Difference between revisions of "系统调用列表"

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Revision as of 13:08, 29 March 2013

@SVC ==

系统调用

Id Description
0x1 Result ControlMemory(u32* outaddr, u32 addr0, u32 addr1, u32 size, u32 operation, u32 permissions) (outaddr is usually the same as the input addr0)
0x2 Result QueryMemory(MemoryInfo* info, PageInfo* out, u32 Addr)
0x3 void ExitProcess(void)
0x4 Result GetProcessAffinityMask(u8* affinitymask, Handle process, s32 processorcount)
0x5 Result SetProcessAffinityMask(Handle process, u8* affinitymask, s32 processorcount)
0x6 Result GetProcessIdealProcessor(s32 *idealprocessor, Handle process)
0x7 Result SetProcessIdealProcessor(Handle process, s32 idealprocessor)
0x8 Result CreateThread(Handle* thread, func entrypoint, u32 arg, u32 stacktop, s32 threadpriority, s32 processorid)
0x9 void ExitThread(void)
0xA void SleepThread(s64 nanoseconds)
0xB Result GetThreadPriority(s32* priority, Handle thread)
0xC Result SetThreadPriority(Handle thread, s32 priority)
0xD Result GetThreadAffinityMask(u8* affinitymask, Handle thread, s32 processorcount)
0xE Result SetThreadAffinityMask(Handle thread, u8* affinitymask, s32 processorcount)
0xF Result GetThreadIdealProcessor(s32* processorid, Handle thread)
0x10 Result SetThreadIdealProcessor(Handle thread, s32 processorid)
0x11 s32 GetCurrentProcessorNumber(void)
0x12 Result Run(Handle process, StartupInfo* info) (This starts the main() thread. Buf+0 is main-thread priority, Buf+4 is main-thread stack-size.)
0x13 Result CreateMutex(Handle* mutex, bool initialLocked)
0x14 Result ReleaseMutex(Handle mutex)
0x15 Result CreateSemaphore(Handle* semaphore, s32 initialCount, s32 maxCount)
0x16 Result ReleaseSemaphore(s32* count, Handle semaphore, s32 releaseCount)
0x17 Result CreateEvent(Handle* event, ResetType resettype)
0x18 Result SignalEvent(Handle event)
0x19 Result ClearEvent(Handle event)
0x1A Result CreateTimer(Handle* timer, ResetType resettype)
0x1B Result SetTimer(Handle timer, s64 initial, s64 interval)
0x1C Result CancelTimer(Handle timer)
0x1D Result ClearTimer(Handle timer)
0x1E Result CreateMemoryBlock(Handle* memblock, u32 memory, u32 size, u32 mypermission, u32 otherpermission)
0x1F Result MapMemoryBlock(Handle memblock, u32 addr, u32 mypermissions, u32 otherpermission)
0x20 Result UnmapMemoryBlock(Handle memblock, u32 addr)
0x21 Result CreateAddressArbiter(Handle* arbiter)
0x22 Result ArbitrateAddress(Handle arbiter, u32 addr, ArbitrationType type, s32 value)
0x23 Result CloseHandle(Handle handle)
0x24 Result WaitSynchronization1(Handle handle, s64 nanoseconds)
0x25 Result WaitSynchronizationN(s32* out, Handle* handles, s32 handlecount, bool waitAll, s64 nanoseconds)
0x26 Result SignalAndWait(s32* out, Handle signal, Handle* handles, s32 handleCount, bool waitAll, s64 nanoseconds)
0x27 Result DuplicateHandle(Handle* out, Handle original)
0x28 s64 GetSystemTick(void)
0x29 Result GetHandleInfo(s64* out, Handle handle, HandleInfoType type)
0x2A Result GetSystemInfo(s64* out, SystemInfoType type, s32 param)
0x2B Result GetProcessInfo(s64* out, Handle process, ProcessInfoType type)
0x2C Result GetThreadInfo(s64* out, Handle thread, ThreadInfoType type)
0x2D Result ConnectToPort(Handle* out, const char* portName)
0x2E Result SendSyncRequest1(Handle session) (Stubbed)
0x2F Result SendSyncRequest2(Handle session) (Stubbed)
0x30 Result SendSyncRequest3(Handle session) (Stubbed)
0x31 Result SendSyncRequest4(Handle session) (Stubbed)
0x32 Result SendSyncRequest(Handle session)
0x33 Result OpenProcess(Handle* process, u32 processId)
0x34 Result OpenThread(Handle* thread, Handle process, u32 threadId)
0x35 Result GetProcessId(u32* processId, Handle process)
0x36 Result GetProcessIdOfThread(u32* processId, Handle thread)
0x37 Result GetThreadId(u32* threadId, Handle thread)
0x38 Result GetResourceLimit(Handle* resourceLimit, Handle process)
0x39 Result GetResourceLimitLimitValues(s64* values, Handle resourceLimit, LimitableResource* names, s32 nameCount)
0x3A Result GetResourceLimitCurrentValues(s64* values, Handle resourceLimit, LimitableResource* names, s32 nameCount)
0x3B Result GetThreadContext(ThreadContext* context, Handle thread) (Stubbed)
0x3C Break(BreakReason)
0x3D OutputDebugString(void const, int) (Does nothing on non-debug units)
0x3E ControlPerformanceCounter(unsigned long long, int, unsigned int, unsigned long long)
0x47 Result CreatePort(Handle* portServer, Handle* portClient, const char* name, s32 maxSessions)
0x48 Result CreateSessionToPort(Handle* session, Handle port)
0x49 Result CreateSession(Handle* sessionServer, Handle* sessionClient)
0x4A Result AcceptSession(Handle* session, Handle port)
0x4B Result ReplyAndReceive1(s32* index, Handle* handles, s32 handleCount, Handle replyTarget) (Stubbed)
0x4C Result ReplyAndReceive2(s32* index, Handle* handles, s32 handleCount, Handle replyTarget) (Stubbed)
0x4D Result ReplyAndReceive3(s32* index, Handle* handles, s32 handleCount, Handle replyTarget) (Stubbed)
0x4E Result ReplyAndReceive4(s32* index, Handle* handles, s32 handleCount, Handle replyTarget) (Stubbed)
0x4F Result ReplyAndReceive(s32* index, Handle* handles, s32 handleCount, Handle replyTarget)
0x50 Result BindInterrupt(Interrupt name, Handle syncObject, s32 priority, bool isManualClear)
0x51 Result UnbindInterrupt(Interrupt name, Handle syncObject)
0x52 Result InvalidateProcessDataCache(Handle process, void* addr, u32 size)
0x53 Result StoreProcessDataCache(Handle process, void const* addr, u32 size)
0x54 Result FlushProcessDataCache(Handle process, void const* addr, u32 size)
0x55 Result StartInterProcessDma(Handle* dma, Handle dstProcess, void* dst, Handle srcProcess, const void* src, u32 size, const DmaConfig& config )
0x56 Result StopDma(Handle dma)
0x57 Result GetDmaState(DmaState* state, Handle dma)
0x58 RestartDma(nn::Handle, void *, void const*, unsigned int, signed char)
0x60 Result DebugActiveProcess(Handle* debug, u32 processID)
0x61 Result BreakDebugProcess(Handle debug)
0x62 Result TerminateDebugProcess(Handle debug)
0x63 Result GetProcessDebugEvent(DebugEventInfo* info, Handle debug)
0x64 Result ContinueDebugEvent(Handle debug, u32 flags)
0x65 Result GetProcessList(s32* processCount, u32* processIds, s32 processIdMaxCount)
0x66 Result GetThreadList(s32* threadCount, u32* threadIds, s32 threadIdMaxCount, Handle domain)
0x67 Result GetDebugThreadContext(ThreadContext* context, Handle debug, u32 threadId, u32 controlFlags)
0x68 Result SetDebugThreadContext(Handle debug, u32 threadId, ThreadContext* context, u32 controlFlags)
0x69 Result QueryDebugProcessMemory(MemoryInfo* blockInfo, PageInfo* pageInfo, Handle process, u32 addr)
0x6A Result ReadProcessMemory(void* buffer, Handle debug, u32 addr, u32 size)
0x6B Result WriteProcessMemory(Handle debug, void const* buffer, u32 addr, u32 size)
0x6C Result SetHardwareBreakPoint(s32 registerId, u32 control, u32 value)
0x6D GetDebugThreadParam(long long *, int *, nn::Handle, unsigned int, nn::dmnt::DebugThreadParam) (Disabled on regular kernel)
0x70 ControlProcessMemory(Handle KProcess, unsigned int Addr0, unsigned int Addr1, unsigned int Size, unsigned int Type, unsigned int Permissions)
0x71 MapProcessMemory(Handle KProcess, unsigned int StartAddr, unsigned int EndAddr)
0x72 UnmapProcessMemory(Handle KProcess, unsigned int StartAddr, unsigned int EndAddr)
0x73 ?
0x74 Stubbed on regular kernel
0x75 ?
0x76 TerminateProcess(Handle)
0x77 (Handle KProcess, Handle KResourceLimit)
0x78 CreateResourceLimit(Handle *KResourceLimit)
0x79 ?
0x7A DisableExecuteNever(unsigned int Addr, unsigned int Size) (Stubbed for regular kernel beginning with 2.0.0-2)
0x7C KernelSetState(unsigned int Type, unsigned int Param0, unsigned int Param1, unsigned int Param2) (The Type determines the usage of each param)
0x7D QueryProcessMemory(MemInfo *Info, unsigned int *Out, Handle KProcess, unsigned int Addr)
0xFF Debug related (The Syscall access control mask doesn't apply for this SVC)

新建线程

R0=s32 threadpriority
R1=func entrypoint
R2=u32 arg
R3=u32 stacktop
R4=s32 processorid
Result result=R0
Handle* thread=R1

类型和结构

枚举MemoryState

Memory state flags Bit
FREE 0
RESERVED 1
IO 2
STATIC 3
CODE 4
PRIVATE 5
SHARED 6
CONTINUOUS 7
ALIASED 8
ALIAS 9
ALIAS CODE 10
LOCKED 11

枚举PageFlags

Page flags Bit
LOCKED 0
CHANGED 1

枚举MemoryOperation

Memory operation Id
FREE 1
RESERVE 2
COMMIT 3
MAP 4
UNMAP 5
PROTECT 6
REGION APP 0x100
REGION SYSTEM 0x200
REGION BASE 0x300
LINEAR 0x1000

枚举MemoryPermission

Memory permission Id
NONE 0
READ 1
WRITE 2
READWRITE 3
DONTCARE 0x10000000


枚举ResetType

Reset type Id
ONESHOT 0
STICKY 1
PULSE 2

结构MemoryInfo

Type Field
u32 Base address
u32 Size
u32 Permission
enum MemoryState State

结构PageInfo

Type Field
u32 Flags

结构StartupInfo

Type Field
s32 Priority
u32 Stack size
s32 argc
s16* argv
s16* envp


进程

任何进程只能使用在exheader中为本进程启用的SVCs。ARM11内核SVN句柄会在SVC模式的栈中检查系统访问控制掩码以确定SVC是否已经启用,SVC没有启用时会触发kernelpanic。每个进程都有独立的SVC模式栈,这个栈和存放其中的系统访问控制掩码是在进程启动时候初始化的。应用程序一般只有那些<=0x3D的SVC访问权限,不过并非所有应用程序都有<=0x3D的所有SVCs权限。大部分应用程序可访问的SVCs并没有被应用程序使用。

每个进程都有各自的句柄表,表达大小存在exheader里面。在句柄表中的句柄不能被其他进程的上下文使用,因为这些句柄并不存在于其他的句柄表中。

0xFFFF8001是当前KProcess的句柄别称,而0xFFFF8000则是当前KThread的句柄别称。

在零售版机器上调用svcBreak只能造成调用这个SVC的进程被终止。

线程

对于svcCreateThread,用于Entrypoint_Param和StackTop输入地址常常一样,不过这可以任意设置。比如主线程的Entrypoint_Param就是0值。

用KThread句柄调用CloseHandle()会终结指定的线程。

内存映射

ControlMemory和MapMemoryBlock可以在映射内存页面时使用,这两个SVCs只支持映射不可执行的R/W页面。为这两个SVCs输入的权限和参数必须<=3,如果要取消映射,需要使用0值。对于ControlMemory参数MemoryType的位码0xF00是内存类型,该位使用0的时候,会从exheader中ARM11内核描述的内核标记中,为使用此SVC的进程读取内存类型。ControlMemory参数MemoryType取值0x10003对应的是映射GSP。低八位是类型:1是未映射内存,3是已经映射的内存;类型4用于备份,从Addr1到Addr0的RW内存,如果Addr1在只读区域,类型4会返回一个错误。Addr1在类型1和3中不使用。

ControlProcessMemory映射指定进程的内存,只是唯一允许映射可执行区域内存的SVC。内存映射SVC的权限格式为bit0=R, bit1=W, bit2=X。类型6设置Addr0已经映射的内存权限到输入权限。

MapProcessMemory映射指定KProcess由当前进程指定的StartAddr从0x00100000开始的RW内存。MapProcessMemory之后会映射指定进程的0x08000000到当前进程StartAddr+0x7f00000的内存。UnmapProcessMemory则取消MapProcessMemory映射的内存。

调试

DebugActiveProcess用于调试时附加进程。这个SVC只有在目标进程的exheader的ARM11描述中设置了"Enable debug"才能调用。如果目标进程的那个标记是零,那么调用这个SVC的进程必须有设置内核标记的"Force debug"标记为一才行。

KernelSetState

类型0为启动固件初始化programID,然后触发启动固件。参数0和参数2没有使用。参数1是programID低位,而programID的高位时0x00040138。

类型3用于给启动的固件初始化0x1000字节的缓存。参数2没用。当参数0为1时候,缓存会复制到FCRAM的0xF0000000开始的地址,参数1没用。当参数0为0,这段内核缓存会映射到进程地址参数1。

GetSystemInfo

类型0值为26(类型1没用)会将直接由内核启动的进程总数写到输出。对于NATIVE_FIRM/SAFE_MODE_FIRM固件的ARM11内核,结果常为5,也即是进程sm,fs,pm,loader,和pxi。