forked from Mirror/Ryujinx
00579927e4
* Initial implementation of KProcess * Some improvements to the memory manager, implement back guest stack trace printing * Better GetInfo implementation, improve checking in some places with information from process capabilities * Allow the cpu to read/write from the correct memory locations for accesses crossing a page boundary * Change long -> ulong for address/size on memory related methods to avoid unnecessary casts * Attempt at implementing ldr:ro with new KProcess * Allow BSS with size 0 on ldr:ro * Add checking for memory block slab heap usage, return errors if full, exit gracefully * Use KMemoryBlockSize const from KMemoryManager * Allow all methods to read from non-contiguous locations * Fix for TransactParcelAuto * Address PR feedback, additionally fix some small issues related to the KIP loader and implement SVCs GetProcessId, GetProcessList, GetSystemInfo, CreatePort and ManageNamedPort * Fix wrong check for source pages count from page list on MapPhysicalMemory * Fix some issues with UnloadNro on ldr:ro
136 lines
No EOL
4.7 KiB
C#
136 lines
No EOL
4.7 KiB
C#
using System;
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namespace Ryujinx.HLE.HOS.Kernel
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{
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static class KernelInit
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{
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public static void InitializeResourceLimit(KResourceLimit ResourceLimit)
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{
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void EnsureSuccess(KernelResult Result)
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{
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if (Result != KernelResult.Success)
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{
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throw new InvalidOperationException($"Unexpected result \"{Result}\".");
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}
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}
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int KernelMemoryCfg = 0;
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long RamSize = GetRamSize(KernelMemoryCfg);
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EnsureSuccess(ResourceLimit.SetLimitValue(LimitableResource.Memory, RamSize));
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EnsureSuccess(ResourceLimit.SetLimitValue(LimitableResource.Thread, 800));
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EnsureSuccess(ResourceLimit.SetLimitValue(LimitableResource.Event, 700));
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EnsureSuccess(ResourceLimit.SetLimitValue(LimitableResource.TransferMemory, 200));
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EnsureSuccess(ResourceLimit.SetLimitValue(LimitableResource.Session, 900));
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if (!ResourceLimit.Reserve(LimitableResource.Memory, 0) ||
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!ResourceLimit.Reserve(LimitableResource.Memory, 0x60000))
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{
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throw new InvalidOperationException("Unexpected failure reserving memory on resource limit.");
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}
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}
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public static KMemoryRegionManager[] GetMemoryRegions()
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{
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KMemoryArrange Arrange = GetMemoryArrange();
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return new KMemoryRegionManager[]
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{
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GetMemoryRegion(Arrange.Application),
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GetMemoryRegion(Arrange.Applet),
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GetMemoryRegion(Arrange.Service),
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GetMemoryRegion(Arrange.NvServices)
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};
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}
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private static KMemoryRegionManager GetMemoryRegion(KMemoryArrangeRegion Region)
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{
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return new KMemoryRegionManager(Region.Address, Region.Size, Region.EndAddr);
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}
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private static KMemoryArrange GetMemoryArrange()
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{
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int McEmemCfg = 0x1000;
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ulong EmemApertureSize = (ulong)(McEmemCfg & 0x3fff) << 20;
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int KernelMemoryCfg = 0;
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ulong RamSize = (ulong)GetRamSize(KernelMemoryCfg);
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ulong RamPart0;
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ulong RamPart1;
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if (RamSize * 2 > EmemApertureSize)
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{
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RamPart0 = EmemApertureSize / 2;
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RamPart1 = EmemApertureSize / 2;
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}
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else
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{
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RamPart0 = EmemApertureSize;
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RamPart1 = 0;
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}
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int MemoryArrange = 1;
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ulong ApplicationRgSize;
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switch (MemoryArrange)
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{
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case 2: ApplicationRgSize = 0x80000000; break;
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case 0x11:
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case 0x21: ApplicationRgSize = 0x133400000; break;
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default: ApplicationRgSize = 0xcd500000; break;
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}
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ulong AppletRgSize;
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switch (MemoryArrange)
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{
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case 2: AppletRgSize = 0x61200000; break;
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case 3: AppletRgSize = 0x1c000000; break;
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case 0x11: AppletRgSize = 0x23200000; break;
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case 0x12:
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case 0x21: AppletRgSize = 0x89100000; break;
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default: AppletRgSize = 0x1fb00000; break;
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}
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KMemoryArrangeRegion ServiceRg;
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KMemoryArrangeRegion NvServicesRg;
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KMemoryArrangeRegion AppletRg;
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KMemoryArrangeRegion ApplicationRg;
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const ulong NvServicesRgSize = 0x29ba000;
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ulong ApplicationRgEnd = DramMemoryMap.DramEnd; //- RamPart0;
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ApplicationRg = new KMemoryArrangeRegion(ApplicationRgEnd - ApplicationRgSize, ApplicationRgSize);
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ulong NvServicesRgEnd = ApplicationRg.Address - AppletRgSize;
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NvServicesRg = new KMemoryArrangeRegion(NvServicesRgEnd - NvServicesRgSize, NvServicesRgSize);
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AppletRg = new KMemoryArrangeRegion(NvServicesRgEnd, AppletRgSize);
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//Note: There is an extra region used by the kernel, however
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//since we are doing HLE we are not going to use that memory, so give all
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//the remaining memory space to services.
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ulong ServiceRgSize = NvServicesRg.Address - DramMemoryMap.SlabHeapEnd;
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ServiceRg = new KMemoryArrangeRegion(DramMemoryMap.SlabHeapEnd, ServiceRgSize);
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return new KMemoryArrange(ServiceRg, NvServicesRg, AppletRg, ApplicationRg);
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}
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private static long GetRamSize(int KernelMemoryCfg)
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{
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switch ((KernelMemoryCfg >> 16) & 3)
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{
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case 1: return 0x180000000;
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case 2: return 0x200000000;
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default: return 0x100000000;
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}
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}
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}
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} |