reactos/rostests/kmtests/ntos_ex/ExFastMutex.c
Timo Kreuzer bccd8b7aea [KMTEST]
Revert the DDK compatibility hack and apply a real fix. I kept the hack for NDK exports, we should consider changing them as well for consistency reasons.

svn path=/trunk/; revision=63268
2014-05-12 23:36:05 +00:00

311 lines
11 KiB
C

/*
* PROJECT: ReactOS kernel-mode tests
* LICENSE: GPLv2+ - See COPYING in the top level directory
* PURPOSE: Kernel-Mode Test Suite Fast Mutex test
* PROGRAMMER: Thomas Faber <thomas.faber@reactos.org>
*/
#include <kmt_test.h>
//#define NDEBUG
#include <debug.h>
NTKERNELAPI VOID FASTCALL ExiAcquireFastMutex(IN OUT PFAST_MUTEX FastMutex);
NTKERNELAPI VOID FASTCALL ExiReleaseFastMutex(IN OUT PFAST_MUTEX FastMutex);
NTKERNELAPI BOOLEAN FASTCALL ExiTryToAcquireFastMutex(IN OUT PFAST_MUTEX FastMutex);
#define CheckMutex(Mutex, ExpectedCount, ExpectedOwner, \
ExpectedContention, ExpectedOldIrql, \
ExpectedIrql) do \
{ \
ok_eq_long((Mutex)->Count, ExpectedCount); \
ok_eq_pointer((Mutex)->Owner, ExpectedOwner); \
ok_eq_ulong((Mutex)->Contention, ExpectedContention); \
ok_eq_ulong((Mutex)->OldIrql, (ULONG)ExpectedOldIrql); \
ok_bool_false(KeAreApcsDisabled(), "KeAreApcsDisabled returned"); \
ok_irql(ExpectedIrql); \
} while (0)
static
VOID
TestFastMutex(
PFAST_MUTEX Mutex,
KIRQL OriginalIrql)
{
PKTHREAD Thread = KeGetCurrentThread();
ok_irql(OriginalIrql);
/* acquire/release normally */
ExAcquireFastMutex(Mutex);
CheckMutex(Mutex, 0L, Thread, 0LU, OriginalIrql, APC_LEVEL);
ok_bool_false(ExTryToAcquireFastMutex(Mutex), "ExTryToAcquireFastMutex returned");
CheckMutex(Mutex, 0L, Thread, 0LU, OriginalIrql, APC_LEVEL);
ExReleaseFastMutex(Mutex);
CheckMutex(Mutex, 1L, NULL, 0LU, OriginalIrql, OriginalIrql);
#ifdef _M_IX86
/* ntoskrnl's fastcall version */
ExiAcquireFastMutex(Mutex);
CheckMutex(Mutex, 0L, Thread, 0LU, OriginalIrql, APC_LEVEL);
ok_bool_false(ExiTryToAcquireFastMutex(Mutex), "ExiTryToAcquireFastMutex returned");
CheckMutex(Mutex, 0L, Thread, 0LU, OriginalIrql, APC_LEVEL);
ExiReleaseFastMutex(Mutex);
CheckMutex(Mutex, 1L, NULL, 0LU, OriginalIrql, OriginalIrql);
#endif
/* try to acquire */
ok_bool_true(ExTryToAcquireFastMutex(Mutex), "ExTryToAcquireFastMutex returned");
CheckMutex(Mutex, 0L, Thread, 0LU, OriginalIrql, APC_LEVEL);
ExReleaseFastMutex(Mutex);
CheckMutex(Mutex, 1L, NULL, 0LU, OriginalIrql, OriginalIrql);
/* shortcut functions with critical region */
ExEnterCriticalRegionAndAcquireFastMutexUnsafe(Mutex);
ok_bool_true(KeAreApcsDisabled(), "KeAreApcsDisabled returned");
ExReleaseFastMutexUnsafeAndLeaveCriticalRegion(Mutex);
/* acquire/release unsafe */
if (!KmtIsCheckedBuild || OriginalIrql == APC_LEVEL)
{
ExAcquireFastMutexUnsafe(Mutex);
CheckMutex(Mutex, 0L, Thread, 0LU, OriginalIrql, OriginalIrql);
ExReleaseFastMutexUnsafe(Mutex);
CheckMutex(Mutex, 1L, NULL, 0LU, OriginalIrql, OriginalIrql);
/* mismatched acquire/release */
ExAcquireFastMutex(Mutex);
CheckMutex(Mutex, 0L, Thread, 0LU, OriginalIrql, APC_LEVEL);
ExReleaseFastMutexUnsafe(Mutex);
CheckMutex(Mutex, 1L, NULL, 0LU, OriginalIrql, APC_LEVEL);
KmtSetIrql(OriginalIrql);
CheckMutex(Mutex, 1L, NULL, 0LU, OriginalIrql, OriginalIrql);
Mutex->OldIrql = 0x55555555LU;
ExAcquireFastMutexUnsafe(Mutex);
CheckMutex(Mutex, 0L, Thread, 0LU, 0x55555555LU, OriginalIrql);
Mutex->OldIrql = PASSIVE_LEVEL;
ExReleaseFastMutex(Mutex);
CheckMutex(Mutex, 1L, NULL, 0LU, PASSIVE_LEVEL, PASSIVE_LEVEL);
KmtSetIrql(OriginalIrql);
CheckMutex(Mutex, 1L, NULL, 0LU, PASSIVE_LEVEL, OriginalIrql);
}
if (!KmtIsCheckedBuild)
{
/* release without acquire */
ExReleaseFastMutexUnsafe(Mutex);
CheckMutex(Mutex, 2L, NULL, 0LU, PASSIVE_LEVEL, OriginalIrql);
--Mutex->Count;
Mutex->OldIrql = OriginalIrql;
ExReleaseFastMutex(Mutex);
CheckMutex(Mutex, 2L, NULL, 0LU, OriginalIrql, OriginalIrql);
ExReleaseFastMutex(Mutex);
CheckMutex(Mutex, 3L, NULL, 0LU, OriginalIrql, OriginalIrql);
Mutex->Count -= 2;
}
/* make sure we survive this in case of error */
ok_eq_long(Mutex->Count, 1L);
Mutex->Count = 1;
ok_irql(OriginalIrql);
KmtSetIrql(OriginalIrql);
}
typedef VOID (FASTCALL *PMUTEX_FUNCTION)(PFAST_MUTEX);
typedef BOOLEAN (FASTCALL *PMUTEX_TRY_FUNCTION)(PFAST_MUTEX);
typedef struct
{
HANDLE Handle;
PKTHREAD Thread;
KIRQL Irql;
PFAST_MUTEX Mutex;
PMUTEX_FUNCTION Acquire;
PMUTEX_TRY_FUNCTION TryAcquire;
PMUTEX_FUNCTION Release;
BOOLEAN Try;
BOOLEAN RetExpected;
KEVENT InEvent;
KEVENT OutEvent;
} THREAD_DATA, *PTHREAD_DATA;
static
VOID
NTAPI
AcquireMutexThread(
PVOID Parameter)
{
PTHREAD_DATA ThreadData = Parameter;
KIRQL Irql;
BOOLEAN Ret = FALSE;
NTSTATUS Status;
KeRaiseIrql(ThreadData->Irql, &Irql);
if (ThreadData->Try)
{
Ret = ThreadData->TryAcquire(ThreadData->Mutex);
ok_eq_bool(Ret, ThreadData->RetExpected);
}
else
ThreadData->Acquire(ThreadData->Mutex);
ok_bool_false(KeSetEvent(&ThreadData->OutEvent, 0, TRUE), "KeSetEvent returned");
Status = KeWaitForSingleObject(&ThreadData->InEvent, Executive, KernelMode, FALSE, NULL);
ok_eq_hex(Status, STATUS_SUCCESS);
if (!ThreadData->Try || Ret)
ThreadData->Release(ThreadData->Mutex);
KeLowerIrql(Irql);
}
static
VOID
InitThreadData(
PTHREAD_DATA ThreadData,
PFAST_MUTEX Mutex,
PMUTEX_FUNCTION Acquire,
PMUTEX_TRY_FUNCTION TryAcquire,
PMUTEX_FUNCTION Release)
{
ThreadData->Mutex = Mutex;
KeInitializeEvent(&ThreadData->InEvent, NotificationEvent, FALSE);
KeInitializeEvent(&ThreadData->OutEvent, NotificationEvent, FALSE);
ThreadData->Acquire = Acquire;
ThreadData->TryAcquire = TryAcquire;
ThreadData->Release = Release;
}
static
NTSTATUS
StartThread(
PTHREAD_DATA ThreadData,
PLARGE_INTEGER Timeout,
KIRQL Irql,
BOOLEAN Try,
BOOLEAN RetExpected)
{
NTSTATUS Status = STATUS_SUCCESS;
OBJECT_ATTRIBUTES Attributes;
ThreadData->Try = Try;
ThreadData->Irql = Irql;
ThreadData->RetExpected = RetExpected;
InitializeObjectAttributes(&Attributes, NULL, OBJ_KERNEL_HANDLE, NULL, NULL);
Status = PsCreateSystemThread(&ThreadData->Handle, GENERIC_ALL, &Attributes, NULL, NULL, AcquireMutexThread, ThreadData);
ok_eq_hex(Status, STATUS_SUCCESS);
Status = ObReferenceObjectByHandle(ThreadData->Handle, SYNCHRONIZE, *PsThreadType, KernelMode, (PVOID *)&ThreadData->Thread, NULL);
ok_eq_hex(Status, STATUS_SUCCESS);
return KeWaitForSingleObject(&ThreadData->OutEvent, Executive, KernelMode, FALSE, Timeout);
}
static
VOID
FinishThread(
PTHREAD_DATA ThreadData)
{
NTSTATUS Status = STATUS_SUCCESS;
KeSetEvent(&ThreadData->InEvent, 0, TRUE);
Status = KeWaitForSingleObject(ThreadData->Thread, Executive, KernelMode, FALSE, NULL);
ok_eq_hex(Status, STATUS_SUCCESS);
ObDereferenceObject(ThreadData->Thread);
Status = ZwClose(ThreadData->Handle);
ok_eq_hex(Status, STATUS_SUCCESS);
KeClearEvent(&ThreadData->InEvent);
KeClearEvent(&ThreadData->OutEvent);
}
static
VOID
TestFastMutexConcurrent(
PFAST_MUTEX Mutex)
{
NTSTATUS Status;
THREAD_DATA ThreadData;
THREAD_DATA ThreadData2;
THREAD_DATA ThreadDataUnsafe;
THREAD_DATA ThreadDataTry;
LARGE_INTEGER Timeout;
Timeout.QuadPart = -10 * 1000 * 10; /* 10 ms */
InitThreadData(&ThreadData, Mutex, ExAcquireFastMutex, NULL, ExReleaseFastMutex);
InitThreadData(&ThreadData2, Mutex, ExAcquireFastMutex, NULL, ExReleaseFastMutex);
InitThreadData(&ThreadDataUnsafe, Mutex, ExAcquireFastMutexUnsafe, NULL, ExReleaseFastMutexUnsafe);
InitThreadData(&ThreadDataTry, Mutex, NULL, ExTryToAcquireFastMutex, ExReleaseFastMutex);
/* have a thread acquire the mutex */
Status = StartThread(&ThreadData, NULL, PASSIVE_LEVEL, FALSE, FALSE);
ok_eq_hex(Status, STATUS_SUCCESS);
CheckMutex(Mutex, 0L, ThreadData.Thread, 0LU, PASSIVE_LEVEL, PASSIVE_LEVEL);
/* have a second thread try to acquire it -- should fail */
Status = StartThread(&ThreadDataTry, NULL, PASSIVE_LEVEL, TRUE, FALSE);
ok_eq_hex(Status, STATUS_SUCCESS);
CheckMutex(Mutex, 0L, ThreadData.Thread, 0LU, PASSIVE_LEVEL, PASSIVE_LEVEL);
FinishThread(&ThreadDataTry);
/* have another thread acquire it -- should block */
Status = StartThread(&ThreadData2, &Timeout, APC_LEVEL, FALSE, FALSE);
ok_eq_hex(Status, STATUS_TIMEOUT);
CheckMutex(Mutex, -1L, ThreadData.Thread, 1LU, PASSIVE_LEVEL, PASSIVE_LEVEL);
/* finish the first thread -- now the second should become available */
FinishThread(&ThreadData);
Status = KeWaitForSingleObject(&ThreadData2.OutEvent, Executive, KernelMode, FALSE, NULL);
ok_eq_hex(Status, STATUS_SUCCESS);
CheckMutex(Mutex, 0L, ThreadData2.Thread, 1LU, APC_LEVEL, PASSIVE_LEVEL);
/* block two more threads */
Status = StartThread(&ThreadDataUnsafe, &Timeout, APC_LEVEL, FALSE, FALSE);
ok_eq_hex(Status, STATUS_TIMEOUT);
CheckMutex(Mutex, -1L, ThreadData2.Thread, 2LU, APC_LEVEL, PASSIVE_LEVEL);
Status = StartThread(&ThreadData, &Timeout, PASSIVE_LEVEL, FALSE, FALSE);
ok_eq_hex(Status, STATUS_TIMEOUT);
CheckMutex(Mutex, -2L, ThreadData2.Thread, 3LU, APC_LEVEL, PASSIVE_LEVEL);
/* finish 1 */
FinishThread(&ThreadData2);
Status = KeWaitForSingleObject(&ThreadDataUnsafe.OutEvent, Executive, KernelMode, FALSE, NULL);
ok_eq_hex(Status, STATUS_SUCCESS);
CheckMutex(Mutex, -1L, ThreadDataUnsafe.Thread, 3LU, APC_LEVEL, PASSIVE_LEVEL);
/* finish 2 */
FinishThread(&ThreadDataUnsafe);
Status = KeWaitForSingleObject(&ThreadData.OutEvent, Executive, KernelMode, FALSE, NULL);
ok_eq_hex(Status, STATUS_SUCCESS);
CheckMutex(Mutex, 0L, ThreadData.Thread, 3LU, PASSIVE_LEVEL, PASSIVE_LEVEL);
/* finish 3 */
FinishThread(&ThreadData);
CheckMutex(Mutex, 1L, NULL, 3LU, PASSIVE_LEVEL, PASSIVE_LEVEL);
}
START_TEST(ExFastMutex)
{
FAST_MUTEX Mutex;
KIRQL Irql;
memset(&Mutex, 0x55, sizeof Mutex);
ExInitializeFastMutex(&Mutex);
CheckMutex(&Mutex, 1L, NULL, 0LU, 0x55555555LU, PASSIVE_LEVEL);
TestFastMutex(&Mutex, PASSIVE_LEVEL);
KeRaiseIrql(APC_LEVEL, &Irql);
TestFastMutex(&Mutex, APC_LEVEL);
if (!KmtIsCheckedBuild)
{
KeRaiseIrql(DISPATCH_LEVEL, &Irql);
TestFastMutex(&Mutex, DISPATCH_LEVEL);
KeRaiseIrql(HIGH_LEVEL, &Irql);
TestFastMutex(&Mutex, HIGH_LEVEL);
}
KeLowerIrql(PASSIVE_LEVEL);
TestFastMutexConcurrent(&Mutex);
}