path: root/drivers/mxc/gpu-viv/hal/kernel/gc_hal_kernel_mmu.c

/****************************************************************************
*
*    Copyright (C) 2005 - 2011 by Vivante Corp.
*
*    This program is free software; you can redistribute it and/or modify
*    it under the terms of the GNU General Public License as published by
*    the Free Software Foundation; either version 2 of the license, or
*    (at your option) any later version.
*
*    This program is distributed in the hope that it will be useful,
*    but WITHOUT ANY WARRANTY; without even the implied warranty of
*    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
*    GNU General Public License for more details.
*
*    You should have received a copy of the GNU General Public License
*    along with this program; if not write to the Free Software
*    Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*
*****************************************************************************/




#include "gc_hal_kernel_precomp.h"

#define _GC_OBJ_ZONE    gcvZONE_MMU

typedef enum _gceMMU_TYPE
{
    gcvMMU_USED = 0,
    gcvMMU_SINGLE,
    gcvMMU_FREE,
}
gceMMU_TYPE;

#define gcdMMU_TABLE_DUMP       0

#define gcdMMU_MTLB_SHIFT           22
#define gcdMMU_STLB_4K_SHIFT        12
#define gcdMMU_STLB_64K_SHIFT       16

#define gcdMMU_MTLB_BITS            (32 - gcdMMU_MTLB_SHIFT)
#define gcdMMU_PAGE_4K_BITS         gcdMMU_STLB_4K_SHIFT
#define gcdMMU_STLB_4K_BITS         (32 - gcdMMU_MTLB_BITS - gcdMMU_PAGE_4K_BITS)
#define gcdMMU_PAGE_64K_BITS        gcdMMU_STLB_64K_SHIFT
#define gcdMMU_STLB_64K_BITS        (32 - gcdMMU_MTLB_BITS - gcdMMU_PAGE_64K_BITS)

#define gcdMMU_MTLB_ENTRY_NUM       (1 << gcdMMU_MTLB_BITS)
#define gcdMMU_MTLB_SIZE            (gcdMMU_MTLB_ENTRY_NUM << 2)
#define gcdMMU_STLB_4K_ENTRY_NUM    (1 << gcdMMU_STLB_4K_BITS)
#define gcdMMU_STLB_4K_SIZE         (gcdMMU_STLB_4K_ENTRY_NUM << 2)
#define gcdMMU_PAGE_4K_SIZE         (1 << gcdMMU_STLB_4K_SHIFT)
#define gcdMMU_STLB_64K_ENTRY_NUM   (1 << gcdMMU_STLB_64K_BITS)
#define gcdMMU_STLB_64K_SIZE        (gcdMMU_STLB_64K_ENTRY_NUM << 2)
#define gcdMMU_PAGE_64K_SIZE        (1 << gcdMMU_STLB_64K_SHIFT)

#define gcdMMU_MTLB_MASK            (~((1U << gcdMMU_MTLB_SHIFT)-1))
#define gcdMMU_STLB_4K_MASK         ((~0U << gcdMMU_STLB_4K_SHIFT) ^ gcdMMU_MTLB_MASK)
#define gcdMMU_PAGE_4K_MASK         (gcdMMU_PAGE_4K_SIZE - 1)
#define gcdMMU_STLB_64K_MASK        ((~((1U << gcdMMU_STLB_64K_SHIFT)-1)) ^ gcdMMU_MTLB_MASK)
#define gcdMMU_PAGE_64K_MASK        (gcdMMU_PAGE_64K_SIZE - 1)

typedef struct _gcsMMU_STLB *gcsMMU_STLB_PTR;

typedef struct _gcsMMU_STLB
{
    gctPHYS_ADDR    physical;
    gctUINT32_PTR   logical;
    gctSIZE_T       size;
    gctUINT32       physBase;
    gctSIZE_T       pageCount;
    gctUINT32       mtlbIndex;
    gctUINT32       mtlbEntryNum;
    gcsMMU_STLB_PTR next;
} gcsMMU_STLB;

#define gcvMMU_STLB_SIZE gcmALIGN(sizeof(gcsMMU_STLB), 4)

static gceSTATUS
_Link(
    IN gckMMU Mmu,
    IN gctUINT32 Index,
    IN gctUINT32 Next
    )
{
    if (Index >= Mmu->pageTableEntries)
    {
        /* Just move heap pointer. */
        Mmu->heapList = Next;
    }
    else
    {
        /* Address page table. */
        gctUINT32_PTR pageTable = Mmu->pageTableLogical;

        /* Dispatch on node type. */
        switch (pageTable[Index] & 0xFF)
        {
        case gcvMMU_SINGLE:
            /* Set single index. */
            pageTable[Index] = (Next << 8) | gcvMMU_SINGLE;
            break;

        case gcvMMU_FREE:
            /* Set index. */
            pageTable[Index + 1] = Next;
            break;

        default:
            gcmkFATAL("MMU table correcupted at index %u!", Index);
            return gcvSTATUS_HEAP_CORRUPTED;
        }
    }

    /* Success. */
    return gcvSTATUS_OK;
}

static gceSTATUS
_AddFree(
    IN gckMMU Mmu,
    IN gctUINT32 Index,
    IN gctUINT32 Node,
    IN gctUINT32 Count
    )
{
    gctUINT32_PTR pageTable = Mmu->pageTableLogical;

    if (Count == 1)
    {
        /* Initialize a single page node. */
        pageTable[Node] = (~((1U<<8)-1)) | gcvMMU_SINGLE;
    }
    else
    {
        /* Initialize the node. */
        pageTable[Node + 0] = (Count << 8) | gcvMMU_FREE;
        pageTable[Node + 1] = ~0U;
    }

    /* Append the node. */
    return _Link(Mmu, Index, Node);
}

static gceSTATUS
_Collect(
    IN gckMMU Mmu
    )
{
    gctUINT32_PTR pageTable = Mmu->pageTableLogical;
    gceSTATUS status;
    gctUINT32 i, previous, start = 0, count = 0;

    /* Flush the MMU cache. */
    gcmkONERROR(
        gckHARDWARE_FlushMMU(Mmu->hardware));

    previous = Mmu->heapList = ~0U;
    Mmu->freeNodes = gcvFALSE;

    /* Walk the entire page table. */
    for (i = 0; i < Mmu->pageTableEntries; ++i)
    {
        /* Dispatch based on type of page. */
        switch (pageTable[i] & 0xFF)
        {
        case gcvMMU_USED:
            /* Used page, so close any open node. */
            if (count > 0)
            {
                /* Add the node. */
                gcmkONERROR(_AddFree(Mmu, previous, start, count));

                /* Reset the node. */
                previous = start;
                count    = 0;
            }
            break;

        case gcvMMU_SINGLE:
            /* Single free node. */
            if (count++ == 0)
            {
                /* Start a new node. */
                start = i;
            }
            break;

        case gcvMMU_FREE:
            /* A free node. */
            if (count == 0)
            {
                /* Start a new node. */
                start = i;
            }

            /* Advance the count. */
            count += pageTable[i] >> 8;

            /* Advance the index into the page table. */
            i     += (pageTable[i] >> 8) - 1;
            break;

        default:
            gcmkFATAL("MMU page table correcupted at index %u!", i);
            return gcvSTATUS_HEAP_CORRUPTED;
        }
    }

    /* See if we have an open node left. */
    if (count > 0)
    {
        /* Add the node to the list. */
        gcmkONERROR(_AddFree(Mmu, previous, start, count));
    }

    gcmkTRACE_ZONE(gcvLEVEL_INFO, gcvZONE_MMU,
                   "Performed a garbage collection of the MMU heap.");

    /* Success. */
    return gcvSTATUS_OK;

OnError:
    /* Return the staus. */
    return status;
}

static gceSTATUS
_GetStlb(
    IN gckMMU Mmu,
    IN gctSIZE_T PageCount,
    OUT gcsMMU_STLB_PTR *Stlb
    )
{
    gceSTATUS status;
    gcsMMU_STLB_PTR stlb = gcvNULL;
    gctPHYS_ADDR physical;
    gctPOINTER logical = gcvNULL;
    gctSIZE_T size = (PageCount << 2) + gcvMMU_STLB_SIZE;
    gctUINT32 address;

    gcmkONERROR(
            gckOS_AllocateContiguous(Mmu->os,
                                     gcvFALSE,
                                     &size,
                                     &physical,
                                     &logical));

    gcmkONERROR(gckOS_ZeroMemory(logical, size));

    /* Convert logical address into a physical address. */
    gcmkONERROR(
        gckOS_GetPhysicalAddress(Mmu->os, logical, &address));

    stlb = (gcsMMU_STLB_PTR)logical;
    stlb->pageCount = PageCount;
    stlb->logical = logical;
    stlb->physical = physical;
    stlb->physBase = address;
    stlb->size = size;
    stlb->mtlbIndex = ~0U;
    stlb->mtlbEntryNum = 0;
    stlb->next = gcvNULL;

    *Stlb = stlb;

    return gcvSTATUS_OK;

OnError:

    if (logical != gcvNULL)
    {
        gckOS_FreeContiguous(
            Mmu->os,
            physical,
            logical,
            size
            );
    }

    return status;
}

static gceSTATUS
_PutStlb(
    IN gckMMU Mmu,
    IN gcsMMU_STLB_PTR Stlb
    )
{
    gcmkASSERT(Stlb->logical == (gctPOINTER)Stlb);

    return gckOS_FreeContiguous(
            Mmu->os,
            Stlb->physical,
            Stlb,
            Stlb->size
            );
}

static gctUINT32
_SetPage(gctUINT32 PageAddress)
{
    return PageAddress
           /* writable */
           | (1 << 2)
           /* Ignore exception */
           | (0 << 1)
           /* Present */
           | (1 << 0);
}

static gceSTATUS
_FillFlatMapping(
    IN gckMMU Mmu,
    IN gctUINT32 PhysBase,
    OUT gctSIZE_T Size
    )
{
    gceSTATUS status;
    gctBOOL mutex = gcvFALSE;
    gcsMMU_STLB_PTR head = gcvNULL, pre = gcvNULL;
    gctUINT32 start = PhysBase & (~gcdMMU_PAGE_64K_MASK);
    gctUINT32 end = (PhysBase + Size - 1) & (~gcdMMU_PAGE_64K_MASK);
    gctUINT32 mStart = start >> gcdMMU_MTLB_SHIFT;
    gctUINT32 mEnd = end >> gcdMMU_MTLB_SHIFT;
    gctUINT32 sStart = (start & gcdMMU_STLB_64K_MASK) >> gcdMMU_STLB_64K_SHIFT;
    gctUINT32 sEnd = (end & gcdMMU_STLB_64K_MASK) >> gcdMMU_STLB_64K_SHIFT;

    /* Grab the mutex. */
    gcmkONERROR(gckOS_AcquireMutex(Mmu->os, Mmu->pageTableMutex, gcvINFINITE));
    mutex = gcvTRUE;

    while (mStart <= mEnd)
    {
        gcmkASSERT(mStart < gcdMMU_MTLB_ENTRY_NUM);
        if (*(Mmu->pageTableLogical + mStart) == 0)
        {
            gcsMMU_STLB_PTR stlb;
            gctPOINTER pointer = gcvNULL;
            gctUINT32 last = (mStart == mEnd) ? sEnd : (gcdMMU_STLB_64K_ENTRY_NUM - 1);

            gcmkONERROR(gckOS_Allocate(Mmu->os, sizeof(struct _gcsMMU_STLB), &pointer));
            stlb = pointer;

            stlb->mtlbEntryNum = 0;
            stlb->next = gcvNULL;
            stlb->physical = gcvNULL;
            stlb->logical = gcvNULL;
            stlb->size = gcdMMU_STLB_64K_SIZE;
            stlb->pageCount = 0;

            if (pre == gcvNULL)
            {
                pre = head = stlb;
            }
            else
            {
                gcmkASSERT(pre->next == gcvNULL);
                pre->next = stlb;
                pre = stlb;
            }

            gcmkONERROR(
                    gckOS_AllocateContiguous(Mmu->os,
                                             gcvFALSE,
                                             &stlb->size,
                                             &stlb->physical,
                                             (gctPOINTER)&stlb->logical));

            gcmkONERROR(gckOS_ZeroMemory(stlb->logical, stlb->size));

            gcmkONERROR(gckOS_GetPhysicalAddress(
                Mmu->os,
                stlb->logical,
                &stlb->physBase));

            if (stlb->physBase & (gcdMMU_STLB_64K_SIZE - 1))
            {
                gcmkONERROR(gcvSTATUS_NOT_ALIGNED);
            }

            *(Mmu->pageTableLogical + mStart)
                      = stlb->physBase
                        /* 64KB page size */
                        | (1 << 2)
                        /* Ignore exception */
                        | (0 << 1)
                        /* Present */
                        | (1 << 0);
#if gcdMMU_TABLE_DUMP
            gckOS_Print("%s(%d): insert MTLB[%d]: %08x\n",
                __FUNCTION__, __LINE__,
                mStart,
                *(Mmu->pageTableLogical + mStart));
#endif

            stlb->mtlbIndex = mStart;
            stlb->mtlbEntryNum = 1;
#if gcdMMU_TABLE_DUMP
            gckOS_Print("%s(%d): STLB: logical:%08x -> physical:%08x\n",
                    __FUNCTION__, __LINE__,
                    stlb->logical,
                    stlb->physBase);
#endif

            while (sStart <= last)
            {
                gcmkASSERT(!(start & gcdMMU_PAGE_64K_MASK));
                *(stlb->logical + sStart) = _SetPage(start);
#if gcdMMU_TABLE_DUMP
                gckOS_Print("%s(%d): insert STLB[%d]: %08x\n",
                    __FUNCTION__, __LINE__,
                    sStart,
                    *(stlb->logical + sStart));
#endif
                /* next page. */
                start += gcdMMU_PAGE_64K_SIZE;
                sStart++;
                stlb->pageCount++;
            }

            sStart = 0;
            ++mStart;
        }
        else
        {
            gcmkONERROR(gcvSTATUS_INVALID_REQUEST);
        }
    }

    /* Insert the stlb into staticSTLB. */
    if (Mmu->staticSTLB == gcvNULL)
    {
        Mmu->staticSTLB = head;
    }
    else
    {
		gcmkASSERT(pre == gcvNULL);
        gcmkASSERT(pre->next == gcvNULL);
        pre->next = Mmu->staticSTLB;
        Mmu->staticSTLB = head;
    }

    /* Release the mutex. */
    gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->pageTableMutex));

    return gcvSTATUS_OK;

OnError:

    /* Roll back. */
    while (head != gcvNULL)
    {
        pre = head;
        head = head->next;

        if (pre->physical != gcvNULL)
        {
            gcmkVERIFY_OK(
                gckOS_FreeContiguous(Mmu->os,
                    pre->physical,
                    pre->logical,
                    pre->size));
        }

        if (pre->mtlbEntryNum != 0)
        {
            gcmkASSERT(pre->mtlbEntryNum == 1);
            *(Mmu->pageTableLogical + pre->mtlbIndex) = 0;
        }

        gcmkVERIFY_OK(gcmkOS_SAFE_FREE(Mmu->os, pre));
    }

    if (mutex)
    {
        /* Release the mutex. */
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->pageTableMutex));
    }

    return status;
}

/*******************************************************************************
**
**  gckMMU_Construct
**
**  Construct a new gckMMU object.
**
**  INPUT:
**
**      gckKERNEL Kernel
**          Pointer to an gckKERNEL object.
**
**      gctSIZE_T MmuSize
**          Number of bytes for the page table.
**
**  OUTPUT:
**
**      gckMMU * Mmu
**          Pointer to a variable that receives the gckMMU object pointer.
*/
gceSTATUS
gckMMU_Construct(
    IN gckKERNEL Kernel,
    IN gctSIZE_T MmuSize,
    OUT gckMMU * Mmu
    )
{
    gckOS os;
    gckHARDWARE hardware;
    gceSTATUS status;
    gckMMU mmu = gcvNULL;
    gctUINT32_PTR pageTable;
    gctPOINTER pointer = gcvNULL;

    gcmkHEADER_ARG("Kernel=0x%x MmuSize=%lu", Kernel, MmuSize);

    /* Verify the arguments. */
    gcmkVERIFY_OBJECT(Kernel, gcvOBJ_KERNEL);
    gcmkVERIFY_ARGUMENT(MmuSize > 0);
    gcmkVERIFY_ARGUMENT(Mmu != gcvNULL);

    /* Extract the gckOS object pointer. */
    os = Kernel->os;
    gcmkVERIFY_OBJECT(os, gcvOBJ_OS);

    /* Extract the gckHARDWARE object pointer. */
    hardware = Kernel->hardware;
    gcmkVERIFY_OBJECT(hardware, gcvOBJ_HARDWARE);

    /* Allocate memory for the gckMMU object. */
    gcmkONERROR(gckOS_Allocate(os, sizeof(struct _gckMMU), &pointer));

    mmu = pointer;

    /* Initialize the gckMMU object. */
    mmu->object.type      = gcvOBJ_MMU;
    mmu->os               = os;
    mmu->hardware         = hardware;
    mmu->pageTableMutex   = gcvNULL;
    mmu->pageTableLogical = gcvNULL;
    mmu->staticSTLB       = gcvNULL;
    mmu->enabled          = gcvFALSE;
#ifdef __QNXNTO__
    mmu->nodeList         = gcvNULL;
    mmu->nodeMutex        = gcvNULL;
#endif

    /* Create the page table mutex. */
    gcmkONERROR(gckOS_CreateMutex(os, &mmu->pageTableMutex));

#ifdef __QNXNTO__
    /* Create the node list mutex. */
    gcmkONERROR(gckOS_CreateMutex(os, &mmu->nodeMutex));
#endif

    if (hardware->mmuVersion == 0)
    {
        /* Allocate the page table (not more than 256 kB). */
        mmu->pageTableSize = gcmMIN(MmuSize, 256 << 10);
        gcmkONERROR(
            gckOS_AllocateContiguous(os,
                                     gcvFALSE,
                                     &mmu->pageTableSize,
                                     &mmu->pageTablePhysical,
                                     &pointer));

        mmu->pageTableLogical = pointer;

        /* Compute number of entries in page table. */
        mmu->pageTableEntries = mmu->pageTableSize / sizeof(gctUINT32);

        /* Mark all pages as free. */
        pageTable      = mmu->pageTableLogical;
        pageTable[0]   = (mmu->pageTableEntries << 8) | gcvMMU_FREE;
        pageTable[1]   = ~0U;
        mmu->heapList  = 0;
        mmu->freeNodes = gcvFALSE;

        /* Set page table address. */
        gcmkONERROR(
            gckHARDWARE_SetMMU(hardware, (gctPOINTER) mmu->pageTableLogical));
    }
    else
    {
        /* Allocate the 4K mode MTLB table. */
        mmu->pageTableSize = gcdMMU_MTLB_SIZE + 64;

        gcmkONERROR(
            gckOS_AllocateContiguous(os,
                                     gcvFALSE,
                                     &mmu->pageTableSize,
                                     &mmu->pageTablePhysical,
                                     &pointer));

        mmu->pageTableLogical = pointer;

        /* Invalid all the entries. */
        gcmkONERROR(
            gckOS_ZeroMemory(pointer, mmu->pageTableSize));
    }

    /* Return the gckMMU object pointer. */
    *Mmu = mmu;

    /* Success. */
    gcmkFOOTER_ARG("*Mmu=0x%x", *Mmu);
    return gcvSTATUS_OK;

OnError:
    /* Roll back. */
    if (mmu != gcvNULL)
    {
        if (mmu->pageTableLogical != gcvNULL)
        {
            /* Free the page table. */
            gcmkVERIFY_OK(
                gckOS_FreeContiguous(os,
                                     mmu->pageTablePhysical,
                                     (gctPOINTER) mmu->pageTableLogical,
                                     mmu->pageTableSize));
        }

        if (mmu->pageTableMutex != gcvNULL)
        {
            /* Delete the mutex. */
            gcmkVERIFY_OK(
                gckOS_DeleteMutex(os, mmu->pageTableMutex));
        }

#ifdef __QNXNTO__
        if (mmu->nodeMutex != gcvNULL)
        {
            /* Delete the mutex. */
            gcmkVERIFY_OK(
                gckOS_DeleteMutex(os, mmu->nodeMutex));
        }
#endif

        /* Mark the gckMMU object as unknown. */
        mmu->object.type = gcvOBJ_UNKNOWN;

        /* Free the allocates memory. */
        gcmkVERIFY_OK(gcmkOS_SAFE_FREE(os, mmu));
    }

    /* Return the status. */
    gcmkFOOTER();
    return status;
}

/*******************************************************************************
**
**  gckMMU_Destroy
**
**  Destroy a gckMMU object.
**
**  INPUT:
**
**      gckMMU Mmu
**          Pointer to an gckMMU object.
**
**  OUTPUT:
**
**      Nothing.
*/
gceSTATUS
gckMMU_Destroy(
    IN gckMMU Mmu
    )
{
#ifdef __QNXNTO__
    gcuVIDMEM_NODE_PTR node, next;
#endif

    gcmkHEADER_ARG("Mmu=0x%x", Mmu);

    /* Verify the arguments. */
    gcmkVERIFY_OBJECT(Mmu, gcvOBJ_MMU);

#ifdef __QNXNTO__
    /* Free all associated virtual memory. */
    for (node = Mmu->nodeList; node != gcvNULL; node = next)
    {
        next = node->Virtual.next;
        gcmkVERIFY_OK(gckVIDMEM_Free(node));
    }
#endif

    while (Mmu->staticSTLB != gcvNULL)
    {
        gcsMMU_STLB_PTR pre = Mmu->staticSTLB;
        Mmu->staticSTLB = pre->next;

        if (pre->physical != gcvNULL)
        {
            gcmkVERIFY_OK(
                gckOS_FreeContiguous(Mmu->os,
                    pre->physical,
                    pre->logical,
                    pre->size));
        }

        if (pre->mtlbEntryNum != 0)
        {
            gcmkASSERT(pre->mtlbEntryNum == 1);
            *(Mmu->pageTableLogical + pre->mtlbIndex) = 0;
#if gcdMMU_TABLE_DUMP
            gckOS_Print("%s(%d): clean MTLB[%d]\n",
                __FUNCTION__, __LINE__,
                pre->mtlbIndex);
#endif
        }

        gcmkVERIFY_OK(gcmkOS_SAFE_FREE(Mmu->os, pre));
    }

    /* Free the page table. */
    gcmkVERIFY_OK(
        gckOS_FreeContiguous(Mmu->os,
                             Mmu->pageTablePhysical,
                             (gctPOINTER) Mmu->pageTableLogical,
                             Mmu->pageTableSize));

#ifdef __QNXNTO__
    /* Delete the node list mutex. */
    gcmkVERIFY_OK(gckOS_DeleteMutex(Mmu->os, Mmu->nodeMutex));
#endif

    /* Delete the page table mutex. */
    gcmkVERIFY_OK(gckOS_DeleteMutex(Mmu->os, Mmu->pageTableMutex));

    /* Mark the gckMMU object as unknown. */
    Mmu->object.type = gcvOBJ_UNKNOWN;

    /* Free the gckMMU object. */
    gcmkVERIFY_OK(gcmkOS_SAFE_FREE(Mmu->os, Mmu));

    /* Success. */
    gcmkFOOTER_NO();
    return gcvSTATUS_OK;
}

/*******************************************************************************
**
**  gckMMU_AllocatePages
**
**  Allocate pages inside the page table.
**
**  INPUT:
**
**      gckMMU Mmu
**          Pointer to an gckMMU object.
**
**      gctSIZE_T PageCount
**          Number of pages to allocate.
**
**  OUTPUT:
**
**      gctPOINTER * PageTable
**          Pointer to a variable that receives the base address of the page
**          table.
**
**      gctUINT32 * Address
**          Pointer to a variable that receives the hardware specific address.
*/
gceSTATUS
gckMMU_AllocatePages(
    IN gckMMU Mmu,
    IN gctSIZE_T PageCount,
    OUT gctPOINTER * PageTable,
    OUT gctUINT32 * Address
    )
{
    gceSTATUS status;
    gctBOOL mutex = gcvFALSE;
    gctUINT32 index = 0, previous = ~0U, left;
    gctUINT32_PTR pageTable;
    gctBOOL gotIt;
    gctUINT32 address;

    gcmkHEADER_ARG("Mmu=0x%x PageCount=%lu", Mmu, PageCount);

    /* Verify the arguments. */
    gcmkVERIFY_OBJECT(Mmu, gcvOBJ_MMU);
    gcmkVERIFY_ARGUMENT(PageCount > 0);
    gcmkVERIFY_ARGUMENT(PageTable != gcvNULL);

    if (Mmu->hardware->mmuVersion == 0)
    {
        if (PageCount > Mmu->pageTableEntries)
        {
            /* Not enough pages avaiable. */
            gcmkONERROR(gcvSTATUS_OUT_OF_RESOURCES);
        }

        /* Grab the mutex. */
        gcmkONERROR(gckOS_AcquireMutex(Mmu->os, Mmu->pageTableMutex, gcvINFINITE));
        mutex = gcvTRUE;

        /* Cast pointer to page table. */
        for (pageTable = Mmu->pageTableLogical, gotIt = gcvFALSE; !gotIt;)
        {
            /* Walk the heap list. */
            for (index = Mmu->heapList; !gotIt && (index < Mmu->pageTableEntries);)
            {
                /* Check the node type. */
                switch (pageTable[index] & 0xFF)
                {
                case gcvMMU_SINGLE:
                    /* Single odes are valid if we only need 1 page. */
                    if (PageCount == 1)
                    {
                        gotIt = gcvTRUE;
                    }
                    else
                    {
                        /* Move to next node. */
                        previous = index;
                        index    = pageTable[index] >> 8;
                    }
                    break;

                case gcvMMU_FREE:
                    /* Test if the node has enough space. */
                    if (PageCount <= (pageTable[index] >> 8))
                    {
                        gotIt = gcvTRUE;
                    }
                    else
                    {
                        /* Move to next node. */
                        previous = index;
                        index    = pageTable[index + 1];
                    }
                    break;

                default:
                    gcmkFATAL("MMU table correcupted at index %u!", index);
                    gcmkONERROR(gcvSTATUS_OUT_OF_RESOURCES);
                }
            }

            /* Test if we are out of memory. */
            if (index >= Mmu->pageTableEntries)
            {
                if (Mmu->freeNodes)
                {
                    /* Time to move out the trash! */
                    gcmkONERROR(_Collect(Mmu));
                }
                else
                {
                    /* Out of resources. */
                    gcmkONERROR(gcvSTATUS_OUT_OF_RESOURCES);
                }
            }
        }

        switch (pageTable[index] & 0xFF)
        {
        case gcvMMU_SINGLE:
            /* Unlink single node from free list. */
            gcmkONERROR(
                _Link(Mmu, previous, pageTable[index] >> 8));
            break;

        case gcvMMU_FREE:
            /* Check how many pages will be left. */
            left = (pageTable[index] >> 8) - PageCount;
            switch (left)
            {
            case 0:
                /* The entire node is consumed, just unlink it. */
                gcmkONERROR(
                    _Link(Mmu, previous, pageTable[index + 1]));
                break;

            case 1:
                /* One page will remain.  Convert the node to a single node and
                ** advance the index. */
                pageTable[index] = (pageTable[index + 1] << 8) | gcvMMU_SINGLE;
                index ++;
                break;

            default:
                /* Enough pages remain for a new node.  However, we will just adjust
                ** the size of the current node and advance the index. */
                pageTable[index] = (left << 8) | gcvMMU_FREE;
                index += left;
                break;
            }
            break;
        }

        /* Mark node as used. */
        pageTable[index] = gcvMMU_USED;

        /* Return pointer to page table. */
        *PageTable = &pageTable[index];

        /* Build virtual address. */
        gcmkONERROR(
            gckHARDWARE_BuildVirtualAddress(Mmu->hardware, index, 0, &address));

        if (Address != gcvNULL)
        {
            *Address = address;
        }

        /* Release the mutex. */
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->pageTableMutex));

        /* Success. */
        gcmkFOOTER_ARG("*PageTable=0x%x *Address=%08x",
                       *PageTable, gcmOPT_VALUE(Address));
        return gcvSTATUS_OK;
    }
    else
    {
        gctUINT i, j;
        gctUINT32 addr;
        gctBOOL succeed = gcvFALSE;
        gcsMMU_STLB_PTR stlb = gcvNULL;
        gctUINT nMtlbEntry =
            gcmALIGN(PageCount, gcdMMU_STLB_4K_ENTRY_NUM) / gcdMMU_STLB_4K_ENTRY_NUM;

        if (Mmu->enabled == gcvFALSE)
        {
            gcmkTRACE_ZONE(gcvLEVEL_INFO, gcvZONE_MMU,
                "gckMMU_AllocatePages(New MMU): failed by the MMU not enabled");

            gcmkONERROR(gcvSTATUS_INVALID_REQUEST);
        }

        /* Grab the mutex. */
        gcmkONERROR(gckOS_AcquireMutex(Mmu->os, Mmu->pageTableMutex, gcvINFINITE));
        mutex = gcvTRUE;

        for (i = 0; i < gcdMMU_MTLB_ENTRY_NUM; i++)
        {
            if (*(Mmu->pageTableLogical + i) == 0)
            {
                succeed = gcvTRUE;

                for (j = 1; j < nMtlbEntry; j++)
                {
                    if (*(Mmu->pageTableLogical + i + j) != 0)
                    {
                        succeed = gcvFALSE;
                        break;
                    }
                }

                if (succeed == gcvTRUE)
                {
                    break;
                }
            }
        }

        if (succeed == gcvFALSE)
        {
            gcmkONERROR(gcvSTATUS_OUT_OF_RESOURCES);
        }

        gcmkONERROR(_GetStlb(Mmu, PageCount, &stlb));

        stlb->mtlbIndex = i;
        stlb->mtlbEntryNum = nMtlbEntry;

        addr = stlb->physBase;
        for (j = 0; j < nMtlbEntry; j++)
        {
            gcmkASSERT(!(addr & (gcdMMU_STLB_4K_SIZE - 1)));
            *(Mmu->pageTableLogical + i + j) =  addr
                        /* 4KB page size */
                        | (0 << 2)
                        /* Ignore exception */
                        | (0 << 1)
                        /* Present */
                        | (1 << 0);
#if gcdMMU_TABLE_DUMP
            gckOS_Print("%s(%d): insert MTLB[%d]: %08x\n",
                __FUNCTION__, __LINE__,
                i + j,
                *(Mmu->pageTableLogical + i + j));
#endif
            addr += gcdMMU_STLB_4K_SIZE;
        }

        /* Release the mutex. */
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->pageTableMutex));

        *PageTable = (gctUINT8_PTR)stlb + gcvMMU_STLB_SIZE;

        if (Address != gcvNULL)
        {
            *Address = (i << gcdMMU_MTLB_SHIFT)
                     | (gcvMMU_STLB_SIZE << 10);
        }

        /* Flush the MMU cache. */
        gcmkONERROR(
            gckHARDWARE_FlushMMU(Mmu->hardware));

        /* Success. */
        gcmkFOOTER_ARG("*PageTable=0x%x *Address=%08x",
                       *PageTable, gcmOPT_VALUE(Address));
        return gcvSTATUS_OK;
    }

OnError:

    if (mutex)
    {
        /* Release the mutex. */
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->pageTableMutex));
    }

    /* Return the status. */
    gcmkFOOTER();
    return status;
}

/*******************************************************************************
**
**  gckMMU_FreePages
**
**  Free pages inside the page table.
**
**  INPUT:
**
**      gckMMU Mmu
**          Pointer to an gckMMU object.
**
**      gctPOINTER PageTable
**          Base address of the page table to free.
**
**      gctSIZE_T PageCount
**          Number of pages to free.
**
**  OUTPUT:
**
**      Nothing.
*/
gceSTATUS
gckMMU_FreePages(
    IN gckMMU Mmu,
    IN gctPOINTER PageTable,
    IN gctSIZE_T PageCount
    )
{
    gceSTATUS status;
    gctBOOL mutex = gcvFALSE;

    gcmkHEADER_ARG("Mmu=0x%x PageTable=0x%x PageCount=%lu",
                   Mmu, PageTable, PageCount);

    /* Verify the arguments. */
    gcmkVERIFY_OBJECT(Mmu, gcvOBJ_MMU);
    gcmkVERIFY_ARGUMENT(PageTable != gcvNULL);
    gcmkVERIFY_ARGUMENT(PageCount > 0);

    if (Mmu->hardware->mmuVersion == 0)
    {
        gctUINT32_PTR pageTable;

        /* Convert the pointer. */
        pageTable = (gctUINT32_PTR) PageTable;

        if (PageCount == 1)
        {
            /* Single page node. */
            pageTable[0] = (~((1U<<8)-1)) | gcvMMU_SINGLE;
        }
        else
        {
            /* Mark the node as free. */
            pageTable[0] = (PageCount << 8) | gcvMMU_FREE;
            pageTable[1] = ~0U;
        }

        /* We have free nodes. */
        Mmu->freeNodes = gcvTRUE;

        /* Success. */
        gcmkFOOTER_NO();
        return gcvSTATUS_OK;
    }
    else
    {
        gcsMMU_STLB_PTR stlb = (gcsMMU_STLB_PTR)((gctUINT8_PTR) PageTable - gcvMMU_STLB_SIZE);
        gctUINT32 i;

        if (Mmu->enabled == gcvFALSE)
        {
            gcmkTRACE_ZONE(gcvLEVEL_INFO, gcvZONE_MMU,
                "gckMMU_FreePages(New MMU): failed by the MMU not enabled");

            gcmkONERROR(gcvSTATUS_INVALID_REQUEST);
        }

        if ((stlb->logical != (gctPOINTER)stlb)
            || (stlb->pageCount != PageCount)
            || (stlb->mtlbIndex >= gcdMMU_MTLB_ENTRY_NUM)
            || (stlb->mtlbEntryNum == 0))
        {
            gcmkONERROR(gcvSTATUS_INVALID_ARGUMENT);
        }

        /* Flush the MMU cache. */
        gcmkONERROR(
            gckHARDWARE_FlushMMU(Mmu->hardware));

        /* Grab the mutex. */
        gcmkONERROR(gckOS_AcquireMutex(Mmu->os, Mmu->pageTableMutex, gcvINFINITE));
        mutex = gcvTRUE;

        for (i = 0; i < stlb->mtlbEntryNum; i++)
        {
            /* clean the MTLB entries. */
            gcmkASSERT((*(Mmu->pageTableLogical + stlb->mtlbIndex + i) & 7) == 1);
            *(Mmu->pageTableLogical + stlb->mtlbIndex + i) = 0;
#if gcdMMU_TABLE_DUMP
            gckOS_Print("%s(%d): clean MTLB[%d]\n",
                __FUNCTION__, __LINE__,
                stlb->mtlbIndex + i);
#endif
        }

        /* Release the mutex. */
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->pageTableMutex));
        mutex = gcvFALSE;

        gcmkONERROR(_PutStlb(Mmu, stlb));

        /* Success. */
        gcmkFOOTER_NO();
        return gcvSTATUS_OK;
    }

OnError:
    if (mutex)
    {
        /* Release the mutex. */
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->pageTableMutex));
    }

    /* Return the status. */
    gcmkFOOTER();
    return status;
}

gceSTATUS
gckMMU_Enable(
    IN gckMMU Mmu,
    IN gctUINT32 PhysBaseAddr,
    IN gctUINT32 PhysSize
    )
{
    gceSTATUS status;

    gcmkHEADER_ARG("Mmu=0x%x", Mmu);

    /* Verify the arguments. */
    gcmkVERIFY_OBJECT(Mmu, gcvOBJ_MMU);

    if (Mmu->hardware->mmuVersion == 0)
    {
        /* Success. */
        gcmkFOOTER_ARG("Status=%d", gcvSTATUS_SKIP);
        return gcvSTATUS_SKIP;
    }
    else
    {
        if (PhysSize != 0)
        {
            gcmkONERROR(_FillFlatMapping(
                Mmu,
                PhysBaseAddr,
                PhysSize
                ));
        }

        gcmkONERROR(
            gckHARDWARE_SetMMUv2(
                Mmu->hardware,
                gcvTRUE,
                Mmu->pageTableLogical,
                gcvMMU_MODE_4K,
                (gctUINT8_PTR)Mmu->pageTableLogical + gcdMMU_MTLB_SIZE
                ));

        Mmu->enabled = gcvTRUE;

        /* Success. */
        gcmkFOOTER_NO();
        return gcvSTATUS_OK;
    }

OnError:
    /* Return the status. */
    gcmkFOOTER();
    return status;
}

gceSTATUS
gckMMU_SetPage(
    IN gckMMU Mmu,
    IN gctUINT32 PageAddress,
    IN gctUINT32 *PageEntry
    )
{
    gcmkHEADER_ARG("Mmu=0x%x", Mmu);

    /* Verify the arguments. */
    gcmkVERIFY_OBJECT(Mmu, gcvOBJ_MMU);
    gcmkVERIFY_ARGUMENT(PageEntry != gcvNULL);
    gcmkVERIFY_ARGUMENT(!(PageAddress & 0xFFF));

    if (Mmu->hardware->mmuVersion == 0)
    {
        *PageEntry = PageAddress;
    }
    else
    {
        *PageEntry = _SetPage(PageAddress);
    }

    /* Success. */
    gcmkFOOTER_NO();
    return gcvSTATUS_OK;
}

#ifdef __QNXNTO__
gceSTATUS
gckMMU_InsertNode(
    IN gckMMU Mmu,
    IN gcuVIDMEM_NODE_PTR Node)
{
    gceSTATUS status;
    gctBOOL mutex = gcvFALSE;

    gcmkHEADER_ARG("Mmu=0x%x Node=0x%x", Mmu, Node);

    gcmkVERIFY_OBJECT(Mmu, gcvOBJ_MMU);

    gcmkONERROR(gckOS_AcquireMutex(Mmu->os, Mmu->nodeMutex, gcvINFINITE));
    mutex = gcvTRUE;

    Node->Virtual.next = Mmu->nodeList;
    Mmu->nodeList = Node;

    gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->nodeMutex));

    gcmkFOOTER();
    return gcvSTATUS_OK;

OnError:
    if (mutex)
    {
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->nodeMutex));
    }

    gcmkFOOTER();
    return status;
}

gceSTATUS
gckMMU_RemoveNode(
    IN gckMMU Mmu,
    IN gcuVIDMEM_NODE_PTR Node)
{
    gceSTATUS status;
    gctBOOL mutex = gcvFALSE;
    gcuVIDMEM_NODE_PTR *iter;

    gcmkHEADER_ARG("Mmu=0x%x Node=0x%x", Mmu, Node);

    gcmkVERIFY_OBJECT(Mmu, gcvOBJ_MMU);

    gcmkONERROR(gckOS_AcquireMutex(Mmu->os, Mmu->nodeMutex, gcvINFINITE));
    mutex = gcvTRUE;

    for (iter = &Mmu->nodeList; *iter; iter = &(*iter)->Virtual.next)
    {
        if (*iter == Node)
        {
            *iter = Node->Virtual.next;
            break;
        }
    }

    gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->nodeMutex));

    gcmkFOOTER();
    return gcvSTATUS_OK;

OnError:
    if (mutex)
    {
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->nodeMutex));
    }

    gcmkFOOTER();
    return status;
}

gceSTATUS
gckMMU_FreeHandleMemory(
    IN gckKERNEL Kernel,
    IN gckMMU Mmu,
    IN gctUINT32 Pid
    )
{
    gceSTATUS status;
    gctBOOL acquired = gcvFALSE;
    gcuVIDMEM_NODE_PTR curr, next;

    gcmkHEADER_ARG("Kernel=0x%x, Mmu=0x%x Pid=%u", Kernel, Mmu, Pid);

    gcmkVERIFY_OBJECT(Kernel, gcvOBJ_KERNEL);
    gcmkVERIFY_OBJECT(Mmu, gcvOBJ_MMU);

    gcmkONERROR(gckOS_AcquireMutex(Mmu->os, Mmu->nodeMutex, gcvINFINITE));
    acquired = gcvTRUE;

    for (curr = Mmu->nodeList; curr != gcvNULL; curr = next)
    {
        next = curr->Virtual.next;

        if (curr->Virtual.processID == Pid)
        {
            while (curr->Virtual.unlockPendings[Kernel->core] == 0 && curr->Virtual.lockeds[Kernel->core] > 0)
            {
                gcmkONERROR(gckVIDMEM_Unlock(Kernel, curr, gcvSURF_TYPE_UNKNOWN, gcvNULL));
            }

            gcmkVERIFY_OK(gckVIDMEM_Free(curr));
        }
    }

    gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->nodeMutex));

    gcmkFOOTER();
    return gcvSTATUS_OK;

OnError:
    if (acquired)
    {
        gcmkVERIFY_OK(gckOS_ReleaseMutex(Mmu->os, Mmu->nodeMutex));
    }

    gcmkFOOTER();
    return status;
}
#endif

/******************************************************************************
****************************** T E S T   C O D E ******************************
******************************************************************************/