/* * Copyright (c) Atmosphère-NX * * This program is free software; you can redistribute it and/or modify it * under the terms and conditions of the GNU General Public License, * version 2, as published by the Free Software Foundation. * * This program is distributed in the hope it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for * more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include namespace ams::kern::svc { /* ============================= Common ============================= */ namespace { Result GetInitialProcessIdRange(u64 *out, ams::svc::InitialProcessIdRangeInfo info) { switch (info) { case ams::svc::InitialProcessIdRangeInfo_Minimum: MESOSPHERE_ABORT_UNLESS(GetInitialProcessIdMin() <= GetInitialProcessIdMax()); *out = GetInitialProcessIdMin(); break; case ams::svc::InitialProcessIdRangeInfo_Maximum: MESOSPHERE_ABORT_UNLESS(GetInitialProcessIdMin() <= GetInitialProcessIdMax()); *out = GetInitialProcessIdMax(); break; default: R_THROW(svc::ResultInvalidCombination()); } R_SUCCEED(); } Result GetInfoImpl(u64 *out, ams::svc::InfoType info_type, KProcess *process) { switch (info_type) { case ams::svc::InfoType_CoreMask: *out = process->GetCoreMask(); break; case ams::svc::InfoType_PriorityMask: *out = process->GetPriorityMask(); break; case ams::svc::InfoType_AliasRegionAddress: *out = GetInteger(process->GetPageTable().GetAliasRegionStart()); break; case ams::svc::InfoType_AliasRegionSize: *out = process->GetPageTable().GetAliasRegionSize(); break; case ams::svc::InfoType_HeapRegionAddress: *out = GetInteger(process->GetPageTable().GetHeapRegionStart()); break; case ams::svc::InfoType_HeapRegionSize: *out = process->GetPageTable().GetHeapRegionSize(); break; case ams::svc::InfoType_TotalMemorySize: *out = process->GetTotalUserPhysicalMemorySize(); break; case ams::svc::InfoType_UsedMemorySize: *out = process->GetUsedUserPhysicalMemorySize(); break; case ams::svc::InfoType_AslrRegionAddress: *out = GetInteger(process->GetPageTable().GetAliasCodeRegionStart()); break; case ams::svc::InfoType_AslrRegionSize: *out = process->GetPageTable().GetAliasCodeRegionSize(); break; case ams::svc::InfoType_StackRegionAddress: *out = GetInteger(process->GetPageTable().GetStackRegionStart()); break; case ams::svc::InfoType_StackRegionSize: *out = process->GetPageTable().GetStackRegionSize(); break; case ams::svc::InfoType_SystemResourceSizeTotal: *out = process->GetTotalSystemResourceSize(); break; case ams::svc::InfoType_SystemResourceSizeUsed: *out = process->GetUsedSystemResourceSize(); break; case ams::svc::InfoType_ProgramId: *out = process->GetProgramId(); break; case ams::svc::InfoType_UserExceptionContextAddress: *out = GetInteger(process->GetProcessLocalRegionAddress()); break; case ams::svc::InfoType_TotalNonSystemMemorySize: *out = process->GetTotalNonSystemUserPhysicalMemorySize(); break; case ams::svc::InfoType_UsedNonSystemMemorySize: *out = process->GetUsedNonSystemUserPhysicalMemorySize(); break; case ams::svc::InfoType_IsApplication: *out = process->IsApplication(); break; case ams::svc::InfoType_FreeThreadCount: if (KResourceLimit *resource_limit = process->GetResourceLimit(); resource_limit != nullptr) { const auto current_value = resource_limit->GetCurrentValue(ams::svc::LimitableResource_ThreadCountMax); const auto limit_value = resource_limit->GetLimitValue(ams::svc::LimitableResource_ThreadCountMax); *out = limit_value - current_value; } else { *out = 0; } break; case ams::svc::InfoType_AliasRegionExtraSize: *out = process->GetPageTable().GetAliasRegionExtraSize(); break; MESOSPHERE_UNREACHABLE_DEFAULT_CASE(); } R_SUCCEED(); } Result GetInfo(u64 *out, ams::svc::InfoType info_type, ams::svc::Handle handle, u64 info_subtype) { switch (info_type) { case ams::svc::InfoType_CoreMask: case ams::svc::InfoType_PriorityMask: case ams::svc::InfoType_AliasRegionAddress: case ams::svc::InfoType_AliasRegionSize: case ams::svc::InfoType_HeapRegionAddress: case ams::svc::InfoType_HeapRegionSize: case ams::svc::InfoType_TotalMemorySize: case ams::svc::InfoType_UsedMemorySize: case ams::svc::InfoType_AslrRegionAddress: case ams::svc::InfoType_AslrRegionSize: case ams::svc::InfoType_StackRegionAddress: case ams::svc::InfoType_StackRegionSize: case ams::svc::InfoType_SystemResourceSizeTotal: case ams::svc::InfoType_SystemResourceSizeUsed: case ams::svc::InfoType_ProgramId: case ams::svc::InfoType_UserExceptionContextAddress: case ams::svc::InfoType_TotalNonSystemMemorySize: case ams::svc::InfoType_UsedNonSystemMemorySize: case ams::svc::InfoType_IsApplication: case ams::svc::InfoType_FreeThreadCount: case ams::svc::InfoType_AliasRegionExtraSize: { /* These info types don't support non-zero subtypes. */ R_UNLESS(info_subtype == 0, svc::ResultInvalidCombination()); /* Get the process from its handle. */ KScopedAutoObject process = GetCurrentProcess().GetHandleTable().GetObject(handle); #if defined(MESOSPHERE_ENABLE_GET_INFO_OF_DEBUG_PROCESS) /* If we the process is valid, use it. */ if (process.IsNotNull()) { R_RETURN(GetInfoImpl(out, info_type, process.GetPointerUnsafe())); } /* Otherwise, as a mesosphere extension check if we were passed a usable KDebug. */ KScopedAutoObject debug = GetCurrentProcess().GetHandleTable().GetObject(handle); R_UNLESS(debug.IsNotNull(), svc::ResultInvalidHandle()); /* Get the process from the debug object. */ /* TODO: ResultInvalidHandle()? */ R_UNLESS(debug->IsAttached(), svc::ResultProcessTerminated()); R_UNLESS(debug->OpenProcess(), svc::ResultProcessTerminated()); /* Close the process when we're done. */ ON_SCOPE_EXIT { debug->CloseProcess(); }; /* Return the info. */ R_RETURN(GetInfoImpl(out, info_type, debug->GetProcessUnsafe())); #else /* Verify that the process is valid. */ R_UNLESS(process.IsNotNull(), svc::ResultInvalidHandle()); /* Return the relevant info. */ R_RETURN(GetInfoImpl(out, info_type, process.GetPointerUnsafe())); #endif } break; case ams::svc::InfoType_DebuggerAttached: { /* Verify the input handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Verify the sub-type is valid. */ R_UNLESS(info_subtype == 0, svc::ResultInvalidCombination()); /* Get whether debugger is attached. */ *out = GetCurrentProcess().GetDebugObject() != nullptr; } break; case ams::svc::InfoType_ResourceLimit: { /* Verify the input handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Verify the sub-type is valid. */ R_UNLESS(info_subtype == 0, svc::ResultInvalidCombination()); /* Get the handle table and resource limit. */ KHandleTable &handle_table = GetCurrentProcess().GetHandleTable(); KResourceLimit *resource_limit = GetCurrentProcess().GetResourceLimit(); if (resource_limit != nullptr) { /* Get a new handle for the resource limit. */ ams::svc::Handle tmp; R_TRY(handle_table.Add(std::addressof(tmp), resource_limit)); /* Set the output. */ *out = tmp; } else { /* Set the output. */ *out = ams::svc::InvalidHandle; } } break; case ams::svc::InfoType_IdleTickCount: { /* Verify the input handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Disable dispatch while we get the tick count. */ KScopedDisableDispatch dd; /* Verify the requested core is valid. */ const bool core_valid = (info_subtype == static_cast(-1ul)) || (info_subtype == static_cast(GetCurrentCoreId())); R_UNLESS(core_valid, svc::ResultInvalidCombination()); /* Get the idle tick count. */ *out = Kernel::GetScheduler().GetIdleThread()->GetCpuTime() - Kernel::GetInterruptTaskManager().GetCpuTime(); } break; case ams::svc::InfoType_RandomEntropy: { /* Verify the input handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Verify the requested entropy is valid. */ R_UNLESS(info_subtype < 4, svc::ResultInvalidCombination()); /* Get the entropy. */ *out = GetCurrentProcess().GetRandomEntropy(info_subtype); } break; case ams::svc::InfoType_InitialProcessIdRange: { /* NOTE: This info type was added in 4.0.0, and removed in 5.0.0. */ R_UNLESS(GetTargetFirmware() < TargetFirmware_5_0_0, svc::ResultInvalidEnumValue()); /* Verify the input handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Get the process id range. */ R_TRY(GetInitialProcessIdRange(out, static_cast(info_subtype))); } break; case ams::svc::InfoType_ThreadTickCount: { /* Verify the requested core is valid. */ const bool core_valid = (info_subtype == static_cast(-1ul)) || (info_subtype < cpu::NumVirtualCores); R_UNLESS(core_valid, svc::ResultInvalidCombination()); /* Get the thread from its handle. */ KScopedAutoObject thread = GetCurrentProcess().GetHandleTable().GetObject(handle); R_UNLESS(thread.IsNotNull(), svc::ResultInvalidHandle()); /* Disable dispatch while we get the tick count. */ KScopedDisableDispatch dd; /* Determine the tick count. */ s64 tick_count; if (info_subtype == static_cast(-1ul)) { tick_count = thread->GetCpuTime(); if (GetCurrentThreadPointer() == thread.GetPointerUnsafe()) { const s64 cur_tick = KHardwareTimer::GetTick(); const s64 prev_switch = Kernel::GetScheduler().GetLastContextSwitchTime(); tick_count += (cur_tick - prev_switch); } } else { const s32 phys_core = cpu::VirtualToPhysicalCoreMap[info_subtype]; MESOSPHERE_ABORT_UNLESS(phys_core < static_cast(cpu::NumCores)); tick_count = thread->GetCpuTime(phys_core); if (GetCurrentThreadPointer() == thread.GetPointerUnsafe() && phys_core == GetCurrentCoreId()) { const s64 cur_tick = KHardwareTimer::GetTick(); const s64 prev_switch = Kernel::GetScheduler().GetLastContextSwitchTime(); tick_count += (cur_tick - prev_switch); } } /* Set the output. */ *out = tick_count; } break; case ams::svc::InfoType_IsSvcPermitted: { /* Verify the input handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Verify the sub-type is valid. */ R_UNLESS(info_subtype == svc::SvcId_SynchronizePreemptionState, svc::ResultInvalidCombination()); /* Get whether the svc is permitted. */ *out = GetCurrentProcess().IsPermittedSvc(static_cast(info_subtype)); } break; case ams::svc::InfoType_IoRegionHint: { /* Verify the sub-type is valid. */ R_UNLESS(info_subtype == 0, svc::ResultInvalidCombination()); /* Get the io region from its handle. */ KScopedAutoObject io_region = GetCurrentProcess().GetHandleTable().GetObject(handle); R_UNLESS(io_region.IsNotNull(), svc::ResultInvalidHandle()); /* Get the io region's address hint. */ *out = io_region->GetHint(); } break; case ams::svc::InfoType_TransferMemoryHint: { /* Verify the sub-type is valid. */ R_UNLESS(info_subtype == 0, svc::ResultInvalidCombination()); /* Get the transfer memory from its handle. */ KScopedAutoObject transfer_memory = GetCurrentProcess().GetHandleTable().GetObject(handle); R_UNLESS(transfer_memory.IsNotNull(), svc::ResultInvalidHandle()); /* Get the transfer memory's address hint. */ *out = transfer_memory->GetHint(); } break; case ams::svc::InfoType_MesosphereMeta: { /* Verify the handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); switch (static_cast(info_subtype)) { case ams::svc::MesosphereMetaInfo_KernelVersion: { /* Return the supported kernel version. */ *out = ams::svc::SupportedKernelVersion; } break; case ams::svc::MesosphereMetaInfo_IsKTraceEnabled: { /* Return whether the kernel supports tracing. */ constexpr u64 KTraceValue = ams::kern::IsKTraceEnabled ? 1 : 0; *out = KTraceValue; } break; case ams::svc::MesosphereMetaInfo_IsSingleStepEnabled: { /* Return whether the kernel supports hardware single step. */ #if defined(MESOSPHERE_ENABLE_HARDWARE_SINGLE_STEP) *out = 1; #else *out = 0; #endif } break; default: R_THROW(svc::ResultInvalidCombination()); } } break; case ams::svc::InfoType_MesosphereCurrentProcess: { /* Verify the input handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Verify the sub-type is valid. */ R_UNLESS(info_subtype == 0, svc::ResultInvalidCombination()); /* Get the handle table. */ KHandleTable &handle_table = GetCurrentProcess().GetHandleTable(); /* Get a new handle for the current process. */ ams::svc::Handle tmp; R_TRY(handle_table.Add(std::addressof(tmp), GetCurrentProcessPointer())); /* Set the output. */ *out = tmp; } break; default: { /* For debug, log the invalid info call. */ MESOSPHERE_LOG("GetInfo(%p, %u, %08x, %lu) was called\n", out, static_cast(info_type), static_cast(handle), info_subtype); } R_THROW(svc::ResultInvalidEnumValue()); } R_SUCCEED(); } constexpr bool IsValidMemoryPool(u64 pool) { switch (static_cast(pool)) { case KMemoryManager::Pool_Application: case KMemoryManager::Pool_Applet: case KMemoryManager::Pool_System: case KMemoryManager::Pool_SystemNonSecure: return true; default: return false; } } Result GetSystemInfo(u64 *out, ams::svc::SystemInfoType info_type, ams::svc::Handle handle, u64 info_subtype) { switch (info_type) { case ams::svc::SystemInfoType_TotalPhysicalMemorySize: case ams::svc::SystemInfoType_UsedPhysicalMemorySize: { /* Verify the input handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Verify the sub-type is valid. */ R_UNLESS(IsValidMemoryPool(info_subtype), svc::ResultInvalidCombination()); /* Convert to pool. */ const auto pool = static_cast(info_subtype); /* Get the memory size. */ auto &mm = Kernel::GetMemoryManager(); switch (info_type) { case ams::svc::SystemInfoType_TotalPhysicalMemorySize: *out = mm.GetSize(pool); break; case ams::svc::SystemInfoType_UsedPhysicalMemorySize: *out = mm.GetSize(pool) - mm.GetFreeSize(pool); break; MESOSPHERE_UNREACHABLE_DEFAULT_CASE(); } } break; case ams::svc::SystemInfoType_InitialProcessIdRange: { /* Verify the handle is invalid. */ R_UNLESS(handle == ams::svc::InvalidHandle, svc::ResultInvalidHandle()); /* Get the process id range. */ R_TRY(GetInitialProcessIdRange(out, static_cast(info_subtype))); } break; default: R_THROW(svc::ResultInvalidEnumValue()); } R_SUCCEED(); } } /* ============================= 64 ABI ============================= */ Result GetInfo64(uint64_t *out, ams::svc::InfoType info_type, ams::svc::Handle handle, uint64_t info_subtype) { R_RETURN(GetInfo(out, info_type, handle, info_subtype)); } Result GetSystemInfo64(uint64_t *out, ams::svc::SystemInfoType info_type, ams::svc::Handle handle, uint64_t info_subtype) { R_RETURN(GetSystemInfo(out, info_type, handle, info_subtype)); } /* ============================= 64From32 ABI ============================= */ Result GetInfo64From32(uint64_t *out, ams::svc::InfoType info_type, ams::svc::Handle handle, uint64_t info_subtype) { R_RETURN(GetInfo(out, info_type, handle, info_subtype)); } Result GetSystemInfo64From32(uint64_t *out, ams::svc::SystemInfoType info_type, ams::svc::Handle handle, uint64_t info_subtype) { R_RETURN(GetSystemInfo(out, info_type, handle, info_subtype)); } }