C语言驱动开发之内核通过PEB获取进程参数

PEB结构(ProcessEnvirormentBlockStructure)其中文名是进程环境块信息，进程环境块内部包含了进程运行的详细参数信息，每一个进程在运行后都会存在一个特有的PEB结构...

PEB结构(Process Envirorment block Structure)其中文名是进程环境块信息，进程环境块内部包含了进程运行的详细参数信息，每一个进程在运行后都会存在一个特有的PEB结构，通过附加进程并遍历这段结构即可得到非常多的有用信息。

在应用层下，如果想要得到PEB的基地址只需要取fs:[0x30]即可，TEB线程环境块则是fs:[0x18]，如果在内核层想要得到应用层进程的PEB信息我们需要调用特定的内核函数来获取，如下案例将教大家如何在内核层取到应用层进程的PEB结构。

首先在开始写代码之前需要先定义好PEB进程环境快结构体，用于对内存指针解析，新建peb.h文件并保存如下代码，这些是微软的结构定义分为32位与64位，官方定义规范而已不需要费工夫。

#pragma once
#include <ntifs.h>

typedef struct _CURDIR              // 2 elements, 0x18 bytes (sizeof) 
{
/*0x000*/     struct _UNICODE_STRING DOSPath; // 3 elements, 0x10 bytes (sizeof) 
/*0x010*/     VOID*        Handle;
}CURDIR, *PCURDIR;

typedef struct _RTL_DRIVE_LETTER_CURDIR // 4 elements, 0x18 bytes (sizeof) 
{
/*0x000*/     UINT16       Flags;
/*0x002*/     UINT16       Length;
/*0x004*/     ULONG32      TimeStamp;
/*0x008*/     struct _STRING DosPath;             // 3 elements, 0x10 bytes (sizeof) 
}RTL_DRIVE_LETTER_CURDIR, *PRTL_DRIVE_LETTER_CURDIR;

typedef enum _SYSTEM_DLL_TYPE  // 7 elements, 0x4 bytes
{
PsNativeSystemDll = 0 /*0x0*/,
PsWowX86SystemDll = 1 /*0x1*/,
PsWowArm32SystemDll = 2 /*0x2*/,
PsWowAmd64SystemDll = 3 /*0x3*/,
PsWowChpeX86SystemDll = 4 /*0x4*/,
PsVsmEnclaveRuntimeDll = 5 /*0x5*/,
PsSystemDllTotalTypes = 6 /*0x6*/
}SYSTEM_DLL_TYPE, *PSYSTEM_DLL_TYPE;

typedef struct _EWOW64PROCESS        // 3 elements, 0x10 bytes (sizeof) 
{
/*0x000*/     VOID*        Peb;
/*0x008*/     UINT16       MAChine;
/*0x00A*/     UINT8        _PADDING0_[0x2];
/*0x00C*/     enum _SYSTEM_DLL_TYPE NtdllType;
}EWOW64PROCESS, *PEWOW64PROCESS;

typedef struct _RTL_USER_PROCESS_PARAMETERS                // 37 elements, 0x440 bytes (sizeof) 
{
/*0x000*/     ULONG32      MaximumLength;
/*0x004*/     ULONG32      Length;
/*0x008*/     ULONG32      Flags;
/*0x00C*/     ULONG32      DebugFlags;
/*0x010*/     VOID*        ConsoleHandle;
/*0x018*/     ULONG32      ConsoleFlags;
/*0x01C*/     UINT8        _PADDING0_[0x4];
/*0x020*/     VOID*        StandardInput;
/*0x028*/     VOID*        StandardOutput;
/*0x030*/     VOID*        StandardError;
/*0x038*/     struct _CURDIR CurrentDirectory;                       // 2 elements, 0x18 bytes (sizeof)   
/*0x050*/     struct _UNICODE_STRING DllPath;                        // 3 elements, 0x10 bytes (sizeof)   
/*0x060*/     struct _UNICODE_STRING ImagePathName;                  // 3 elements, 0x10 bytes (sizeof)   
/*0x070*/     struct _UNICODE_STRING CommandLine;                    // 3 elements, 0x10 bytes (sizeof)   
/*0x080*/     VOID*        Environment;
/*0x088*/     ULONG32      StartingX;
/*0x08C*/     ULONG32      StartingY;
/*0x090*/     ULONG32      CountX;
/*0x094*/     ULONG32      CountY;
/*0x098*/     ULONG32      CountCharsX;
/*0x09C*/     ULONG32      CountCharsY;
/*0x0A0*/     ULONG32      FillAttribute;
/*0x0A4*/     ULONG32      WindowFlags;
/*0x0A8*/     ULONG32      ShowWindowFlags;
/*0x0AC*/     UINT8        _PADDING1_[0x4];
/*0x0B0*/     struct _UNICODE_STRING WindowTitle;                    // 3 elements, 0x10 bytes (sizeof)   
/*0x0C0*/     struct _UNICODE_STRING DesktopInfo;                    // 3 elements, 0x10 bytes (sizeof)   
/*0x0D0*/     struct _UNICODE_STRING ShellInfo;                      // 3 elements, 0x10 bytes (sizeof)   
/*0x0E0*/     struct _UNICODE_STRING RuntimeData;                    // 3 elements, 0x10 bytes (sizeof)   
/*0x0F0*/     struct _RTL_DRIVE_LETTER_CURDIR CurrentDirectores[32];
/*0x3F0*/     UINT64       EnvironmentSize;
/*0x3F8*/     UINT64       EnvironmentVersion;
/*0x400*/     VOID*        PackageDependencyData;
/*0x408*/     ULONG32      ProcessGroupId;
/*0x40C*/     ULONG32      LoaderThreads;
/*0x410*/     struct _UNICODE_STRING RedirectionDllName;             // 3 elements, 0x10 bytes (sizeof)   
/*0x420*/     struct _UNICODE_STRING HeapPartitionName;              // 3 elements, 0x10 bytes (sizeof)   
/*0x430*/     UINT64*      DefaultThreadpoolCpuSetMasks;
/*0x438*/     ULONG32      DefaultThreadpoolCpuSetMaskCount;
/*0x43C*/     UINT8        _PADDING2_[0x4];
}RTL_USER_PROCESS_PARAMETERS, *PRTL_USER_PROCESS_PARAMETERS;

typedef struct _PEB_LDR_DATA                            // 9 elements, 0x58 bytes (sizeof) 
{
/*0x000*/     ULONG32      Length;
/*0x004*/     UINT8        Initialized;
/*0x005*/     UINT8        _PADDING0_[0x3];
/*0x008*/     VOID*        SsHandle;
/*0x010*/     struct _LIST_ENTRY InLoadOrderModuleList;           // 2 elements, 0x10 bytes (sizeof) 
/*0x020*/     struct _LIST_ENTRY InMemoryOrderModuleList;         // 2 elements, 0x10 bytes (sizeof) 
/*0x030*/     struct _LIST_ENTRY InInitializationOrderModuleList; // 2 elements, 0x10 bytes (sizeof) 
/*0x040*/     VOID*        EntryInProgress;
/*0x048*/     UINT8        ShutdownInProgress;
/*0x049*/     UINT8        _PADDING1_[0x7];
/*0x050*/     VOID*        ShutdownThreadId;
}PEB_LDR_DATA, *PPEB_LDR_DATA;

typedef struct _PEB64
{
UCHAR InheritedAddressSpace;
UCHAR ReadImageFileExecOptions;
UCHAR BeingDebugged;
UCHAR BitField;
ULONG64 Mutant;
ULONG64 ImageBaseAddress;
PPEB_LDR_DATA Ldr;
PRTL_USER_PROCESS_PARAMETERS ProcessParameters;
ULONG64 SubSystemData;
ULONG64 ProcessHeap;
ULONG64 FastPebLock;
ULONG64 AtlThunkSListPtr;
ULONG64 IFEOKey;
ULONG64 CrossProcessFlags;
ULONG64 UserSharedInfoPtr;
ULONG SystemReserved;
ULONG AtlThunkSListPtr32;
ULONG64 ApiSetMap;
} PEB64, *PPEB64;

#pragma pack(4)
typedef struct _PEB32
{
UCHAR InheritedAddressSpace;
UCHAR ReadImageFileExecOptions;
UCHAR BeingDebugged;
UCHAR BitField;
ULONG Mutant;
ULONG ImageBaseAddress;
ULONG Ldr;
ULONG ProcessParameters;
ULONG SubSystemData;
ULONG ProcessHeap;
ULONG FastPebLock;
ULONG AtlThunkSListPtr;
ULONG IFEOKey;
ULONG CrossProcessFlags;
ULONG UserSharedInfoPtr;
ULONG SystemReserved;
ULONG AtlThunkSListPtr32;
ULONG ApiSetMap;
} PEB32, *PPEB32;

typedef struct _PEB_LDR_DATA32
{
ULONG Length;
BOOLEAN Initialized;
ULONG SsHandle;
LIST_ENTRY32 InLoadOrderModuleList;
LIST_ENTRY32 InMemoryOrderModuleList;
LIST_ENTRY32 InInitializationOrderModuleList;
ULONG EntryInProgress;
} PEB_LDR_DATA32, *PPEB_LDR_DATA32;

typedef struct _LDR_DATA_TABLE_ENTRY32
{
LIST_ENTRY32 InLoadOrderLinks;
LIST_ENTRY32 InMemoryOrderModuleList;
LIST_ENTRY32 InInitializationOrderModuleList;
ULONG DllBase;
ULONG EntryPoint;
ULONG SizeOfImage;
UNICODE_STRING32 FullDllName;
UNICODE_STRING32 BaseDllName;
ULONG Flags;
USHORT LoadCount;
USHORT TlsIndex;
union
{
LIST_ENTRY32 HashLinks;
ULONG SectionPointer;
}u1;
ULONG CheckSum;
union
{
ULONG TimeDateStamp;
ULONG LoadedImports;
}u2;
ULONG EntryPointActivationContext;
ULONG PatchInformation;
} LDR_DATA_TABLE_ENTRY32, *PLDR_DATA_TABLE_ENTRY32;

#pragma pack()

接着就来实现对PEB的获取操作，以64位为例，我们需要调用PsGetProcessPeb()这个内核函数，因为该内核函数没有被公开所以调用之前需要头部导出，该函数需要传入用户进程的EProcess结构，该结构可用PsLookupProcessByProcessId函数动态获取到，获取到以后直接KeStackAttachProcess()附加到应用层进程上，即可直接输出进程的PEB结构信息，如下代码。

#include "peb.h"
#include <ntifs.h>

// 定义导出
NTKERNELAPI PVOID NTAPI PsGetProcessPeb(_In_ PEPROCESS Process);

VOID UnDriver(PDRIVER_OBJECT driver)
{
DbgPrint(("Uninstall Driver Is OK \n"));
}
// LyShark
NTSTATUS DriverEntry(IN PDRIVER_OBJECT Driver, PUNICODE_STRING RegistryPath)
{
DbgPrint("hello lyshark \n");

NTSTATUS status = STATUS_UNSUCCESSFUL;
PEPROCESS eproc = NULL;
KAPC_STATE kpc = { 0 };

PPEB64 pPeb64 = NULL;

__try
{
// HANDLE)4656 进程PID
status = PsLookupProcessByProcessId((HANDLE)4656, &eproc);

// 得到64位PEB
pPeb64 = (PPEB64)PsGetProcessPeb(eproc);

DbgPrint("PEB64 = %p \n", pPeb64);

if (pPeb64 != 0)
{
// 验证可读性
ProbeForRead(pPeb64, sizeof(PEB32), 1);

// 附加进程
KeStackAttachProcess(eproc, &kpc);

DbgPrint("进程基地址: 0x%p \n", pPeb64->ImageBaseAddress);
DbgPrint("ProcessHeap = 0x%p \n", pPeb64->ProcessHeap);
DbgPrint("BeingDebugged = %d \n", pPeb64->BeingDebugged);

// 脱离进程
KeUnstackDetachProcess(&kpc);
}
}
__except (EXCEPTION_EXECUTE_HANDLER)
{
Driver->DriverUnload = UnDriver;
return STATUS_SUCCESS;
}

Driver->DriverUnload = UnDriver;
return STATUS_SUCCESS;
}

PEB64代码运行后，我们加载驱动即可看到如下结果:

而相对于64位进程来说，获取32位进程的PEB信息可以直接调用PsGetProcessWow64Process()函数得到，该函数已被导出可以任意使用，获取PEB代码如下。

#include "peb.h"
#include <ntifs.h>

// 定义导出
NTKERNELAPI PVOID NTAPI PsGetProcessPeb(_In_ PEPROCESS Process);

VOID UnDriver(PDRIVER_OBJECT driver)
{
DbgPrint(("Uninstall Driver Is OK \n"));
}

// LyShark
NTSTATUS DriverEntry(IN PDRIVER_OBJECT Driver, PUNICODE_STRING RegistryPath)
{
DbgPrint("hello lyshark \n");

NTSTATUS status = STATUS_UNSUCCESSFUL;
PEPROCESS eproc = NULL;
KAPC_STATE kpc = { 0 };

PPEB32 pPeb32 = NULL;

__try
{
// HANDLE)4656 进程PID
status = PsLookupProcessByProcessId((HANDLE)6164, &eproc);

// 得到32位PEB
pPeb32 = (PPEB32)PsGetProcessWow64Process(eproc);

DbgPrint("PEB32 = %p \n", pPeb32);

if (pPeb32 != 0)
{
// 验证可读性
ProbeForRead(pPeb32, sizeof(PEB32), 1);

// 附加进程
KeStackAttachProcess(eproc, &kpc);

DbgPrint("进程基地址: 0x%p \n", pPeb32->ImageBaseAddress);
DbgPrint("ProcessHeap = 0x%p \n", pPeb32->ProcessHeap);
DbgPrint("BeingDebugged = %d \n", pPeb32->BeingDebugged);

// 脱离进程
KeUnstackDetachProcess(&kpc);
}

}
__except (EXCEPTION_EXECUTE_HANDLER)
{
Driver->DriverUnload = UnDriver;
return STATUS_SUCCESS;
}

Driver->DriverUnload = UnDriver;
return STATUS_SUCCESS;
}

PEB32代码运行后，我们加载驱动即可看到如下结果:

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