reactos/rostests/apitests/ntdll/NtAllocateVirtualMemory.c

/*
 * PROJECT:         ReactOS API Tests
 * LICENSE:         GPLv2+ - See COPYING in the top level directory
 * PURPOSE:         Stress Test for virtual memory allocation
 * PROGRAMMER:      Thomas Faber <thfabba@gmx.de>
 */

#define WIN32_NO_STATUS
#include <stdio.h>
#include <wine/test.h>
#include <ndk/rtlfuncs.h>
#include <ndk/mmfuncs.h>

static PVOID Allocations[4096] = { NULL };
static ULONG CurrentAllocation = 0;

static
VOID
ValidateAllocations(VOID)
{
    ULONG i;

    ASSERT(CurrentAllocation < sizeof(Allocations) / sizeof(Allocations[0]));
    for (i = 0; i < CurrentAllocation; ++i)
    {
        PUCHAR UserBuffer = Allocations[i];
        SIZE_T AllocationSize;
        SIZE_T DataSize;

        if (UserBuffer == NULL)
            continue;

        AllocationSize = ((PSIZE_T)UserBuffer)[-2];
        DataSize = ((PSIZE_T)UserBuffer)[-1];
        ASSERT(DataSize != 0);
        ASSERT(((SIZE_T)UserBuffer + DataSize) % PAGE_SIZE == 0);
    }
}

static
PVOID
Allocate(
    SIZE_T DataSize)
{
    NTSTATUS Status;
    PVOID AllocationStart = NULL;
    SIZE_T AllocationSize = PAGE_ROUND_UP(DataSize + PAGE_SIZE + 2 * sizeof(SIZE_T));
    PVOID FirstPageStart;
    SIZE_T NumberOfPages = AllocationSize / PAGE_SIZE;
    SIZE_T Size;
    PUCHAR UserBuffer;

    Status = NtAllocateVirtualMemory(NtCurrentProcess(), &AllocationStart, 0, &AllocationSize, MEM_RESERVE, PAGE_NOACCESS);

    if (!NT_SUCCESS(Status))
        return NULL;

    FirstPageStart = (PUCHAR)AllocationStart + AllocationSize - PAGE_SIZE * NumberOfPages;
    Size = (NumberOfPages - 1) * PAGE_SIZE;
    Status = NtAllocateVirtualMemory(NtCurrentProcess(), &FirstPageStart, 0, &Size, MEM_COMMIT, PAGE_READWRITE);
    if (!NT_SUCCESS(Status))
    {
        Size = 0;
        Status = NtFreeVirtualMemory(NtCurrentProcess(), &AllocationStart, &AllocationSize, MEM_RELEASE);
        ASSERT(Status == STATUS_SUCCESS);
        return NULL;
    }

    UserBuffer = AllocationStart;
    UserBuffer += AllocationSize - PAGE_SIZE - DataSize;
    RtlFillMemory(FirstPageStart, UserBuffer - (PUCHAR)FirstPageStart, 0xae);
    RtlZeroMemory(UserBuffer, DataSize);
    ((PSIZE_T)UserBuffer)[-2] = AllocationSize;
    ((PSIZE_T)UserBuffer)[-1] = DataSize;

    Allocations[CurrentAllocation++] = UserBuffer;
    ValidateAllocations();
    return UserBuffer;
}

static
VOID
Free(
    PVOID UserBuffer)
{
    NTSTATUS Status;
    PVOID AllocationStart;
    SIZE_T Zero = 0;
    SIZE_T AllocationSize;
    SIZE_T DataSize;
    ULONG i;

    AllocationSize = ((PSIZE_T)UserBuffer)[-2];
    DataSize = ((PSIZE_T)UserBuffer)[-1];
    ASSERT(DataSize != 0);

    AllocationStart = (PUCHAR)UserBuffer + DataSize + PAGE_SIZE - AllocationSize;
    ASSERT((SIZE_T)AllocationStart % PAGE_SIZE == 0);

    RtlFillMemory(UserBuffer, DataSize, 0xbe);
    ((PSIZE_T)UserBuffer)[-1] = 0;
    ((PSIZE_T)UserBuffer)[-2] = 0xFAFBFCFD;

    for (i = 0; i < CurrentAllocation; ++i)
        if (Allocations[i] == UserBuffer)
        {
            Allocations[i] = NULL;
            break;
        }
    ValidateAllocations();

    Status = NtFreeVirtualMemory(NtCurrentProcess(), &AllocationStart, &Zero, MEM_RELEASE);
    ASSERT(Status == STATUS_SUCCESS);
}

static
PVOID
ReAllocate(
    PVOID OldUserBuffer,
    SIZE_T NewDataSize)
{
    PVOID NewUserBuffer;
    SIZE_T OldDataSize;

    OldDataSize = ((PSIZE_T)OldUserBuffer)[-1];
    ASSERT(OldDataSize != 0);

    NewUserBuffer = Allocate(NewDataSize);
    ASSERT(((PSIZE_T)OldUserBuffer)[-1] == OldDataSize);
    RtlCopyMemory(NewUserBuffer, OldUserBuffer, min(OldDataSize, NewDataSize));
    ASSERT(((PSIZE_T)OldUserBuffer)[-1] == OldDataSize);
    Free(OldUserBuffer);
    return NewUserBuffer;
}

static
VOID
AccessMemory1(
    PVOID UserBuffer,
    SIZE_T DataSize)
{
    PBYTE Buffer = UserBuffer;
    SIZE_T i;

    for (i = 0; i < DataSize; ++i)
        Buffer[i] = LOBYTE(i);
}

static
BOOLEAN
CheckMemory1(
    PVOID UserBuffer,
    SIZE_T DataSize)
{
    PBYTE Buffer = UserBuffer;
    SIZE_T i;

    for (i = 0; i < DataSize; ++i)
        if (Buffer[i] != LOBYTE(i))
        {
            trace("Mismatch in region %p at index %lu. Value=%02x\n", UserBuffer, (ULONG)i, Buffer[i]);
            ASSERT(FALSE);
            return FALSE;
        }
    return TRUE;
}

static
VOID
AccessMemory2(
    PVOID UserBuffer,
    SIZE_T DataSize)
{
    PBYTE Buffer = UserBuffer;
    SIZE_T i;

    for (i = 0; i < DataSize; ++i)
        Buffer[i] = UCHAR_MAX - LOBYTE(i);
}

static
BOOLEAN
CheckMemory2(
    PVOID UserBuffer,
    SIZE_T DataSize)
{
    PBYTE Buffer = UserBuffer;
    SIZE_T i;

    for (i = 0; i < DataSize; ++i)
        if (Buffer[i] != UCHAR_MAX - LOBYTE(i))
        {
            trace("Mismatch in region %p at index %lu. Value=%02x\n", UserBuffer, (ULONG)i, Buffer[i]);
            ASSERT(FALSE);
            return FALSE;
        }
    return TRUE;
}

#define RUNS 32

START_TEST(NtAllocateVirtualMemory)
{
    PVOID Mem1, Mem2;
    SIZE_T Size1, Size2;
    ULONG i;

    Size1 = 32;
    Mem1 = Allocate(Size1);
    AccessMemory1(Mem1, Size1);
    Size2 = 128;
    Mem2 = Allocate(Size2);
    AccessMemory2(Mem2, Size2);
    for (i = 0; i < RUNS; ++i)
    {
        PVOID New;
        ok(CheckMemory1(Mem1, Size1) == TRUE, "CheckMemory1 failure\n");
        New = ReAllocate(Mem1, Size1 * 3 / 2);
        if (New == NULL)
        {
            skip("Realloc failure\n");
            break;
        }
        Mem1 = New;
        ok(CheckMemory1(Mem1, Size1) == TRUE, "CheckMemory1 failure\n");
        Size1 = Size1 * 3 / 2;
        AccessMemory1(Mem1, Size1);

        ok(CheckMemory2(Mem2, Size2) == TRUE, "CheckMemory2 failure\n");
        New = ReAllocate(Mem2, Size2 + 128);
        if (New == NULL)
        {
            skip("Realloc failure\n");
            break;
        }
        Mem2 = New;
        ok(CheckMemory2(Mem2, Size2) == TRUE, "CheckMemory2 failure\n");
        Size2 += 128;
        AccessMemory2(Mem2, Size2);
    }
    ok(CheckMemory2(Mem2, Size2) == TRUE, "CheckMemory2 failure\n");
    Free(Mem2);
    ok(CheckMemory1(Mem1, Size1) == TRUE, "CheckMemory1 failure\n");
    Free(Mem1);
}
[NTDLL_APITEST] - Add NtAllocateVirtualMemory test, which is a small stress test for virtual memory allocation/freeing/reuse - Can be used to reproduce bug 5857 in third stage (install with VT-x enabled, then disable for the test) - Shows that the bug is a race condition in Mm, and not heap's fault - I've put ASSERTs instead of ok's for easier debugging svn path=/trunk/; revision=54548 2011-11-30 17:00:23 +00:00			`/*`
			`* PROJECT: ReactOS API Tests`
			`* LICENSE: GPLv2+ - See COPYING in the top level directory`
			`* PURPOSE: Stress Test for virtual memory allocation`
			`* PROGRAMMER: Thomas Faber <thfabba@gmx.de>`
			`*/`

			`#define WIN32_NO_STATUS`
			`#include <stdio.h>`
			`#include <wine/test.h>`
			`#include <ndk/rtlfuncs.h>`
			`#include <ndk/mmfuncs.h>`

			`static PVOID Allocations[4096] = { NULL };`
			`static ULONG CurrentAllocation = 0;`

			`static`
			`VOID`
			`ValidateAllocations(VOID)`
			`{`
			`ULONG i;`

			`ASSERT(CurrentAllocation < sizeof(Allocations) / sizeof(Allocations[0]));`
			`for (i = 0; i < CurrentAllocation; ++i)`
			`{`
			`PUCHAR UserBuffer = Allocations[i];`
			`SIZE_T AllocationSize;`
			`SIZE_T DataSize;`

			`if (UserBuffer == NULL)`
			`continue;`

			`AllocationSize = ((PSIZE_T)UserBuffer)[-2];`
			`DataSize = ((PSIZE_T)UserBuffer)[-1];`
			`ASSERT(DataSize != 0);`
			`ASSERT(((SIZE_T)UserBuffer + DataSize) % PAGE_SIZE == 0);`
			`}`
			`}`

			`static`
			`PVOID`
			`Allocate(`
			`SIZE_T DataSize)`
			`{`
			`NTSTATUS Status;`
			`PVOID AllocationStart = NULL;`
			`SIZE_T AllocationSize = PAGE_ROUND_UP(DataSize + PAGE_SIZE + 2 * sizeof(SIZE_T));`
			`PVOID FirstPageStart;`
			`SIZE_T NumberOfPages = AllocationSize / PAGE_SIZE;`
			`SIZE_T Size;`
			`PUCHAR UserBuffer;`

			`Status = NtAllocateVirtualMemory(NtCurrentProcess(), &AllocationStart, 0, &AllocationSize, MEM_RESERVE, PAGE_NOACCESS);`

			`if (!NT_SUCCESS(Status))`
			`return NULL;`

			`FirstPageStart = (PUCHAR)AllocationStart + AllocationSize - PAGE_SIZE * NumberOfPages;`
			`Size = (NumberOfPages - 1) * PAGE_SIZE;`
			`Status = NtAllocateVirtualMemory(NtCurrentProcess(), &FirstPageStart, 0, &Size, MEM_COMMIT, PAGE_READWRITE);`
			`if (!NT_SUCCESS(Status))`
			`{`
			`Size = 0;`
			`Status = NtFreeVirtualMemory(NtCurrentProcess(), &AllocationStart, &AllocationSize, MEM_RELEASE);`
			`ASSERT(Status == STATUS_SUCCESS);`
			`return NULL;`
			`}`

			`UserBuffer = AllocationStart;`
			`UserBuffer += AllocationSize - PAGE_SIZE - DataSize;`
			`RtlFillMemory(FirstPageStart, UserBuffer - (PUCHAR)FirstPageStart, 0xae);`
			`RtlZeroMemory(UserBuffer, DataSize);`
			`((PSIZE_T)UserBuffer)[-2] = AllocationSize;`
			`((PSIZE_T)UserBuffer)[-1] = DataSize;`

			`Allocations[CurrentAllocation++] = UserBuffer;`
			`ValidateAllocations();`
			`return UserBuffer;`
			`}`

			`static`
			`VOID`
			`Free(`
			`PVOID UserBuffer)`
			`{`
			`NTSTATUS Status;`
			`PVOID AllocationStart;`
			`SIZE_T Zero = 0;`
			`SIZE_T AllocationSize;`
			`SIZE_T DataSize;`
			`ULONG i;`

			`AllocationSize = ((PSIZE_T)UserBuffer)[-2];`
			`DataSize = ((PSIZE_T)UserBuffer)[-1];`
			`ASSERT(DataSize != 0);`

			`AllocationStart = (PUCHAR)UserBuffer + DataSize + PAGE_SIZE - AllocationSize;`
			`ASSERT((SIZE_T)AllocationStart % PAGE_SIZE == 0);`

			`RtlFillMemory(UserBuffer, DataSize, 0xbe);`
			`((PSIZE_T)UserBuffer)[-1] = 0;`
			`((PSIZE_T)UserBuffer)[-2] = 0xFAFBFCFD;`

			`for (i = 0; i < CurrentAllocation; ++i)`
			`if (Allocations[i] == UserBuffer)`
			`{`
			`Allocations[i] = NULL;`
			`break;`
			`}`
			`ValidateAllocations();`

			`Status = NtFreeVirtualMemory(NtCurrentProcess(), &AllocationStart, &Zero, MEM_RELEASE);`
			`ASSERT(Status == STATUS_SUCCESS);`
			`}`

			`static`
			`PVOID`
			`ReAllocate(`
			`PVOID OldUserBuffer,`
			`SIZE_T NewDataSize)`
			`{`
			`PVOID NewUserBuffer;`
			`SIZE_T OldDataSize;`

			`OldDataSize = ((PSIZE_T)OldUserBuffer)[-1];`
			`ASSERT(OldDataSize != 0);`

			`NewUserBuffer = Allocate(NewDataSize);`
			`ASSERT(((PSIZE_T)OldUserBuffer)[-1] == OldDataSize);`
			`RtlCopyMemory(NewUserBuffer, OldUserBuffer, min(OldDataSize, NewDataSize));`
			`ASSERT(((PSIZE_T)OldUserBuffer)[-1] == OldDataSize);`
			`Free(OldUserBuffer);`
			`return NewUserBuffer;`
			`}`

			`static`
			`VOID`
			`AccessMemory1(`
			`PVOID UserBuffer,`
			`SIZE_T DataSize)`
			`{`
			`PBYTE Buffer = UserBuffer;`
			`SIZE_T i;`

			`for (i = 0; i < DataSize; ++i)`
			`Buffer[i] = LOBYTE(i);`
			`}`

			`static`
			`BOOLEAN`
			`CheckMemory1(`
			`PVOID UserBuffer,`
			`SIZE_T DataSize)`
			`{`
			`PBYTE Buffer = UserBuffer;`
			`SIZE_T i;`

			`for (i = 0; i < DataSize; ++i)`
			`if (Buffer[i] != LOBYTE(i))`
			`{`
			`trace("Mismatch in region %p at index %lu. Value=%02x\n", UserBuffer, (ULONG)i, Buffer[i]);`
			`ASSERT(FALSE);`
			`return FALSE;`
			`}`
			`return TRUE;`
			`}`

			`static`
			`VOID`
			`AccessMemory2(`
			`PVOID UserBuffer,`
			`SIZE_T DataSize)`
			`{`
			`PBYTE Buffer = UserBuffer;`
			`SIZE_T i;`

			`for (i = 0; i < DataSize; ++i)`
			`Buffer[i] = UCHAR_MAX - LOBYTE(i);`
			`}`

			`static`
			`BOOLEAN`
			`CheckMemory2(`
			`PVOID UserBuffer,`
			`SIZE_T DataSize)`
			`{`
			`PBYTE Buffer = UserBuffer;`
			`SIZE_T i;`

			`for (i = 0; i < DataSize; ++i)`
			`if (Buffer[i] != UCHAR_MAX - LOBYTE(i))`
			`{`
			`trace("Mismatch in region %p at index %lu. Value=%02x\n", UserBuffer, (ULONG)i, Buffer[i]);`
			`ASSERT(FALSE);`
			`return FALSE;`
			`}`
			`return TRUE;`
			`}`

			`#define RUNS 32`

			`START_TEST(NtAllocateVirtualMemory)`
			`{`
			`PVOID Mem1, Mem2;`
			`SIZE_T Size1, Size2;`
			`ULONG i;`

			`Size1 = 32;`
			`Mem1 = Allocate(Size1);`
			`AccessMemory1(Mem1, Size1);`
			`Size2 = 128;`
			`Mem2 = Allocate(Size2);`
			`AccessMemory2(Mem2, Size2);`
			`for (i = 0; i < RUNS; ++i)`
			`{`
			`PVOID New;`
			`ok(CheckMemory1(Mem1, Size1) == TRUE, "CheckMemory1 failure\n");`
			`New = ReAllocate(Mem1, Size1 * 3 / 2);`
			`if (New == NULL)`
			`{`
			`skip("Realloc failure\n");`
			`break;`
			`}`
			`Mem1 = New;`
			`ok(CheckMemory1(Mem1, Size1) == TRUE, "CheckMemory1 failure\n");`
			`Size1 = Size1 * 3 / 2;`
			`AccessMemory1(Mem1, Size1);`

			`ok(CheckMemory2(Mem2, Size2) == TRUE, "CheckMemory2 failure\n");`
			`New = ReAllocate(Mem2, Size2 + 128);`
			`if (New == NULL)`
			`{`
			`skip("Realloc failure\n");`
			`break;`
			`}`
			`Mem2 = New;`
			`ok(CheckMemory2(Mem2, Size2) == TRUE, "CheckMemory2 failure\n");`
			`Size2 += 128;`
			`AccessMemory2(Mem2, Size2);`
			`}`
			`ok(CheckMemory2(Mem2, Size2) == TRUE, "CheckMemory2 failure\n");`
			`Free(Mem2);`
			`ok(CheckMemory1(Mem1, Size1) == TRUE, "CheckMemory1 failure\n");`
			`Free(Mem1);`
			`}`