mirror-ac/driver/modules.c

#include "modules.h"

#include "callbacks.h"
#include "driver.h"

#define WHITELISTED_MODULE_TAG 'whte'

#define NMI_DELAY 200 * 10000

#define WHITELISTED_MODULE_COUNT 3
#define MODULE_MAX_STRING_SIZE 256

#define NTOSKRNL 0
#define CLASSPNP 1
#define WDF01000 2

CHAR WHITELISTED_MODULES[ WHITELISTED_MODULE_COUNT ][ MODULE_MAX_STRING_SIZE ] =
{
	"ntoskrnl.exe",
	"CLASSPNP.SYS",
	"Wdf01000.sys",
};

#define MODULE_REPORT_DRIVER_NAME_BUFFER_SIZE 128

#define REASON_NO_BACKING_MODULE 1
#define REASON_INVALID_IOCTL_DISPATCH 2

typedef struct _WHITELISTED_REGIONS
{
	UINT64 base;
	UINT64 end;

}WHITELISTED_REGIONS, * PWHITELISTED_REGIONS;

typedef struct _NMI_POOLS
{
	PVOID thread_data_pool;
	PVOID stack_frames;
	PVOID nmi_context;

}NMI_POOLS, * PNMI_POOLS;

typedef struct _NMI_CORE_CONTEXT
{
	INT nmi_callbacks_run;

}NMI_CORE_CONTEXT, * PNMI_CORE_CONTEXT;

typedef struct _MODULE_VALIDATION_FAILURE_HEADER
{
	INT module_count;

}MODULE_VALIDATION_FAILURE_HEADER, * PMODULE_VALIDATION_FAILURE_HEADER;

typedef struct _NMI_CONTEXT
{
	PVOID thread_data_pool;
	PVOID stack_frames;
	PVOID nmi_core_context;
	INT core_count;

}NMI_CONTEXT, * PNMI_CONTEXT;

typedef struct _NMI_CALLBACK_DATA
{
	UINT64		kthread_address;
	UINT64		kprocess_address;
	UINT64		start_address;
	UINT64		stack_limit;
	UINT64		stack_base;
	uintptr_t	stack_frames_offset;
	INT			num_frames_captured;
	UINT64		cr3;

}NMI_CALLBACK_DATA, * PNMI_CALLBACK_DATA;

typedef struct _INVALID_DRIVER
{
	struct _INVALID_DRIVER* next;
	INT reason;
	PDRIVER_OBJECT driver;

}INVALID_DRIVER, * PINVALID_DRIVER;

typedef struct _INVALID_DRIVERS_HEAD
{
	PINVALID_DRIVER first_entry;
	INT count;

}INVALID_DRIVERS_HEAD, * PINVALID_DRIVERS_HEAD;

#define SYSTEM_IDLE_PROCESS_ID 0
#define SYSTEM_PROCESS_ID 4
#define SVCHOST_PROCESS_ID 8

/*
* TODO: this needs to be refactored to just return the entry not the whole fukin thing
*/
PRTL_MODULE_EXTENDED_INFO 
FindSystemModuleByName(
	_In_ LPCSTR ModuleName,
	_In_ PSYSTEM_MODULES SystemModules
)
{
	if ( !ModuleName || !SystemModules )
		return STATUS_INVALID_PARAMETER;

	for ( INT index = 0; index < SystemModules->module_count; index++ )
	{
		PRTL_MODULE_EXTENDED_INFO system_module = ( PRTL_MODULE_EXTENDED_INFO )(
			( uintptr_t )SystemModules->address + index * sizeof( RTL_MODULE_EXTENDED_INFO ) );

		if ( strstr( system_module->FullPathName, ModuleName ) )
		{
			return system_module;
		}
	}
}

STATIC
NTSTATUS 
PopulateWhitelistedModuleBuffer(
	_In_ PVOID Buffer,
	_In_ PSYSTEM_MODULES SystemModules
)
{
	if ( !Buffer || !SystemModules)
		return STATUS_INVALID_PARAMETER;

	for ( INT index = 0; index < WHITELISTED_MODULE_COUNT; index++ )
	{
		LPCSTR name = WHITELISTED_MODULES[ index ];

		PRTL_MODULE_EXTENDED_INFO module = FindSystemModuleByName( name, SystemModules );

		WHITELISTED_REGIONS region;
		region.base = (UINT64)module->ImageBase;
		region.end = region.base + module->ImageSize;

		RtlCopyMemory(
			( UINT64 )Buffer + index * sizeof( WHITELISTED_REGIONS ),
			&region,
			sizeof( WHITELISTED_REGIONS )
		);
	}

	return STATUS_SUCCESS;
}

STATIC
NTSTATUS 
ValidateDriverIOCTLDispatchRegion(
	_In_ PDRIVER_OBJECT Driver,
	_In_ PSYSTEM_MODULES Modules,
	_In_ PWHITELISTED_REGIONS WhitelistedRegions,
	_In_ PBOOLEAN Flag
)
{
	if ( !Modules || !Driver || !Flag || !WhitelistedRegions )
		return STATUS_INVALID_PARAMETER;

	UINT64 dispatch_function;
	UINT64 module_base;
	UINT64 module_end;

	*Flag = TRUE;

	dispatch_function = Driver->MajorFunction[ IRP_MJ_DEVICE_CONTROL ];

	if ( dispatch_function == NULL )
		return STATUS_SUCCESS;

	for ( INT index = 0; index < Modules->module_count; index++ )
	{
		PRTL_MODULE_EXTENDED_INFO system_module = ( PRTL_MODULE_EXTENDED_INFO )(
			( uintptr_t )Modules->address + index * sizeof( RTL_MODULE_EXTENDED_INFO ) );

		if ( system_module->ImageBase != Driver->DriverStart )
			continue;

		/* make sure our driver has a device object which is required for IOCTL */
		if ( Driver->DeviceObject == NULL )
			return STATUS_SUCCESS;

		module_base = ( UINT64 )system_module->ImageBase;
		module_end = module_base + system_module->ImageSize;

		/* firstly, check if its inside its own module */
		if ( dispatch_function >= module_base && dispatch_function <= module_end )
			return STATUS_SUCCESS;

		/*
		* The WDF framework and other low level drivers often hook the dispatch routines
		* when initiating the respective config of their framework or system. With a bit of
		* digging you can view the drivers reponsible for the hooks. What this means is that
		* there will be legit drivers with dispatch routines that point outside of ntoskrnl 
		* and their own memory region. So, I have formed a list which contains the drivers
		* that perform these hooks and we iteratively check if the dispatch routine is contained
		* within one of these whitelisted regions. A note on how to imrpove this is the fact
		* that a code cave can be used inside a whitelisted region which then jumps to an invalid
		* region such as a manually mapped driver. So in the future we should implement a function
		* which checks for standard hook implementations like mov rax jmp rax etc.
		*/
		for ( INT index = 0; index < WHITELISTED_MODULE_COUNT; index++ )
		{
			if ( dispatch_function >= WhitelistedRegions[ index ].base &&
				dispatch_function <= WhitelistedRegions[ index ].end )
				return STATUS_SUCCESS;
		}

		DEBUG_LOG( "name: %s, base: %p, size: %lx, dispatch: %llx, type: %lx",
			system_module->FullPathName,
			system_module->ImageBase,
			system_module->ImageSize,
			dispatch_function,
			Driver->DeviceObject->DeviceType);

		*Flag = FALSE;
		return STATUS_SUCCESS;
	}

	return STATUS_SUCCESS;
}

STATIC
VOID 
InitDriverList(
	_In_ PINVALID_DRIVERS_HEAD ListHead
)
{
	ListHead->count = 0;
	ListHead->first_entry = NULL;
}

STATIC
VOID 
AddDriverToList(
	_In_ PINVALID_DRIVERS_HEAD InvalidDriversHead,
	_In_ PDRIVER_OBJECT Driver,
	_In_ INT Reason
)
{
	PINVALID_DRIVER new_entry = ExAllocatePool2(
		POOL_FLAG_NON_PAGED,
		sizeof( INVALID_DRIVER ),
		INVALID_DRIVER_LIST_ENTRY_POOL
	);

	if ( !new_entry )
		return;

	new_entry->driver = Driver;
	new_entry->reason = Reason;
	new_entry->next = InvalidDriversHead->first_entry;
	InvalidDriversHead->first_entry = new_entry;
}

STATIC
VOID 
RemoveInvalidDriverFromList(
	_In_ PINVALID_DRIVERS_HEAD InvalidDriversHead
)
{
	if ( InvalidDriversHead->first_entry )
	{
		PINVALID_DRIVER entry = InvalidDriversHead->first_entry;
		InvalidDriversHead->first_entry = InvalidDriversHead->first_entry->next;
		ExFreePoolWithTag( entry, INVALID_DRIVER_LIST_ENTRY_POOL );
	}
}

STATIC
VOID 
EnumerateInvalidDrivers(
	_In_ PINVALID_DRIVERS_HEAD InvalidDriversHead
)
{
	PINVALID_DRIVER entry = InvalidDriversHead->first_entry;

	while ( entry != NULL )
	{
		DEBUG_LOG( "Invalid Driver: %wZ", entry->driver->DriverName );
		entry = entry->next;
	}
}

STATIC
NTSTATUS 
ValidateDriverObjectHasBackingModule(
	_In_ PSYSTEM_MODULES ModuleInformation,
	_In_ PDRIVER_OBJECT DriverObject,
	_Out_ PBOOLEAN Result
)
{
	if ( !ModuleInformation || !DriverObject || !Result )
		return STATUS_INVALID_PARAMETER;

	for ( INT i = 0; i < ModuleInformation->module_count; i++ )
	{
		PRTL_MODULE_EXTENDED_INFO system_module = ( PRTL_MODULE_EXTENDED_INFO )(
			( uintptr_t )ModuleInformation->address + i * sizeof( RTL_MODULE_EXTENDED_INFO ) );

		if ( system_module->ImageBase == DriverObject->DriverStart )
		{
			*Result = TRUE;
			return STATUS_SUCCESS;
		}
	}

	DEBUG_LOG( "invalid driver found" );
	*Result = FALSE;

	return STATUS_SUCCESS;
}

//https://imphash.medium.com/windows-process-internals-a-few-concepts-to-know-before-jumping-on-memory-forensics-part-3-4a0e195d947b
NTSTATUS 
GetSystemModuleInformation(
	_Inout_ PSYSTEM_MODULES ModuleInformation
)
{
	if ( !ModuleInformation )
		return STATUS_INVALID_PARAMETER;

	ULONG size = 0;

	/*
	* query system module information without an output buffer to get
	* number of bytes required to store all module info structures
	*/
	if ( !NT_SUCCESS( RtlQueryModuleInformation(
		&size,
		sizeof( RTL_MODULE_EXTENDED_INFO ),
		NULL
	) ) )
	{
		DEBUG_ERROR( "Failed to query module information" );
		return STATUS_ABANDONED;
	}

	/* Allocate a pool equal to the output size of RtlQueryModuleInformation */
	PRTL_MODULE_EXTENDED_INFO driver_information = ExAllocatePool2(
		POOL_FLAG_NON_PAGED,
		size,
		SYSTEM_MODULES_POOL
	);

	if ( !driver_information )
	{
		DEBUG_ERROR( "Failed to allocate pool LOL" );
		return STATUS_ABANDONED;
	}

	/* Query the modules again this time passing a pointer to the allocated buffer */
	if ( !NT_SUCCESS( RtlQueryModuleInformation(
		&size,
		sizeof( RTL_MODULE_EXTENDED_INFO ),
		driver_information
	) ) )
	{
		DEBUG_ERROR( "Failed lolz" );
		ExFreePoolWithTag( driver_information, SYSTEM_MODULES_POOL );
		return STATUS_ABANDONED;
	}

	ModuleInformation->address = driver_information;
	ModuleInformation->module_count = size / sizeof( RTL_MODULE_EXTENDED_INFO );

	return STATUS_SUCCESS;
}

STATIC
NTSTATUS 
ValidateDriverObjects(
	_In_ PSYSTEM_MODULES SystemModules,
	_In_ PINVALID_DRIVERS_HEAD InvalidDriverListHead
)
{
	if ( !SystemModules || !InvalidDriverListHead )
		return STATUS_INVALID_PARAMETER;

	HANDLE handle;
	OBJECT_ATTRIBUTES attributes = { 0 };
	PVOID directory = { 0 };
	UNICODE_STRING directory_name;
	NTSTATUS status;

	RtlInitUnicodeString( &directory_name, L"\\Driver" );

	InitializeObjectAttributes(
		&attributes,
		&directory_name,
		OBJ_CASE_INSENSITIVE,
		NULL,
		NULL
	);

	if ( !NT_SUCCESS( ZwOpenDirectoryObject(
		&handle,
		DIRECTORY_ALL_ACCESS,
		&attributes
	) ) )
	{
		DEBUG_ERROR( "Failed to query directory object" );
		return STATUS_ABANDONED;
	}

	if ( !NT_SUCCESS( ObReferenceObjectByHandle(
		handle,
		DIRECTORY_ALL_ACCESS,
		NULL,
		KernelMode,
		&directory,
		NULL
	) ) )
	{
		DEBUG_ERROR( "Failed to reference directory by handle" );
		ZwClose( handle );
		return STATUS_ABANDONED;
	}

	/*
	* Windows organises its drivers in object directories (not the same as
	* files directories). For the driver directory, there are 37 entries,
	* each driver is hashed and indexed. If there is a driver with a duplicate
	* index, it is inserted into same index in a linked list using the
	* _OBJECT_DIRECTORY_ENTRY struct. So to enumerate all drivers we visit
	* each entry in the hashmap, enumerate all objects in the linked list
	* at entry j then we increment the hashmap index i. The motivation behind
	* this is that when a driver is accessed, it is brought to the first index
	* in the linked list, so drivers that are accessed the most can be
	* accessed quickly
	*/

	POBJECT_DIRECTORY directory_object = ( POBJECT_DIRECTORY )directory;

	ExAcquirePushLockExclusiveEx( &directory_object->Lock, NULL );

	PVOID whitelisted_regions_buffer = ExAllocatePool2(
		POOL_FLAG_NON_PAGED,
		WHITELISTED_MODULE_COUNT * MODULE_MAX_STRING_SIZE,
		WHITELISTED_MODULE_TAG 
	);

	if ( !whitelisted_regions_buffer )
		goto end;

	status = PopulateWhitelistedModuleBuffer(
		whitelisted_regions_buffer,
		SystemModules
	);

	if ( !NT_SUCCESS( status ) )
	{
		DEBUG_ERROR( "PopulateWhiteListedBuffer failed with status %x", status );
		goto end;
	}

	for ( INT i = 0; i < NUMBER_HASH_BUCKETS; i++ )
	{
		POBJECT_DIRECTORY_ENTRY entry = directory_object->HashBuckets[ i ];

		if ( !entry )
			continue;

		POBJECT_DIRECTORY_ENTRY sub_entry = entry;

		while ( sub_entry )
		{
			PDRIVER_OBJECT current_driver = sub_entry->Object;
			BOOLEAN flag;

			/* validate driver has backing module */

			if ( !NT_SUCCESS( ValidateDriverObjectHasBackingModule(
				SystemModules,
				current_driver,
				&flag
			) ) )
			{
				DEBUG_LOG( "Error validating driver object" );
				ExReleasePushLockExclusiveEx( &directory_object->Lock, 0 );
				ObDereferenceObject( directory );
				ZwClose( handle );
				return STATUS_ABANDONED;
			}

			if ( !flag )
			{
				InvalidDriverListHead->count += 1;
				AddDriverToList( InvalidDriverListHead, current_driver, REASON_NO_BACKING_MODULE );
			}

			/* validate drivers IOCTL dispatch routines */

			if ( !NT_SUCCESS( ValidateDriverIOCTLDispatchRegion(
				current_driver,
				SystemModules,
				(PWHITELISTED_REGIONS)whitelisted_regions_buffer,
				&flag
			) ) )
			{
				DEBUG_LOG( "Error validating drivers IOCTL routines" );
				ExReleasePushLockExclusiveEx( &directory_object->Lock, 0 );
				ObDereferenceObject( directory );
				ZwClose( handle );
				return STATUS_ABANDONED;
			}

			if ( !flag )
			{
				InvalidDriverListHead->count += 1;
				AddDriverToList( InvalidDriverListHead, current_driver, REASON_INVALID_IOCTL_DISPATCH );
			}

			sub_entry = sub_entry->ChainLink;
		}
	}

end:
	if ( whitelisted_regions_buffer) 
		ExFreePoolWithTag( whitelisted_regions_buffer, WHITELISTED_MODULE_TAG );

	ExReleasePushLockExclusiveEx( &directory_object->Lock, 0 );
	ObDereferenceObject( directory );
	ZwClose( handle );

	return STATUS_SUCCESS;
}

NTSTATUS 
HandleValidateDriversIOCTL(
	_In_ PIRP Irp
)
{
	NTSTATUS status = STATUS_SUCCESS;
	SYSTEM_MODULES system_modules = { 0 };

	/* Fix annoying visual studio linting error */
	RtlZeroMemory( &system_modules, sizeof( SYSTEM_MODULES ) );

	status = GetSystemModuleInformation( &system_modules );

	if ( !NT_SUCCESS( status ) )
	{
		DEBUG_ERROR( "Error retriving system module information" );
		return status;
	}

	PINVALID_DRIVERS_HEAD head =
		ExAllocatePool2( POOL_FLAG_NON_PAGED, sizeof( INVALID_DRIVERS_HEAD ), INVALID_DRIVER_LIST_HEAD_POOL );

	if ( !head )
	{
		ExFreePoolWithTag( system_modules.address, SYSTEM_MODULES_POOL );
		return STATUS_ABANDONED;
	}

	/*
	* Use a linked list here so that so we have easy access to the invalid drivers
	* which we can then use to copy the drivers logic for further analysis in
	* identifying drivers specifically used for the purpose of cheating
	*/

	InitDriverList( head );

	if ( !NT_SUCCESS( ValidateDriverObjects( &system_modules, head ) ) )
	{
		DEBUG_ERROR( "Failed to validate driver objects" );
		ExFreePoolWithTag( system_modules.address, SYSTEM_MODULES_POOL );
		return STATUS_ABANDONED;
	}

	MODULE_VALIDATION_FAILURE_HEADER header;

	header.module_count = head->count >= MODULE_VALIDATION_FAILURE_MAX_REPORT_COUNT
		? MODULE_VALIDATION_FAILURE_MAX_REPORT_COUNT
		: head->count;

	if ( head->count > 0 )
	{
		DEBUG_LOG( "found INVALID drivers with count: %i", head->count );

		PVOID buffer = ExAllocatePool2(POOL_FLAG_NON_PAGED, sizeof( MODULE_VALIDATION_FAILURE_HEADER ) +
			MODULE_VALIDATION_FAILURE_MAX_REPORT_COUNT * sizeof( MODULE_VALIDATION_FAILURE ), MODULES_REPORT_POOL_TAG );

		if (!buffer )
		{
			ExFreePoolWithTag( head, INVALID_DRIVER_LIST_HEAD_POOL );
			ExFreePoolWithTag( system_modules.address, SYSTEM_MODULES_POOL );
			return STATUS_MEMORY_NOT_ALLOCATED;
		}

		Irp->IoStatus.Information = sizeof( MODULE_VALIDATION_FAILURE_HEADER ) +
			MODULE_VALIDATION_FAILURE_MAX_REPORT_COUNT * sizeof( MODULE_VALIDATION_FAILURE );

		RtlCopyMemory(
			buffer,
			&header,
			sizeof( MODULE_VALIDATION_FAILURE_HEADER )
		);

		for ( INT i = 0; i < head->count; i++ )
		{
			/* make sure we free any non reported modules */
			if ( i >= MODULE_VALIDATION_FAILURE_MAX_REPORT_COUNT )
			{
				RemoveInvalidDriverFromList( head );
				continue;
			}

			MODULE_VALIDATION_FAILURE report;
			report.report_code = REPORT_MODULE_VALIDATION_FAILURE;
			report.report_type = head->first_entry->reason;
			report.driver_base_address = head->first_entry->driver->DriverStart;
			report.driver_size = head->first_entry->driver->DriverSize;

			ANSI_STRING string;
			string.Length = 0;
			string.MaximumLength = MODULE_REPORT_DRIVER_NAME_BUFFER_SIZE;
			string.Buffer = &report.driver_name;

			status = RtlUnicodeStringToAnsiString(
				&string,
				&head->first_entry->driver->DriverName,
				FALSE
			);

			/* still continue if we fail to get the driver name */
			if ( !NT_SUCCESS( status ) )
				DEBUG_ERROR( "RtlUnicodeStringToAnsiString failed with statsu %x", status );

			RtlCopyMemory(
				( UINT64 )buffer + sizeof( MODULE_VALIDATION_FAILURE_HEADER ) + i * sizeof( MODULE_VALIDATION_FAILURE ),
				&report,
				sizeof( MODULE_VALIDATION_FAILURE ) );

			RemoveInvalidDriverFromList( head );
		}

		RtlCopyMemory(
			Irp->AssociatedIrp.SystemBuffer,
			buffer,
			sizeof( MODULE_VALIDATION_FAILURE_HEADER ) + MODULE_VALIDATION_FAILURE_MAX_REPORT_COUNT * sizeof( MODULE_VALIDATION_FAILURE )
		);

		ExFreePoolWithTag( buffer, MODULES_REPORT_POOL_TAG );
	}
	else
	{
		DEBUG_LOG( "No INVALID drivers found :)" );
	}

	ExFreePoolWithTag( head, INVALID_DRIVER_LIST_HEAD_POOL );
	ExFreePoolWithTag( system_modules.address, SYSTEM_MODULES_POOL );

	return status;
}

NTSTATUS 
IsInstructionPointerInInvalidRegion(
	_In_ UINT64 RIP,
	_In_ PSYSTEM_MODULES SystemModules,
	_Out_ PBOOLEAN Result
)
{
	if ( !RIP || !SystemModules || !Result )
		return STATUS_INVALID_PARAMETER;

	/* Note that this does not check for HAL or PatchGuard Execution */
	for ( INT i = 0; i < SystemModules->module_count; i++ )
	{
		PRTL_MODULE_EXTENDED_INFO system_module = ( PRTL_MODULE_EXTENDED_INFO )(
			( uintptr_t )SystemModules->address + i * sizeof( RTL_MODULE_EXTENDED_INFO ) );

		UINT64 base = ( UINT64 )system_module->ImageBase;
		UINT64 end = base + system_module->ImageSize;

		if ( RIP >= base && RIP <= end )
		{
			*Result = TRUE;
			return STATUS_SUCCESS;;
		}
	}

	*Result = FALSE;
	return STATUS_SUCCESS;
}

STATIC
NTSTATUS 
AnalyseNmiData(
	_In_ PNMI_CONTEXT NmiContext,
	_In_ PSYSTEM_MODULES SystemModules,
	_In_ PIRP Irp
)
{
	if ( !NmiContext || !SystemModules )
		return STATUS_INVALID_PARAMETER;

	for ( INT core = 0; core < NmiContext->core_count; core++ )
	{
		PNMI_CORE_CONTEXT context = ( PNMI_CORE_CONTEXT )( ( uintptr_t )NmiContext->nmi_core_context + core * sizeof( NMI_CORE_CONTEXT ) );

		/* Make sure our NMIs were run  */
		if ( !context->nmi_callbacks_run )
		{
			NMI_CALLBACK_FAILURE report;
			report.report_code = REPORT_NMI_CALLBACK_FAILURE;
			report.kthread_address = NULL;
			report.invalid_rip = NULL;
			report.were_nmis_disabled = TRUE;

			Irp->IoStatus.Information = sizeof( NMI_CALLBACK_FAILURE );

			RtlCopyMemory(
				Irp->AssociatedIrp.SystemBuffer,
				&report,
				sizeof( NMI_CALLBACK_FAILURE )
			);

			return STATUS_SUCCESS;
		}

		PNMI_CALLBACK_DATA thread_data = ( PNMI_CALLBACK_DATA )(
			( uintptr_t )NmiContext->thread_data_pool + core * sizeof( NMI_CALLBACK_DATA ) );

		DEBUG_LOG( "cpu number: %i callback count: %i", core, context->nmi_callbacks_run );

		/* Walk the stack */
		for ( INT frame = 0; frame < thread_data->num_frames_captured; frame++ )
		{
			BOOLEAN flag;
			DWORD64 stack_frame = *( DWORD64* )(
				( ( uintptr_t )NmiContext->stack_frames + thread_data->stack_frames_offset + frame * sizeof( PVOID ) ) );

			if ( !NT_SUCCESS( IsInstructionPointerInInvalidRegion( stack_frame, SystemModules, &flag ) ) )
			{
				DEBUG_ERROR( "errro checking RIP for current stack address" );
				continue;
			}

			if ( flag == FALSE )
			{
				/*
				* Note: for now, we only handle 1 report at a time so we stop the
				* analysis once we receive a report since we only send a buffer
				* large enough for 1 report. In the future this should be changed
				* to a buffer that can hold atleast 4 reports (since the chance we
				* get 4 reports with a single NMI would be impossible) so we can
				* continue parsing the rest of the stack frames after receiving a
				* single report.
				*/

				NMI_CALLBACK_FAILURE report;
				report.report_code = REPORT_NMI_CALLBACK_FAILURE;
				report.kthread_address = thread_data->kthread_address;
				report.invalid_rip = stack_frame;
				report.were_nmis_disabled = FALSE;

				Irp->IoStatus.Information = sizeof( NMI_CALLBACK_FAILURE );

				RtlCopyMemory(
					Irp->AssociatedIrp.SystemBuffer,
					&report,
					sizeof( NMI_CALLBACK_FAILURE )
				);

				return STATUS_SUCCESS;
			}
		}
	}

	return STATUS_SUCCESS;
}

STATIC
BOOLEAN 
NmiCallback(
	_In_ PVOID Context,
	_In_ BOOLEAN Handled
)
{
	UNREFERENCED_PARAMETER( Handled );

	PVOID current_thread = KeGetCurrentThread();
	NMI_CALLBACK_DATA thread_data = { 0 };
	PNMI_CONTEXT nmi_context = ( PNMI_CONTEXT )Context;
	ULONG proc_num = KeGetCurrentProcessorNumber();

	/*
	* Cannot allocate pool in this function as it runs at IRQL >= dispatch level
	* so ive just allocated a global pool with size equal to 0x200 * num_procs
	*/
	INT num_frames_captured = RtlCaptureStackBackTrace(
		NULL,
		STACK_FRAME_POOL_SIZE / sizeof(UINT64),
		( uintptr_t )nmi_context->stack_frames + proc_num * STACK_FRAME_POOL_SIZE,
		NULL
	);

	/*
	* This function is run in the context of the interrupted thread hence we can
	* gather any and all information regarding the thread that may be useful for analysis
	*/
	thread_data.kthread_address = ( UINT64 )current_thread;
	thread_data.kprocess_address = ( UINT64 )PsGetCurrentProcess();
	thread_data.stack_base = *( ( UINT64* )( ( uintptr_t )current_thread + KTHREAD_STACK_BASE_OFFSET ) );
	thread_data.stack_limit = *( ( UINT64* )( ( uintptr_t )current_thread + KTHREAD_STACK_LIMIT_OFFSET ) );
	thread_data.start_address = *( ( UINT64* )( ( uintptr_t )current_thread + KTHREAD_START_ADDRESS_OFFSET ) );
	thread_data.cr3 = __readcr3();
	thread_data.stack_frames_offset = proc_num * STACK_FRAME_POOL_SIZE;
	thread_data.num_frames_captured = num_frames_captured;

	RtlCopyMemory(
		( ( uintptr_t )nmi_context->thread_data_pool ) + proc_num * sizeof( thread_data ),
		&thread_data,
		sizeof( thread_data )
	);

	PNMI_CORE_CONTEXT core_context =
		( PNMI_CORE_CONTEXT )( ( uintptr_t )nmi_context->nmi_core_context + proc_num * sizeof( NMI_CORE_CONTEXT ) );

	core_context->nmi_callbacks_run += 1;

	return TRUE;
}

STATIC
NTSTATUS 
LaunchNonMaskableInterrupt(
	_In_ PNMI_CONTEXT NmiContext
)
{
	if ( !NmiContext )
		return STATUS_INVALID_PARAMETER;

	PKAFFINITY_EX ProcAffinityPool =
		ExAllocatePool2( POOL_FLAG_NON_PAGED, sizeof( KAFFINITY_EX ), PROC_AFFINITY_POOL );

	if ( !ProcAffinityPool )
		return STATUS_MEMORY_NOT_ALLOCATED;

	NmiContext->stack_frames =
		ExAllocatePool2( POOL_FLAG_NON_PAGED, NmiContext->core_count * STACK_FRAME_POOL_SIZE, STACK_FRAMES_POOL );

	if ( !NmiContext->stack_frames )
	{
		ExFreePoolWithTag( ProcAffinityPool, PROC_AFFINITY_POOL );
		return STATUS_MEMORY_NOT_ALLOCATED;
	}

	NmiContext->thread_data_pool =
		ExAllocatePool2( POOL_FLAG_NON_PAGED, NmiContext->core_count * sizeof( NMI_CALLBACK_DATA ), THREAD_DATA_POOL );

	if ( !NmiContext->thread_data_pool )
	{
		ExFreePoolWithTag( NmiContext->stack_frames, STACK_FRAMES_POOL );
		ExFreePoolWithTag( ProcAffinityPool, PROC_AFFINITY_POOL );
		return STATUS_MEMORY_NOT_ALLOCATED;
	}

	LARGE_INTEGER delay = { 0 };
	delay.QuadPart -= 100 * 10000;

	for ( ULONG core = 0; core < NmiContext->core_count; core++ )
	{
		KeInitializeAffinityEx( ProcAffinityPool );
		KeAddProcessorAffinityEx( ProcAffinityPool, core );

		HalSendNMI( ProcAffinityPool );

		/*
		* Only a single NMI can be active at any given time, so arbitrarily
		* delay execution  to allow time for the NMI to be processed
		*/
		KeDelayExecutionThread( KernelMode, FALSE, &delay );
	}

	ExFreePoolWithTag( ProcAffinityPool, PROC_AFFINITY_POOL );

	return STATUS_SUCCESS;
}

NTSTATUS 
HandleNmiIOCTL(
	_In_ PIRP Irp
)
{
	NTSTATUS status = STATUS_SUCCESS;
	SYSTEM_MODULES system_modules = { 0 };
	NMI_CONTEXT nmi_context = { 0 };
	PVOID callback_handle;

	nmi_context.core_count = KeQueryActiveProcessorCountEx( 0 );
	nmi_context.nmi_core_context =
		ExAllocatePool2( POOL_FLAG_NON_PAGED, nmi_context.core_count * sizeof( NMI_CORE_CONTEXT ), NMI_CONTEXT_POOL );

	if ( !nmi_context.nmi_core_context )
		return STATUS_MEMORY_NOT_ALLOCATED;

	/*
	* We want to register and unregister our callback each time so it becomes harder
	* for people to hook our callback and get up to some funny business
	*/
	callback_handle = KeRegisterNmiCallback( NmiCallback, &nmi_context );

	if ( !callback_handle )
	{
		DEBUG_ERROR( "KeRegisterNmiCallback failed" );
		ExFreePoolWithTag( nmi_context.nmi_core_context, NMI_CONTEXT_POOL );
		return STATUS_ABANDONED;
	}

	/*
	* We query the system modules each time since they can potentially
	* change at any time
	*/
	status = GetSystemModuleInformation( &system_modules );

	if ( !NT_SUCCESS( status ) )
	{
		DEBUG_ERROR( "Error retriving system module information" );
		return status;
	}
	status = LaunchNonMaskableInterrupt( &nmi_context );

	if ( !NT_SUCCESS( status ) )
	{
		DEBUG_ERROR( "Error running NMI callbacks" );
		ExFreePoolWithTag( system_modules.address, SYSTEM_MODULES_POOL );
		return status;
	}
	status = AnalyseNmiData( &nmi_context, &system_modules, Irp );

	if ( !NT_SUCCESS( status ) )
		DEBUG_ERROR( "Error analysing nmi data" );

	ExFreePoolWithTag( system_modules.address, SYSTEM_MODULES_POOL );
	ExFreePoolWithTag( nmi_context.nmi_core_context, NMI_CONTEXT_POOL );

	if ( nmi_context.stack_frames )
		ExFreePoolWithTag( nmi_context.stack_frames, STACK_FRAMES_POOL );

	if (nmi_context.thread_data_pool )
		ExFreePoolWithTag( nmi_context.thread_data_pool, THREAD_DATA_POOL );

	KeDeregisterNmiCallback( callback_handle );

	return status;
}

/*
* The RundownRoutine is executed if the thread terminates before the APC was delivered to
* user mode.
*/
STATIC
VOID 
ApcRundownRoutine(
	_In_ PRKAPC Apc
)
{
	FreeApcAndDecrementApcCount( Apc, APC_CONTEXT_ID_STACKWALK );
}

/*
* The KernelRoutine is executed in kernel mode at APC_LEVEL before the APC is delivered. This
* is also where we want to free our APC object.
*/
STATIC
VOID 
ApcKernelRoutine(
	_In_ PRKAPC Apc,
	_Inout_ _Deref_pre_maybenull_ PKNORMAL_ROUTINE* NormalRoutine, 
	_Inout_ _Deref_pre_maybenull_ PVOID* NormalContext,
	_Inout_ _Deref_pre_maybenull_ PVOID* SystemArgument1,
	_Inout_ _Deref_pre_maybenull_ PVOID* SystemArgument2
		)
		{
			PVOID buffer = NULL;
			INT frames_captured = 0;
			UINT64 stack_frame = 0;
			NTSTATUS status;
			BOOLEAN flag = FALSE;
			PAPC_STACKWALK_CONTEXT context;

			context = ( PAPC_STACKWALK_CONTEXT )Apc->NormalContext;

			buffer = ExAllocatePool2( POOL_FLAG_NON_PAGED, 0x200, POOL_TAG_APC );

			if ( !buffer )
				goto free;

			frames_captured = RtlCaptureStackBackTrace(
				NULL,
				STACK_FRAME_POOL_SIZE / sizeof( UINT64 ),
				buffer,
				NULL
			);

			if ( frames_captured == NULL )
				goto free;

			for ( INT index = 0; index < frames_captured; index++ )
			{
				stack_frame = *( UINT64* )( ( UINT64 )buffer + index * sizeof( UINT64 ) );

				/*
				* Apc->NormalContext holds the address of our context data structure that we passed into
				* KeInitializeApc as the last argument.
				*/
				status = IsInstructionPointerInInvalidRegion(
					stack_frame,
					context->modules,
					&flag
				);

				if ( !NT_SUCCESS( status ) )
				{
					DEBUG_ERROR( "IsInstructionPointerInInvalidRegion failed with status %x", status );
					goto free;
				}
			}

		free:

			if ( buffer )
				ExFreePoolWithTag( buffer, POOL_TAG_APC );

			FreeApcAndDecrementApcCount( Apc, APC_CONTEXT_ID_STACKWALK );
}

	/*
	* The NormalRoutine is executed in user mode when the APC is delivered.
	*/
	STATIC
		VOID
		ApcNormalRoutine(
			_In_opt_ PVOID NormalContext,
			_In_opt_ PVOID SystemArgument1,
			_In_opt_ PVOID SystemArgument2
		)
	{

	}

	STATIC
		VOID
		ValidateThreadViaKernelApcCallback(
			_In_ PEPROCESS Process,
			_In_ PVOID Context
		)
	{
		NTSTATUS status;
		PLIST_ENTRY thread_list_head;
		PLIST_ENTRY thread_list_entry;
		PETHREAD current_thread;
		PKAPC apc = NULL;
		BOOLEAN apc_status;
		PAPC_STACKWALK_CONTEXT context = ( PAPC_STACKWALK_CONTEXT )Context;
		LPCSTR process_name = PsGetProcessImageFileName( Process );

		/* we dont want to schedule an apc to threads owned by the kernel */
		if ( Process == PsInitialSystemProcess )
			return;

		/* We are not interested in these processess.. for now lol */
		if ( !strcmp( process_name, "svchost.exe" ) ||
			 !strcmp( process_name, "Registry" ) ||
			 !strcmp( process_name, "smss.exe" ) ||
			 !strcmp( process_name, "csrss.exe" ) )
			return;

	thread_list_head = ( PLIST_ENTRY )( ( UINT64 )Process + KPROCESS_THREADLIST_OFFSET );
	thread_list_entry = thread_list_head->Flink;

	context->header.allocation_in_progress = TRUE;

	while ( thread_list_entry != thread_list_head )
	{
		current_thread = ( PETHREAD )( ( UINT64 )thread_list_entry - KTHREAD_THREADLIST_OFFSET );

		if (current_thread == KeGetCurrentThread())
			goto increment;

		apc = ( PKAPC )ExAllocatePool2( POOL_FLAG_NON_PAGED, sizeof( KAPC ), POOL_TAG_APC );

		if ( !apc )
			goto increment;

		KeInitializeApc(
			apc,
			current_thread,
			OriginalApcEnvironment,
			ApcKernelRoutine,
			ApcRundownRoutine,
			ApcNormalRoutine,
			KernelMode,
			Context
		);

		apc_status = KeInsertQueueApc(
			apc,
			NULL,
			NULL,
			IO_NO_INCREMENT
		);

		if ( !apc_status )
		{
			DEBUG_ERROR( "KeInsertQueueApc failed" );
			goto increment;
		}

		IncrementApcCount( APC_CONTEXT_ID_STACKWALK );

	increment:
		thread_list_entry = thread_list_entry->Flink;
	}

	context->header.allocation_in_progress = FALSE;
}

/*
* Since NMIs are only executed on the thread that is running on each logical core, it makes
* sense to make use of APCs that, while can be masked off, provide us to easily issue a callback
* routine to threads we want a stack trace of. Hence by utilising both APCs and NMIs we get 
* excellent coverage of the entire system.
*/
NTSTATUS 
ValidateThreadsViaKernelApc()
{
	NTSTATUS status;
	PAPC_STACKWALK_CONTEXT context = NULL;

	context = ExAllocatePool2( POOL_FLAG_NON_PAGED, sizeof( APC_STACKWALK_CONTEXT ), POOL_TAG_APC );

	if ( !context )
		return STATUS_MEMORY_NOT_ALLOCATED;

	context->header.context_id = APC_CONTEXT_ID_STACKWALK;
	context->modules = ExAllocatePool2( POOL_FLAG_NON_PAGED, sizeof( SYSTEM_MODULES ), POOL_TAG_APC );

	if ( !context->modules )
	{
		ExFreePoolWithTag( context, POOL_TAG_APC );
		return STATUS_MEMORY_NOT_ALLOCATED;
	}

	status = GetSystemModuleInformation( context->modules );

	if ( !NT_SUCCESS( status ) )
	{
		ExFreePoolWithTag( context->modules, POOL_TAG_APC );
		ExFreePoolWithTag( context, POOL_TAG_APC );
		return STATUS_MEMORY_NOT_ALLOCATED;
	}

	InsertApcContext( context );

	EnumerateProcessListWithCallbackFunction(
		ValidateThreadViaKernelApcCallback,
		context
	);
}

VOID 
FreeApcStackwalkApcContextInformation(
	_In_ PAPC_STACKWALK_CONTEXT Context
)
{
	if (Context->modules->address )
		ExFreePoolWithTag( Context->modules->address, SYSTEM_MODULES_POOL );

	if ( Context->modules )
		ExFreePoolWithTag( Context->modules, POOL_TAG_APC );
}