadPriority32([R(1)] int handle, [R(1)] out int priority)
{
return _syscall.GetThreadPriority(handle, out priority);
}
public KernelResult SetThreadPriority32([R(0)] int handle, [R(1)] int priority)
{
return _syscall.SetThreadPriority(handle, priority);
}
public KernelResult GetThreadCoreMask32([R(2)] int handle, [R(1)] out int preferredCore, [R(2)] out int affinityMaskLow, [R(3)] out int affinityMaskHigh)
{
KernelResult result = _syscall.GetThreadCoreMask(handle, out preferredCore, out long affinityMask);
affinityMaskLow = (int)(affinityMask & uint.MaxValue);
affinityMaskHigh = (int)(affinityMask >> 32);
return result;
}
public KernelResult SetThreadCoreMask32([R(0)] int handle, [R(1)] int preferredCore, [R(2)] uint affinityMaskLow, [R(3)] uint affinityMaskHigh)
{
long affinityMask = (long)(affinityMaskLow | ((ulong)affinityMaskHigh << 32));
return _syscall.SetThreadCoreMask(handle, preferredCore, affinityMask);
}
public int GetCurrentProcessorNumber32()
{
return _syscall.GetCurrentProcessorNumber();
}
public KernelResult GetThreadId32([R(1)] int handle, [R(1)] out uint threadUidLow, [R(2)] out uint threadUidHigh)
{
long threadUid;
KernelResult result = _syscall.GetThreadId(handle, out threadUid);
threadUidLow = (uint)(threadUid >> 32);
threadUidHigh = (uint)(threadUid & uint.MaxValue);
return result;
}
public KernelResult SetThreadActivity32([R(0)] int handle, [R(1)] bool pause)
{
return _syscall.SetThreadActivity(handle, pause);
}
public KernelResult GetThreadContext332([R(0)] uint address, [R(1)] int handle)
{
return _syscall.GetThreadContext3(address, handle);
}
// Thread synchronization
public KernelResult WaitSynchronization32(
[R(0)] uint timeoutLow,
[R(1)] uint handlesPtr,
[R(2)] int handlesCount,
[R(3)] uint timeoutHigh,
[R(1)] out int handleIndex)
{
long timeout = (long)(timeoutLow | ((ulong)timeoutHigh << 32));
return _syscall.WaitSynchronization(handlesPtr, handlesCount, timeout, out handleIndex);
}
public KernelResult CancelSynchronization32([R(0)] int handle)
{
return _syscall.CancelSynchronization(handle);
}
public KernelResult ArbitrateLock32([R(0)] int ownerHandle, [R(1)] uint mutexAddress, [R(2)] int requesterHandle)
{
return _syscall.ArbitrateLock(ownerHandle, mutexAddress, requesterHandle);
}
public KernelResult ArbitrateUnlock32([R(0)] uint mutexAddress)
{
return _syscall.ArbitrateUnlock(mutexAddress);
}
public KernelResult WaitProcessWideKeyAtomic32(
[R(0)] uint mutexAddress,
[R(1)] uint condVarAddress,
[R(2)] int handle,
[R(3)] uint timeoutLow,
[R(4)] uint timeoutHigh)
{
long timeout = (long)(timeoutLow | ((ulong)timeoutHigh << 32));
return _syscall.WaitProcessWideKeyAtomic(mutexAddress, condVarAddress, handle, timeout);
}
public KernelResult SignalProcessWideKey32([R(0)] uint address, [R(1)] int count)
{
return _syscall.SignalProcessWideKey(address, count);
}
public KernelResult WaitForAddress32([R(0)] uint address, [R(1)] ArbitrationType type, [R(2)] int value, [R(3)] uint timeoutLow, [R(4)] uint timeoutHigh)
{
long timeout = (long)(timeoutLow | ((ulong)timeoutHigh << 32));
return _syscall.WaitForAddress(address, type, value, timeout);
}
public KernelResult SignalToAddress32([R(0)] uint address, [R(1)] SignalType type, [R(2)] int value, [R(3)] int count)
{
return _syscall.SignalToAddress(address, type, value, count);
}
}
}