board/trab/vfd.c - github/trini/u-boot - Gitiles

 /*
  * (C) Copyright 2001
  * Wolfgang Denk, DENX Software Engineering -- wd@denx.de
  *
  * See file CREDITS for list of people who contributed to this
  * project.
  *
  * 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., 59 Temple Place, Suite 330, Boston,
  * MA 02111-1307 USA
  */

 /************************************************************************/
 /* ** DEBUG SETTINGS							*/
 /************************************************************************/

 /* #define DEBUG	*/

 /************************************************************************/
 /* ** HEADER FILES							*/
 /************************************************************************/

 #include <config.h>
 #include <common.h>
 #include <version.h>
 #include <stdarg.h>
 #include <linux/types.h>
 #include <devices.h>
 #include <s3c2400.h>

 DECLARE_GLOBAL_DATA_PTR;

 #ifdef CONFIG_VFD

 /************************************************************************/
 /* ** CONFIG STUFF -- should be moved to board config file		*/
 /************************************************************************/

 /************************************************************************/

 #ifndef PAGE_SIZE
 #define	PAGE_SIZE	4096
 #endif

 #define ROT	0x09
 #define BLAU	0x0C
 #define VIOLETT	0X0D

 /* MAGIC */
 #define	FRAME_BUF_SIZE	((256*4*56)/8)
 #define frame_buf_offs 4

 /* defines for starting Timer3 as CPLD-Clk */
 #define START3			(1 << 16)
 #define UPDATE3			(1 << 17)
 #define INVERT3			(1 << 18)
 #define RELOAD3			(1 << 19)

 /* CPLD-Register for controlling vfd-blank-signal */
 #define VFD_DISABLE	(*(volatile uchar *)0x04038000=0x0000)
 #define VFD_ENABLE	(*(volatile uchar *)0x04038000=0x0001)

 /* Supported VFD Types */
 #define	VFD_TYPE_T119C		1	/* Noritake T119C VFD */
 #define	VFD_TYPE_MN11236	2

 /*#define NEW_CPLD_CLK*/

 int vfd_board_id;

 /* taken from armboot/common/vfd.c */
 unsigned long adr_vfd_table[112][18][2][4][2];
 unsigned char bit_vfd_table[112][18][2][4][2];

 /*
  * initialize the values for the VFD-grid-control in the framebuffer
  */
 void init_grid_ctrl(void)
 {
 	ulong adr, grid_cycle;
 	unsigned int bit, display;
 	unsigned char temp, bit_nr;

 	/*
 	 * clear frame buffer (logical clear => set to "black")
 	 */
 	memset ((void *)(gd->fb_base), 0, FRAME_BUF_SIZE);

 	switch (gd->vfd_type) {
 	case VFD_TYPE_T119C:
 	    for (display=0; display<4; display++) {
 		for(grid_cycle=0; grid_cycle<56; grid_cycle++) {
 			bit = grid_cycle * 256  * 4 +
 			     (grid_cycle + 200) * 4 +
 			     frame_buf_offs + display;
 			/* wrap arround if offset (see manual S3C2400) */
 			if (bit>=FRAME_BUF_SIZE*8)
 				bit = bit - (FRAME_BUF_SIZE * 8);
 			adr = gd->fb_base + (bit/32) * 4 + (3 - (bit%32) / 8);
 			bit_nr = bit % 8;
 			bit_nr = (bit_nr > 3) ? bit_nr-4 : bit_nr+4;
 			temp=(*(volatile unsigned char*)(adr));
 			temp |=  (1<<bit_nr);
 			(*(volatile unsigned char*)(adr))=temp;

 			if(grid_cycle<55)
 				bit = grid_cycle*256*4+(grid_cycle+201)*4+frame_buf_offs+display;
 			else
 				bit = grid_cycle*256*4+200*4+frame_buf_offs+display-4;	/* grid nr. 0 */
 			/* wrap arround if offset (see manual S3C2400) */
 			if (bit>=FRAME_BUF_SIZE*8)
 				bit = bit-(FRAME_BUF_SIZE*8);
 			adr = gd->fb_base+(bit/32)*4+(3-(bit%32)/8);
 			bit_nr = bit%8;
 			bit_nr = (bit_nr>3)?bit_nr-4:bit_nr+4;
 			temp=(*(volatile unsigned char*)(adr));
 			temp |=  (1<<bit_nr);
 			(*(volatile unsigned char*)(adr))=temp;
 		}
 	    }
 	    break;
 	case VFD_TYPE_MN11236:
 	    for (display=0; display<4; display++) {
 		for (grid_cycle=0; grid_cycle<38; grid_cycle++) {
 			bit = grid_cycle * 256  * 4 +
 			     (253 - grid_cycle) * 4 +
 			     frame_buf_offs + display;
 			/* wrap arround if offset (see manual S3C2400) */
 			if (bit>=FRAME_BUF_SIZE*8)
 				bit = bit - (FRAME_BUF_SIZE * 8);
 			adr = gd->fb_base + (bit/32) * 4 + (3 - (bit%32) / 8);
 			bit_nr = bit % 8;
 			bit_nr = (bit_nr > 3) ? bit_nr-4 : bit_nr+4;
 			temp=(*(volatile unsigned char*)(adr));
 			temp |=  (1<<bit_nr);
 			(*(volatile unsigned char*)(adr))=temp;

 			if(grid_cycle<37)
 				bit = grid_cycle*256*4+(252-grid_cycle)*4+frame_buf_offs+display;

 			/* wrap arround if offset (see manual S3C2400) */
 			if (bit>=FRAME_BUF_SIZE*8)
 				bit = bit-(FRAME_BUF_SIZE*8);
 			adr = gd->fb_base+(bit/32)*4+(3-(bit%32)/8);
 			bit_nr = bit%8;
 			bit_nr = (bit_nr>3)?bit_nr-4:bit_nr+4;
 			temp=(*(volatile unsigned char*)(adr));
 			temp |=  (1<<bit_nr);
 			(*(volatile unsigned char*)(adr))=temp;
 		}
 	    }
 	    break;
 	default:
 	    printf ("Warning: unknown display type\n");
 	    break;
 	}
 }

 /*
  *create translation table for getting easy the right position in the
  *physical framebuffer for some x/y-coordinates of the VFDs
  */
 void create_vfd_table(void)
 {
 	unsigned long vfd_table[112][18][2][4][2];
 	unsigned int x, y, color, display, entry, pixel;
 	unsigned int x_abcdef = 0;

 	switch (gd->vfd_type) {
 	case VFD_TYPE_T119C:
 	    for(y=0; y<=17; y++) {	/* Line */
 		for(x=0; x<=111; x++) {	/* Column */
 		    for(display=0; display <=3; display++) {

 			    /* Display 0 blue pixels */
 			    vfd_table[x][y][0][display][0] =
 				(x==0) ? y*16+display
 				       : (x%4)*4+y*16+((x-1)/2)*1024+display;
 			    /* Display 0 red pixels */
 			    vfd_table[x][y][1][display][0] =
 				(x==0) ? y*16+512+display
 				       : (x%4)*4+y*16+((x-1)/2)*1024+512+display;
 		    }
 		}
 	    }
 	    break;
 	case VFD_TYPE_MN11236:
 	    for(y=0; y<=17; y++) {	/* Line */
 		for(x=0; x<=111; x++) {	/* Column */
 		    for(display=0; display <=3; display++) {

 			    vfd_table[x][y][0][display][0]=0;
 			    vfd_table[x][y][0][display][1]=0;
 			    vfd_table[x][y][1][display][0]=0;
 			    vfd_table[x][y][1][display][1]=0;

 			    switch (x%6) {
 			    case 0: x_abcdef=0; break; /* a -> a */
 			    case 1: x_abcdef=2; break; /* b -> c */
 			    case 2: x_abcdef=4; break; /* c -> e */
 			    case 3: x_abcdef=5; break; /* d -> f */
 			    case 4: x_abcdef=3; break; /* e -> d */
 			    case 5: x_abcdef=1; break; /* f -> b */
 			    }

 			    /* blue pixels */
 			    vfd_table[x][y][0][display][0] =
 				(x>1) ? x_abcdef*4+((x-1)/3)*1024+y*48+display
 				      : x_abcdef*4+             0+y*48+display;
 			    /* blue pixels */
 			    if (x>1 && (x-1)%3)
 				    vfd_table[x][y][0][display][1] = x_abcdef*4+((x-1)/3+1)*1024+y*48+display;

 			    /* red pixels */
 			    vfd_table[x][y][1][display][0] =
 				(x>1) ? x_abcdef*4+24+((x-1)/3)*1024+y*48+display
 				      : x_abcdef*4+24+             0+y*48+display;
 			    /* red pixels */
 			    if (x>1 && (x-1)%3)
 				    vfd_table[x][y][1][display][1] = x_abcdef*4+24+((x-1)/3+1)*1024+y*48+display;
 		    }
 		}
 	    }
 	    break;
 	default:
 	    /* do nothing */
 	    return;
 	}

 	/*
 	 * Create table with entries for physical byte adresses and
 	 * bit-number within the byte
 	 * from table with bit-numbers within the total framebuffer
 	 */
 	for(y=0;y<18;y++) {
 	    for(x=0;x<112;x++) {
 		for(color=0;color<2;color++) {
 		    for(display=0;display<4;display++) {
 			for(entry=0;entry<2;entry++) {
 			    unsigned long adr  = gd->fb_base;
 			    unsigned int bit_nr = 0;

 			    pixel  = vfd_table[x][y][color][display][entry] + frame_buf_offs;
 			    /*
 			     * wrap arround if offset
 			     * (see manual S3C2400)
 			     */
 			    if (pixel>=FRAME_BUF_SIZE*8)
 				    pixel = pixel-(FRAME_BUF_SIZE*8);
 			    adr    = gd->fb_base+(pixel/32)*4+(3-(pixel%32)/8);
 			    bit_nr = pixel%8;
 			    bit_nr = (bit_nr>3)?bit_nr-4:bit_nr+4;

 			    adr_vfd_table[x][y][color][display][entry] = adr;
 			    bit_vfd_table[x][y][color][display][entry] = bit_nr;
 			}
 		    }
 		}
 	    }
 	}
 }

 /*
  * Set/clear pixel of the VFDs
  */
 void set_vfd_pixel(unsigned char x, unsigned char y,
 		   unsigned char color, unsigned char display,
 		   unsigned char value)
 {
 	ulong adr;
 	unsigned char bit_nr, temp;

 	if (! gd->vfd_type) {
 		/* Unknown type. */
 		return;
 	}

 	/* Pixel-Eintrag Nr. 1 */
 	adr = adr_vfd_table[x][y][color][display][0];
 	/* Pixel-Eintrag Nr. 1 */
 	bit_nr = bit_vfd_table[x][y][color][display][0];
 	temp=(*(volatile unsigned char*)(adr));

 	if (value)
 		temp |=  (1<<bit_nr);
 	else
 		temp &= ~(1<<bit_nr);

 	(*(volatile unsigned char*)(adr))=temp;
 }

 /*
  * transfer image from BMP-File
  */
 void transfer_pic(int display, unsigned char *adr, int height, int width)
 {
 	int x, y;
 	unsigned char temp;

 	for (; height > 0; height -= 18)
 	{
 		if (height > 18)
 			y = 18;
 		else
 			y = height;
 		for (; y > 0; y--)
 		{
 			for (x = 0; x < width; x += 2)
 			{
 				temp = *adr++;
 				set_vfd_pixel(x, y-1, 0, display, 0);
 				set_vfd_pixel(x, y-1, 1, display, 0);
 				if ((temp >> 4) == BLAU)
 					set_vfd_pixel(x, y-1, 0, display, 1);
 				else if ((temp >> 4) == ROT)
 					set_vfd_pixel(x, y-1, 1, display, 1);
 				else if ((temp >> 4) == VIOLETT)
 				{
 					set_vfd_pixel(x, y-1, 0, display, 1);
 					set_vfd_pixel(x, y-1, 1, display, 1);
 				}
 				set_vfd_pixel(x+1, y-1, 0, display, 0);
 				set_vfd_pixel(x+1, y-1, 1, display, 0);
 				if ((temp & 0x0F) == BLAU)
 					set_vfd_pixel(x+1, y-1, 0, display, 1);
 				else if ((temp & 0x0F) == ROT)
 					set_vfd_pixel(x+1, y-1, 1, display, 1);
 				else if ((temp & 0x0F) == VIOLETT)
 				{
 					set_vfd_pixel(x+1, y-1, 0, display, 1);
 					set_vfd_pixel(x+1, y-1, 1, display, 1);
 				}
 			}
 		}
 		if (display > 0)
 			display--;
 		else
 			display = 3;
 	}
 }

 /*
  * This function initializes VFD clock that is needed for the CPLD that
  * manages the keyboard.
  */
 int vfd_init_clocks (void)
 {
 	int i;

 	S3C24X0_GPIO * const gpio = S3C24X0_GetBase_GPIO();
 	S3C24X0_TIMERS * const timers = S3C24X0_GetBase_TIMERS();
 	S3C24X0_LCD * const lcd = S3C24X0_GetBase_LCD();

 	/* try to determine display type from the value
 	 * defined by pull-ups
 	 */
 	gpio->PCUP = (gpio->PCUP & 0xFFF0);	/* activate  GPC0...GPC3 pullups */
 	gpio->PCCON = (gpio->PCCON & 0xFFFFFF00);	/* configure GPC0...GPC3 as inputs */
 	/* allow signals to settle */
 	for (i=0; i<10000; i++)	/* udelay isn't working yet at this point! */
 		__asm("NOP");
 	vfd_board_id = (~gpio->PCDAT) & 0x000F;	/* read GPC0...GPC3 port pins */

 	VFD_DISABLE;				/* activate blank for the vfd */

 #define	NEW_CPLD_CLK

 #ifdef NEW_CPLD_CLK
 	if (vfd_board_id) {
 		/* If new board revision, then use PWM 3 as cpld-clock */
 		/* Enable 500 Hz timer for fill level sensor to operate properly */
 		/* Configure TOUT3 as functional pin, disable pull-up */
 		gpio->PDCON &= ~0x30000;
 		gpio->PDCON |= 0x20000;
 		gpio->PDUP |= (1 << 8);

 		/* Configure the prescaler */
 		timers->TCFG0 &= ~0xff00;
 		timers->TCFG0 |= 0x0f00;

 		/* Select MUX input (divider) for timer3 (1/16) */
 		timers->TCFG1 &= ~0xf000;
 		timers->TCFG1 |= 0x3000;

 		/* Enable autoreload and set the counter and compare
 		 * registers to values for the 500 Hz clock
 		 * (for a given  prescaler (15) and divider (16)):
 		 * counter = (66000000 / 500) >> 9;
 		 */
 		timers->ch[3].TCNTB = 0x101;
 		timers->ch[3].TCMPB = 0x101 / 2;

 		/* Start timer */
 		timers->TCON = (timers->TCON | UPDATE3 | RELOAD3) & ~INVERT3;
 		timers->TCON = (timers->TCON | START3) & ~UPDATE3;
 	}
 #endif
 	/* If old board revision, then use vm-signal as cpld-clock */
 	lcd->LCDCON2 = 0x00FFC000;
 	lcd->LCDCON3 = 0x0007FF00;
 	lcd->LCDCON4 = 0x00000000;
 	lcd->LCDCON5 = 0x00000400;
 	lcd->LCDCON1 = 0x00000B75;
 	/* VM (GPD1) is used as clock for the CPLD */
 	gpio->PDCON = (gpio->PDCON & 0xFFFFFFF3) | 0x00000008;

 	return 0;
 }

 /*
  * initialize LCD-Controller of the S3C2400 for using VFDs
  *
  * VFD detection depends on the board revision:
  * starting from Rev. 200 a type code can be read from the data pins,
  * driven by some pull-up resistors; all earlier systems must be
  * manually configured. The type is set in the "vfd_type" environment
  * variable.
  */
 int drv_vfd_init(void)
 {
 	S3C24X0_LCD * const lcd = S3C24X0_GetBase_LCD();
 	S3C24X0_GPIO * const gpio = S3C24X0_GetBase_GPIO();
 	char *tmp;
 	ulong palette;
 	static int vfd_init_done = 0;
 	int vfd_inv_data = 0;

 	if (vfd_init_done != 0)
 		return (0);
 	vfd_init_done = 1;

 	debug("Detecting Revison of WA4-VFD: ID=0x%X\n", vfd_board_id);

 	switch (vfd_board_id) {
 	case 0:			/* board revision < Rev.200 */
 		if ((tmp = getenv ("vfd_type")) == NULL) {
 			break;
 		}
 		if (strcmp(tmp, "T119C") == 0) {
 			gd->vfd_type = VFD_TYPE_T119C;
 		} else if (strcmp(tmp, "MN11236") == 0) {
 			gd->vfd_type = VFD_TYPE_MN11236;
 		} else {
 			/* cannot use printf for a warning here */
 			gd->vfd_type = 0;	/* unknown */
 		}

 		break;
 	default:		/* default to MN11236, data inverted */
 		gd->vfd_type = VFD_TYPE_MN11236;
 		vfd_inv_data = 1;
 		setenv ("vfd_type", "MN11236");
 	}
 	debug ("VFD type: %s%s\n",
 		(gd->vfd_type == VFD_TYPE_T119C)   ? "T119C" :
 		(gd->vfd_type == VFD_TYPE_MN11236) ? "MN11236" :
 		"unknown",
 		vfd_inv_data ? ", inverted data" : "");

 	gd->fb_base = gd->fb_base;
 	create_vfd_table();
 	init_grid_ctrl();

 	for (palette=0; palette < 16; palette++)
 		(*(volatile unsigned int*)(PALETTE+(palette*4)))=palette;
 	for (palette=16; palette < 256; palette++)
 		(*(volatile unsigned int*)(PALETTE+(palette*4)))=0x00;

 	/*
 	 * Hinweis: Der Framebuffer ist um genau ein Nibble verschoben
 	 * Das erste angezeigte Pixel wird aus dem zweiten Nibble geholt
 	 * das letzte angezeigte Pixel wird aus dem ersten Nibble geholt
 	 * (wrap around)
 	 * see manual S3C2400
 	 */
 	/* Stopp LCD-Controller */
 	lcd->LCDCON1 = 0x00000000;
 	/* frame buffer startadr */
 	lcd->LCDSADDR1 = gd->fb_base >> 1;
 	/* frame buffer endadr */
 	lcd->LCDSADDR2 = (gd->fb_base + FRAME_BUF_SIZE) >> 1;
 	lcd->LCDSADDR3 = ((256/4));
 	lcd->LCDCON2 = 0x000DC000;
 	if(gd->vfd_type == VFD_TYPE_MN11236)
 		lcd->LCDCON2 = 37 << 14;	/* MN11236: 38 lines */
 	else
 		lcd->LCDCON2 = 55 << 14;	/* T119C:   56 lines */
 	lcd->LCDCON3 = 0x0051000A;
 	lcd->LCDCON4 = 0x00000001;
 	if (gd->vfd_type && vfd_inv_data)
 		lcd->LCDCON5 = 0x000004C0;
 	else
 		lcd->LCDCON5 = 0x00000440;

 	/* Port pins as LCD output */
 	gpio->PCCON =   (gpio->PCCON & 0xFFFFFF00)| 0x000000AA;
 	gpio->PDCON =   (gpio->PDCON & 0xFFFFFF03)| 0x000000A8;

 	/* Synchronize VFD enable with LCD controller to avoid flicker	*/
 	lcd->LCDCON1 = 0x00000B75;			/* Start LCD-Controller	*/
 	while((lcd->LCDCON5 & 0x180000)!=0x100000);	/* Wait for end of VSYNC */
 	while((lcd->LCDCON5 & 0x060000)!=0x040000);	/* Wait for next HSYNC	*/
 	while((lcd->LCDCON5 & 0x060000)==0x040000);
 	while((lcd->LCDCON5 & 0x060000)!=0x000000);
 	if(gd->vfd_type)
 		VFD_ENABLE;

 	debug ("LCDSADDR1: %lX\n", lcd->LCDSADDR1);
 	debug ("LCDSADDR2: %lX\n", lcd->LCDSADDR2);
 	debug ("LCDSADDR3: %lX\n", lcd->LCDSADDR3);

 	return 0;
 }

 /*
  * Disable VFD: should be run before resetting the system:
  * disable VM, enable pull-up
  */
 void disable_vfd (void)
 {
 	S3C24X0_GPIO * const gpio = S3C24X0_GetBase_GPIO();

 	VFD_DISABLE;
 	gpio->PDCON &= ~0xC;
 	gpio->PDUP  &= ~0x2;
 }

 /************************************************************************/
 /* ** ROM capable initialization part - needed to reserve FB memory	*/
 /************************************************************************/

 /*
  * This is called early in the system initialization to grab memory
  * for the VFD controller.
  *
  * Note that this is running from ROM, so no write access to global data.
  */
 ulong vfd_setmem (ulong addr)
 {
 	ulong size;

 	/* Round up to nearest full page */
 	size = (FRAME_BUF_SIZE + (PAGE_SIZE - 1)) & ~(PAGE_SIZE - 1);

 	debug ("Reserving %ldk for VFD Framebuffer at: %08lx\n", size>>10, addr);

 	return (size);
 }

 /*
  * Calculate fb size for VIDEOLFB_ATAG. Size returned contains fb,
  * descriptors and palette areas.
  */
 ulong calc_fbsize (void)
 {
 	return FRAME_BUF_SIZE;
 }

 #endif /* CONFIG_VFD */
	/*
	* (C) Copyright 2001
	* Wolfgang Denk, DENX Software Engineering -- wd@denx.de
	*
	* See file CREDITS for list of people who contributed to this
	* project.
	*
	* 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., 59 Temple Place, Suite 330, Boston,
	* MA 02111-1307 USA
	*/

	/************************************************************************/
	/* ** DEBUG SETTINGS */
	/************************************************************************/

	/* #define DEBUG */

	/************************************************************************/
	/* ** HEADER FILES */
	/************************************************************************/

	#include <config.h>
	#include <common.h>
	#include <version.h>
	#include <stdarg.h>
	#include <linux/types.h>
	#include <devices.h>
	#include <s3c2400.h>

	DECLARE_GLOBAL_DATA_PTR;

	#ifdef CONFIG_VFD

	/************************************************************************/
	/* ** CONFIG STUFF -- should be moved to board config file */
	/************************************************************************/

	/************************************************************************/

	#ifndef PAGE_SIZE
	#define PAGE_SIZE 4096
	#endif

	#define ROT 0x09
	#define BLAU 0x0C
	#define VIOLETT 0X0D

	/* MAGIC */
	#define FRAME_BUF_SIZE ((256456)/8)
	#define frame_buf_offs 4

	/* defines for starting Timer3 as CPLD-Clk */
	#define START3 (1 << 16)
	#define UPDATE3 (1 << 17)
	#define INVERT3 (1 << 18)
	#define RELOAD3 (1 << 19)

	/* CPLD-Register for controlling vfd-blank-signal */
	#define VFD_DISABLE ((volatile uchar )0x04038000=0x0000)
	#define VFD_ENABLE ((volatile uchar )0x04038000=0x0001)

	/* Supported VFD Types */
	#define VFD_TYPE_T119C 1 /* Noritake T119C VFD */
	#define VFD_TYPE_MN11236 2

	/#define NEW_CPLD_CLK/

	int vfd_board_id;

	/* taken from armboot/common/vfd.c */
	unsigned long adr_vfd_table[112][18][2][4][2];
	unsigned char bit_vfd_table[112][18][2][4][2];

	/*
	* initialize the values for the VFD-grid-control in the framebuffer
	*/
	void init_grid_ctrl(void)
	{
	ulong adr, grid_cycle;
	unsigned int bit, display;
	unsigned char temp, bit_nr;

	/*
	* clear frame buffer (logical clear => set to "black")
	*/
	memset ((void *)(gd->fb_base), 0, FRAME_BUF_SIZE);

	switch (gd->vfd_type) {
	case VFD_TYPE_T119C:
	for (display=0; display<4; display++) {
	for(grid_cycle=0; grid_cycle<56; grid_cycle++) {
	bit = grid_cycle * 256 * 4 +
	(grid_cycle + 200) * 4 +
	frame_buf_offs + display;
	/* wrap arround if offset (see manual S3C2400) */
	if (bit>=FRAME_BUF_SIZE*8)
	bit = bit - (FRAME_BUF_SIZE * 8);
	adr = gd->fb_base + (bit/32) * 4 + (3 - (bit%32) / 8);
	bit_nr = bit % 8;
	bit_nr = (bit_nr > 3) ? bit_nr-4 : bit_nr+4;
	temp=((volatile unsigned char)(adr));
	temp \|= (1<<bit_nr);
	((volatile unsigned char)(adr))=temp;

	if(grid_cycle<55)
	bit = grid_cycle2564+(grid_cycle+201)*4+frame_buf_offs+display;
	else
	bit = grid_cycle2564+2004+frame_buf_offs+display-4; / grid nr. 0 */
	/* wrap arround if offset (see manual S3C2400) */
	if (bit>=FRAME_BUF_SIZE*8)
	bit = bit-(FRAME_BUF_SIZE*8);
	adr = gd->fb_base+(bit/32)*4+(3-(bit%32)/8);
	bit_nr = bit%8;
	bit_nr = (bit_nr>3)?bit_nr-4:bit_nr+4;
	temp=((volatile unsigned char)(adr));
	temp \|= (1<<bit_nr);
	((volatile unsigned char)(adr))=temp;
	}
	}
	break;
	case VFD_TYPE_MN11236:
	for (display=0; display<4; display++) {
	for (grid_cycle=0; grid_cycle<38; grid_cycle++) {
	bit = grid_cycle * 256 * 4 +
	(253 - grid_cycle) * 4 +
	frame_buf_offs + display;
	/* wrap arround if offset (see manual S3C2400) */
	if (bit>=FRAME_BUF_SIZE*8)
	bit = bit - (FRAME_BUF_SIZE * 8);
	adr = gd->fb_base + (bit/32) * 4 + (3 - (bit%32) / 8);
	bit_nr = bit % 8;
	bit_nr = (bit_nr > 3) ? bit_nr-4 : bit_nr+4;
	temp=((volatile unsigned char)(adr));
	temp \|= (1<<bit_nr);
	((volatile unsigned char)(adr))=temp;

	if(grid_cycle<37)
	bit = grid_cycle2564+(252-grid_cycle)*4+frame_buf_offs+display;

	/* wrap arround if offset (see manual S3C2400) */
	if (bit>=FRAME_BUF_SIZE*8)
	bit = bit-(FRAME_BUF_SIZE*8);
	adr = gd->fb_base+(bit/32)*4+(3-(bit%32)/8);
	bit_nr = bit%8;
	bit_nr = (bit_nr>3)?bit_nr-4:bit_nr+4;
	temp=((volatile unsigned char)(adr));
	temp \|= (1<<bit_nr);
	((volatile unsigned char)(adr))=temp;
	}
	}
	break;
	default:
	printf ("Warning: unknown display type\n");
	break;
	}
	}

	/*
	*create translation table for getting easy the right position in the
	*physical framebuffer for some x/y-coordinates of the VFDs
	*/
	void create_vfd_table(void)
	{
	unsigned long vfd_table[112][18][2][4][2];
	unsigned int x, y, color, display, entry, pixel;
	unsigned int x_abcdef = 0;

	switch (gd->vfd_type) {
	case VFD_TYPE_T119C:
	for(y=0; y<=17; y++) { /* Line */
	for(x=0; x<=111; x++) { /* Column */
	for(display=0; display <=3; display++) {

	/* Display 0 blue pixels */
	vfd_table[x][y][0][display][0] =
	(x==0) ? y*16+display
	: (x%4)4+y16+((x-1)/2)*1024+display;
	/* Display 0 red pixels */
	vfd_table[x][y][1][display][0] =
	(x==0) ? y*16+512+display
	: (x%4)4+y16+((x-1)/2)*1024+512+display;
	}
	}
	}
	break;
	case VFD_TYPE_MN11236:
	for(y=0; y<=17; y++) { /* Line */
	for(x=0; x<=111; x++) { /* Column */
	for(display=0; display <=3; display++) {

	vfd_table[x][y][0][display][0]=0;
	vfd_table[x][y][0][display][1]=0;
	vfd_table[x][y][1][display][0]=0;
	vfd_table[x][y][1][display][1]=0;

	switch (x%6) {
	case 0: x_abcdef=0; break; /* a -> a */
	case 1: x_abcdef=2; break; /* b -> c */
	case 2: x_abcdef=4; break; /* c -> e */
	case 3: x_abcdef=5; break; /* d -> f */
	case 4: x_abcdef=3; break; /* e -> d */
	case 5: x_abcdef=1; break; /* f -> b */
	}

	/* blue pixels */
	vfd_table[x][y][0][display][0] =
	(x>1) ? x_abcdef4+((x-1)/3)1024+y*48+display
	: x_abcdef4+ 0+y48+display;
	/* blue pixels */
	if (x>1 && (x-1)%3)
	vfd_table[x][y][0][display][1] = x_abcdef4+((x-1)/3+1)1024+y*48+display;

	/* red pixels */
	vfd_table[x][y][1][display][0] =
	(x>1) ? x_abcdef4+24+((x-1)/3)1024+y*48+display
	: x_abcdef4+24+ 0+y48+display;
	/* red pixels */
	if (x>1 && (x-1)%3)
	vfd_table[x][y][1][display][1] = x_abcdef4+24+((x-1)/3+1)1024+y*48+display;
	}
	}
	}
	break;
	default:
	/* do nothing */
	return;
	}

	/*
	* Create table with entries for physical byte adresses and
	* bit-number within the byte
	* from table with bit-numbers within the total framebuffer
	*/
	for(y=0;y<18;y++) {
	for(x=0;x<112;x++) {
	for(color=0;color<2;color++) {
	for(display=0;display<4;display++) {
	for(entry=0;entry<2;entry++) {
	unsigned long adr = gd->fb_base;
	unsigned int bit_nr = 0;

	pixel = vfd_table[x][y][color][display][entry] + frame_buf_offs;
	/*
	* wrap arround if offset
	* (see manual S3C2400)
	*/
	if (pixel>=FRAME_BUF_SIZE*8)
	pixel = pixel-(FRAME_BUF_SIZE*8);
	adr = gd->fb_base+(pixel/32)*4+(3-(pixel%32)/8);
	bit_nr = pixel%8;
	bit_nr = (bit_nr>3)?bit_nr-4:bit_nr+4;

	adr_vfd_table[x][y][color][display][entry] = adr;
	bit_vfd_table[x][y][color][display][entry] = bit_nr;
	}
	}
	}
	}
	}
	}

	/*
	* Set/clear pixel of the VFDs
	*/
	void set_vfd_pixel(unsigned char x, unsigned char y,
	unsigned char color, unsigned char display,
	unsigned char value)
	{
	ulong adr;
	unsigned char bit_nr, temp;

	if (! gd->vfd_type) {
	/* Unknown type. */
	return;
	}

	/* Pixel-Eintrag Nr. 1 */
	adr = adr_vfd_table[x][y][color][display][0];
	/* Pixel-Eintrag Nr. 1 */
	bit_nr = bit_vfd_table[x][y][color][display][0];
	temp=((volatile unsigned char)(adr));

	if (value)
	temp \|= (1<<bit_nr);
	else
	temp &= ~(1<<bit_nr);

	((volatile unsigned char)(adr))=temp;
	}

	/*
	* transfer image from BMP-File
	*/
	void transfer_pic(int display, unsigned char *adr, int height, int width)
	{
	int x, y;
	unsigned char temp;

	for (; height > 0; height -= 18)
	{
	if (height > 18)
	y = 18;
	else
	y = height;
	for (; y > 0; y--)
	{
	for (x = 0; x < width; x += 2)
	{
	temp = *adr++;
	set_vfd_pixel(x, y-1, 0, display, 0);
	set_vfd_pixel(x, y-1, 1, display, 0);
	if ((temp >> 4) == BLAU)
	set_vfd_pixel(x, y-1, 0, display, 1);
	else if ((temp >> 4) == ROT)
	set_vfd_pixel(x, y-1, 1, display, 1);
	else if ((temp >> 4) == VIOLETT)
	{
	set_vfd_pixel(x, y-1, 0, display, 1);
	set_vfd_pixel(x, y-1, 1, display, 1);
	}
	set_vfd_pixel(x+1, y-1, 0, display, 0);
	set_vfd_pixel(x+1, y-1, 1, display, 0);
	if ((temp & 0x0F) == BLAU)
	set_vfd_pixel(x+1, y-1, 0, display, 1);
	else if ((temp & 0x0F) == ROT)
	set_vfd_pixel(x+1, y-1, 1, display, 1);
	else if ((temp & 0x0F) == VIOLETT)
	{
	set_vfd_pixel(x+1, y-1, 0, display, 1);
	set_vfd_pixel(x+1, y-1, 1, display, 1);
	}
	}
	}
	if (display > 0)
	display--;
	else
	display = 3;
	}
	}

	/*
	* This function initializes VFD clock that is needed for the CPLD that
	* manages the keyboard.
	*/
	int vfd_init_clocks (void)
	{
	int i;

	S3C24X0_GPIO * const gpio = S3C24X0_GetBase_GPIO();
	S3C24X0_TIMERS * const timers = S3C24X0_GetBase_TIMERS();
	S3C24X0_LCD * const lcd = S3C24X0_GetBase_LCD();

	/* try to determine display type from the value
	* defined by pull-ups
	*/
	gpio->PCUP = (gpio->PCUP & 0xFFF0); /* activate GPC0...GPC3 pullups */
	gpio->PCCON = (gpio->PCCON & 0xFFFFFF00); /* configure GPC0...GPC3 as inputs */
	/* allow signals to settle */
	for (i=0; i<10000; i++) /* udelay isn't working yet at this point! */
	__asm("NOP");
	vfd_board_id = (~gpio->PCDAT) & 0x000F; /* read GPC0...GPC3 port pins */

	VFD_DISABLE; /* activate blank for the vfd */

	#define NEW_CPLD_CLK

	#ifdef NEW_CPLD_CLK
	if (vfd_board_id) {
	/* If new board revision, then use PWM 3 as cpld-clock */
	/* Enable 500 Hz timer for fill level sensor to operate properly */
	/* Configure TOUT3 as functional pin, disable pull-up */
	gpio->PDCON &= ~0x30000;
	gpio->PDCON \|= 0x20000;
	gpio->PDUP \|= (1 << 8);

	/* Configure the prescaler */
	timers->TCFG0 &= ~0xff00;
	timers->TCFG0 \|= 0x0f00;

	/* Select MUX input (divider) for timer3 (1/16) */
	timers->TCFG1 &= ~0xf000;
	timers->TCFG1 \|= 0x3000;

	/* Enable autoreload and set the counter and compare
	* registers to values for the 500 Hz clock
	* (for a given prescaler (15) and divider (16)):
	* counter = (66000000 / 500) >> 9;
	*/
	timers->ch[3].TCNTB = 0x101;
	timers->ch[3].TCMPB = 0x101 / 2;

	/* Start timer */
	timers->TCON = (timers->TCON \| UPDATE3 \| RELOAD3) & ~INVERT3;
	timers->TCON = (timers->TCON \| START3) & ~UPDATE3;
	}
	#endif
	/* If old board revision, then use vm-signal as cpld-clock */
	lcd->LCDCON2 = 0x00FFC000;
	lcd->LCDCON3 = 0x0007FF00;
	lcd->LCDCON4 = 0x00000000;
	lcd->LCDCON5 = 0x00000400;
	lcd->LCDCON1 = 0x00000B75;
	/* VM (GPD1) is used as clock for the CPLD */
	gpio->PDCON = (gpio->PDCON & 0xFFFFFFF3) \| 0x00000008;

	return 0;
	}

	/*
	* initialize LCD-Controller of the S3C2400 for using VFDs
	*
	* VFD detection depends on the board revision:
	* starting from Rev. 200 a type code can be read from the data pins,
	* driven by some pull-up resistors; all earlier systems must be
	* manually configured. The type is set in the "vfd_type" environment
	* variable.
	*/
	int drv_vfd_init(void)
	{
	S3C24X0_LCD * const lcd = S3C24X0_GetBase_LCD();
	S3C24X0_GPIO * const gpio = S3C24X0_GetBase_GPIO();
	char *tmp;
	ulong palette;
	static int vfd_init_done = 0;
	int vfd_inv_data = 0;

	if (vfd_init_done != 0)
	return (0);
	vfd_init_done = 1;

	debug("Detecting Revison of WA4-VFD: ID=0x%X\n", vfd_board_id);

	switch (vfd_board_id) {
	case 0: /* board revision < Rev.200 */
	if ((tmp = getenv ("vfd_type")) == NULL) {
	break;
	}
	if (strcmp(tmp, "T119C") == 0) {
	gd->vfd_type = VFD_TYPE_T119C;
	} else if (strcmp(tmp, "MN11236") == 0) {
	gd->vfd_type = VFD_TYPE_MN11236;
	} else {
	/* cannot use printf for a warning here */
	gd->vfd_type = 0; /* unknown */
	}

	break;
	default: /* default to MN11236, data inverted */
	gd->vfd_type = VFD_TYPE_MN11236;
	vfd_inv_data = 1;
	setenv ("vfd_type", "MN11236");
	}
	debug ("VFD type: %s%s\n",
	(gd->vfd_type == VFD_TYPE_T119C) ? "T119C" :
	(gd->vfd_type == VFD_TYPE_MN11236) ? "MN11236" :
	"unknown",
	vfd_inv_data ? ", inverted data" : "");

	gd->fb_base = gd->fb_base;
	create_vfd_table();
	init_grid_ctrl();

	for (palette=0; palette < 16; palette++)
	((volatile unsigned int)(PALETTE+(palette*4)))=palette;
	for (palette=16; palette < 256; palette++)
	((volatile unsigned int)(PALETTE+(palette*4)))=0x00;

	/*
	* Hinweis: Der Framebuffer ist um genau ein Nibble verschoben
	* Das erste angezeigte Pixel wird aus dem zweiten Nibble geholt
	* das letzte angezeigte Pixel wird aus dem ersten Nibble geholt
	* (wrap around)
	* see manual S3C2400
	*/
	/* Stopp LCD-Controller */
	lcd->LCDCON1 = 0x00000000;
	/* frame buffer startadr */
	lcd->LCDSADDR1 = gd->fb_base >> 1;
	/* frame buffer endadr */
	lcd->LCDSADDR2 = (gd->fb_base + FRAME_BUF_SIZE) >> 1;
	lcd->LCDSADDR3 = ((256/4));
	lcd->LCDCON2 = 0x000DC000;
	if(gd->vfd_type == VFD_TYPE_MN11236)
	lcd->LCDCON2 = 37 << 14; /* MN11236: 38 lines */
	else
	lcd->LCDCON2 = 55 << 14; /* T119C: 56 lines */
	lcd->LCDCON3 = 0x0051000A;
	lcd->LCDCON4 = 0x00000001;
	if (gd->vfd_type && vfd_inv_data)
	lcd->LCDCON5 = 0x000004C0;
	else
	lcd->LCDCON5 = 0x00000440;

	/* Port pins as LCD output */
	gpio->PCCON = (gpio->PCCON & 0xFFFFFF00)\| 0x000000AA;
	gpio->PDCON = (gpio->PDCON & 0xFFFFFF03)\| 0x000000A8;

	/* Synchronize VFD enable with LCD controller to avoid flicker */
	lcd->LCDCON1 = 0x00000B75; /* Start LCD-Controller */
	while((lcd->LCDCON5 & 0x180000)!=0x100000); /* Wait for end of VSYNC */
	while((lcd->LCDCON5 & 0x060000)!=0x040000); /* Wait for next HSYNC */
	while((lcd->LCDCON5 & 0x060000)==0x040000);
	while((lcd->LCDCON5 & 0x060000)!=0x000000);
	if(gd->vfd_type)
	VFD_ENABLE;

	debug ("LCDSADDR1: %lX\n", lcd->LCDSADDR1);
	debug ("LCDSADDR2: %lX\n", lcd->LCDSADDR2);
	debug ("LCDSADDR3: %lX\n", lcd->LCDSADDR3);

	return 0;
	}

	/*
	* Disable VFD: should be run before resetting the system:
	* disable VM, enable pull-up
	*/
	void disable_vfd (void)
	{
	S3C24X0_GPIO * const gpio = S3C24X0_GetBase_GPIO();

	VFD_DISABLE;
	gpio->PDCON &= ~0xC;
	gpio->PDUP &= ~0x2;
	}

	/************************************************************************/
	/* ** ROM capable initialization part - needed to reserve FB memory */
	/************************************************************************/

	/*
	* This is called early in the system initialization to grab memory
	* for the VFD controller.
	*
	* Note that this is running from ROM, so no write access to global data.
	*/
	ulong vfd_setmem (ulong addr)
	{
	ulong size;

	/* Round up to nearest full page */
	size = (FRAME_BUF_SIZE + (PAGE_SIZE - 1)) & ~(PAGE_SIZE - 1);

	debug ("Reserving %ldk for VFD Framebuffer at: %08lx\n", size>>10, addr);

	return (size);
	}

	/*
	* Calculate fb size for VIDEOLFB_ATAG. Size returned contains fb,
	* descriptors and palette areas.
	*/
	ulong calc_fbsize (void)
	{
	return FRAME_BUF_SIZE;
	}

	#endif /* CONFIG_VFD */