对于windwos逆向人员来说,不论是写外挂、写病毒/木马,都需要打开其他内存的空间,改写某些关键数据,达到改变其原有执行流程的目的。那么日常的工作肯定涉及到openprocess、readprocessmemory、writeprocessmemory等函数;这些函数都是怎么被调用的了?
1、windows提供了大量的系统函数供3层的应用调用。这些函数被统一编号,入口地址放在一张表里,编号就是索引,通过编号就能找到函数的入口地址;64位的表结构可以通过windbg查看,如下:
x64的SSDT表和32位比复杂了一些,为了便于读者理解,我用不同颜色(黄、绿、蓝、橙)做了标注;开发人员在3环调用openprocess、readprocessmemory、writeprocessmemory等函数,最终都会通过这个表找到对应的内核入口地址,进而跳转到内核空间执行;具体的函数实现可以通过逆向ntdll.dll、kerner32.dll、ntoskrl.exe等内核文件查看,这里不赘述(SSDT hook已经烂大街了,google一下资料大堆);各大厂商最初的驱动保护就是hook SSDT表的关键函数,一旦发现第三方程序打开自己的进程,直接返回false,达到保护自己进程数据不被篡改的目的;今天演示一下hook terminalprocess函数,让其无法关闭计算器或记事本的进程;
2、通过微软官网查询得知:windwos提供的terminalProcess函数在kerner32.dll中:
用IDA打开kernerl32.dll,切换到import,发现terminalProcess是从ntdll.dll导入的
继续追查ntdll.dll,在export找到目标函数,双击进入函数体,如下:
这个函数有两个重要信息:
(1)mov eax, 2Ch: 2c=44,是系统调用号(同一函数在windwos不同版本的调用号是不一样的,我刚开始做实验时总是蓝屏,调试了好长时间才发现是调用号搞错了),也就是terminalprocess在SSDT中的编号,根据这个编号就能找到函数的入口地址(当然不是直接现成地展示在表内,而要经过一些简单地计算)
(2)通过syscall进入内核
3、核心代码(下面的参考【3】);注意:本人的测试环境是win10.0.16299.125,调用号是0x2c;其他版本的系统可能不一样,建议读者自己用IDA查查ntdll.dll,否则直接蓝屏;
#include "hook.h" #include "asmUtil.h" PSYSTEM_SERVICE_TABLE KeServiceDescriptorTable; NTTERMINATEPROCESS NtTerminateProcess = NULL; ULONG OldTpVal; /* 用户点击关闭,系统会调用原NtTerminateProcess,并传递ProcessHandle和ExitStatus两个参数;但SSDT已经被改成了KeBugCheckEx,所以 会先执行KeBugCheckEx。进入后又执行jmp,跳转到我们自己定义的Fake_NtTerminateProcess。这时EIP变了好几次,但是堆栈一直没变,所以 Fake_NtTerminateProcess的参数就是原NtTerminateProcess的参数ProcessHandle和ExitStatus;所以后续也能重新调回NtTerminateProcess 走原来正常的流程; */ NTSTATUS __fastcall Fake_NtTerminateProcess(IN HANDLE ProcessHandle, IN NTSTATUS ExitStatus) { //Dbg_Break(); PEPROCESS Process; // 通过进程句柄来获取该进程所对应的FileObject对象,由于这里是进程对象,自然获得的是EPROCESS对象 NTSTATUS st = ObReferenceObjectByHandle(ProcessHandle, 0, *PsProcessType, KernelMode, &Process, NULL); DbgPrint(" -------Fake_NtTerminateProcess called! NT_SUCCESS(st):% d------------------------ ",NT_SUCCESS(st)); DbgPrint(" -------Fake_NtTerminateProcess called! st:% d------------------------ ", st); if (NT_SUCCESS(st)) //#define NT_SUCCESS(Status) (((NTSTATUS)(Status)) >= 0) { //if (!_stricmp(PsGetProcessImageFileName(Process), "Calculator.exe")) //if (strcmp(PsGetProcessImageFileName(Process), "Calculator.exe") == 0) DbgPrint(" -------PsGetProcessImageFileName(Process):% s------------------------ ", PsGetProcessImageFileName(Process)); if ((!_stricmp(PsGetProcessImageFileName(Process), "Calculator.exe")) || (!_stricmp(PsGetProcessImageFileName(Process), "notepad.exe"))) { //ObDeReferenceObject(&Process); return STATUS_ACCESS_DENIED; } else { //ObDeReferenceObject(&Process); /*这个已经被挂钩了,会不会形成死循环????*/ return NtTerminateProcess(ProcessHandle, ExitStatus); } } else { return STATUS_ACCESS_DENIED; } } /*关闭内核页面写保护*/ KIRQL WPOFFx64() { KIRQL irql = KeRaiseIrqlToDpcLevel(); UINT64 cr0 = __readcr0(); cr0 &= 0xfffffffffffeffff; __writecr0(cr0); _disable(); return irql; } /*打开内核页面写保护*/ void WPONx64(KIRQL irql) { UINT64 cr0 = __readcr0(); cr0 |= 0x10000; _enable(); __writecr0(cr0); KeLowerIrql(irql); } // win10的变了,用下面的替代 ULONGLONG GetKeServiceDescriptorTable64_win10() { PUCHAR StartSearchAddress = (PUCHAR)__readmsr(0xC0000082); PUCHAR EndSearchAddress = StartSearchAddress + 0x500; PUCHAR i = NULL; UCHAR b1 = 0, b2 = 0, b3 = 0; ULONG templong = 0; ULONGLONG addr = 0; for (i = StartSearchAddress; i < EndSearchAddress; i++) { if (MmIsAddressValid(i) && MmIsAddressValid(i + 1) && MmIsAddressValid(i + 2)) { b1 = *i; b2 = *(i + 1); b3 = *(i + 2); if (b1 == 0x4c && b2 == 0x8d && b3 == 0x15) //4c8d15 { memcpy(&templong, i + 3, 4); addr = (ULONGLONG)templong + (ULONGLONG)i + 7; return addr; } } } return 0; } /* 根据调用号找到目标内核函数地址 kd> x nt!KeServiceDescriptorTable fffff803`4e9a1880 nt!KeServiceDescriptorTable = <no type information> kd> dq fffff803`4e9a1880 fffff803`4e9a1880 fffff803`4e839c10 00000000`00000000 fffff803`4e9a1890 00000000`000001d0 fffff803`4e83a354 注意事项: 1、这4个都是指针,都是8字节的; ServiceTableBase:fffff803`4e839c10 ServiceCounterTableBase:00000000`00000000 NumberOfServices:00000000`000001d0 ParamTableBase:fffff803`4e83a354 2、ServiceTableBase存储的是4字节的偏移: (2.2) 第0x2c=44号函数NtTerminateProcess偏移: kd> dd fffff803`4e839c10+0x29*4 fffff803`4e839cb4 fd9c8d00 01a27c00 01a99001 02150f00;注意低位在后面 0x29函数偏移:fffff803`4e839c10 + 02150f00>>4 =fffff803`4e839c10 + 2150F0 = FFFF F803 4EA4 ED00,和下面NtTerminateProcess的起始地址是吻合的: kd> u nt!NtTerminateProcess nt!NtTerminateProcess: fffff803`4ea4ed00 4c8bdc mov r11,rsp fffff803`4ea4ed03 49895b10 mov qword ptr [r11+10h],rbx fffff803`4ea4ed07 49897320 mov qword ptr [r11+20h],rsi */ ULONGLONG GetSSDTFuncCurAddr(ULONG id) { LONG dwtmp = 0; PULONG ServiceTableBase = NULL; ServiceTableBase = (PULONG)KeServiceDescriptorTable->ServiceTableBase; dwtmp = ServiceTableBase[id]; dwtmp = dwtmp >> 4; return (LONGLONG)dwtmp + (ULONGLONG)ServiceTableBase; } /* (2.3)反过来求偏移 (2.3.1)kd> u nt!NtTerminateProcess nt!NtTerminateProcess: fffff803`4ea4ed00 4c8bdc mov r11,rsp (2.3.2)差距: nt!NtTerminateProcess:fffff803`4ea4ed00 - ServiceTableBase:fffff803`4e839c10 = 21 50F0 (2.3.3)偏移: 21 50F0 << 4 = 215 0F00 */ ULONG GetOffsetAddress(ULONGLONG FuncAddr) { ULONG dwtmp = 0; PULONG ServiceTableBase = NULL; ServiceTableBase = (PULONG)KeServiceDescriptorTable->ServiceTableBase; dwtmp = (ULONG)(FuncAddr - (ULONGLONG)ServiceTableBase); return dwtmp << 4; } /* SSDT在ntoskrnl中;内核函数和用户自己的驱动不在一个4GB空间,32位的偏移是直接跳不过去的; 修改这个偏移地址的值,使之跳转到 KeBugCheckEx ,然后在 x KeBugCheckEx 的头部写一个 2 12 字节的 mov - - jmp ,这是一个可以跨越 4GB ! 的跳转,跳到我们的函数里! */ VOID FuckKeBugCheckEx() { KIRQL irql; ULONGLONG myfun; UCHAR jmp_code[] = "x48xB8xFFxFFxFFxFFxFFxFFxFFx00xFFxE0"; /*通过jmp跳转,而不是call,可以让Fake_NtTerminateProcess直接利用原NtTerminateProcess 留下的参数*/ myfun = (ULONGLONG)Fake_NtTerminateProcess; memcpy(jmp_code + 2, &myfun, 8); irql = WPOFFx64(); memset(KeBugCheckEx, 0x90, 15); memcpy(KeBugCheckEx, jmp_code, 12); WPONx64(irql); } /* 填写KeBugCheckEx的地址 在KeBugCheckEx填写jmp,跳到Fake_NtTerminateProcess 不能直接填写Fake_NtTerminateProcess的地址,因为它们不再同一个4GB */ VOID HookSSDT(PSYSTEM_SERVICE_TABLE received) { KIRQL irql; ULONGLONG dwtmp = 0; PULONG ServiceTableBase = NULL; KeServiceDescriptorTable = received; //get old address //Dbg_Break(); NtTerminateProcess = (NTTERMINATEPROCESS)GetSSDTFuncCurAddr(44); DbgPrint(" ------------------------Old_NtTerminateProcess: %llx----------------------- ", (ULONGLONG)NtTerminateProcess); //set kebugcheckex //Dbg_Break(); FuckKeBugCheckEx(); //show new address ServiceTableBase = (PULONG)KeServiceDescriptorTable->ServiceTableBase; //OldTpVal = ServiceTableBase[41]; //win7编号是0x29 = 41 OldTpVal = ServiceTableBase[44]; //win10逆向ntdll的时候发现编号是0x2c = 44 irql = WPOFFx64(); /* 我们挂钩的函数是KeBugCheckEx,所以把该函数的偏移算出来(只有32位,在4GB内) 把SSDT原本terminalProcess的地方替换掉(都在SSDT,在同一个4GB范围内) 这样一旦调用terminalProcess,实际会调用KeBugCheckEx,然后再到我们自己的代码; */ ServiceTableBase[44] = GetOffsetAddress((ULONGLONG)KeBugCheckEx); WPONx64(irql); DbgPrint(" ------------------------KeBugCheckEx: %llx----------------------- ", (ULONGLONG)KeBugCheckEx); DbgPrint(" ------------------------New_NtTerminateProcess: %llx----------------------- ", GetSSDTFuncCurAddr(44)); } VOID UnhookSSDT() { KIRQL irql; PULONG ServiceTableBase = NULL; ServiceTableBase = (PULONG)KeServiceDescriptorTable->ServiceTableBase; //set value irql = WPOFFx64(); ServiceTableBase[44] = GetOffsetAddress((ULONGLONG)NtTerminateProcess); //OldTpVal;//直接填写这个旧值也行 WPONx64(irql); //没必要恢复KeBugCheckEx的内容了,反正执行到KeBugCheckEx时已经完蛋了。 DbgPrint(" ------------------------NtTerminateProcess: %llx----------------------- ", GetSSDTFuncCurAddr(44)); } ULONGLONG SearchforKeServiceDescriptorTable64(ULONGLONG StartSearchAddress, ULONGLONG EndSearchAddress) { UCHAR b1 = 0, b2 = 0, b3 = 0; ULONG templong = 0; ULONGLONG KeServiceDescriptorTable = 0; //地址效验 if (MmIsAddressValid(StartSearchAddress) == FALSE)return NULL; if (MmIsAddressValid(EndSearchAddress) == FALSE)return NULL; for (PUCHAR i = StartSearchAddress; i < EndSearchAddress; i++) { if (MmIsAddressValid(i) && MmIsAddressValid(i + 1) && MmIsAddressValid(i + 2)) { b1 = *i; b2 = *(i + 1); b3 = *(i + 2); //if (b1 == 0x4c && b2 == 0x8d && b3 == 0x15);//4c8d15 //if (b1 == "4c" && b2 == "8d" && b3 == "15" );//4c8d15 //if (*i == 0x4c && *(i + 1) == 0x8d && *(i + 2) == 0x15);// 不能有;号,否则下面的代码一定会执行 if (b1 == 0x4c && b2 == 0x8d && b3 == 0x15) { DbgPrint(" --------- StartSearchAddress: %llx----------------- ------------- ", StartSearchAddress); DbgPrint(" --------- matched targetAddress: %llx----------------- ------------- ", i); DbgPrint(" --------- targetAddress offset: %d----------------- ------------- ", (i - StartSearchAddress)); //Dbg_Break(); memcpy(&templong, i + 3, 4); KeServiceDescriptorTable = (ULONGLONG)templong + (ULONGLONG)i + 7;//i是当前地址,templong是相对SSDT的偏移 DbgPrint(" --------- KeServiceDescriptorTable: %llx----------------- ------------- ", KeServiceDescriptorTable); return KeServiceDescriptorTable; //当前地址 + 长度 + 数值 //fffff800`03c8c772+7 + 002320c7 = FFFFF80003EBE840 /* fffff800`03c8c772 4c8d15c7202300 lea r10,[nt!KeServiceDescriptorTable (fffff800`03ebe840)] fffff800`03c8c779 4c8d1d00212300 lea r11,[nt!KeServiceDescriptorTableShadow (fffff800`03ebe880)] */ } } } return NULL; } //获取SSDT KeServiceDescriptorTable ULONGLONG GetKeServiceDescriptorTable64() { PUCHAR pKiSystemCall64 = (PUCHAR)__readmsr(0xc0000082);//rdmsr c0000082 //定位KiSystemCall64 PUCHAR EndSearchAddress = pKiSystemCall64 + 0x500;//在1280个字节的范围内搜索 ULONGLONG KeServiceDescriptorTable = 0; KeServiceDescriptorTable = SearchforKeServiceDescriptorTable64(pKiSystemCall64, EndSearchAddress); if (KeServiceDescriptorTable) { return KeServiceDescriptorTable; } //msr[0xc0000082]变成了KiSystemCall64Shadow函数 //原来我们64位搜索KeServiceDescriptorTable是通过msr的0xc0000082获得KiSystemCall64字段, //但是现在msr[0xc0000082]变成了KiSystemCall64Shadow函数, 而且这个函数无法直接搜索到KeServiceDescriptorTable。 ULONGLONG KiSystemServiceUser = 0; ULONGLONG templong = 0xffffffffffffffff; for (PUCHAR i = pKiSystemCall64; i < EndSearchAddress + 0xff; i++)//在pKiSystemCall64的0x5ff=1535字节范围内查找 { if (*(PUCHAR)i == 0xe9 && *(PUCHAR)(i + 5) == 0xc3)//找到KiSystemServiceUser //if (*(PUCHAR)i == "e9" && *(PUCHAR)(i + 5) == "c3")//找到KiSystemServiceUser { //fffff803`23733383 e9631ae9ff jmp nt!KiSystemServiceUser(fffff803`235c4deb) //fffff803`23733388 c3 ret RtlCopyMemory(&templong, (PUCHAR)(i + 1), 4); KiSystemServiceUser = templong + 5 + i;//KiSystemServiceUser EndSearchAddress = KiSystemServiceUser + 0x500; KeServiceDescriptorTable = SearchforKeServiceDescriptorTable64(KiSystemServiceUser, EndSearchAddress); return KeServiceDescriptorTable; } } return 0; }
4、效果:想要关闭计算器,直接弹框拒绝访问;
windbg也看到了打印的日志,说明自己写的Fake_NtTerminateProcess函数已经被调用;
其他的窗口能够随意结束;
这次没刻意做驱动隐藏,还是被PCHUNTER发现了:
SSDT hook是好多年以前的老办法了;因为驱动在0环,和windows 内核平起平坐,权力相当大。为了保护自己的客户端,各个厂家都在争先恐后地hook,把内核搞得一团糟,严重影响了用户体验;微软终于坐不住了,近些年在64位的windows做了以下改动:
- 增加PG保护,一旦发现自己的内核代码被改,大概率会直接蓝屏
- 增加驱动签名。运行的驱动必须强制签名。一旦发现某些驱动改内核,直接吊销签名的资格
那么问题又来了,既然不让hook SSDT,各大厂家怎么知道自己的客户端有没有被逆向人员搞了?微软又提供了新的解决方案:注册回调函数;一旦第三方调用openprocess、readprocessmemory、writeprocessmemory等函数搞事,自己的客户端就能收到通知,然后采取响应的措施;回调函数的具体用法见下方【1】;
参考:
1、https://www.write-bug.com/article/2170.html 基于ObRegisterCallbacks实现的线程和进程监控及其保护
2、https://www.cnblogs.com/freesec/p/7623675.html windows 64位 系统非HOOK方式监控进程创建
3、http://www.m5home.com/bbs/thread-8378-1-1.html x64 SSDT正确的偏移计算,一键恢复SSDT表中的所有HOOK