[PATCH] fbcon/fbdev: Move softcursor out of fbdev to fbcon

[safe/jmp/linux-2.6] / drivers / video / skeletonfb.c

/*
 * linux/drivers/video/skeletonfb.c -- Skeleton for a frame buffer device
 *
 *  Modified to new api Jan 2001 by James Simmons (jsimmons@transvirtual.com)
 *
 *  Created 28 Dec 1997 by Geert Uytterhoeven
 *
 *
 *  I have started rewriting this driver as a example of the upcoming new API
 *  The primary goal is to remove the console code from fbdev and place it
 *  into fbcon.c. This reduces the code and makes writing a new fbdev driver
 *  easy since the author doesn't need to worry about console internals. It
 *  also allows the ability to run fbdev without a console/tty system on top 
 *  of it. 
 *
 *  First the roles of struct fb_info and struct display have changed. Struct
 *  display will go away. The way the the new framebuffer console code will
 *  work is that it will act to translate data about the tty/console in 
 *  struct vc_data to data in a device independent way in struct fb_info. Then
 *  various functions in struct fb_ops will be called to store the device 
 *  dependent state in the par field in struct fb_info and to change the 
 *  hardware to that state. This allows a very clean separation of the fbdev
 *  layer from the console layer. It also allows one to use fbdev on its own
 *  which is a bounus for embedded devices. The reason this approach works is  
 *  for each framebuffer device when used as a tty/console device is allocated
 *  a set of virtual terminals to it. Only one virtual terminal can be active 
 *  per framebuffer device. We already have all the data we need in struct 
 *  vc_data so why store a bunch of colormaps and other fbdev specific data
 *  per virtual terminal. 
 *
 *  As you can see doing this makes the con parameter pretty much useless
 *  for struct fb_ops functions, as it should be. Also having struct  
 *  fb_var_screeninfo and other data in fb_info pretty much eliminates the 
 *  need for get_fix and get_var. Once all drivers use the fix, var, and cmap
 *  fbcon can be written around these fields. This will also eliminate the
 *  need to regenerate struct fb_var_screeninfo, struct fb_fix_screeninfo
 *  struct fb_cmap every time get_var, get_fix, get_cmap functions are called
 *  as many drivers do now. 
 *
 *  This file is subject to the terms and conditions of the GNU General Public
 *  License. See the file COPYING in the main directory of this archive for
 *  more details.
 */

#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/string.h>
#include <linux/mm.h>
#include <linux/tty.h>
#include <linux/slab.h>
#include <linux/delay.h>
#include <linux/fb.h>
#include <linux/init.h>

    /*
     *  This is just simple sample code.
     *
     *  No warranty that it actually compiles.
     *  Even less warranty that it actually works :-)
     */

/*
 *  If your driver supports multiple boards, you should make the  
 *  below data types arrays, or allocate them dynamically (using kmalloc()). 
 */ 

/* 
 * This structure defines the hardware state of the graphics card. Normally
 * you place this in a header file in linux/include/video. This file usually
 * also includes register information. That allows other driver subsystems
 * and userland applications the ability to use the same header file to 
 * avoid duplicate work and easy porting of software. 
 */
struct xxx_par;

/*
 * Here we define the default structs fb_fix_screeninfo and fb_var_screeninfo
 * if we don't use modedb. If we do use modedb see xxxfb_init how to use it
 * to get a fb_var_screeninfo. Otherwise define a default var as well. 
 */
static struct fb_fix_screeninfo xxxfb_fix __initdata = {
        .id =           "FB's name", 
        .type =         FB_TYPE_PACKED_PIXELS,
        .visual =       FB_VISUAL_PSEUDOCOLOR,
        .xpanstep =     1,
        .ypanstep =     1,
        .ywrapstep =    1, 
        .accel =        FB_ACCEL_NONE,
};

    /*
     *  Modern graphical hardware not only supports pipelines but some 
     *  also support multiple monitors where each display can have its  
     *  its own unique data. In this case each display could be  
     *  represented by a separate framebuffer device thus a separate 
     *  struct fb_info. Now the struct xxx_par represents the graphics
     *  hardware state thus only one exist per card. In this case the 
     *  struct xxx_par for each graphics card would be shared between 
     *  every struct fb_info that represents a framebuffer on that card. 
     *  This allows when one display changes it video resolution (info->var) 
     *  the other displays know instantly. Each display can always be
     *  aware of the entire hardware state that affects it because they share
     *  the same xxx_par struct. The other side of the coin is multiple
     *  graphics cards that pass data around until it is finally displayed
     *  on one monitor. Such examples are the voodoo 1 cards and high end
     *  NUMA graphics servers. For this case we have a bunch of pars, each
     *  one that represents a graphics state, that belong to one struct 
     *  fb_info. Their you would want to have *par point to a array of device
     *  states and have each struct fb_ops function deal with all those 
     *  states. I hope this covers every possible hardware design. If not
     *  feel free to send your ideas at jsimmons@users.sf.net 
     */

    /*
     *  If your driver supports multiple boards or it supports multiple 
     *  framebuffers, you should make these arrays, or allocate them 
     *  dynamically (using kmalloc()). 
     */ 
static struct fb_info info;

    /* 
     * Each one represents the state of the hardware. Most hardware have
     * just one hardware state. These here represent the default state(s). 
     */
static struct xxx_par __initdata current_par;

int xxxfb_init(void);
int xxxfb_setup(char*);

/**
 *      xxxfb_open - Optional function. Called when the framebuffer is
 *                   first accessed.
 *      @info: frame buffer structure that represents a single frame buffer
 *      @user: tell us if the userland (value=1) or the console is accessing
 *             the framebuffer. 
 *
 *      This function is the first function called in the framebuffer api.
 *      Usually you don't need to provide this function. The case where it 
 *      is used is to change from a text mode hardware state to a graphics
 *      mode state. 
 *
 *      Returns negative errno on error, or zero on success.
 */
static int xxxfb_open(const struct fb_info *info, int user)
{
    return 0;
}

/**
 *      xxxfb_release - Optional function. Called when the framebuffer 
 *                      device is closed. 
 *      @info: frame buffer structure that represents a single frame buffer
 *      @user: tell us if the userland (value=1) or the console is accessing
 *             the framebuffer. 
 *      
 *      Thus function is called when we close /dev/fb or the framebuffer 
 *      console system is released. Usually you don't need this function.
 *      The case where it is usually used is to go from a graphics state
 *      to a text mode state.
 *
 *      Returns negative errno on error, or zero on success.
 */
static int xxxfb_release(const struct fb_info *info, int user)
{
    return 0;
}

/**
 *      xxxfb_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 
 *
 *      Checks to see if the hardware supports the state requested by
 *      var passed in. This function does not alter the hardware state!!! 
 *      This means the data stored in struct fb_info and struct xxx_par do 
 *      not change. This includes the var inside of struct fb_info. 
 *      Do NOT change these. This function can be called on its own if we
 *      intent to only test a mode and not actually set it. The stuff in 
 *      modedb.c is a example of this. If the var passed in is slightly 
 *      off by what the hardware can support then we alter the var PASSED in
 *      to what we can do. If the hardware doesn't support mode change 
 *      a -EINVAL will be returned by the upper layers. You don't need to 
 *      implement this function then. If you hardware doesn't support 
 *      changing the resolution then this function is not needed. In this
 *      case the driver woudl just provide a var that represents the static
 *      state the screen is in.
 *
 *      Returns negative errno on error, or zero on success.
 */
static int xxxfb_check_var(struct fb_var_screeninfo *var, struct fb_info *info)
{
    const struct xxx_par *par = (const struct xxx_par *) info->par;
    /* ... */
    return 0;           
}

/**
 *      xxxfb_set_par - Optional function. Alters the hardware state.
 *      @info: frame buffer structure that represents a single frame buffer
 *
 *      Using the fb_var_screeninfo in fb_info we set the resolution of the
 *      this particular framebuffer. This function alters the par AND the
 *      fb_fix_screeninfo stored in fb_info. It doesn't not alter var in 
 *      fb_info since we are using that data. This means we depend on the
 *      data in var inside fb_info to be supported by the hardware. 
 *      xxxfb_check_var is always called before xxxfb_set_par to ensure this.
 *      Again if you can't change the resolution you don't need this function.
 *
 *      Returns negative errno on error, or zero on success.
 */
static int xxxfb_set_par(struct fb_info *info)
{
    struct xxx_par *par = (struct xxx_par *) info->par;
    /* ... */
    return 0;   
}

/**
 *      xxxfb_setcolreg - Optional function. Sets a color register.
 *      @regno: Which register in the CLUT we are programming 
 *      @red: The red value which can be up to 16 bits wide 
 *      @green: The green value which can be up to 16 bits wide 
 *      @blue:  The blue value which can be up to 16 bits wide.
 *      @transp: If supported, the alpha value which can be up to 16 bits wide.
 *      @info: frame buffer info structure
 * 
 *      Set a single color register. The values supplied have a 16 bit
 *      magnitude which needs to be scaled in this function for the hardware. 
 *      Things to take into consideration are how many color registers, if
 *      any, are supported with the current color visual. With truecolor mode
 *      no color palettes are supported. Here a pseudo palette is created
 *      which we store the value in pseudo_palette in struct fb_info. For
 *      pseudocolor mode we have a limited color palette. To deal with this
 *      we can program what color is displayed for a particular pixel value.
 *      DirectColor is similar in that we can program each color field. If
 *      we have a static colormap we don't need to implement this function. 
 * 
 *      Returns negative errno on error, or zero on success.
 */
static int xxxfb_setcolreg(unsigned regno, unsigned red, unsigned green,
                           unsigned blue, unsigned transp,
                           const struct fb_info *info)
{
    if (regno >= 256)  /* no. of hw registers */
       return -EINVAL;
    /*
     * Program hardware... do anything you want with transp
     */

    /* grayscale works only partially under directcolor */
    if (info->var.grayscale) {
       /* grayscale = 0.30*R + 0.59*G + 0.11*B */
       red = green = blue = (red * 77 + green * 151 + blue * 28) >> 8;
    }

    /* Directcolor:
     *   var->{color}.offset contains start of bitfield
     *   var->{color}.length contains length of bitfield
     *   {hardwarespecific} contains width of DAC
     *   cmap[X] is programmed to (X << red.offset) | (X << green.offset) | (X << blue.offset)
     *   RAMDAC[X] is programmed to (red, green, blue)
     *
     * Pseudocolor:
     *    uses offset = 0 && length = DAC register width.
     *    var->{color}.offset is 0
     *    var->{color}.length contains widht of DAC
     *    cmap is not used
     *    DAC[X] is programmed to (red, green, blue)
     * Truecolor:
     *    does not use RAMDAC (usually has 3 of them).
     *    var->{color}.offset contains start of bitfield
     *    var->{color}.length contains length of bitfield
     *    cmap is programmed to (red << red.offset) | (green << green.offset) |
     *                      (blue << blue.offset) | (transp << transp.offset)
     *    RAMDAC does not exist
     */
#define CNVT_TOHW(val,width) ((((val)<<(width))+0x7FFF-(val))>>16)
    switch (info->fix.visual) {
       case FB_VISUAL_TRUECOLOR:
       case FB_VISUAL_PSEUDOCOLOR:
               red = CNVT_TOHW(red, info->var.red.length);
               green = CNVT_TOHW(green, info->var.green.length);
               blue = CNVT_TOHW(blue, info->var.blue.length);
               transp = CNVT_TOHW(transp, info->var.transp.length);
               break;
       case FB_VISUAL_DIRECTCOLOR:
               /* example here assumes 8 bit DAC. Might be different 
                * for your hardware */  
               red = CNVT_TOHW(red, 8);       
               green = CNVT_TOHW(green, 8);
               blue = CNVT_TOHW(blue, 8);
               /* hey, there is bug in transp handling... */
               transp = CNVT_TOHW(transp, 8);
               break;
    }
#undef CNVT_TOHW
    /* Truecolor has hardware independent palette */
    if (info->fix.visual == FB_VISUAL_TRUECOLOR) {
       u32 v;

       if (regno >= 16)
           return -EINVAL;

       v = (red << info->var.red.offset) |
           (green << info->var.green.offset) |
           (blue << info->var.blue.offset) |
           (transp << info->var.transp.offset);

       switch (info->var.bits_per_pixel) {
                case 8:
                        /* Yes some hand held devices have this. */ 
                        ((u8*)(info->pseudo_palette))[regno] = v;
                        break;  
                case 16:
                        ((u16*)(info->pseudo_palette))[regno] = v;
                        break;
                case 24:
                case 32:        
                        ((u32*)(info->pseudo_palette))[regno] = v;
                        break;
       }
       return 0;
    }
    /* ... */
    return 0;
}

/**
 *      xxxfb_pan_display - NOT a required function. Pans the display.
 *      @var: frame buffer variable screen structure
 *      @info: frame buffer structure that represents a single frame buffer
 *
 *      Pan (or wrap, depending on the `vmode' field) the display using the
 *      `xoffset' and `yoffset' fields of the `var' structure.
 *      If the values don't fit, return -EINVAL.
 *
 *      Returns negative errno on error, or zero on success.
 */
static int xxxfb_pan_display(struct fb_var_screeninfo *var,
                             const struct fb_info *info)
{
    /* ... */
    return 0;
}

/**
 *      xxxfb_blank - NOT a required function. Blanks the display.
 *      @blank_mode: the blank mode we want. 
 *      @info: frame buffer structure that represents a single frame buffer
 *
 *      Blank the screen if blank_mode != 0, else unblank. Return 0 if
 *      blanking succeeded, != 0 if un-/blanking failed due to e.g. a 
 *      video mode which doesn't support it. Implements VESA suspend
 *      and powerdown modes on hardware that supports disabling hsync/vsync:
 *      blank_mode == 2: suspend vsync
 *      blank_mode == 3: suspend hsync
 *      blank_mode == 4: powerdown
 *
 *      Returns negative errno on error, or zero on success.
 *
 */
static int xxxfb_blank(int blank_mode, const struct fb_info *info)
{
    /* ... */
    return 0;
}

/* ------------ Accelerated Functions --------------------- */

/*
 * We provide our own functions if we have hardware acceleration
 * or non packed pixel format layouts. If we have no hardware 
 * acceleration, we can use a generic unaccelerated function. If using
 * a pack pixel format just use the functions in cfb_*.c. Each file 
 * has one of the three different accel functions we support.
 */

/**
 *      xxxfb_fillrect - REQUIRED function. Can use generic routines if 
 *                       non acclerated hardware and packed pixel based.
 *                       Draws a rectangle on the screen.               
 *
 *      @info: frame buffer structure that represents a single frame buffer
 *      @region: The structure representing the rectangular region we 
 *               wish to draw to.
 *
 *      This drawing operation places/removes a retangle on the screen 
 *      depending on the rastering operation with the value of color which
 *      is in the current color depth format.
 */
void xxfb_fillrect(struct fb_info *p, const struct fb_fillrect *region)
{
/*      Meaning of struct fb_fillrect
 *
 *      @dx: The x and y corrdinates of the upper left hand corner of the 
 *      @dy: area we want to draw to. 
 *      @width: How wide the rectangle is we want to draw.
 *      @height: How tall the rectangle is we want to draw.
 *      @color: The color to fill in the rectangle with. 
 *      @rop: The raster operation. We can draw the rectangle with a COPY
 *            of XOR which provides erasing effect. 
 */
}

/**
 *      xxxfb_copyarea - REQUIRED function. Can use generic routines if
 *                       non acclerated hardware and packed pixel based.
 *                       Copies one area of the screen to another area.
 *
 *      @info: frame buffer structure that represents a single frame buffer
 *      @area: Structure providing the data to copy the framebuffer contents
 *             from one region to another.
 *
 *      This drawing operation copies a rectangular area from one area of the
 *      screen to another area.
 */
void xxxfb_copyarea(struct fb_info *p, const struct fb_copyarea *area) 
{
/*
 *      @dx: The x and y coordinates of the upper left hand corner of the
 *      @dy: destination area on the screen.
 *      @width: How wide the rectangle is we want to copy.
 *      @height: How tall the rectangle is we want to copy.
 *      @sx: The x and y coordinates of the upper left hand corner of the
 *      @sy: source area on the screen.
 */
}


/**
 *      xxxfb_imageblit - REQUIRED function. Can use generic routines if
 *                        non acclerated hardware and packed pixel based.
 *                        Copies a image from system memory to the screen. 
 *
 *      @info: frame buffer structure that represents a single frame buffer
 *      @image: structure defining the image.
 *
 *      This drawing operation draws a image on the screen. It can be a 
 *      mono image (needed for font handling) or a color image (needed for
 *      tux). 
 */
void xxxfb_imageblit(struct fb_info *p, const struct fb_image *image) 
{
/*
 *      @dx: The x and y coordinates of the upper left hand corner of the
 *      @dy: destination area to place the image on the screen.
 *      @width: How wide the image is we want to copy.
 *      @height: How tall the image is we want to copy.
 *      @fg_color: For mono bitmap images this is color data for     
 *      @bg_color: the foreground and background of the image to
 *                 write directly to the frmaebuffer.
 *      @depth: How many bits represent a single pixel for this image.
 *      @data: The actual data used to construct the image on the display.
 *      @cmap: The colormap used for color images.   
 */
}

/**
 *      xxxfb_cursor -  OPTIONAL. If your hardware lacks support
 *                      for a cursor, leave this field NULL.
 *
 *      @info: frame buffer structure that represents a single frame buffer
 *      @cursor: structure defining the cursor to draw.
 *
 *      This operation is used to set or alter the properities of the
 *      cursor.
 *
 *      Returns negative errno on error, or zero on success.
 */
int xxxfb_cursor(struct fb_info *info, struct fb_cursor *cursor)
{
/*
 *      @set:   Which fields we are altering in struct fb_cursor 
 *      @enable: Disable or enable the cursor 
 *      @rop:   The bit operation we want to do. 
 *      @mask:  This is the cursor mask bitmap. 
 *      @dest:  A image of the area we are going to display the cursor.
 *              Used internally by the driver.   
 *      @hot:   The hot spot. 
 *      @image: The actual data for the cursor image.
 *
 *      NOTES ON FLAGS (cursor->set):
 *
 *      FB_CUR_SETIMAGE - the cursor image has changed (cursor->image.data)
 *      FB_CUR_SETPOS   - the cursor position has changed (cursor->image.dx|dy)
 *      FB_CUR_SETHOT   - the cursor hot spot has changed (cursor->hot.dx|dy)
 *      FB_CUR_SETCMAP  - the cursor colors has changed (cursor->fg_color|bg_color)
 *      FB_CUR_SETSHAPE - the cursor bitmask has changed (cursor->mask)
 *      FB_CUR_SETSIZE  - the cursor size has changed (cursor->width|height)
 *      FB_CUR_SETALL   - everything has changed
 *
 *      NOTES ON ROPs (cursor->rop, Raster Operation)
 *
 *      ROP_XOR         - cursor->image.data XOR cursor->mask
 *      ROP_COPY        - curosr->image.data AND cursor->mask
 *
 *      OTHER NOTES:
 *
 *      - fbcon only supports a 2-color cursor (cursor->image.depth = 1)
 *      - The fb_cursor structure, @cursor, _will_ always contain valid
 *        fields, whether any particular bitfields in cursor->set is set
 *        or not.
 */
}

/**
 *      xxxfb_rotate -  NOT a required function. If your hardware
 *                      supports rotation the whole screen then 
 *                      you would provide a hook for this. 
 *
 *      @info: frame buffer structure that represents a single frame buffer
 *      @angle: The angle we rotate the screen.   
 *
 *      This operation is used to set or alter the properities of the
 *      cursor.
 */
void xxxfb_rotate(struct fb_info *info, int angle)
{
}

/**
 *      xxxfb_poll - NOT a required function. The purpose of this
 *                   function is to provide a way for some process
 *                   to wait until a specific hardware event occurs
 *                   for the framebuffer device.
 *                               
 *      @info: frame buffer structure that represents a single frame buffer
 *      @wait: poll table where we store process that await a event.     
 */
void xxxfb_poll(struct fb_info *info, poll_table *wait)
{
}

/**
 *      xxxfb_sync - NOT a required function. Normally the accel engine 
 *                   for a graphics card take a specific amount of time.
 *                   Often we have to wait for the accelerator to finish
 *                   its operation before we can write to the framebuffer
 *                   so we can have consistent display output. 
 *
 *      @info: frame buffer structure that represents a single frame buffer
 */
void xxxfb_sync(struct fb_info *info)
{
}

    /*
     *  Initialization
     */

int __init xxxfb_init(void)
{
    int cmap_len, retval;       
   
    /*
     *  For kernel boot options (in 'video=xxxfb:<options>' format)
     */
#ifndef MODULE
    char *option = NULL;

    if (fb_get_options("xxxfb", &option))
            return -ENODEV;
    xxxfb_setup(option);
#endif

    /* 
     * Here we set the screen_base to the virtual memory address
     * for the framebuffer. Usually we obtain the resource address
     * from the bus layer and then translate it to virtual memory
     * space via ioremap. Consult ioport.h. 
     */
    info.screen_base = framebuffer_virtual_memory;      
    info.fbops = &xxxfb_ops;
    info.fix = xxxfb_fix;
    info.pseudo_palette = pseudo_palette;

    /*
     * Set up flags to indicate what sort of acceleration your
     * driver can provide (pan/wrap/copyarea/etc.) and whether it
     * is a module -- see FBINFO_* in include/linux/fb.h
     */
    info.flags = FBINFO_DEFAULT;
    info.par = current_par;

    /*
     * This should give a reasonable default video mode. The following is
     * done when we can set a video mode. 
     */
    if (!mode_option)
        mode_option = "640x480@60";             

    retval = fb_find_mode(&info.var, &info, mode_option, NULL, 0, NULL, 8);
  
    if (!retval || retval == 4)
        return -EINVAL;                 

    /* This has to been done !!! */     
    fb_alloc_cmap(&info.cmap, cmap_len, 0);
        
    /* 
     * The following is done in the case of having hardware with a static 
     * mode. If we are setting the mode ourselves we don't call this. 
     */ 
    info.var = xxxfb_var;
        
    if (register_framebuffer(&info) < 0)
        return -EINVAL;
    printk(KERN_INFO "fb%d: %s frame buffer device\n", info.node,
           info.fix.id);
    return 0;
}

    /*
     *  Cleanup
     */

static void __exit xxxfb_cleanup(void)
{
    /*
     *  If your driver supports multiple boards, you should unregister and
     *  clean up all instances.
     */

    unregister_framebuffer(info);
    fb_dealloc_cmap(&info.cmap);
    /* ... */
}

    /*
     *  Setup
     */

/* 
 * Only necessary if your driver takes special options,
 * otherwise we fall back on the generic fb_setup().
 */
int __init xxxfb_setup(char *options)
{
    /* Parse user speficied options (`video=xxxfb:') */
}

/* ------------------------------------------------------------------------- */

    /*
     *  Frame buffer operations
     */

static struct fb_ops xxxfb_ops = {
        .owner          = THIS_MODULE,
        .fb_open        = xxxfb_open,
        .fb_read        = xxxfb_read,
        .fb_write       = xxxfb_write,
        .fb_release     = xxxfb_release,
        .fb_check_var   = xxxfb_check_var,
        .fb_set_par     = xxxfb_set_par,        
        .fb_setcolreg   = xxxfb_setcolreg,
        .fb_blank       = xxxfb_blank,
        .fb_pan_display = xxxfb_pan_display,    
        .fb_fillrect    = xxxfb_fillrect,       /* Needed !!! */ 
        .fb_copyarea    = xxxfb_copyarea,       /* Needed !!! */ 
        .fb_imageblit   = xxxfb_imageblit,      /* Needed !!! */
        .fb_cursor      = xxxfb_cursor,         /* Optional !!! */
        .fb_rotate      = xxxfb_rotate,
        .fb_poll        = xxxfb_poll,
        .fb_sync        = xxxfb_sync,
        .fb_ioctl       = xxxfb_ioctl,
        .fb_mmap        = xxxfb_mmap,   
};

/* ------------------------------------------------------------------------- */


    /*
     *  Modularization
     */

module_init(xxxfb_init);
module_exit(xxxfb_cleanup);

MODULE_LICENSE("GPL");