reactos/rostests/kmtests/ntos_mm/ZwAllocateVirtualMemory.c
Hermès Bélusca-Maïto 2c7388a0b1 [KMTESTS]
No need now to declare a NTSTATUS ExceptionStatus; variable to be able to use KmtStartSeh() / KmtEndSeh() macros; this is done automagically.

svn path=/trunk/; revision=60320
2013-09-22 19:28:21 +00:00

507 lines
21 KiB
C

/*
* PROJECT: ReactOS kernel-mode tests
* LICENSE: GPLv2+ - See COPYING in the top level directory
* PURPOSE: Kernel-Mode Test Suite ZwAllocateVirtualMemory/ZwFreeVirtualMemory
* PROGRAMMER: Nikolay Borisov <nib9@aber.ac.uk>
*/
#include <kmt_test.h>
#define ROUND_DOWN(n,align) (((ULONG_PTR)n) & ~((align) - 1l))
#define DEFAULT_ALLOC_SIZE 200
#define IGNORE -1
#define PAGE_NOPROT 0x0 //MEM_RESERVE has this type of "protection"
/* These are being used in ZwMapViewOfSection as well */
const char TestString[] = "TheLongBrownFoxJumpedTheWhiteRabbitTheLongBrownFoxJumpedTheWhiteRabbitTheLongBrownFoxJumpedTheWhiteRabbitTheLongBrownFoxJumpedTheWhiteRabbitTheLongBrownFoxJumpedTheWhiteRabbitTheLongBrownFoxJumpedThe";
const ULONG TestStringSize = sizeof(TestString);
VOID Test_ZwAllocateVirtualMemory(VOID);
typedef struct _TEST_CONTEXT
{
HANDLE ProcessHandle;
SIZE_T RegionSize;
ULONG AllocationType;
ULONG Protect;
PVOID Bases[1024];
SHORT ThreadId;
} TEST_CONTEXT, *PTEST_CONTEXT;
#define ALLOC_MEMORY_WITH_FREE(ProcessHandle, BaseAddress, ZeroBits, RegionSize, AllocationType, Protect, RetStatus, FreeStatus) \
do { \
Status = ZwAllocateVirtualMemory(ProcessHandle, &BaseAddress, ZeroBits, &RegionSize, AllocationType, Protect); \
ok_eq_hex(Status, RetStatus); \
RegionSize = 0; \
Status = ZwFreeVirtualMemory(ProcessHandle, &BaseAddress, &RegionSize, MEM_RELEASE); \
if (FreeStatus != IGNORE) ok_eq_hex(Status, FreeStatus); \
BaseAddress = NULL; \
RegionSize = DEFAULT_ALLOC_SIZE; \
} while (0) \
static
BOOLEAN
CheckBuffer(PVOID Buffer, SIZE_T Size, UCHAR Value)
{
PUCHAR Array = Buffer;
SIZE_T i;
for (i = 0; i < Size; i++)
{
if (Array[i] != Value)
{
trace("Expected %x, found %x at offset %lu\n", Value, Array[i], (ULONG)i);
return FALSE;
}
}
return TRUE;
}
static
SIZE_T
CheckBufferRead(CONST VOID *Source, CONST VOID *Destination, SIZE_T Length, NTSTATUS ExpectedStatus)
{
SIZE_T Match = 0;
KmtStartSeh()
Match = RtlCompareMemory(Source, Destination, Length);
KmtEndSeh(ExpectedStatus);
return Match;
}
static
VOID
CheckBufferReadWrite(PVOID Destination, CONST VOID *Source, SIZE_T Length, NTSTATUS ExpectedStatus)
{
//do a little bit of writing/reading to memory
SIZE_T Match = 0;
KmtStartSeh()
RtlCopyMemory(Destination, Source, Length);
KmtEndSeh(ExpectedStatus);
Match = CheckBufferRead(Source, Destination, Length, ExpectedStatus);
if (ExpectedStatus == STATUS_SUCCESS) ok_eq_int(Match, Length);
}
static
VOID
SimpleErrorChecks(VOID)
{
NTSTATUS Status;
PVOID Base = NULL;
SIZE_T RegionSize = DEFAULT_ALLOC_SIZE;
//HANDLE TESTS
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_SUCCESS, STATUS_SUCCESS);
ALLOC_MEMORY_WITH_FREE(NULL, Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_HANDLE, STATUS_INVALID_HANDLE);
ALLOC_MEMORY_WITH_FREE((HANDLE)0xdeadbeef, Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_HANDLE, STATUS_INVALID_HANDLE);
//BASE ADDRESS TESTS
Base = (PVOID)0x00567A20;
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_CONFLICTING_ADDRESSES, STATUS_FREE_VM_NOT_AT_BASE);
Base = (PVOID) 0x60000000;
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_SUCCESS, STATUS_SUCCESS);
Base = (PVOID)((char *)MmSystemRangeStart + 200);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_PARAMETER_2, STATUS_INVALID_PARAMETER_2);
/* http://jira.reactos.org/browse/CORE-6814 */
RegionSize = 0x1000;
Base = Test_ZwAllocateVirtualMemory;
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, MEM_COMMIT, PAGE_READWRITE, STATUS_INVALID_PARAMETER_2, STATUS_INVALID_PARAMETER_2);
//ZERO BITS TESTS
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 21, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_NO_MEMORY, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 22, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_PARAMETER_3, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, -1, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_PARAMETER_3, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 3, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_SUCCESS, STATUS_SUCCESS);
//REGION SIZE TESTS
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_SUCCESS, STATUS_SUCCESS);
RegionSize = -1;
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_PARAMETER_4, STATUS_MEMORY_NOT_ALLOCATED);
RegionSize = 0;
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_PARAMETER_4, STATUS_MEMORY_NOT_ALLOCATED);
RegionSize = 0xFFFFFFFF; // 4 gb is invalid
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_PARAMETER_4, STATUS_MEMORY_NOT_ALLOCATED);
//Allocation type tests
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, MEM_PHYSICAL, PAGE_READWRITE, STATUS_INVALID_PARAMETER_5, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESET), PAGE_READWRITE, STATUS_INVALID_PARAMETER_5, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, 0, PAGE_READWRITE, STATUS_INVALID_PARAMETER_5, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, MEM_TOP_DOWN, PAGE_READWRITE, STATUS_INVALID_PARAMETER_5, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_TOP_DOWN | MEM_RESET), PAGE_READWRITE, STATUS_INVALID_PARAMETER_5, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_TOP_DOWN | MEM_COMMIT), PAGE_READWRITE, STATUS_SUCCESS, STATUS_SUCCESS);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_PHYSICAL | MEM_RESERVE), PAGE_READWRITE, STATUS_SUCCESS, STATUS_SUCCESS);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_PHYSICAL | MEM_COMMIT), PAGE_READWRITE, STATUS_INVALID_PARAMETER_5, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_RESET | MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE, STATUS_INVALID_PARAMETER_5, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, -1, PAGE_READWRITE, STATUS_INVALID_PARAMETER_5, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, MEM_COMMIT, PAGE_READWRITE, STATUS_SUCCESS, STATUS_SUCCESS);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, MEM_RESERVE, PAGE_READWRITE, STATUS_SUCCESS, STATUS_SUCCESS);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, MEM_RESERVE, PAGE_WRITECOPY, STATUS_INVALID_PAGE_PROTECTION, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, MEM_RESERVE, PAGE_EXECUTE_WRITECOPY, STATUS_INVALID_PAGE_PROTECTION, STATUS_MEMORY_NOT_ALLOCATED);
//Memory protection tests
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), 0, STATUS_INVALID_PAGE_PROTECTION, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), -1, STATUS_INVALID_PAGE_PROTECTION, STATUS_MEMORY_NOT_ALLOCATED);
if (!KmtIsCheckedBuild)
{
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), (PAGE_NOACCESS | PAGE_GUARD), STATUS_INVALID_PAGE_PROTECTION, STATUS_MEMORY_NOT_ALLOCATED);
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), (PAGE_NOACCESS | PAGE_WRITECOMBINE), STATUS_INVALID_PAGE_PROTECTION, STATUS_MEMORY_NOT_ALLOCATED);
}
ALLOC_MEMORY_WITH_FREE(NtCurrentProcess(), Base, 0, RegionSize, (MEM_COMMIT | MEM_RESERVE), (PAGE_READONLY | PAGE_WRITECOMBINE), STATUS_SUCCESS, STATUS_SUCCESS);
}
static
NTSTATUS
SimpleAllocation(VOID)
{
NTSTATUS Status;
PVOID Base = NULL;
SIZE_T RegionSize = DEFAULT_ALLOC_SIZE;
//////////////////////////////////////////////////////////////////////////
//Normal operation
//////////////////////////////////////////////////////////////////////////
Status = ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &RegionSize, MEM_COMMIT, PAGE_READWRITE);
ok_eq_size(RegionSize, 4096);
//check for the zero-filled pages
ok_bool_true(CheckBuffer(Base, RegionSize, 0), "The buffer is not zero-filled");
CheckBufferReadWrite(Base, TestString, TestStringSize, STATUS_SUCCESS);
// try freeing
RegionSize = 0;
Status = ZwFreeVirtualMemory(NtCurrentProcess(), &Base, &RegionSize, MEM_RELEASE);
ok_eq_hex(Status, STATUS_SUCCESS);
ok_eq_size(RegionSize, PAGE_SIZE);
//////////////////////////////////////////////////////////////////////////
// COMMIT AND RESERVE SCENARIO AND STATE CHANGE
//////////////////////////////////////////////////////////////////////////
//reserve and then commit
Base = NULL;
RegionSize = DEFAULT_ALLOC_SIZE;
Status = ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &RegionSize, MEM_RESERVE, PAGE_READWRITE);
Test_NtQueryVirtualMemory(Base, RegionSize, MEM_RESERVE, PAGE_NOPROT);
CheckBufferReadWrite(Base, TestString, TestStringSize, STATUS_ACCESS_VIOLATION);
Status = ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &RegionSize, MEM_COMMIT, PAGE_READWRITE);
CheckBufferReadWrite(Base, TestString, TestStringSize, STATUS_SUCCESS);
Test_NtQueryVirtualMemory(Base, RegionSize, MEM_COMMIT, PAGE_READWRITE);
RegionSize = 0;
ZwFreeVirtualMemory(NtCurrentProcess(), &Base, &RegionSize, MEM_RELEASE);
//////////////////////////////////////////////////////////////////////////
// TRY READING/WRITING TO INVALID PROTECTION PAGES
//////////////////////////////////////////////////////////////////////////
RegionSize = DEFAULT_ALLOC_SIZE;
Base = NULL;
ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_NOACCESS);
KmtStartSeh()
RtlCopyMemory(Base, TestString, TestStringSize);
KmtEndSeh(STATUS_ACCESS_VIOLATION);
Test_NtQueryVirtualMemory(Base, RegionSize, MEM_COMMIT, PAGE_NOACCESS);
CheckBufferRead(Base, TestString, TestStringSize, STATUS_ACCESS_VIOLATION);
RegionSize = 0;
ZwFreeVirtualMemory(NtCurrentProcess(), &Base, &RegionSize, MEM_RELEASE);
ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READONLY);
KmtStartSeh()
RtlCopyMemory(Base, TestString, TestStringSize);
KmtEndSeh(STATUS_ACCESS_VIOLATION);
Test_NtQueryVirtualMemory(Base, RegionSize, MEM_COMMIT, PAGE_READONLY);
ok_bool_true(CheckBuffer(Base, TestStringSize, 0), "Couldn't read a read-only buffer");
RegionSize = 0;
ZwFreeVirtualMemory(NtCurrentProcess(), &Base, &RegionSize, MEM_RELEASE);
//////////////////////////////////////////////////////////////////////////
// GUARD PAGES
//////////////////////////////////////////////////////////////////////////
RegionSize = 1000;
Base = NULL;
ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &RegionSize, (MEM_COMMIT | MEM_RESERVE), (PAGE_GUARD | PAGE_READWRITE));
Test_NtQueryVirtualMemory(Base, RegionSize, MEM_COMMIT, (PAGE_GUARD | PAGE_READWRITE));
KmtStartSeh()
RtlCopyMemory(Base, TestString, TestStringSize);
KmtEndSeh(STATUS_GUARD_PAGE_VIOLATION);
Test_NtQueryVirtualMemory(Base, RegionSize, MEM_COMMIT, PAGE_READWRITE);
KmtStartSeh()
RtlCopyMemory(Base, TestString, TestStringSize);
KmtEndSeh(STATUS_SUCCESS);
RegionSize = 0;
ZwFreeVirtualMemory(NtCurrentProcess(), &Base, &RegionSize, MEM_RELEASE);
return Status;
}
static
VOID
CustomBaseAllocation(VOID)
{
NTSTATUS Status;
SIZE_T RegionSize = 200;
PVOID Base = (PVOID) 0x60025000;
PVOID ActualStartingAddress = (PVOID)ROUND_DOWN(Base, MM_ALLOCATION_GRANULARITY); //it is rounded down to the nearest allocation granularity (64k) address
PVOID EndingAddress = (PVOID)(((ULONG_PTR)Base + RegionSize - 1) | (PAGE_SIZE - 1));
SIZE_T ActualSize = BYTES_TO_PAGES((ULONG_PTR)EndingAddress - (ULONG_PTR)ActualStartingAddress) * PAGE_SIZE; //calculates the actual size based on the required pages
// allocate the memory
Status = ZwAllocateVirtualMemory(NtCurrentProcess(), (PVOID *)&Base, 0, &RegionSize, (MEM_COMMIT | MEM_RESERVE), PAGE_READWRITE);
ok_eq_hex(Status, STATUS_SUCCESS);
ok_eq_size(RegionSize, ActualSize);
ok_eq_ulong(Base, ActualStartingAddress);
Test_NtQueryVirtualMemory(ActualStartingAddress, ActualSize, MEM_COMMIT, PAGE_READWRITE);
// try freeing
RegionSize = 0;
Status = ZwFreeVirtualMemory(NtCurrentProcess(), (PVOID *)&Base, &RegionSize, MEM_RELEASE);
ok_eq_hex(Status, STATUS_SUCCESS);
ok_eq_ulong(RegionSize, ActualSize);
}
static
NTSTATUS
StressTesting(ULONG AllocationType)
{
NTSTATUS Status = STATUS_SUCCESS;
NTSTATUS ReturnStatus = STATUS_SUCCESS;
static PVOID bases[1024]; //assume we are going to allocate only 5 gigs. static here means the arrays is not allocated on the stack but in the BSS segment of the driver
ULONG Index = 0;
PVOID Base = NULL;
SIZE_T RegionSize = 5 * 1024 * 1024; // 5 megabytes;
RtlZeroMemory(bases, sizeof(bases));
for (Index = 0; Index < RTL_NUMBER_OF(bases) && NT_SUCCESS(Status); Index++)
{
Status = ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &RegionSize, AllocationType, PAGE_READWRITE);
bases[Index] = Base;
if ((Index % 10) == 0)
{
if (AllocationType == MEM_COMMIT && NT_SUCCESS(Status))
{
CheckBufferReadWrite(Base, TestString, TestStringSize, STATUS_SUCCESS);
}
else
{
CheckBufferReadWrite(Base, TestString, TestStringSize, STATUS_ACCESS_VIOLATION);
}
}
Base = NULL;
}
trace("Finished reserving. Error code %x. Chunks allocated: %d\n", Status, Index );
ReturnStatus = Status;
//free the allocated memory so that we can continue with the tests
Status = STATUS_SUCCESS;
Index = 0;
while (NT_SUCCESS(Status) && Index < RTL_NUMBER_OF(bases))
{
RegionSize = 0;
Status = ZwFreeVirtualMemory(NtCurrentProcess(), &bases[Index], &RegionSize, MEM_RELEASE);
bases[Index++] = NULL;
}
return ReturnStatus;
}
static
VOID
NTAPI
SystemProcessTestWorker(PVOID StartContext)
{
NTSTATUS Status = STATUS_SUCCESS;
PTEST_CONTEXT Context = (PTEST_CONTEXT)StartContext;
ULONG Index = 0;
PVOID Base = NULL;
PAGED_CODE();
RtlZeroMemory(Context->Bases, sizeof(Context->Bases));
Status = ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &Context->RegionSize, Context->AllocationType, Context->Protect);
ZwFreeVirtualMemory(NtCurrentProcess(), &Base, &Context->RegionSize, MEM_RELEASE);
Base = NULL;
//if the previous allocation has failed there is no need to do the loop
while (NT_SUCCESS(Status) && Index < RTL_NUMBER_OF(Context->Bases))
{
Status = ZwAllocateVirtualMemory(NtCurrentProcess(), &Base, 0, &Context->RegionSize, Context->AllocationType, Context->Protect);
Context->Bases[Index] = Base;
if ((Index % 10) == 0)
{
if (Context->AllocationType == MEM_COMMIT)
{
CheckBufferReadWrite(Base, TestString, TestStringSize, STATUS_SUCCESS);
}
else
{
CheckBufferReadWrite(Base, TestString, TestStringSize, STATUS_ACCESS_VIOLATION);
}
}
Base = NULL;
Index++;
}
trace("[SYSTEM THREAD %d]. Error code %x. Chunks allocated: %d\n", Context->ThreadId, Status, Index);
//free the allocated memory so that we can continue with the tests
Status = STATUS_SUCCESS;
Index = 0;
while (NT_SUCCESS(Status) && Index < RTL_NUMBER_OF(Context->Bases))
{
Context->RegionSize = 0;
Status = ZwFreeVirtualMemory(NtCurrentProcess(), &Context->Bases[Index], &Context->RegionSize, MEM_RELEASE);
Context->Bases[Index++] = NULL;
}
PsTerminateSystemThread(Status);
}
static
VOID
KmtInitTestContext(PTEST_CONTEXT Ctx, SHORT ThreadId, ULONG RegionSize, ULONG AllocationType, ULONG Protect)
{
PAGED_CODE();
Ctx->AllocationType = AllocationType;
Ctx->Protect = Protect;
Ctx->RegionSize = RegionSize;
Ctx->ThreadId = ThreadId;
}
static
VOID
SystemProcessTest(VOID)
{
NTSTATUS Status;
HANDLE Thread1 = INVALID_HANDLE_VALUE;
HANDLE Thread2 = INVALID_HANDLE_VALUE;
PVOID ThreadObjects[2] = { NULL };
OBJECT_ATTRIBUTES ObjectAttributes;
PTEST_CONTEXT StartContext1;
PTEST_CONTEXT StartContext2;
PAGED_CODE();
StartContext1 = ExAllocatePoolWithTag(PagedPool, sizeof(TEST_CONTEXT), 'tXTC');
StartContext2 = ExAllocatePoolWithTag(PagedPool, sizeof(TEST_CONTEXT), 'tXTC');
if (StartContext1 == NULL || StartContext2 == NULL)
{
trace("Error allocating space for context structs\n");
goto cleanup;
}
KmtInitTestContext(StartContext1, 1, 1 * 1024 * 1024, MEM_COMMIT, PAGE_READWRITE);
KmtInitTestContext(StartContext2, 2, 3 * 1024 * 1024, MEM_COMMIT, PAGE_READWRITE);
InitializeObjectAttributes(&ObjectAttributes, NULL, OBJ_KERNEL_HANDLE, NULL, NULL);
Status = PsCreateSystemThread(&Thread1, THREAD_ALL_ACCESS, &ObjectAttributes, NULL, NULL, SystemProcessTestWorker, StartContext1);
if (!NT_SUCCESS(Status))
{
trace("Error creating thread1\n");
goto cleanup;
}
Status = ObReferenceObjectByHandle(Thread1, THREAD_ALL_ACCESS, PsThreadType, KernelMode, &ThreadObjects[0], NULL);
if (!NT_SUCCESS(Status))
{
trace("error referencing thread1\n");
goto cleanup;
}
Status = PsCreateSystemThread(&Thread2, THREAD_ALL_ACCESS, &ObjectAttributes, NULL, NULL, SystemProcessTestWorker, StartContext2);
if (!NT_SUCCESS(Status))
{
trace("Error creating thread2\n");
goto cleanup;
}
Status = ObReferenceObjectByHandle(Thread2, THREAD_ALL_ACCESS, PsThreadType, KernelMode, &ThreadObjects[1], NULL);
if (!NT_SUCCESS(Status))
{
trace("error referencing thread2\n");
goto cleanup;
}
cleanup:
if (ThreadObjects[0])
Status = KeWaitForSingleObject(ThreadObjects[0], Executive, KernelMode, FALSE, NULL);
if (StartContext1 != NULL)
ExFreePoolWithTag(StartContext1, 'tXTC');
if (ThreadObjects[1])
Status = KeWaitForSingleObject(ThreadObjects[1], Executive, KernelMode, FALSE, NULL);
if (StartContext2 != NULL)
ExFreePoolWithTag(StartContext2, 'tXTC');
if (ThreadObjects[0] != NULL)
ObDereferenceObject(ThreadObjects[0]);
if (ThreadObjects[1] != NULL)
ObDereferenceObject(ThreadObjects[1]);
if (Thread1 != INVALID_HANDLE_VALUE)
ZwClose(Thread1);
if (Thread2 != INVALID_HANDLE_VALUE)
ZwClose(Thread2);
}
START_TEST(ZwAllocateVirtualMemory)
{
NTSTATUS Status;
SimpleErrorChecks();
SimpleAllocation();
CustomBaseAllocation();
Status = StressTesting(MEM_RESERVE);
ok_eq_hex(Status, STATUS_NO_MEMORY);
Status = STATUS_SUCCESS;
Status = StressTesting(MEM_COMMIT);
ok_eq_hex(Status, STATUS_COMMITMENT_LIMIT);
SystemProcessTest();
}