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/*

 * linux/drivers/video/sstfb.c -- voodoo graphics frame buffer

 *

 *     Copyright (c) 2000-2002 Ghozlane Toumi <gtoumi@laposte.net>

 *

 *     Created 15 Jan 2000 by Ghozlane Toumi

 *

 * Contributions (and many thanks) :

 *

 * 03/2001 James Simmons   <jsimmons@infradead.org>

 * 04/2001 Paul Mundt      <lethal@chaoticdreams.org>

 * 05/2001 Urs Ganse       <ursg@uni.de>

 *      (initial work on voodoo2 port, interlace)

 * 09/2002 Helge Deller    <deller@gmx.de>

 *      (enable driver on big-endian machines (hppa), ioctl fixes)

 * 12/2002 Helge Deller    <deller@gmx.de>

 *      (port driver to new frambuffer infrastructure)

 * 01/2003 Helge Deller    <deller@gmx.de>

 *      (initial work on fb hardware acceleration for voodoo2)

 * 08/2006 Alan Cox        <alan@redhat.com>

 *      Remove never finished and bogus 24/32bit support

 *      Clean up macro abuse

 *      Minor tidying for format.

 * 12/2006 Helge Deller    <deller@gmx.de>

 *      add /sys/class/graphics/fbX/vgapass sysfs-interface

 *      add module option "mode_option" to set initial screen mode

 *      use fbdev default videomode database

 *      remove debug functions from ioctl

 */

/*

 * The voodoo1 has the following memory mapped address space:

 * 0x000000 - 0x3fffff : registers              (4MB)

 * 0x400000 - 0x7fffff : linear frame buffer    (4MB)

 * 0x800000 - 0xffffff : texture memory         (8MB)

 */

/*

 * misc notes, TODOs, toASKs, and deep thoughts

-TODO: at one time or another test that the mode is acceptable by the monitor

-ASK: Can I choose different ordering for the color bitfields (rgba argb ...)

      which one should i use ? is there any preferred one ? It seems ARGB is

      the one ...

-TODO: in  set_var check the validity of timings (hsync vsync)...

-TODO: check and recheck the use of sst_wait_idle : we don't flush the fifo via

       a nop command. so it's ok as long as the commands we pass don't go

       through the fifo. warning: issuing a nop command seems to need pci_fifo

-FIXME: in case of failure in the init sequence, be sure we return to a safe

        state.

- FIXME: Use accelerator for 2D scroll

-FIXME: 4MB boards have banked memory (FbiInit2 bits 1 & 20)

 */

/*

 * debug info

 * SST_DEBUG : enable debugging

 * SST_DEBUG_REG : debug registers

 *   0 :  no debug

 *   1 : dac calls, [un]set_bits, FbiInit

 *   2 : insane debug level (log every register read/write)

 * SST_DEBUG_FUNC : functions

 *   0 : no debug

 *   1 : function call / debug ioctl

 *   2 : variables

 *   3 : flood . you don't want to do that. trust me.

 * SST_DEBUG_VAR : debug display/var structs

 *   0 : no debug

 *   1 : dumps display, fb_var

 *

 * sstfb specific ioctls:

 *              toggle vga (0x46db) : toggle vga_pass_through

 */

#undef SST_DEBUG

/*

 * Includes

 */

#include <linux/string.h>

#include <linux/kernel.h>

#include <linux/module.h>

#include <linux/fb.h>

#include <linux/pci.h>

#include <linux/delay.h>

#include <linux/init.h>

#include <linux/slab.h>

#include <asm/io.h>

#include <linux/uaccess.h>

#include <video/sstfb.h>

/* initialized by setup */

static int vgapass;             /* enable VGA passthrough cable */

static int mem;                 /* mem size in MB, 0 = autodetect */

static int clipping = 1;        /* use clipping (slower, safer) */

static int gfxclk;              /* force FBI freq in Mhz . Dangerous */

static int slowpci;             /* slow PCI settings */

/*

  Possible default video modes: 800x600@60, 640x480@75, 1024x768@76, 640x480@60

*/

#define DEFAULT_VIDEO_MODE "640x480@60"

static char *mode_option __devinitdata = DEFAULT_VIDEO_MODE;

enum {

        ID_VOODOO1 = 0,

        ID_VOODOO2 = 1,

};

#define IS_VOODOO2(par) ((par)->type == ID_VOODOO2)

static struct sst_spec voodoo_spec[] __devinitdata = {

 { .name = "Voodoo Graphics", .default_gfx_clock = 50000, .max_gfxclk = 60 },

 { .name = "Voodoo2",         .default_gfx_clock = 75000, .max_gfxclk = 85 },

};

/*

 * debug functions

 */

#if (SST_DEBUG_REG > 0)

static void sst_dbg_print_read_reg(u32 reg, u32 val) {

        const char *regname;

        switch (reg) {

        case FBIINIT0:  regname = "FbiInit0"; break;

        case FBIINIT1:  regname = "FbiInit1"; break;

        case FBIINIT2:  regname = "FbiInit2"; break;

        case FBIINIT3:  regname = "FbiInit3"; break;

        case FBIINIT4:  regname = "FbiInit4"; break;

        case FBIINIT5:  regname = "FbiInit5"; break;

        case FBIINIT6:  regname = "FbiInit6"; break;

        default:        regname = NULL;       break;

        }

        if (regname == NULL)

                r_ddprintk("sst_read(%#x): %#x\n", reg, val);

        else

                r_dprintk(" sst_read(%s): %#x\n", regname, val);

}

static void sst_dbg_print_write_reg(u32 reg, u32 val) {

        const char *regname;

        switch (reg) {

        case FBIINIT0:  regname = "FbiInit0"; break;

        case FBIINIT1:  regname = "FbiInit1"; break;

        case FBIINIT2:  regname = "FbiInit2"; break;

        case FBIINIT3:  regname = "FbiInit3"; break;

        case FBIINIT4:  regname = "FbiInit4"; break;

        case FBIINIT5:  regname = "FbiInit5"; break;

        case FBIINIT6:  regname = "FbiInit6"; break;

        default:        regname = NULL;       break;

        }

        if (regname == NULL)

                r_ddprintk("sst_write(%#x, %#x)\n", reg, val);

        else

                r_dprintk(" sst_write(%s, %#x)\n", regname, val);

}

#else /*  (SST_DEBUG_REG > 0) */

#  define sst_dbg_print_read_reg(reg, val)      do {} while(0)

#  define sst_dbg_print_write_reg(reg, val)     do {} while(0)

#endif /*  (SST_DEBUG_REG > 0) */

/*

 * hardware access functions

 */

/* register access */

#define sst_read(reg)           __sst_read(par->mmio_vbase, reg)

#define sst_write(reg,val)      __sst_write(par->mmio_vbase, reg, val)

#define sst_set_bits(reg,val)   __sst_set_bits(par->mmio_vbase, reg, val)

#define sst_unset_bits(reg,val) __sst_unset_bits(par->mmio_vbase, reg, val)

#define sst_dac_read(reg)       __sst_dac_read(par->mmio_vbase, reg)

#define sst_dac_write(reg,val)  __sst_dac_write(par->mmio_vbase, reg, val)

#define dac_i_read(reg)         __dac_i_read(par->mmio_vbase, reg)

#define dac_i_write(reg,val)    __dac_i_write(par->mmio_vbase, reg, val)

static inline u32 __sst_read(u8 __iomem *vbase, u32 reg)

{

        u32 ret = readl(vbase + reg);

        sst_dbg_print_read_reg(reg, ret);

        return ret;

}

static inline void __sst_write(u8 __iomem *vbase, u32 reg, u32 val)

{

        sst_dbg_print_write_reg(reg, val);

        writel(val, vbase + reg);

}

static inline void __sst_set_bits(u8 __iomem *vbase, u32 reg, u32 val)

{

        r_dprintk("sst_set_bits(%#x, %#x)\n", reg, val);

        __sst_write(vbase, reg, __sst_read(vbase, reg) | val);

}

static inline void __sst_unset_bits(u8 __iomem *vbase, u32 reg, u32 val)

{

        r_dprintk("sst_unset_bits(%#x, %#x)\n", reg, val);

        __sst_write(vbase, reg, __sst_read(vbase, reg) & ~val);

}

/*

 * wait for the fbi chip. ASK: what happens if the fbi is stuck ?

 *

 * the FBI is supposed to be ready if we receive 5 time

 * in a row a "idle" answer to our requests

 */

#define sst_wait_idle() __sst_wait_idle(par->mmio_vbase)

static int __sst_wait_idle(u8 __iomem *vbase)

{

        int count = 0;

        /* if (doFBINOP) __sst_write(vbase, NOPCMD, 0); */

        while(1) {

                if (__sst_read(vbase, STATUS) & STATUS_FBI_BUSY) {

                        f_dddprintk("status: busy\n");

/* FIXME basicaly, this is a busy wait. maybe not that good. oh well;

 * this is a small loop after all.

 * Or maybe we should use mdelay() or udelay() here instead ? */

                        count = 0;

                } else {

                        count++;

                        f_dddprintk("status: idle(%d)\n", count);

                }

                if (count >= 5) return 1;

/* XXX  do something to avoid hanging the machine if the voodoo is out */

        }

}

/* dac access */

/* dac_read should be remaped to FbiInit2 (via the pci reg init_enable) */

static u8 __sst_dac_read(u8 __iomem *vbase, u8 reg)

{

        u8 ret;

        reg &= 0x07;

        __sst_write(vbase, DAC_DATA, ((u32)reg << 8) | DAC_READ_CMD );

        __sst_wait_idle(vbase);

        /* udelay(10); */

        ret = __sst_read(vbase, DAC_READ) & 0xff;

        r_dprintk("sst_dac_read(%#x): %#x\n", reg, ret);

        return ret;

}

static void __sst_dac_write(u8 __iomem *vbase, u8 reg, u8 val)

{

        r_dprintk("sst_dac_write(%#x, %#x)\n", reg, val);

        reg &= 0x07;

        __sst_write(vbase, DAC_DATA,(((u32)reg << 8)) | (u32)val);

        __sst_wait_idle(vbase);

}

/* indexed access to ti/att dacs */

static u32 __dac_i_read(u8 __iomem *vbase, u8 reg)

{

        u32 ret;

        __sst_dac_write(vbase, DACREG_ADDR_I, reg);

        ret = __sst_dac_read(vbase, DACREG_DATA_I);

        r_dprintk("sst_dac_read_i(%#x): %#x\n", reg, ret);

        return ret;

}

static void __dac_i_write(u8 __iomem *vbase, u8 reg,u8 val)

{

        r_dprintk("sst_dac_write_i(%#x, %#x)\n", reg, val);

        __sst_dac_write(vbase, DACREG_ADDR_I, reg);

        __sst_dac_write(vbase, DACREG_DATA_I, val);

}

/* compute the m,n,p  , returns the real freq

 * (ics datasheet :  N <-> N1 , P <-> N2)

 *

 * Fout= Fref * (M+2)/( 2^P * (N+2))

 *  we try to get close to the asked freq

 *  with P as high, and M as low as possible

 * range:

 * ti/att : 0 <= M <= 255; 0 <= P <= 3; 0<= N <= 63

 * ics    : 1 <= M <= 127; 0 <= P <= 3; 1<= N <= 31

 * we'll use the lowest limitation, should be precise enouth

 */

static int sst_calc_pll(const int freq, int *freq_out, struct pll_timing *t)

{

        int m, m2, n, p, best_err, fout;

        int best_n = -1;

        int best_m = -1;

        best_err = freq;

        p = 3;

        /* f * 2^P = vco should be less than VCOmax ~ 250 MHz for ics*/

        while (((1 << p) * freq > VCO_MAX) && (p >= 0))

                p--;

        if (p == -1)

                return -EINVAL;

        for (n = 1; n < 32; n++) {

                /* calc 2 * m so we can round it later*/

                m2 = (2 * freq * (1 << p) * (n + 2) ) / DAC_FREF - 4 ;

                m = (m2 % 2 ) ? m2/2+1 : m2/2 ;

                if (m >= 128)

                        break;

                fout = (DAC_FREF * (m + 2)) / ((1 << p) * (n + 2));

                if ((abs(fout - freq) < best_err) && (m > 0)) {

                        best_n = n;

                        best_m = m;

                        best_err = abs(fout - freq);

                        /* we get the lowest m , allowing 0.5% error in freq*/

                        if (200*best_err < freq) break;

                }

        }

        if (best_n == -1)  /* unlikely, but who knows ? */

                return -EINVAL;

        t->p = p;

        t->n = best_n;

        t->m = best_m;

        *freq_out = (DAC_FREF * (t->m + 2)) / ((1 << t->p) * (t->n + 2));

        f_ddprintk ("m: %d, n: %d, p: %d, F: %dKhz\n",

                  t->m, t->n, t->p, *freq_out);

        return 0;

}

/*

 * clear lfb screen

 */

static void sstfb_clear_screen(struct fb_info *info)

{

        /* clear screen */

        fb_memset(info->screen_base, 0, info->fix.smem_len);

}

/**

 *      sstfb_check_var - Optional function.  Validates a var passed in.

 *      @var: frame buffer variable screen structure

 *      @info: frame buffer structure that represents a single frame buffer

 *

 *      Limit to the abilities of a single chip as SLI is not supported

 *      by this driver.

 */

static int sstfb_check_var(struct fb_var_screeninfo *var,

                struct fb_info *info)

{

        struct sstfb_par *par = info->par;

        int hSyncOff   = var->xres + var->right_margin + var->left_margin;

        int vSyncOff   = var->yres + var->lower_margin + var->upper_margin;

        int vBackPorch = var->left_margin, yDim = var->yres;

        int vSyncOn    = var->vsync_len;

        int tiles_in_X, real_length;

        unsigned int freq;

        if (sst_calc_pll(PICOS2KHZ(var->pixclock), &freq, &par->pll)) {

                printk(KERN_ERR "sstfb: Pixclock at %ld KHZ out of range\n",

                                PICOS2KHZ(var->pixclock));

                return -EINVAL;

        }

        var->pixclock = KHZ2PICOS(freq);

        if (var->vmode & FB_VMODE_INTERLACED)

                vBackPorch += (vBackPorch % 2);

        if (var->vmode & FB_VMODE_DOUBLE) {

                vBackPorch <<= 1;

                yDim <<=1;

                vSyncOn <<=1;

                vSyncOff <<=1;

        }

        switch (var->bits_per_pixel) {

        case 0 ... 16 :

                var->bits_per_pixel = 16;

                break;

        default :

                printk(KERN_ERR "sstfb: Unsupported bpp %d\n", var->bits_per_pixel);

                return -EINVAL;

        }

        /* validity tests */

        if (var->xres <= 1 || yDim <= 0 || var->hsync_len <= 1  ||

            hSyncOff <= 1  || var->left_margin <= 2  || vSyncOn <= 0 ||

            vSyncOff <= 0 || vBackPorch <= 0) {

                return -EINVAL;

        }

        if (IS_VOODOO2(par)) {

                /* Voodoo 2 limits */

                tiles_in_X = (var->xres + 63 ) / 64 * 2;

                if (var->xres  > POW2(11) || yDim >= POW2(11)) {

                        printk(KERN_ERR "sstfb: Unsupported resolution %dx%d\n",

                                 var->xres, var->yres);

                        return -EINVAL;

                }

                if (var->hsync_len > POW2(9) || hSyncOff > POW2(11) ||

                    var->left_margin - 2 >= POW2(9) || vSyncOn >= POW2(13) ||

                    vSyncOff >= POW2(13) || vBackPorch >= POW2(9) ||

                    tiles_in_X >= POW2(6) || tiles_in_X <= 0) {

                        printk(KERN_ERR "sstfb: Unsupported timings\n");

                        return -EINVAL;

                }

        } else {

                /* Voodoo limits */

                tiles_in_X = (var->xres + 63 ) / 64;

                if (var->vmode) {

                        printk(KERN_ERR "sstfb: Interlace/doublescan not supported %#x\n",

                                var->vmode);

                        return -EINVAL;

                }

                if (var->xres > POW2(10) || var->yres >= POW2(10)) {

                        printk(KERN_ERR "sstfb: Unsupported resolution %dx%d\n",

                                 var->xres, var->yres);

                        return -EINVAL;

                }

                if (var->hsync_len > POW2(8) || hSyncOff - 1 > POW2(10) ||

                    var->left_margin - 2 >= POW2(8) || vSyncOn >= POW2(12) ||

                    vSyncOff >= POW2(12) || vBackPorch >= POW2(8) ||

                    tiles_in_X >= POW2(4) || tiles_in_X <= 0) {

                        printk(KERN_ERR "sstfb: Unsupported timings\n");

                        return -EINVAL;

                }

        }

        /* it seems that the fbi uses tiles of 64x16 pixels to "map" the mem */

        /* FIXME: i don't like this... looks wrong */

        real_length = tiles_in_X  * (IS_VOODOO2(par) ? 32 : 64 )

                      * ((var->bits_per_pixel == 16) ? 2 : 4);

        if (real_length * yDim > info->fix.smem_len) {

                printk(KERN_ERR "sstfb: Not enough video memory\n");

                return -ENOMEM;

        }

        var->sync &= (FB_SYNC_HOR_HIGH_ACT | FB_SYNC_VERT_HIGH_ACT);

        var->vmode &= (FB_VMODE_INTERLACED | FB_VMODE_DOUBLE);

        var->xoffset = 0;

        var->yoffset = 0;

        var->height  = -1;

        var->width   = -1;

        /*

         * correct the color bit fields

         */

        /* var->{red|green|blue}.msb_right = 0; */

        switch (var->bits_per_pixel) {

        case 16:        /* RGB 565  LfbMode 0 */

                var->red.length    = 5;

                var->green.length  = 6;

                var->blue.length   = 5;

                var->transp.length = 0;

                var->red.offset    = 11;

                var->green.offset  = 5;

                var->blue.offset   = 0;

                var->transp.offset = 0;

                break;

        default:

                return -EINVAL;

        }

        return 0;

}

/**

 *      sstfb_set_par - Optional function.  Alters the hardware state.

 *      @info: frame buffer structure that represents a single frame buffer

 */

static int sstfb_set_par(struct fb_info *info)

{

        struct sstfb_par *par = info->par;

        u32 lfbmode, fbiinit1, fbiinit2, fbiinit3, fbiinit5, fbiinit6=0;

        struct pci_dev *sst_dev = par->dev;

        unsigned int freq;

        int ntiles;

        par->hSyncOff   = info->var.xres + info->var.right_margin + info->var.left_margin;

        par->yDim       = info->var.yres;

        par->vSyncOn    = info->var.vsync_len;

        par->vSyncOff   = info->var.yres + info->var.lower_margin + info->var.upper_margin;

        par->vBackPorch = info->var.upper_margin;

        /* We need par->pll */

        sst_calc_pll(PICOS2KHZ(info->var.pixclock), &freq, &par->pll);

        if (info->var.vmode & FB_VMODE_INTERLACED)

                par->vBackPorch += (par->vBackPorch % 2);

        if (info->var.vmode & FB_VMODE_DOUBLE) {

                par->vBackPorch <<= 1;

                par->yDim <<=1;

                par->vSyncOn <<=1;

                par->vSyncOff <<=1;

        }

        if (IS_VOODOO2(par)) {

                /* voodoo2 has 32 pixel wide tiles , BUT stange things

                   happen with odd number of tiles */

                par->tiles_in_X = (info->var.xres + 63 ) / 64 * 2;

        } else {

                /* voodoo1 has 64 pixels wide tiles. */

                par->tiles_in_X = (info->var.xres + 63 ) / 64;

        }

        f_ddprintk("hsync_len hSyncOff vsync_len vSyncOff\n");

        f_ddprintk("%-7d %-8d %-7d %-8d\n",

                   info->var.hsync_len, par->hSyncOff,

                   par->vSyncOn, par->vSyncOff);

        f_ddprintk("left_margin upper_margin xres yres Freq\n");

        f_ddprintk("%-10d %-10d %-4d %-4d %-8ld\n",

                   info->var.left_margin, info->var.upper_margin,

                   info->var.xres, info->var.yres, PICOS2KHZ(info->var.pixclock));

        sst_write(NOPCMD, 0);

        sst_wait_idle();

        pci_write_config_dword(sst_dev, PCI_INIT_ENABLE, PCI_EN_INIT_WR);

        sst_set_bits(FBIINIT1, VIDEO_RESET);

        sst_set_bits(FBIINIT0, FBI_RESET | FIFO_RESET);

        sst_unset_bits(FBIINIT2, EN_DRAM_REFRESH);

        sst_wait_idle();

        /*sst_unset_bits (FBIINIT0, FBI_RESET); / reenable FBI ? */

        sst_write(BACKPORCH, par->vBackPorch << 16 | (info->var.left_margin - 2));

        sst_write(VIDEODIMENSIONS, par->yDim << 16 | (info->var.xres - 1));

        sst_write(HSYNC, (par->hSyncOff - 1) << 16 | (info->var.hsync_len - 1));

        sst_write(VSYNC,       par->vSyncOff << 16 | par->vSyncOn);

        fbiinit2 = sst_read(FBIINIT2);

        fbiinit3 = sst_read(FBIINIT3);

        /* everything is reset. we enable fbiinit2/3 remap : dac acces ok */

        pci_write_config_dword(sst_dev, PCI_INIT_ENABLE,

                               PCI_EN_INIT_WR | PCI_REMAP_DAC );

        par->dac_sw.set_vidmod(info, info->var.bits_per_pixel);

        /* set video clock */

        par->dac_sw.set_pll(info, &par->pll, VID_CLOCK);

        /* disable fbiinit2/3 remap */

        pci_write_config_dword(sst_dev, PCI_INIT_ENABLE,

                               PCI_EN_INIT_WR);

        /* restore fbiinit2/3 */

        sst_write(FBIINIT2,fbiinit2);

        sst_write(FBIINIT3,fbiinit3);

        fbiinit1 = (sst_read(FBIINIT1) & VIDEO_MASK)

                    | EN_DATA_OE

                    | EN_BLANK_OE

                    | EN_HVSYNC_OE

                    | EN_DCLK_OE

                 /* | (15 << TILES_IN_X_SHIFT) */

                    | SEL_INPUT_VCLK_2X

                 /* | (2 << VCLK_2X_SEL_DEL_SHIFT)

                    | (2 << VCLK_DEL_SHIFT) */;

/* try with vclk_in_delay =0 (bits 29:30) , vclk_out_delay =0 (bits(27:28)

 in (near) future set them accordingly to revision + resolution (cf glide)

 first understand what it stands for :)

 FIXME: there are some artefacts... check for the vclk_in_delay

 lets try with 6ns delay in both vclk_out & in...

 doh... they're still there :\

*/

        ntiles = par->tiles_in_X;

        if (IS_VOODOO2(par)) {

                fbiinit1 |= ((ntiles & 0x20) >> 5) << TILES_IN_X_MSB_SHIFT

                            | ((ntiles & 0x1e) >> 1) << TILES_IN_X_SHIFT;

/* as the only value of importance for us in fbiinit6 is tiles in X (lsb),

   and as reading fbinit 6 will return crap (see FBIINIT6_DEFAULT) we just

   write our value. BTW due to the dac unable to read odd number of tiles, this

   field is always null ... */

                fbiinit6 = (ntiles & 0x1) << TILES_IN_X_LSB_SHIFT;

        }

        else

                fbiinit1 |= ntiles << TILES_IN_X_SHIFT;

        switch (info->var.bits_per_pixel) {

        case 16:

                fbiinit1 |=  SEL_SOURCE_VCLK_2X_SEL;

                break;

        default:

                return -EINVAL;

        }

        sst_write(FBIINIT1, fbiinit1);

        if (IS_VOODOO2(par)) {

                sst_write(FBIINIT6, fbiinit6);

                fbiinit5=sst_read(FBIINIT5) & FBIINIT5_MASK ;

                if (info->var.vmode & FB_VMODE_INTERLACED)

                        fbiinit5 |= INTERLACE;

                if (info->var.vmode & FB_VMODE_DOUBLE)

                        fbiinit5 |= VDOUBLESCAN;

                if (info->var.sync & FB_SYNC_HOR_HIGH_ACT)

                        fbiinit5 |= HSYNC_HIGH;

                if (info->var.sync & FB_SYNC_VERT_HIGH_ACT)

                        fbiinit5 |= VSYNC_HIGH;

                sst_write(FBIINIT5, fbiinit5);

        }

        sst_wait_idle();

        sst_unset_bits(FBIINIT1, VIDEO_RESET);

        sst_unset_bits(FBIINIT0, FBI_RESET | FIFO_RESET);

        sst_set_bits(FBIINIT2, EN_DRAM_REFRESH);

        /* disables fbiinit writes */

        pci_write_config_dword(sst_dev, PCI_INIT_ENABLE, PCI_EN_FIFO_WR);

        /* set lfbmode : set mode + front buffer for reads/writes

           + disable pipeline */

        switch (info->var.bits_per_pixel) {

        case 16:

                lfbmode = LFB_565;

                break;

        default:

                return -EINVAL;

        }

#if defined(__BIG_ENDIAN)

        /* Enable byte-swizzle functionality in hardware.

         * With this enabled, all our read- and write-accesses to

         * the voodoo framebuffer can be done in native format, and

         * the hardware will automatically convert it to little-endian.

         * - tested on HP-PARISC, Helge Deller <deller@gmx.de> */

        lfbmode |= ( LFB_WORD_SWIZZLE_WR | LFB_BYTE_SWIZZLE_WR |

                     LFB_WORD_SWIZZLE_RD | LFB_BYTE_SWIZZLE_RD );

#endif

        if (clipping) {

                sst_write(LFBMODE, lfbmode | EN_PXL_PIPELINE);

        /*

         * Set "clipping" dimensions. If clipping is disabled and

         * writes to offscreen areas of the framebuffer are performed,

         * the "behaviour is undefined" (_very_ undefined) - Urs

         */

        /* btw, it requires enabling pixel pipeline in LFBMODE .

           off screen read/writes will just wrap and read/print pixels

           on screen. Ugly but not that dangerous */

                f_ddprintk("setting clipping dimensions 0..%d, 0..%d\n",

                            info->var.xres - 1, par->yDim - 1);

                sst_write(CLIP_LEFT_RIGHT, info->var.xres);

                sst_write(CLIP_LOWY_HIGHY, par->yDim);

                sst_set_bits(FBZMODE, EN_CLIPPING | EN_RGB_WRITE);

        } else {

                /* no clipping : direct access, no pipeline */

                sst_write(LFBMODE, lfbmode);

        }

        return 0;

}

/**

 *      sstfb_setcolreg - Optional function. Sets a color register.

 *      @regno: hardware colormap register

 *      @red: frame buffer colormap structure

 *      @green: The green value which can be up to 16 bits wide

 *      @blue:  The blue value which can be up to 16 bits wide.