/*******************************************************************************
**
**  gckKERNEL_Dispatch
**
**  Dispatch a command received from the user HAL layer.
**
**  INPUT:
**
**      gckKERNEL Kernel
**          Pointer to an gckKERNEL object.
**
**      gcsHAL_INTERFACE * Interface
**          Pointer to a gcsHAL_INTERFACE structure that defines the command to
**          be dispatched.
**
**  OUTPUT:
**
**      gcsHAL_INTERFACE * Interface
**          Pointer to a gcsHAL_INTERFACE structure that receives any data to be
**          returned.
*/
gceSTATUS gckVGKERNEL_Dispatch(
    IN gckKERNEL Kernel,
    IN gctBOOL FromUser,
    IN OUT gcsHAL_INTERFACE * Interface
    )
{
    gceSTATUS status;
    gcsHAL_INTERFACE * kernelInterface = Interface;
    gcuVIDMEM_NODE_PTR node;
    gctUINT32 processID;

    gcmkHEADER_ARG("Kernel=0x%x Interface=0x%x ", Kernel, Interface);

    /* Verify the arguments. */
    gcmkVERIFY_OBJECT(Kernel, gcvOBJ_KERNEL);
    gcmkVERIFY_ARGUMENT(Interface != gcvNULL);

    gcmkONERROR(gckOS_GetProcessID(&processID));

    /* Dispatch on command. */
    switch (Interface->command)
    {
    case gcvHAL_QUERY_VIDEO_MEMORY:
        /* Query video memory size. */
        gcmkERR_BREAK(gckKERNEL_QueryVideoMemory(
            Kernel, kernelInterface
            ));
        break;

    case gcvHAL_QUERY_CHIP_IDENTITY:
        /* Query chip identity. */
        gcmkERR_BREAK(gckVGHARDWARE_QueryChipIdentity(
            Kernel->vg->hardware,
            &kernelInterface->u.QueryChipIdentity.chipModel,
            &kernelInterface->u.QueryChipIdentity.chipRevision,
            &kernelInterface->u.QueryChipIdentity.chipFeatures,
            &kernelInterface->u.QueryChipIdentity.chipMinorFeatures,
            &kernelInterface->u.QueryChipIdentity.chipMinorFeatures2
            ));
        break;

    case gcvHAL_QUERY_COMMAND_BUFFER:
        /* Query command buffer information. */
        gcmkERR_BREAK(gckKERNEL_QueryCommandBuffer(
            Kernel,
            &kernelInterface->u.QueryCommandBuffer.information
            ));
        break;
    case gcvHAL_ALLOCATE_NON_PAGED_MEMORY:
        /* Allocate non-paged memory. */
        gcmkERR_BREAK(gckOS_AllocateContiguous(
            Kernel->os,
            gcvTRUE,
            &kernelInterface->u.AllocateNonPagedMemory.bytes,
            &kernelInterface->u.AllocateNonPagedMemory.physical,
            &kernelInterface->u.AllocateNonPagedMemory.logical
            ));
        break;

    case gcvHAL_FREE_NON_PAGED_MEMORY:
        /* Unmap user logical out of physical memory first. */
        gcmkERR_BREAK(gckOS_UnmapUserLogical(
            Kernel->os,
            kernelInterface->u.AllocateNonPagedMemory.physical,
            kernelInterface->u.AllocateNonPagedMemory.bytes,
            kernelInterface->u.AllocateNonPagedMemory.logical
            ));

        /* Free non-paged memory. */
        gcmkERR_BREAK(gckOS_FreeNonPagedMemory(
            Kernel->os,
            kernelInterface->u.AllocateNonPagedMemory.bytes,
            kernelInterface->u.AllocateNonPagedMemory.physical,
            kernelInterface->u.AllocateNonPagedMemory.logical
            ));
        break;

    case gcvHAL_ALLOCATE_CONTIGUOUS_MEMORY:
        /* Allocate contiguous memory. */
        gcmkERR_BREAK(gckOS_AllocateContiguous(
            Kernel->os,
            gcvTRUE,
            &kernelInterface->u.AllocateNonPagedMemory.bytes,
            &kernelInterface->u.AllocateNonPagedMemory.physical,
            &kernelInterface->u.AllocateNonPagedMemory.logical
            ));
        break;

    case gcvHAL_FREE_CONTIGUOUS_MEMORY:
        /* Unmap user logical out of physical memory first. */
        gcmkERR_BREAK(gckOS_UnmapUserLogical(
            Kernel->os,
            kernelInterface->u.AllocateNonPagedMemory.physical,
            kernelInterface->u.AllocateNonPagedMemory.bytes,
            kernelInterface->u.AllocateNonPagedMemory.logical
            ));

        /* Free contiguous memory. */
        gcmkERR_BREAK(gckOS_FreeContiguous(
            Kernel->os,
            kernelInterface->u.AllocateNonPagedMemory.physical,
            kernelInterface->u.AllocateNonPagedMemory.logical,
            kernelInterface->u.AllocateNonPagedMemory.bytes
            ));
        break;

    case gcvHAL_ALLOCATE_VIDEO_MEMORY:
        {
            gctSIZE_T bytes;
            gctUINT32 bitsPerPixel;
            gctUINT32 bits;

            /* Align width and height to tiles. */
            gcmkERR_BREAK(gckVGHARDWARE_AlignToTile(
                Kernel->vg->hardware,
                kernelInterface->u.AllocateVideoMemory.type,
                &kernelInterface->u.AllocateVideoMemory.width,
                &kernelInterface->u.AllocateVideoMemory.height
                ));

            /* Convert format into bytes per pixel and bytes per tile. */
            gcmkERR_BREAK(gckVGHARDWARE_ConvertFormat(
                Kernel->vg->hardware,
                kernelInterface->u.AllocateVideoMemory.format,
                &bitsPerPixel,
                gcvNULL
                ));

            /* Compute number of bits for the allocation. */
            bits
                = kernelInterface->u.AllocateVideoMemory.width
                * kernelInterface->u.AllocateVideoMemory.height
                * kernelInterface->u.AllocateVideoMemory.depth
                * bitsPerPixel;

            /* Compute number of bytes for the allocation. */
            bytes = gcmALIGN(bits, 8) / 8;

            /* Allocate memory. */
            gcmkERR_BREAK(gckKERNEL_AllocateLinearMemory(
                Kernel,
                &kernelInterface->u.AllocateVideoMemory.pool,
                bytes,
                64,
                kernelInterface->u.AllocateVideoMemory.type,
                &kernelInterface->u.AllocateVideoMemory.node
                ));
        }
        break;

    case gcvHAL_ALLOCATE_LINEAR_VIDEO_MEMORY:
        /* Allocate memory. */
        gcmkERR_BREAK(gckKERNEL_AllocateLinearMemory(
            Kernel,
            &kernelInterface->u.AllocateLinearVideoMemory.pool,
            kernelInterface->u.AllocateLinearVideoMemory.bytes,
            kernelInterface->u.AllocateLinearVideoMemory.alignment,
            kernelInterface->u.AllocateLinearVideoMemory.type,
            &kernelInterface->u.AllocateLinearVideoMemory.node
            ));

        gcmkERR_BREAK(gckKERNEL_AddProcessDB(Kernel,
           processID, gcvDB_VIDEO_MEMORY,
           Interface->u.AllocateLinearVideoMemory.node,
           gcvNULL,
           kernelInterface->u.AllocateLinearVideoMemory.bytes
           ));

        break;

    case gcvHAL_FREE_VIDEO_MEMORY:
#ifdef __QNXNTO__
        /* Unmap the video memory */
        node = Interface->u.FreeVideoMemory.node;

        if ((node->VidMem.memory->object.type == gcvOBJ_VIDMEM) &&
            (node->VidMem.logical != gcvNULL))
        {
            gckKERNEL_UnmapVideoMemory(Kernel,
                                       node->VidMem.logical,
                                       processID,
                                       node->VidMem.bytes);
            node->VidMem.logical = gcvNULL;
        }
#endif /* __QNXNTO__ */

        /* Free video memory. */
        gcmkERR_BREAK(gckVIDMEM_Free(
            Interface->u.FreeVideoMemory.node
            ));

        gcmkERR_BREAK(gckKERNEL_RemoveProcessDB(
            Kernel,
            processID, gcvDB_VIDEO_MEMORY,
            Interface->u.FreeVideoMemory.node
            ));

        break;

    case gcvHAL_MAP_MEMORY:
        /* Map memory. */
        gcmkERR_BREAK(gckKERNEL_MapMemory(
            Kernel,
            kernelInterface->u.MapMemory.physical,
            kernelInterface->u.MapMemory.bytes,
            &kernelInterface->u.MapMemory.logical
            ));
        break;

    case gcvHAL_UNMAP_MEMORY:
        /* Unmap memory. */
        gcmkERR_BREAK(gckKERNEL_UnmapMemory(
            Kernel,
            kernelInterface->u.MapMemory.physical,
            kernelInterface->u.MapMemory.bytes,
            kernelInterface->u.MapMemory.logical
            ));
        break;

    case gcvHAL_MAP_USER_MEMORY:
        /* Map user memory to DMA. */
        gcmkERR_BREAK(gckOS_MapUserMemory(
            Kernel->os,
            gcvCORE_VG,
            kernelInterface->u.MapUserMemory.memory,
            kernelInterface->u.MapUserMemory.physical,
            kernelInterface->u.MapUserMemory.size,
            &kernelInterface->u.MapUserMemory.info,
            &kernelInterface->u.MapUserMemory.address
            ));
        break;

    case gcvHAL_UNMAP_USER_MEMORY:
        /* Unmap user memory. */
        gcmkERR_BREAK(gckOS_UnmapUserMemory(
            Kernel->os,
            gcvCORE_VG,
            kernelInterface->u.UnmapUserMemory.memory,
            kernelInterface->u.UnmapUserMemory.size,
            kernelInterface->u.UnmapUserMemory.info,
            kernelInterface->u.UnmapUserMemory.address
            ));
        break;
    case gcvHAL_LOCK_VIDEO_MEMORY:
        /* Lock video memory. */
        gcmkERR_BREAK(
            gckVIDMEM_Lock(Kernel,
                           Interface->u.LockVideoMemory.node,
                           gcvFALSE,
                           &Interface->u.LockVideoMemory.address));

        node = Interface->u.LockVideoMemory.node;
        if (node->VidMem.memory->object.type == gcvOBJ_VIDMEM)
        {
            /* Map video memory address into user space. */
#ifdef __QNXNTO__
        if (node->VidMem.logical == gcvNULL)
        {
            gcmkONERROR(
                gckKERNEL_MapVideoMemory(Kernel,
                                         FromUser,
                                         Interface->u.LockVideoMemory.address,
                                         processID,
                                         node->VidMem.bytes,
                                         &node->VidMem.logical));
        }

        Interface->u.LockVideoMemory.memory = node->VidMem.logical;
#else
            gcmkERR_BREAK(
                gckKERNEL_MapVideoMemoryEx(Kernel,
                                         gcvCORE_VG,
                                         FromUser,
                                         Interface->u.LockVideoMemory.address,
                                         &Interface->u.LockVideoMemory.memory));
#endif
        }
        else
        {
            Interface->u.LockVideoMemory.memory = node->Virtual.logical;

            /* Success. */
            status = gcvSTATUS_OK;
        }

#if gcdSECURE_USER
        /* Return logical address as physical address. */
        Interface->u.LockVideoMemory.address =
            gcmPTR2INT(Interface->u.LockVideoMemory.memory);
#endif
        gcmkERR_BREAK(
            gckKERNEL_AddProcessDB(Kernel,
                                   processID, gcvDB_VIDEO_MEMORY_LOCKED,
                                   Interface->u.LockVideoMemory.node,
                                   gcvNULL,
                                   0));
        break;

    case gcvHAL_UNLOCK_VIDEO_MEMORY:
        /* Unlock video memory. */
        node = Interface->u.UnlockVideoMemory.node;

#if gcdSECURE_USER
        /* Save node information before it disappears. */
        if (node->VidMem.memory->object.type == gcvOBJ_VIDMEM)
        {
            logical = gcvNULL;
            bytes   = 0;
        }
        else
        {
            logical = node->Virtual.logical;
            bytes   = node->Virtual.bytes;
        }
#endif

        /* Unlock video memory. */
        gcmkERR_BREAK(
            gckVIDMEM_Unlock(Kernel,
                             node,
                             Interface->u.UnlockVideoMemory.type,
                             &Interface->u.UnlockVideoMemory.asynchroneous,
                             gcvFALSE));

#if gcdSECURE_USER
        /* Flush the translation cache for virtual surfaces. */
        if (logical != gcvNULL)
        {
            gcmkVERIFY_OK(gckKERNEL_FlushTranslationCache(Kernel,
                                                          cache,
                                                          logical,
                                                          bytes));
        }
#endif

        if (Interface->u.UnlockVideoMemory.asynchroneous == gcvFALSE)
        {
            /* There isn't a event to unlock this node, remove record now */
            gcmkERR_BREAK(
                    gckKERNEL_RemoveProcessDB(Kernel,
                        processID, gcvDB_VIDEO_MEMORY_LOCKED,
                        Interface->u.UnlockVideoMemory.node));
        }

        break;
    case gcvHAL_USER_SIGNAL:
#if !USE_NEW_LINUX_SIGNAL
        /* Dispatch depends on the user signal subcommands. */
        switch(Interface->u.UserSignal.command)
        {
        case gcvUSER_SIGNAL_CREATE:
            /* Create a signal used in the user space. */
            gcmkERR_BREAK(
                gckOS_CreateUserSignal(Kernel->os,
                                       Interface->u.UserSignal.manualReset,
                                       &Interface->u.UserSignal.id));

            gcmkVERIFY_OK(
                gckKERNEL_AddProcessDB(Kernel,
                                       processID, gcvDB_SIGNAL,
                                       gcmINT2PTR(Interface->u.UserSignal.id),
                                       gcvNULL,
                                       0));
            break;

        case gcvUSER_SIGNAL_DESTROY:
            /* Destroy the signal. */
            gcmkERR_BREAK(
                gckOS_DestroyUserSignal(Kernel->os,
                                        Interface->u.UserSignal.id));

            gcmkVERIFY_OK(gckKERNEL_RemoveProcessDB(
                Kernel,
                processID, gcvDB_SIGNAL,
                gcmINT2PTR(Interface->u.UserSignal.id)));
            break;

        case gcvUSER_SIGNAL_SIGNAL:
            /* Signal the signal. */
            gcmkERR_BREAK(
                gckOS_SignalUserSignal(Kernel->os,
                                       Interface->u.UserSignal.id,
                                       Interface->u.UserSignal.state));
            break;

        case gcvUSER_SIGNAL_WAIT:
            /* Wait on the signal. */
            status = gckOS_WaitUserSignal(Kernel->os,
                                          Interface->u.UserSignal.id,
                                          Interface->u.UserSignal.wait);
            break;

        default:
            /* Invalid user signal command. */
            gcmkERR_BREAK(gcvSTATUS_INVALID_ARGUMENT);
        }
#endif
        break;

    case gcvHAL_COMMIT:
        /* Commit a command and context buffer. */
        gcmkERR_BREAK(gckVGCOMMAND_Commit(
            Kernel->vg->command,
            kernelInterface->u.VGCommit.context,
            kernelInterface->u.VGCommit.queue,
            kernelInterface->u.VGCommit.entryCount,
            kernelInterface->u.VGCommit.taskTable
            ));
        break;
    case gcvHAL_VERSION:
        kernelInterface->u.Version.major = gcvVERSION_MAJOR;
        kernelInterface->u.Version.minor = gcvVERSION_MINOR;
        kernelInterface->u.Version.patch = gcvVERSION_PATCH;
        kernelInterface->u.Version.build = gcvVERSION_BUILD;
        status = gcvSTATUS_OK;
        break;

    case gcvHAL_GET_BASE_ADDRESS:
        /* Get base address. */
        gcmkERR_BREAK(
            gckOS_GetBaseAddress(Kernel->os,
                                 &kernelInterface->u.GetBaseAddress.baseAddress));
        break;
    default:
        /* Invalid command. */
        status = gcvSTATUS_INVALID_ARGUMENT;
    }

OnError:
    /* Save status. */
    kernelInterface->status = status;

    gcmkFOOTER();

    /* Return the status. */
    return status;
}
int drv_release(
    struct inode* inode,
    struct file* filp
    )
{
    gceSTATUS status = gcvSTATUS_OK;
    gcsHAL_PRIVATE_DATA_PTR data = gcvNULL;
    gckGALDEVICE device;
    gctINT i;

    gcmkHEADER_ARG("inode=0x%08X filp=0x%08X", inode, filp);

    if (filp == gcvNULL)
    {
        gcmkTRACE_ZONE(
            gcvLEVEL_ERROR, gcvZONE_DRIVER,
            "%s(%d): filp is NULL\n",
            __FUNCTION__, __LINE__
            );

        gcmkONERROR(gcvSTATUS_INVALID_ARGUMENT);
    }

    data = filp->private_data;

    if (data == gcvNULL)
    {
        gcmkTRACE_ZONE(
            gcvLEVEL_ERROR, gcvZONE_DRIVER,
            "%s(%d): private_data is NULL\n",
            __FUNCTION__, __LINE__
            );

        gcmkONERROR(gcvSTATUS_INVALID_ARGUMENT);
    }

    device = data->device;

    if (device == gcvNULL)
    {
        gcmkTRACE_ZONE(
            gcvLEVEL_ERROR, gcvZONE_DRIVER,
            "%s(%d): device is NULL\n",
            __FUNCTION__, __LINE__
            );

        gcmkONERROR(gcvSTATUS_INVALID_ARGUMENT);
    }

    if (!device->contiguousMapped)
    {
        if (data->contiguousLogical != gcvNULL)
        {
            gcmkONERROR(gckOS_UnmapMemoryEx(
                galDevice->os,
                galDevice->contiguousPhysical,
                galDevice->contiguousSize,
                data->contiguousLogical,
                data->pidOpen
                ));

            for (i = 0; i < gcdMAX_GPU_COUNT; i++)
            {
                if (galDevice->kernels[i] != gcvNULL)
                {
                    gcmkVERIFY_OK(
                         gckKERNEL_RemoveProcessDB(galDevice->kernels[i],
                                                   data->pidOpen, gcvDB_MAP_MEMORY,
                                                   data->contiguousLogical));
                }
            }

            data->contiguousLogical = gcvNULL;
        }
    }

    /* A process gets detached. */
    gcmkPRINT("Process %d released (%s)\n", data->pidOpen, _GC_VERSION_STRING_);
    for (i = 0; i < gcdMAX_GPU_COUNT; i++)
    {
        if (galDevice->kernels[i] != gcvNULL)
        {
            /*gcmkONERROR(gckKERNEL_ShowProcessMemUsage(galDevice->kernels[i], data->pidOpen));*/
            gcmkONERROR(gckKERNEL_AttachProcessEx(galDevice->kernels[i], gcvFALSE, data->pidOpen));
        }
    }

    kfree(data);
    filp->private_data = gcvNULL;

    /* Print memory information
    _gc_gather_infomation(buf, &len);
    printk("%s", buf);*/

    /* Success. */
    gcmkFOOTER_NO();
    return 0;

OnError:
    if(data!=gcvNULL)
    {
        kfree(data);
        filp->private_data = gcvNULL;
    }
    gcmkFOOTER();
    return -ENOTTY;
}
Exemplo n.º 3
0
int drv_release(
    struct inode* inode,
    struct file* filp
    )
{
    gceSTATUS status;
    gcsHAL_PRIVATE_DATA_PTR data;
    gckGALDEVICE device;
    gctINT i;
    gctUINT32 processID;


    gcmkHEADER_ARG("inode=0x%08X filp=0x%08X", inode, filp);

    if (filp == gcvNULL)
    {
        gcmkTRACE_ZONE(
            gcvLEVEL_ERROR, gcvZONE_DRIVER,
            "%s(%d): filp is NULL\n",
            __FUNCTION__, __LINE__
            );

        gcmkONERROR(gcvSTATUS_INVALID_ARGUMENT);
    }

    data = filp->private_data;

    if (data == gcvNULL)
    {
        gcmkTRACE_ZONE(
            gcvLEVEL_ERROR, gcvZONE_DRIVER,
            "%s(%d): private_data is NULL\n",
            __FUNCTION__, __LINE__
            );

        gcmkONERROR(gcvSTATUS_INVALID_ARGUMENT);
    }

    device = data->device;

    if (device == gcvNULL)
    {
        gcmkTRACE_ZONE(
            gcvLEVEL_ERROR, gcvZONE_DRIVER,
            "%s(%d): device is NULL\n",
            __FUNCTION__, __LINE__
            );

        gcmkONERROR(gcvSTATUS_INVALID_ARGUMENT);
    }

    if (!device->contiguousMapped)
    {
        if (data->contiguousLogical != gcvNULL)
        {
            gcmkVERIFY_OK(gckOS_GetProcessID(&processID));
            gcmkONERROR(gckOS_UnmapMemoryEx(
                galDevice->os,
                galDevice->contiguousPhysical,
                galDevice->contiguousSize,
                data->contiguousLogical,
                data->pidOpen
                ));

            for (i = 0; i < gcdCORE_COUNT; i++)
            {
                if (galDevice->kernels[i] != gcvNULL)
                {
                    gcmkVERIFY_OK(
                         gckKERNEL_RemoveProcessDB(galDevice->kernels[i],
                                                   processID, gcvDB_MAP_MEMORY,
                                                   data->contiguousLogical));
                }
            }

            data->contiguousLogical = gcvNULL;
        }
    }

    /* Clean user signals if exit unnormally. */
    gcmkVERIFY_OK(gckOS_GetProcessID(&processID));
    gcmkVERIFY_OK(gckOS_CleanProcessSignal(galDevice->os, (gctHANDLE)processID));

    /* A process gets detached. */
    for (i = 0; i < gcdCORE_COUNT; i++)
    {
        if (galDevice->kernels[i] != gcvNULL)
        {
            gcmkONERROR(gckKERNEL_AttachProcessEx(galDevice->kernels[i], gcvFALSE, data->pidOpen));
        }
    }

    kfree(data);
    filp->private_data = NULL;

    /* Success. */
    gcmkFOOTER_NO();
    return 0;

OnError:
    gcmkFOOTER();
    return -ENOTTY;
}
int drv_open(
    struct inode* inode,
    struct file* filp
    )
{
    gceSTATUS status = gcvSTATUS_OK;
    gctBOOL attached = gcvFALSE;
    gcsHAL_PRIVATE_DATA_PTR data = gcvNULL;
    gctINT i;

    gcmkHEADER_ARG("inode=0x%08X filp=0x%08X", inode, filp);

    if (filp == gcvNULL)
    {
        gcmkTRACE_ZONE(
            gcvLEVEL_ERROR, gcvZONE_DRIVER,
            "%s(%d): filp is NULL\n",
            __FUNCTION__, __LINE__
            );

        gcmkONERROR(gcvSTATUS_INVALID_ARGUMENT);
    }

    data = kmalloc(sizeof(gcsHAL_PRIVATE_DATA), GFP_KERNEL | __GFP_NOWARN);

    if (data == gcvNULL)
    {
        gcmkTRACE_ZONE(
            gcvLEVEL_ERROR, gcvZONE_DRIVER,
            "%s(%d): private_data is NULL\n",
            __FUNCTION__, __LINE__
            );

        gcmkONERROR(gcvSTATUS_OUT_OF_MEMORY);
    }

    data->device             = galDevice;
    data->mappedMemory       = gcvNULL;
    data->contiguousLogical  = gcvNULL;
    gcmkONERROR(gckOS_GetProcessID(&data->pidOpen));

    /* Attached the process. */
    for (i = 0; i < gcdMAX_GPU_COUNT; i++)
    {
        if (galDevice->kernels[i] != gcvNULL)
        {
            gcmkONERROR(gckKERNEL_AttachProcess(galDevice->kernels[i], gcvTRUE));
        }
    }
    attached = gcvTRUE;

    if (!galDevice->contiguousMapped)
    {
        gcmkONERROR(gckOS_MapMemory(
            galDevice->os,
            galDevice->contiguousPhysical,
            galDevice->contiguousSize,
            &data->contiguousLogical
            ));

        for (i = 0; i < gcdMAX_GPU_COUNT; i++)
        {
            if (galDevice->kernels[i] != gcvNULL)
            {
                gcmkVERIFY_OK(gckKERNEL_AddProcessDB(
                    galDevice->kernels[i],
                    data->pidOpen,
                    gcvDB_MAP_MEMORY,
                    data->contiguousLogical,
                    galDevice->contiguousPhysical,
                    galDevice->contiguousSize));
            }
        }
    }

    filp->private_data = data;

    /* Success. */
    gcmkFOOTER_NO();
    return 0;

OnError:
    if (data != gcvNULL)
    {
        if (data->contiguousLogical != gcvNULL)
        {
            gcmkVERIFY_OK(gckOS_UnmapMemory(
                galDevice->os,
                galDevice->contiguousPhysical,
                galDevice->contiguousSize,
                data->contiguousLogical
                ));

            for(i = 0; i < gcdMAX_GPU_COUNT; i++)
            {
                gcmkVERIFY_OK(
                         gckKERNEL_RemoveProcessDB(galDevice->kernels[i],
                                                   data->pidOpen,
                                                   gcvDB_MAP_MEMORY,
                                                   data->contiguousLogical));
            }
        }

        kfree(data);
        data = gcvNULL;
    }

    if (attached)
    {
        for (i = 0; i < gcdMAX_GPU_COUNT; i++)
        {
            if (galDevice->kernels[i] != gcvNULL)
            {
                gcmkVERIFY_OK(gckKERNEL_AttachProcess(galDevice->kernels[i], gcvFALSE));
            }
        }
    }

    gcmkFOOTER();
    return -ENOTTY;
}