// SPDX-License-Identifier: MPL-2.0 // Copyright © 2020 Skyline Team and Contributors (https://github.com/skyline-emu/) #include #include "svc.h" namespace skyline::kernel::svc { void SetHeapSize(DeviceState &state) { constexpr auto heapSizeAlign = 0x200000; // The heap size has to be a multiple of this value auto size = state.ctx->registers.w1; if (size % heapSizeAlign != 0) { state.ctx->registers.w0 = constant::status::InvSize; state.ctx->registers.x1 = 0; state.logger->Warn("svcSetHeapSize: 'size' not divisible by 2MB: {}", size); return; } auto &heap = state.process->heap; heap->Resize(size); state.ctx->registers.w0 = constant::status::Success; state.ctx->registers.x1 = heap->address; state.logger->Debug("svcSetHeapSize: Allocated at 0x{:X} for 0x{:X} bytes", heap->address, heap->size); } void SetMemoryAttribute(DeviceState &state) { auto address = state.ctx->registers.x0; if (!util::PageAligned(address)) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcSetMemoryAttribute: 'address' not page aligned: 0x{:X}", address); return; } auto size = state.ctx->registers.x1; if (!util::PageAligned(size)) { state.ctx->registers.w0 = constant::status::InvSize; state.logger->Warn("svcSetMemoryAttribute: 'size' {}: 0x{:X}", size ? "not page aligned" : "is zero", size); return; } memory::MemoryAttribute mask{.value = state.ctx->registers.w2}; memory::MemoryAttribute value{.value = state.ctx->registers.w3}; auto maskedValue = mask.value | value.value; if (maskedValue != mask.value || !mask.isUncached || mask.isDeviceShared || mask.isBorrowed || mask.isIpcLocked) { state.ctx->registers.w0 = constant::status::InvCombination; state.logger->Warn("svcSetMemoryAttribute: 'mask' invalid: 0x{:X}, 0x{:X}", mask.value, value.value); return; } auto chunk = state.os->memory.GetChunk(address); auto block = state.os->memory.GetBlock(address); if (!chunk || !block) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcSetMemoryAttribute: Cannot find memory region: 0x{:X}", address); return; } if (!chunk->state.attributeChangeAllowed) { state.ctx->registers.w0 = constant::status::InvState; state.logger->Warn("svcSetMemoryAttribute: Attribute change not allowed for chunk: 0x{:X}", address); return; } block->attributes.isUncached = value.isUncached; MemoryManager::InsertBlock(chunk, *block); state.logger->Debug("svcSetMemoryAttribute: Set caching to {} at 0x{:X} for 0x{:X} bytes", !block->attributes.isUncached, address, size); state.ctx->registers.w0 = constant::status::Success; } void MapMemory(DeviceState &state) { auto destination = state.ctx->registers.x0; auto source = state.ctx->registers.x1; auto size = state.ctx->registers.x2; if (!util::PageAligned(destination) || !util::PageAligned(source)) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcMapMemory: Addresses not page aligned: Source: 0x{:X}, Destination: 0x{:X} (Size: 0x{:X} bytes)", source, destination, size); return; } if (!util::PageAligned(size)) { state.ctx->registers.w0 = constant::status::InvSize; state.logger->Warn("svcMapMemory: 'size' {}: 0x{:X}", size ? "not page aligned" : "is zero", size); return; } auto stack = state.os->memory.GetRegion(memory::Regions::Stack); if (!stack.IsInside(destination)) { state.ctx->registers.w0 = constant::status::InvMemRange; state.logger->Warn("svcMapMemory: Destination not within stack region: Source: 0x{:X}, Destination: 0x{:X} (Size: 0x{:X} bytes)", source, destination, size); return; } auto descriptor = state.os->memory.Get(source); if (!descriptor) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcMapMemory: Source has no descriptor: Source: 0x{:X}, Destination: 0x{:X} (Size: 0x{:X} bytes)", source, destination, size); return; } if (!descriptor->chunk.state.mapAllowed) { state.ctx->registers.w0 = constant::status::InvState; state.logger->Warn("svcMapMemory: Source doesn't allow usage of svcMapMemory: Source: 0x{:X}, Destination: 0x{:X} (Size: 0x{:X} bytes) 0x{:X}", source, destination, size, descriptor->chunk.state.value); return; } state.process->NewHandle(destination, size, descriptor->block.permission, memory::states::Stack); state.process->CopyMemory(source, destination, size); auto object = state.process->GetMemoryObject(source); if (!object) throw exception("svcMapMemory: Cannot find memory object in handle table for address 0x{:X}", source); object->item->UpdatePermission(source, size, {false, false, false}); state.logger->Debug("svcMapMemory: Mapped range 0x{:X} - 0x{:X} to 0x{:X} - 0x{:X} (Size: 0x{:X} bytes)", source, source + size, destination, destination + size, size); state.ctx->registers.w0 = constant::status::Success; } void UnmapMemory(DeviceState &state) { auto source = state.ctx->registers.x0; auto destination = state.ctx->registers.x1; auto size = state.ctx->registers.x2; if (!util::PageAligned(destination) || !util::PageAligned(source)) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcUnmapMemory: Addresses not page aligned: Source: 0x{:X}, Destination: 0x{:X} (Size: 0x{:X} bytes)", source, destination, size); return; } if (!util::PageAligned(size)) { state.ctx->registers.w0 = constant::status::InvSize; state.logger->Warn("svcUnmapMemory: 'size' {}: 0x{:X}", size ? "not page aligned" : "is zero", size); return; } auto stack = state.os->memory.GetRegion(memory::Regions::Stack); if (!stack.IsInside(source)) { state.ctx->registers.w0 = constant::status::InvMemRange; state.logger->Warn("svcUnmapMemory: Source not within stack region: Source: 0x{:X}, Destination: 0x{:X} (Size: 0x{:X} bytes)", source, destination, size); return; } auto sourceDesc = state.os->memory.Get(source); auto destDesc = state.os->memory.Get(destination); if (!sourceDesc || !destDesc) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcUnmapMemory: Addresses have no descriptor: Source: 0x{:X}, Destination: 0x{:X} (Size: 0x{:X} bytes)", source, destination, size); return; } if (!destDesc->chunk.state.mapAllowed) { state.ctx->registers.w0 = constant::status::InvState; state.logger->Warn("svcUnmapMemory: Destination doesn't allow usage of svcMapMemory: Source: 0x{:X}, Destination: 0x{:X} (Size: 0x{:X} bytes) 0x{:X}", source, destination, size, destDesc->chunk.state.value); return; } auto destObject = state.process->GetMemoryObject(destination); if (!destObject) throw exception("svcUnmapMemory: Cannot find destination memory object in handle table for address 0x{:X}", destination); destObject->item->UpdatePermission(destination, size, sourceDesc->block.permission); state.process->CopyMemory(destination, source, size); auto sourceObject = state.process->GetMemoryObject(destination); if (!sourceObject) throw exception("svcUnmapMemory: Cannot find source memory object in handle table for address 0x{:X}", source); state.process->DeleteHandle(sourceObject->handle); state.logger->Debug("svcUnmapMemory: Unmapped range 0x{:X} - 0x{:X} to 0x{:X} - 0x{:X} (Size: 0x{:X} bytes)", source, source + size, destination, destination + size, size); state.ctx->registers.w0 = constant::status::Success; } void QueryMemory(DeviceState &state) { memory::MemoryInfo memInfo{}; auto address = state.ctx->registers.x2; auto descriptor = state.os->memory.Get(address); if (descriptor) { memInfo = { .address = descriptor->block.address, .size = descriptor->block.size, .type = static_cast(descriptor->chunk.state.type), .attributes = descriptor->block.attributes.value, .permissions = static_cast(descriptor->block.permission.Get()), .deviceRefCount = 0, .ipcRefCount = 0, }; state.logger->Debug("svcQueryMemory: Address: 0x{:X}, Size: 0x{:X}, Type: 0x{:X}, Is Uncached: {}, Permissions: {}{}{}", memInfo.address, memInfo.size, memInfo.type, static_cast(descriptor->block.attributes.isUncached), descriptor->block.permission.r ? "R" : "-", descriptor->block.permission.w ? "W" : "-", descriptor->block.permission.x ? "X" : "-"); } else { auto region = state.os->memory.GetRegion(memory::Regions::Base); auto baseEnd = region.address + region.size; memInfo = { .address = region.address, .size = ~baseEnd + 1, .type = static_cast(memory::MemoryType::Unmapped), }; state.logger->Debug("svcQueryMemory: Cannot find block of address: 0x{:X}", address); } state.process->WriteMemory(memInfo, state.ctx->registers.x0); state.ctx->registers.w0 = constant::status::Success; } void ExitProcess(DeviceState &state) { state.logger->Debug("svcExitProcess: Exiting current process: {}", state.process->pid); state.os->KillThread(state.process->pid); } void CreateThread(DeviceState &state) { u64 entryAddress = state.ctx->registers.x1; u64 entryArgument = state.ctx->registers.x2; u64 stackTop = state.ctx->registers.x3; u8 priority = static_cast(state.ctx->registers.w4); if ((priority < constant::SwitchPriority.first) || (priority > constant::SwitchPriority.second)) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcCreateThread: 'priority' invalid: {}", priority); return; } auto thread = state.process->CreateThread(entryAddress, entryArgument, stackTop, priority); state.logger->Debug("svcCreateThread: Created thread with handle 0x{:X} (Entry Point: 0x{:X}, Argument: 0x{:X}, Stack Pointer: 0x{:X}, Priority: {}, PID: {})", thread->handle, entryAddress, entryArgument, stackTop, priority, thread->tid); state.ctx->registers.w1 = thread->handle; state.ctx->registers.w0 = constant::status::Success; } void StartThread(DeviceState &state) { auto handle = state.ctx->registers.w0; try { auto thread = state.process->GetHandle(handle); state.logger->Debug("svcStartThread: Starting thread: 0x{:X}, PID: {}", handle, thread->tid); thread->Start(); state.ctx->registers.w0 = constant::status::Success; } catch (const std::exception &) { state.logger->Warn("svcStartThread: 'handle' invalid: 0x{:X}", handle); state.ctx->registers.w0 = constant::status::InvHandle; } } void ExitThread(DeviceState &state) { state.logger->Debug("svcExitThread: Exiting current thread: {}", state.thread->tid); state.os->KillThread(state.thread->tid); } void SleepThread(DeviceState &state) { auto in = state.ctx->registers.x0; switch (in) { case 0: case 1: case 2: state.logger->Debug("svcSleepThread: Yielding thread: {}", in); break; default: struct timespec spec = { .tv_sec = static_cast(state.ctx->registers.x0 / 1000000000), .tv_nsec = static_cast(state.ctx->registers.x0 % 1000000000) }; nanosleep(&spec, nullptr); state.logger->Debug("svcSleepThread: Thread sleeping for {} ns", in); } } void GetThreadPriority(DeviceState &state) { auto handle = state.ctx->registers.w0; try { auto priority = state.process->GetHandle(handle)->priority; state.logger->Debug("svcGetThreadPriority: Writing thread priority {}", priority); state.ctx->registers.w1 = priority; state.ctx->registers.w0 = constant::status::Success; } catch (const std::exception &) { state.logger->Warn("svcGetThreadPriority: 'handle' invalid: 0x{:X}", handle); state.ctx->registers.w0 = constant::status::InvHandle; } } void SetThreadPriority(DeviceState &state) { auto handle = state.ctx->registers.w0; auto priority = state.ctx->registers.w1; try { state.logger->Debug("svcSetThreadPriority: Setting thread priority to {}", priority); state.process->GetHandle(handle)->UpdatePriority(static_cast(priority)); state.ctx->registers.w0 = constant::status::Success; } catch (const std::exception &) { state.logger->Warn("svcSetThreadPriority: 'handle' invalid: 0x{:X}", handle); state.ctx->registers.w0 = constant::status::InvHandle; } } void MapSharedMemory(DeviceState &state) { try { auto object = state.process->GetHandle(state.ctx->registers.w0); u64 address = state.ctx->registers.x1; if (!util::PageAligned(address)) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcMapSharedMemory: 'address' not page aligned: 0x{:X}", address); return; } auto size = state.ctx->registers.x2; if (!util::PageAligned(size)) { state.ctx->registers.w0 = constant::status::InvSize; state.logger->Warn("svcMapSharedMemory: 'size' {}: 0x{:X}", size ? "not page aligned" : "is zero", size); return; } u32 perm = state.ctx->registers.w3; memory::Permission permission = *reinterpret_cast(&perm); if ((permission.w && !permission.r) || (permission.x && !permission.r)) { state.logger->Warn("svcMapSharedMemory: 'permission' invalid: {}{}{}", permission.r ? "R" : "-", permission.w ? "W" : "-", permission.x ? "X" : "-"); state.ctx->registers.w0 = constant::status::InvPermission; return; } state.logger->Debug("svcMapSharedMemory: Mapping shared memory at 0x{:X} for {} bytes ({}{}{})", address, size, permission.r ? "R" : "-", permission.w ? "W" : "-", permission.x ? "X" : "-"); object->Map(address, size, permission); state.ctx->registers.w0 = constant::status::Success; } catch (const std::exception &) { state.logger->Warn("svcMapSharedMemory: 'handle' invalid: 0x{:X}", state.ctx->registers.w0); state.ctx->registers.w0 = constant::status::InvHandle; } } void CreateTransferMemory(DeviceState &state) { u64 address = state.ctx->registers.x1; if (!util::PageAligned(address)) { state.ctx->registers.w0 = constant::status::InvAddress; state.logger->Warn("svcCreateTransferMemory: 'address' not page aligned: 0x{:X}", address); return; } u64 size = state.ctx->registers.x2; if (!util::PageAligned(size)) { state.ctx->registers.w0 = constant::status::InvSize; state.logger->Warn("svcCreateTransferMemory: 'size' {}: 0x{:X}", size ? "not page aligned" : "is zero", size); return; } u32 perm = state.ctx->registers.w3; memory::Permission permission = *reinterpret_cast(&perm); if ((permission.w && !permission.r) || (permission.x && !permission.r)) { state.logger->Warn("svcCreateTransferMemory: 'permission' invalid: {}{}{}", permission.r ? "R" : "-", permission.w ? "W" : "-", permission.x ? "X" : "-"); state.ctx->registers.w0 = constant::status::InvPermission; return; } state.logger->Debug("svcCreateTransferMemory: Creating transfer memory at 0x{:X} for {} bytes ({}{}{})", address, size, permission.r ? "R" : "-", permission.w ? "W" : "-", permission.x ? "X" : "-"); auto shmem = state.process->NewHandle(state.process->pid, address, size, permission); state.ctx->registers.w0 = constant::status::Success; state.ctx->registers.w1 = shmem.handle; } void CloseHandle(DeviceState &state) { auto handle = static_cast(state.ctx->registers.w0); try { state.process->handles.erase(handle); state.logger->Debug("svcCloseHandle: Closing handle: 0x{:X}", handle); state.ctx->registers.w0 = constant::status::Success; } catch (const std::exception &) { state.logger->Warn("svcCloseHandle: 'handle' invalid: 0x{:X}", handle); state.ctx->registers.w0 = constant::status::InvHandle; } } void ResetSignal(DeviceState &state) { auto handle = state.ctx->registers.w0; try { auto &object = state.process->handles.at(handle); switch (object->objectType) { case (type::KType::KEvent): std::static_pointer_cast(object)->ResetSignal(); break; case (type::KType::KProcess): std::static_pointer_cast(object)->ResetSignal(); break; default: { state.logger->Warn("svcResetSignal: 'handle' type invalid: 0x{:X} ({})", handle, object->objectType); state.ctx->registers.w0 = constant::status::InvHandle; return; } } state.logger->Debug("svcResetSignal: Resetting signal: 0x{:X}", handle); state.ctx->registers.w0 = constant::status::Success; } catch (const std::out_of_range &) { state.logger->Warn("svcResetSignal: 'handle' invalid: 0x{:X}", handle); state.ctx->registers.w0 = constant::status::InvHandle; return; } } void WaitSynchronization(DeviceState &state) { constexpr auto maxSyncHandles = 0x40; // The total amount of handles that can be passed to WaitSynchronization auto numHandles = state.ctx->registers.w2; if (numHandles > maxSyncHandles) { state.ctx->registers.w0 = constant::status::MaxHandles; return; } std::string handleStr; std::vector> objectTable; std::vector waitHandles(numHandles); state.process->ReadMemory(waitHandles.data(), state.ctx->registers.x1, numHandles * sizeof(KHandle)); for (const auto &handle : waitHandles) { handleStr += fmt::format("* 0x{:X}\n", handle); auto object = state.process->handles.at(handle); switch (object->objectType) { case type::KType::KProcess: case type::KType::KThread: case type::KType::KEvent: case type::KType::KSession: break; default: { state.ctx->registers.w0 = constant::status::InvHandle; return; } } objectTable.push_back(std::static_pointer_cast(object)); } auto timeout = state.ctx->registers.x3; state.logger->Debug("svcWaitSynchronization: Waiting on handles:\n{}Timeout: 0x{:X} ns", handleStr, timeout); auto start = util::GetTimeNs(); while (true) { if (state.thread->cancelSync) { state.thread->cancelSync = false; state.ctx->registers.w0 = constant::status::Interrupted; break; } uint index{}; for (const auto &object : objectTable) { if (object->signalled) { state.logger->Debug("svcWaitSynchronization: Signalled handle: 0x{:X}", waitHandles.at(index)); state.ctx->registers.w0 = constant::status::Success; state.ctx->registers.w1 = index; return; } index++; } if ((util::GetTimeNs() - start) >= timeout) { state.logger->Debug("svcWaitSynchronization: Wait has timed out"); state.ctx->registers.w0 = constant::status::Timeout; return; } } } void CancelSynchronization(DeviceState &state) { try { state.process->GetHandle(state.ctx->registers.w0)->cancelSync = true; } catch (const std::exception &) { state.logger->Warn("svcCancelSynchronization: 'handle' invalid: 0x{:X}", state.ctx->registers.w0); state.ctx->registers.w0 = constant::status::InvHandle; } } void ArbitrateLock(DeviceState &state) { auto address = state.ctx->registers.x1; if (!util::WordAligned(address)) { state.logger->Warn("svcArbitrateLock: 'address' not word aligned: 0x{:X}", address); state.ctx->registers.w0 = constant::status::InvAddress; return; } auto ownerHandle = state.ctx->registers.w0; auto requesterHandle = state.ctx->registers.w2; if (requesterHandle != state.thread->handle) throw exception("svcWaitProcessWideKeyAtomic: Handle doesn't match current thread: 0x{:X} for thread 0x{:X}", requesterHandle, state.thread->handle); state.logger->Debug("svcArbitrateLock: Locking mutex at 0x{:X}", address); if (state.process->MutexLock(address, ownerHandle)) state.logger->Debug("svcArbitrateLock: Locked mutex at 0x{:X}", address); else state.logger->Debug("svcArbitrateLock: Owner handle did not match current owner for mutex or didn't have waiter flag at 0x{:X}", address); state.ctx->registers.w0 = constant::status::Success; } void ArbitrateUnlock(DeviceState &state) { auto address = state.ctx->registers.x0; if (!util::WordAligned(address)) { state.logger->Warn("svcArbitrateUnlock: 'address' not word aligned: 0x{:X}", address); state.ctx->registers.w0 = constant::status::InvAddress; return; } state.logger->Debug("svcArbitrateUnlock: Unlocking mutex at 0x{:X}", address); if (state.process->MutexUnlock(address)) { state.logger->Debug("svcArbitrateUnlock: Unlocked mutex at 0x{:X}", address); state.ctx->registers.w0 = constant::status::Success; } else { state.logger->Debug("svcArbitrateUnlock: A non-owner thread tried to release a mutex at 0x{:X}", address); state.ctx->registers.w0 = constant::status::InvAddress; } } void WaitProcessWideKeyAtomic(DeviceState &state) { auto mtxAddress = state.ctx->registers.x0; if (!util::WordAligned(mtxAddress)) { state.logger->Warn("svcWaitProcessWideKeyAtomic: mutex address not word aligned: 0x{:X}", mtxAddress); state.ctx->registers.w0 = constant::status::InvAddress; return; } auto condAddress = state.ctx->registers.x1; auto handle = state.ctx->registers.w2; if (handle != state.thread->handle) throw exception("svcWaitProcessWideKeyAtomic: Handle doesn't match current thread: 0x{:X} for thread 0x{:X}", handle, state.thread->handle); if (!state.process->MutexUnlock(mtxAddress)) { state.logger->Debug("WaitProcessWideKeyAtomic: A non-owner thread tried to release a mutex at 0x{:X}", mtxAddress); state.ctx->registers.w0 = constant::status::InvAddress; return; } auto timeout = state.ctx->registers.x3; state.logger->Debug("svcWaitProcessWideKeyAtomic: Mutex: 0x{:X}, Conditional-Variable: 0x{:X}, Timeout: {} ns", mtxAddress, condAddress, timeout); if (state.process->ConditionalVariableWait(condAddress, mtxAddress, timeout)) { state.logger->Debug("svcWaitProcessWideKeyAtomic: Waited for conditional variable and relocked mutex"); state.ctx->registers.w0 = constant::status::Success; } else { state.logger->Debug("svcWaitProcessWideKeyAtomic: Wait has timed out"); state.ctx->registers.w0 = constant::status::Timeout; } } void SignalProcessWideKey(DeviceState &state) { auto address = state.ctx->registers.x0; auto count = state.ctx->registers.w1; state.logger->Debug("svcSignalProcessWideKey: Signalling Conditional-Variable at 0x{:X} for {}", address, count); state.process->ConditionalVariableSignal(address, count); state.ctx->registers.w0 = constant::status::Success; } void GetSystemTick(DeviceState &state) { u64 tick; asm("STR X1, [SP, #-16]!\n\t" "MRS %0, CNTVCT_EL0\n\t" "MOV X1, #0xF800\n\t" "MOVK X1, #0x124, lsl #16\n\t" "MUL %0, %0, X1\n\t" "MRS X1, CNTFRQ_EL0\n\t" "UDIV %0, %0, X1\n\t" "LDR X1, [SP], #16" : "=r"(tick)); state.ctx->registers.x0 = tick; } void ConnectToNamedPort(DeviceState &state) { constexpr auto portSize = 0x8; //!< The size of a port name string std::string_view port(state.process->GetPointer(state.ctx->registers.x1), portSize); KHandle handle{}; if (port.compare("sm:") >= 0) { handle = state.os->serviceManager.NewSession(service::Service::sm_IUserInterface); } else { state.logger->Warn("svcConnectToNamedPort: Connecting to invalid port: '{}'", port); state.ctx->registers.w0 = constant::status::NotFound; return; } state.logger->Debug("svcConnectToNamedPort: Connecting to port '{}' at 0x{:X}", port, handle); state.ctx->registers.w1 = handle; state.ctx->registers.w0 = constant::status::Success; } void SendSyncRequest(DeviceState &state) { state.os->serviceManager.SyncRequestHandler(static_cast(state.ctx->registers.x0)); state.ctx->registers.w0 = constant::status::Success; } void GetThreadId(DeviceState &state) { constexpr KHandle threadSelf = 0xFFFF8000; // This is the handle used by threads to refer to themselves auto handle = state.ctx->registers.w1; pid_t pid{}; if (handle != threadSelf) pid = state.process->GetHandle(handle)->tid; else pid = state.thread->tid; state.logger->Debug("svcGetThreadId: Handle: 0x{:X}, PID: {}", handle, pid); state.ctx->registers.x1 = static_cast(pid); state.ctx->registers.w0 = constant::status::Success; } void OutputDebugString(DeviceState &state) { auto debug = state.process->GetString(state.ctx->registers.x0, state.ctx->registers.x1); if (debug.back() == '\n') debug.pop_back(); state.logger->Info("Debug Output: {}", debug); state.ctx->registers.w0 = constant::status::Success; } void GetInfo(DeviceState &state) { auto id0 = state.ctx->registers.w1; auto handle = state.ctx->registers.w2; auto id1 = state.ctx->registers.x3; u64 out{}; constexpr auto totalPhysicalMemory = 0xF8000000; // ~4 GB of RAM switch (id0) { case constant::infoState::AllowedCpuIdBitmask: case constant::infoState::AllowedThreadPriorityMask: case constant::infoState::IsCurrentProcessBeingDebugged: case constant::infoState::TitleId: case constant::infoState::PrivilegedProcessId: break; case constant::infoState::AliasRegionBaseAddr: out = state.os->memory.GetRegion(memory::Regions::Alias).address; break; case constant::infoState::AliasRegionSize: out = state.os->memory.GetRegion(memory::Regions::Alias).size; break; case constant::infoState::HeapRegionBaseAddr: out = state.os->memory.GetRegion(memory::Regions::Heap).address; break; case constant::infoState::HeapRegionSize: out = state.os->memory.GetRegion(memory::Regions::Heap).size; break; case constant::infoState::TotalMemoryAvailable: out = totalPhysicalMemory; break; case constant::infoState::TotalMemoryUsage: out = state.process->heap->address + constant::DefStackSize + state.os->memory.GetProgramSize(); break; case constant::infoState::AddressSpaceBaseAddr: out = state.os->memory.GetRegion(memory::Regions::Base).address; break; case constant::infoState::AddressSpaceSize: out = state.os->memory.GetRegion(memory::Regions::Base).size; break; case constant::infoState::StackRegionBaseAddr: out = state.os->memory.GetRegion(memory::Regions::Stack).address; break; case constant::infoState::StackRegionSize: out = state.os->memory.GetRegion(memory::Regions::Stack).size; break; case constant::infoState::PersonalMmHeapSize: out = totalPhysicalMemory; break; case constant::infoState::PersonalMmHeapUsage: out = state.process->heap->address + constant::DefStackSize; break; case constant::infoState::TotalMemoryAvailableWithoutMmHeap: out = totalPhysicalMemory; // TODO: NPDM specifies SystemResourceSize, subtract that from this break; case constant::infoState::TotalMemoryUsedWithoutMmHeap: out = state.process->heap->size + constant::DefStackSize; // TODO: Same as above break; case constant::infoState::UserExceptionContextAddr: out = state.process->tlsPages[0]->Get(0); break; default: state.logger->Warn("svcGetInfo: Unimplemented case ID0: {}, ID1: {}", id0, id1); state.ctx->registers.w0 = constant::status::Unimpl; return; } state.logger->Debug("svcGetInfo: ID0: {}, ID1: {}, Out: 0x{:X}", id0, id1, out); state.ctx->registers.x1 = out; state.ctx->registers.w0 = constant::status::Success; } }