vgasrc/stdvga.c - chromiumos/third_party/seabios - Git at Google

 // Standard VGA driver code
 //
 // Copyright (C) 2009  Kevin O'Connor <kevin@koconnor.net>
 // Copyright (C) 2001-2008 the LGPL VGABios developers Team
 //
 // This file may be distributed under the terms of the GNU LGPLv3 license.

 #include "biosvar.h" // GET_GLOBAL
 #include "farptr.h" // SET_FARVAR
 #include "stdvga.h" // stdvga_setup
 #include "string.h" // memset_far
 #include "vgabios.h" // struct vgamode_s
 #include "x86.h" // outb


 /****************************************************************
  * Attribute control
  ****************************************************************/

 void
 stdvga_set_border_color(u8 color)
 {
     u8 v1 = color & 0x0f;
     if (v1 & 0x08)
         v1 += 0x08;
     stdvga_attr_write(0x00, v1);

     int i;
     for (i = 1; i < 4; i++)
         stdvga_attr_mask(i, 0x10, color & 0x10);
 }

 void
 stdvga_set_overscan_border_color(u8 color)
 {
     stdvga_attr_write(0x11, color);
 }

 u8
 stdvga_get_overscan_border_color(void)
 {
     return stdvga_attr_read(0x11);
 }

 void
 stdvga_set_palette(u8 palid)
 {
     int i;
     for (i = 1; i < 4; i++)
         stdvga_attr_mask(i, 0x01, palid & 0x01);
 }

 void
 stdvga_set_all_palette_reg(u16 seg, u8 *data_far)
 {
     int i;
     for (i = 0; i < 0x10; i++) {
         stdvga_attr_write(i, GET_FARVAR(seg, *data_far));
         data_far++;
     }
     stdvga_attr_write(0x11, GET_FARVAR(seg, *data_far));
 }

 void
 stdvga_get_all_palette_reg(u16 seg, u8 *data_far)
 {
     int i;
     for (i = 0; i < 0x10; i++) {
         SET_FARVAR(seg, *data_far, stdvga_attr_read(i));
         data_far++;
     }
     SET_FARVAR(seg, *data_far, stdvga_attr_read(0x11));
 }

 void
 stdvga_toggle_intensity(u8 flag)
 {
     stdvga_attr_mask(0x10, 0x08, (flag & 0x01) << 3);
 }

 void
 stdvga_select_video_dac_color_page(u8 flag, u8 data)
 {
     if (!(flag & 0x01)) {
         // select paging mode
         stdvga_attr_mask(0x10, 0x80, data << 7);
         return;
     }
     // select page
     u8 val = stdvga_attr_read(0x10);
     if (!(val & 0x80))
         data <<= 2;
     data &= 0x0f;
     stdvga_attr_write(0x14, data);
 }

 void
 stdvga_read_video_dac_state(u8 *pmode, u8 *curpage)
 {
     u8 val1 = stdvga_attr_read(0x10) >> 7;
     u8 val2 = stdvga_attr_read(0x14) & 0x0f;
     if (!(val1 & 0x01))
         val2 >>= 2;
     *pmode = val1;
     *curpage = val2;
 }


 /****************************************************************
  * DAC control
  ****************************************************************/

 void
 stdvga_perform_gray_scale_summing(u16 start, u16 count)
 {
     stdvga_attrindex_write(0x00);
     int i;
     for (i = start; i < start+count; i++) {
         u8 rgb[3];
         stdvga_dac_read(GET_SEG(SS), rgb, i, 1);

         // intensity = ( 0.3 * Red ) + ( 0.59 * Green ) + ( 0.11 * Blue )
         u16 intensity = ((77 * rgb[0] + 151 * rgb[1] + 28 * rgb[2]) + 0x80) >> 8;
         if (intensity > 0x3f)
             intensity = 0x3f;
         rgb[0] = rgb[1] = rgb[2] = intensity;

         stdvga_dac_write(GET_SEG(SS), rgb, i, 1);
     }
     stdvga_attrindex_write(0x20);
 }


 /****************************************************************
  * Memory control
  ****************************************************************/

 void
 stdvga_set_text_block_specifier(u8 spec)
 {
     stdvga_sequ_write(0x03, spec);
 }

 // Enable reads and writes to the given "plane" when in planar4 mode.
 void
 stdvga_planar4_plane(int plane)
 {
     if (plane < 0) {
         // Return to default mode (read plane0, write all planes)
         stdvga_sequ_write(0x02, 0x0f);
         stdvga_grdc_write(0x04, 0);
     } else {
         stdvga_sequ_write(0x02, 1<<plane);
         stdvga_grdc_write(0x04, plane);
     }
 }


 /****************************************************************
  * Font loading
  ****************************************************************/

 static void
 get_font_access(void)
 {
     stdvga_sequ_write(0x00, 0x01);
     stdvga_sequ_write(0x02, 0x04);
     stdvga_sequ_write(0x04, 0x07);
     stdvga_sequ_write(0x00, 0x03);
     stdvga_grdc_write(0x04, 0x02);
     stdvga_grdc_write(0x05, 0x00);
     stdvga_grdc_write(0x06, 0x04);
 }

 static void
 release_font_access(void)
 {
     stdvga_sequ_write(0x00, 0x01);
     stdvga_sequ_write(0x02, 0x03);
     stdvga_sequ_write(0x04, 0x03);
     stdvga_sequ_write(0x00, 0x03);
     u16 v = (stdvga_misc_read() & 0x01) ? 0x0e : 0x0a;
     stdvga_grdc_write(0x06, v);
     stdvga_grdc_write(0x04, 0x00);
     stdvga_grdc_write(0x05, 0x10);
 }

 void
 stdvga_load_font(u16 seg, void *src_far, u16 count
                  , u16 start, u8 destflags, u8 fontsize)
 {
     get_font_access();
     u16 blockaddr = ((destflags & 0x03) << 14) + ((destflags & 0x04) << 11);
     void *dest_far = (void*)(blockaddr + start*32);
     u16 i;
     for (i = 0; i < count; i++)
         memcpy_far(SEG_GRAPH, dest_far + i*32
                    , seg, src_far + i*fontsize, fontsize);
     release_font_access();
 }


 /****************************************************************
  * CRTC registers
  ****************************************************************/

 u16
 stdvga_get_crtc(void)
 {
     if (stdvga_misc_read() & 1)
         return VGAREG_VGA_CRTC_ADDRESS;
     return VGAREG_MDA_CRTC_ADDRESS;
 }

 // Ratio between system visible framebuffer ram and the actual videoram used.
 int
 stdvga_vram_ratio(struct vgamode_s *vmode_g)
 {
     switch (GET_GLOBAL(vmode_g->memmodel)) {
     case MM_TEXT:
         return 2;
     case MM_CGA:
         return 4 / GET_GLOBAL(vmode_g->depth);
     case MM_PLANAR:
         return 4;
     default:
         return 1;
     }
 }

 void
 stdvga_set_cursor_shape(u16 cursor_type)
 {
     u16 crtc_addr = stdvga_get_crtc();
     stdvga_crtc_write(crtc_addr, 0x0a, cursor_type >> 8);
     stdvga_crtc_write(crtc_addr, 0x0b, cursor_type);
 }

 void
 stdvga_set_cursor_pos(int address)
 {
     u16 crtc_addr = stdvga_get_crtc();
     address /= 2;  // Assume we're in text mode.
     stdvga_crtc_write(crtc_addr, 0x0e, address >> 8);
     stdvga_crtc_write(crtc_addr, 0x0f, address);
 }

 void
 stdvga_set_scan_lines(u8 lines)
 {
     stdvga_crtc_mask(stdvga_get_crtc(), 0x09, 0x1f, lines - 1);
 }

 // Get vertical display end
 u16
 stdvga_get_vde(void)
 {
     u16 crtc_addr = stdvga_get_crtc();
     u16 vde = stdvga_crtc_read(crtc_addr, 0x12);
     u8 ovl = stdvga_crtc_read(crtc_addr, 0x07);
     vde += (((ovl & 0x02) << 7) + ((ovl & 0x40) << 3) + 1);
     return vde;
 }

 int
 stdvga_get_window(struct vgamode_s *vmode_g, int window)
 {
     return -1;
 }

 int
 stdvga_set_window(struct vgamode_s *vmode_g, int window, int val)
 {
     return -1;
 }

 int
 stdvga_get_linelength(struct vgamode_s *vmode_g)
 {
     u8 val = stdvga_crtc_read(stdvga_get_crtc(), 0x13);
     return val * 8 / stdvga_vram_ratio(vmode_g);
 }

 int
 stdvga_set_linelength(struct vgamode_s *vmode_g, int val)
 {
     val = DIV_ROUND_UP(val * stdvga_vram_ratio(vmode_g), 8);
     stdvga_crtc_write(stdvga_get_crtc(), 0x13, val);
     return 0;
 }

 int
 stdvga_get_displaystart(struct vgamode_s *vmode_g)
 {
     u16 crtc_addr = stdvga_get_crtc();
     int addr = (stdvga_crtc_read(crtc_addr, 0x0c) << 8
                 | stdvga_crtc_read(crtc_addr, 0x0d));
     return addr * 4 / stdvga_vram_ratio(vmode_g);
 }

 int
 stdvga_set_displaystart(struct vgamode_s *vmode_g, int val)
 {
     u16 crtc_addr = stdvga_get_crtc();
     val = val * stdvga_vram_ratio(vmode_g) / 4;
     stdvga_crtc_write(crtc_addr, 0x0c, val >> 8);
     stdvga_crtc_write(crtc_addr, 0x0d, val);
     return 0;
 }

 int
 stdvga_get_dacformat(struct vgamode_s *vmode_g)
 {
     return -1;
 }

 int
 stdvga_set_dacformat(struct vgamode_s *vmode_g, int val)
 {
     return -1;
 }


 /****************************************************************
  * Save/Restore state
  ****************************************************************/

 struct saveVideoHardware {
     u8 sequ_index;
     u8 crtc_index;
     u8 grdc_index;
     u8 actl_index;
     u8 feature;
     u8 sequ_regs[4];
     u8 sequ0;
     u8 crtc_regs[25];
     u8 actl_regs[20];
     u8 grdc_regs[9];
     u16 crtc_addr;
     u8 plane_latch[4];
 } PACKED;

 static void
 stdvga_save_hw_state(u16 seg, struct saveVideoHardware *info)
 {
     u16 crtc_addr = stdvga_get_crtc();
     SET_FARVAR(seg, info->sequ_index, inb(VGAREG_SEQU_ADDRESS));
     SET_FARVAR(seg, info->crtc_index, inb(crtc_addr));
     SET_FARVAR(seg, info->grdc_index, inb(VGAREG_GRDC_ADDRESS));
     SET_FARVAR(seg, info->actl_index, stdvga_attrindex_read());
     SET_FARVAR(seg, info->feature, inb(VGAREG_READ_FEATURE_CTL));

     int i;
     for (i=0; i<4; i++)
         SET_FARVAR(seg, info->sequ_regs[i], stdvga_sequ_read(i+1));
     SET_FARVAR(seg, info->sequ0, stdvga_sequ_read(0));

     for (i=0; i<25; i++)
         SET_FARVAR(seg, info->crtc_regs[i], stdvga_crtc_read(crtc_addr, i));

     for (i=0; i<20; i++)
         SET_FARVAR(seg, info->actl_regs[i], stdvga_attr_read(i));

     for (i=0; i<9; i++)
         SET_FARVAR(seg, info->grdc_regs[i], stdvga_grdc_read(i));

     SET_FARVAR(seg, info->crtc_addr, crtc_addr);

     /* XXX: read plane latches */
     for (i=0; i<4; i++)
         SET_FARVAR(seg, info->plane_latch[i], 0);
 }

 static void
 stdvga_restore_hw_state(u16 seg, struct saveVideoHardware *info)
 {
     int i;
     for (i=0; i<4; i++)
         stdvga_sequ_write(i+1, GET_FARVAR(seg, info->sequ_regs[i]));
     stdvga_sequ_write(0x00, GET_FARVAR(seg, info->sequ0));

     // Disable CRTC write protection
     u16 crtc_addr = GET_FARVAR(seg, info->crtc_addr);
     stdvga_crtc_write(crtc_addr, 0x11, 0x00);
     // Set CRTC regs
     for (i=0; i<25; i++)
         if (i != 0x11)
             stdvga_crtc_write(crtc_addr, i, GET_FARVAR(seg, info->crtc_regs[i]));
     // select crtc base address
     stdvga_misc_mask(0x01, crtc_addr == VGAREG_VGA_CRTC_ADDRESS ? 0x01 : 0x00);

     // enable write protection if needed
     stdvga_crtc_write(crtc_addr, 0x11, GET_FARVAR(seg, info->crtc_regs[0x11]));

     // Set Attribute Ctl
     for (i=0; i<20; i++)
         stdvga_attr_write(i, GET_FARVAR(seg, info->actl_regs[i]));
     stdvga_attrindex_write(GET_FARVAR(seg, info->actl_index));

     for (i=0; i<9; i++)
         stdvga_grdc_write(i, GET_FARVAR(seg, info->grdc_regs[i]));

     outb(GET_FARVAR(seg, info->sequ_index), VGAREG_SEQU_ADDRESS);
     outb(GET_FARVAR(seg, info->crtc_index), crtc_addr);
     outb(GET_FARVAR(seg, info->grdc_index), VGAREG_GRDC_ADDRESS);
     outb(GET_FARVAR(seg, info->feature), crtc_addr - 0x4 + 0xa);
 }

 struct saveDACcolors {
     u8 rwmode;
     u8 peladdr;
     u8 pelmask;
     u8 dac[768];
     u8 color_select;
 } PACKED;

 static void
 stdvga_save_dac_state(u16 seg, struct saveDACcolors *info)
 {
     /* XXX: check this */
     SET_FARVAR(seg, info->rwmode, inb(VGAREG_DAC_STATE));
     SET_FARVAR(seg, info->peladdr, inb(VGAREG_DAC_WRITE_ADDRESS));
     SET_FARVAR(seg, info->pelmask, stdvga_pelmask_read());
     stdvga_dac_read(seg, info->dac, 0, 256);
     SET_FARVAR(seg, info->color_select, 0);
 }

 static void
 stdvga_restore_dac_state(u16 seg, struct saveDACcolors *info)
 {
     stdvga_pelmask_write(GET_FARVAR(seg, info->pelmask));
     stdvga_dac_write(seg, info->dac, 0, 256);
     outb(GET_FARVAR(seg, info->peladdr), VGAREG_DAC_WRITE_ADDRESS);
 }

 int
 stdvga_save_restore(int cmd, u16 seg, void *data)
 {
     void *pos = data;
     if (cmd & SR_HARDWARE) {
         if (cmd & SR_SAVE)
             stdvga_save_hw_state(seg, pos);
         if (cmd & SR_RESTORE)
             stdvga_restore_hw_state(seg, pos);
         pos += sizeof(struct saveVideoHardware);
     }
     pos += bda_save_restore(cmd, seg, pos);
     if (cmd & SR_DAC) {
         if (cmd & SR_SAVE)
             stdvga_save_dac_state(seg, pos);
         if (cmd & SR_RESTORE)
             stdvga_restore_dac_state(seg, pos);
         pos += sizeof(struct saveDACcolors);
     }
     return pos - data;
 }


 /****************************************************************
  * Misc
  ****************************************************************/

 void
 stdvga_enable_video_addressing(u8 disable)
 {
     u8 v = (disable & 1) ? 0x00 : 0x02;
     stdvga_misc_mask(0x02, v);
 }

 int
 stdvga_setup(void)
 {
     // switch to color mode and enable CPU access 480 lines
     stdvga_misc_write(0xc3);
     // more than 64k 3C4/04
     stdvga_sequ_write(0x04, 0x02);

     return 0;
 }
	// Standard VGA driver code
	//
	// Copyright (C) 2009 Kevin O'Connor <kevin@koconnor.net>
	// Copyright (C) 2001-2008 the LGPL VGABios developers Team
	//
	// This file may be distributed under the terms of the GNU LGPLv3 license.

	#include "biosvar.h" // GET_GLOBAL
	#include "farptr.h" // SET_FARVAR
	#include "stdvga.h" // stdvga_setup
	#include "string.h" // memset_far
	#include "vgabios.h" // struct vgamode_s
	#include "x86.h" // outb


	/****************************************************************
	* Attribute control
	****************************************************************/

	void
	stdvga_set_border_color(u8 color)
	{
	u8 v1 = color & 0x0f;
	if (v1 & 0x08)
	v1 += 0x08;
	stdvga_attr_write(0x00, v1);

	int i;
	for (i = 1; i < 4; i++)
	stdvga_attr_mask(i, 0x10, color & 0x10);
	}

	void
	stdvga_set_overscan_border_color(u8 color)
	{
	stdvga_attr_write(0x11, color);
	}

	u8
	stdvga_get_overscan_border_color(void)
	{
	return stdvga_attr_read(0x11);
	}

	void
	stdvga_set_palette(u8 palid)
	{
	int i;
	for (i = 1; i < 4; i++)
	stdvga_attr_mask(i, 0x01, palid & 0x01);
	}

	void
	stdvga_set_all_palette_reg(u16 seg, u8 *data_far)
	{
	int i;
	for (i = 0; i < 0x10; i++) {
	stdvga_attr_write(i, GET_FARVAR(seg, *data_far));
	data_far++;
	}
	stdvga_attr_write(0x11, GET_FARVAR(seg, *data_far));
	}

	void
	stdvga_get_all_palette_reg(u16 seg, u8 *data_far)
	{
	int i;
	for (i = 0; i < 0x10; i++) {
	SET_FARVAR(seg, *data_far, stdvga_attr_read(i));
	data_far++;
	}
	SET_FARVAR(seg, *data_far, stdvga_attr_read(0x11));
	}

	void
	stdvga_toggle_intensity(u8 flag)
	{
	stdvga_attr_mask(0x10, 0x08, (flag & 0x01) << 3);
	}

	void
	stdvga_select_video_dac_color_page(u8 flag, u8 data)
	{
	if (!(flag & 0x01)) {
	// select paging mode
	stdvga_attr_mask(0x10, 0x80, data << 7);
	return;
	}
	// select page
	u8 val = stdvga_attr_read(0x10);
	if (!(val & 0x80))
	data <<= 2;
	data &= 0x0f;
	stdvga_attr_write(0x14, data);
	}

	void
	stdvga_read_video_dac_state(u8 pmode, u8 curpage)
	{
	u8 val1 = stdvga_attr_read(0x10) >> 7;
	u8 val2 = stdvga_attr_read(0x14) & 0x0f;
	if (!(val1 & 0x01))
	val2 >>= 2;
	*pmode = val1;
	*curpage = val2;
	}


	/****************************************************************
	* DAC control
	****************************************************************/

	void
	stdvga_perform_gray_scale_summing(u16 start, u16 count)
	{
	stdvga_attrindex_write(0x00);
	int i;
	for (i = start; i < start+count; i++) {
	u8 rgb[3];
	stdvga_dac_read(GET_SEG(SS), rgb, i, 1);

	// intensity = ( 0.3 * Red ) + ( 0.59 * Green ) + ( 0.11 * Blue )
	u16 intensity = ((77 * rgb[0] + 151 * rgb[1] + 28 * rgb[2]) + 0x80) >> 8;
	if (intensity > 0x3f)
	intensity = 0x3f;
	rgb[0] = rgb[1] = rgb[2] = intensity;

	stdvga_dac_write(GET_SEG(SS), rgb, i, 1);
	}
	stdvga_attrindex_write(0x20);
	}


	/****************************************************************
	* Memory control
	****************************************************************/

	void
	stdvga_set_text_block_specifier(u8 spec)
	{
	stdvga_sequ_write(0x03, spec);
	}

	// Enable reads and writes to the given "plane" when in planar4 mode.
	void
	stdvga_planar4_plane(int plane)
	{
	if (plane < 0) {
	// Return to default mode (read plane0, write all planes)
	stdvga_sequ_write(0x02, 0x0f);
	stdvga_grdc_write(0x04, 0);
	} else {
	stdvga_sequ_write(0x02, 1<<plane);
	stdvga_grdc_write(0x04, plane);
	}
	}


	/****************************************************************
	* Font loading
	****************************************************************/

	static void
	get_font_access(void)
	{
	stdvga_sequ_write(0x00, 0x01);
	stdvga_sequ_write(0x02, 0x04);
	stdvga_sequ_write(0x04, 0x07);
	stdvga_sequ_write(0x00, 0x03);
	stdvga_grdc_write(0x04, 0x02);
	stdvga_grdc_write(0x05, 0x00);
	stdvga_grdc_write(0x06, 0x04);
	}

	static void
	release_font_access(void)
	{
	stdvga_sequ_write(0x00, 0x01);
	stdvga_sequ_write(0x02, 0x03);
	stdvga_sequ_write(0x04, 0x03);
	stdvga_sequ_write(0x00, 0x03);
	u16 v = (stdvga_misc_read() & 0x01) ? 0x0e : 0x0a;
	stdvga_grdc_write(0x06, v);
	stdvga_grdc_write(0x04, 0x00);
	stdvga_grdc_write(0x05, 0x10);
	}

	void
	stdvga_load_font(u16 seg, void *src_far, u16 count
	, u16 start, u8 destflags, u8 fontsize)
	{
	get_font_access();
	u16 blockaddr = ((destflags & 0x03) << 14) + ((destflags & 0x04) << 11);
	void dest_far = (void)(blockaddr + start*32);
	u16 i;
	for (i = 0; i < count; i++)
	memcpy_far(SEG_GRAPH, dest_far + i*32
	, seg, src_far + i*fontsize, fontsize);
	release_font_access();
	}


	/****************************************************************
	* CRTC registers
	****************************************************************/

	u16
	stdvga_get_crtc(void)
	{
	if (stdvga_misc_read() & 1)
	return VGAREG_VGA_CRTC_ADDRESS;
	return VGAREG_MDA_CRTC_ADDRESS;
	}

	// Ratio between system visible framebuffer ram and the actual videoram used.
	int
	stdvga_vram_ratio(struct vgamode_s *vmode_g)
	{
	switch (GET_GLOBAL(vmode_g->memmodel)) {
	case MM_TEXT:
	return 2;
	case MM_CGA:
	return 4 / GET_GLOBAL(vmode_g->depth);
	case MM_PLANAR:
	return 4;
	default:
	return 1;
	}
	}

	void
	stdvga_set_cursor_shape(u16 cursor_type)
	{
	u16 crtc_addr = stdvga_get_crtc();
	stdvga_crtc_write(crtc_addr, 0x0a, cursor_type >> 8);
	stdvga_crtc_write(crtc_addr, 0x0b, cursor_type);
	}

	void
	stdvga_set_cursor_pos(int address)
	{
	u16 crtc_addr = stdvga_get_crtc();
	address /= 2; // Assume we're in text mode.
	stdvga_crtc_write(crtc_addr, 0x0e, address >> 8);
	stdvga_crtc_write(crtc_addr, 0x0f, address);
	}

	void
	stdvga_set_scan_lines(u8 lines)
	{
	stdvga_crtc_mask(stdvga_get_crtc(), 0x09, 0x1f, lines - 1);
	}

	// Get vertical display end
	u16
	stdvga_get_vde(void)
	{
	u16 crtc_addr = stdvga_get_crtc();
	u16 vde = stdvga_crtc_read(crtc_addr, 0x12);
	u8 ovl = stdvga_crtc_read(crtc_addr, 0x07);
	vde += (((ovl & 0x02) << 7) + ((ovl & 0x40) << 3) + 1);
	return vde;
	}

	int
	stdvga_get_window(struct vgamode_s *vmode_g, int window)
	{
	return -1;
	}

	int
	stdvga_set_window(struct vgamode_s *vmode_g, int window, int val)
	{
	return -1;
	}

	int
	stdvga_get_linelength(struct vgamode_s *vmode_g)
	{
	u8 val = stdvga_crtc_read(stdvga_get_crtc(), 0x13);
	return val * 8 / stdvga_vram_ratio(vmode_g);
	}

	int
	stdvga_set_linelength(struct vgamode_s *vmode_g, int val)
	{
	val = DIV_ROUND_UP(val * stdvga_vram_ratio(vmode_g), 8);
	stdvga_crtc_write(stdvga_get_crtc(), 0x13, val);
	return 0;
	}

	int
	stdvga_get_displaystart(struct vgamode_s *vmode_g)
	{
	u16 crtc_addr = stdvga_get_crtc();
	int addr = (stdvga_crtc_read(crtc_addr, 0x0c) << 8
	\| stdvga_crtc_read(crtc_addr, 0x0d));
	return addr * 4 / stdvga_vram_ratio(vmode_g);
	}

	int
	stdvga_set_displaystart(struct vgamode_s *vmode_g, int val)
	{
	u16 crtc_addr = stdvga_get_crtc();
	val = val * stdvga_vram_ratio(vmode_g) / 4;
	stdvga_crtc_write(crtc_addr, 0x0c, val >> 8);
	stdvga_crtc_write(crtc_addr, 0x0d, val);
	return 0;
	}

	int
	stdvga_get_dacformat(struct vgamode_s *vmode_g)
	{
	return -1;
	}

	int
	stdvga_set_dacformat(struct vgamode_s *vmode_g, int val)
	{
	return -1;
	}


	/****************************************************************
	* Save/Restore state
	****************************************************************/

	struct saveVideoHardware {
	u8 sequ_index;
	u8 crtc_index;
	u8 grdc_index;
	u8 actl_index;
	u8 feature;
	u8 sequ_regs[4];
	u8 sequ0;
	u8 crtc_regs[25];
	u8 actl_regs[20];
	u8 grdc_regs[9];
	u16 crtc_addr;
	u8 plane_latch[4];
	} PACKED;

	static void
	stdvga_save_hw_state(u16 seg, struct saveVideoHardware *info)
	{
	u16 crtc_addr = stdvga_get_crtc();
	SET_FARVAR(seg, info->sequ_index, inb(VGAREG_SEQU_ADDRESS));
	SET_FARVAR(seg, info->crtc_index, inb(crtc_addr));
	SET_FARVAR(seg, info->grdc_index, inb(VGAREG_GRDC_ADDRESS));
	SET_FARVAR(seg, info->actl_index, stdvga_attrindex_read());
	SET_FARVAR(seg, info->feature, inb(VGAREG_READ_FEATURE_CTL));

	int i;
	for (i=0; i<4; i++)
	SET_FARVAR(seg, info->sequ_regs[i], stdvga_sequ_read(i+1));
	SET_FARVAR(seg, info->sequ0, stdvga_sequ_read(0));

	for (i=0; i<25; i++)
	SET_FARVAR(seg, info->crtc_regs[i], stdvga_crtc_read(crtc_addr, i));

	for (i=0; i<20; i++)
	SET_FARVAR(seg, info->actl_regs[i], stdvga_attr_read(i));

	for (i=0; i<9; i++)
	SET_FARVAR(seg, info->grdc_regs[i], stdvga_grdc_read(i));

	SET_FARVAR(seg, info->crtc_addr, crtc_addr);

	/* XXX: read plane latches */
	for (i=0; i<4; i++)
	SET_FARVAR(seg, info->plane_latch[i], 0);
	}

	static void
	stdvga_restore_hw_state(u16 seg, struct saveVideoHardware *info)
	{
	int i;
	for (i=0; i<4; i++)
	stdvga_sequ_write(i+1, GET_FARVAR(seg, info->sequ_regs[i]));
	stdvga_sequ_write(0x00, GET_FARVAR(seg, info->sequ0));

	// Disable CRTC write protection
	u16 crtc_addr = GET_FARVAR(seg, info->crtc_addr);
	stdvga_crtc_write(crtc_addr, 0x11, 0x00);
	// Set CRTC regs
	for (i=0; i<25; i++)
	if (i != 0x11)
	stdvga_crtc_write(crtc_addr, i, GET_FARVAR(seg, info->crtc_regs[i]));
	// select crtc base address
	stdvga_misc_mask(0x01, crtc_addr == VGAREG_VGA_CRTC_ADDRESS ? 0x01 : 0x00);

	// enable write protection if needed
	stdvga_crtc_write(crtc_addr, 0x11, GET_FARVAR(seg, info->crtc_regs[0x11]));

	// Set Attribute Ctl
	for (i=0; i<20; i++)
	stdvga_attr_write(i, GET_FARVAR(seg, info->actl_regs[i]));
	stdvga_attrindex_write(GET_FARVAR(seg, info->actl_index));

	for (i=0; i<9; i++)
	stdvga_grdc_write(i, GET_FARVAR(seg, info->grdc_regs[i]));

	outb(GET_FARVAR(seg, info->sequ_index), VGAREG_SEQU_ADDRESS);
	outb(GET_FARVAR(seg, info->crtc_index), crtc_addr);
	outb(GET_FARVAR(seg, info->grdc_index), VGAREG_GRDC_ADDRESS);
	outb(GET_FARVAR(seg, info->feature), crtc_addr - 0x4 + 0xa);
	}

	struct saveDACcolors {
	u8 rwmode;
	u8 peladdr;
	u8 pelmask;
	u8 dac[768];
	u8 color_select;
	} PACKED;

	static void
	stdvga_save_dac_state(u16 seg, struct saveDACcolors *info)
	{
	/* XXX: check this */
	SET_FARVAR(seg, info->rwmode, inb(VGAREG_DAC_STATE));
	SET_FARVAR(seg, info->peladdr, inb(VGAREG_DAC_WRITE_ADDRESS));
	SET_FARVAR(seg, info->pelmask, stdvga_pelmask_read());
	stdvga_dac_read(seg, info->dac, 0, 256);
	SET_FARVAR(seg, info->color_select, 0);
	}

	static void
	stdvga_restore_dac_state(u16 seg, struct saveDACcolors *info)
	{
	stdvga_pelmask_write(GET_FARVAR(seg, info->pelmask));
	stdvga_dac_write(seg, info->dac, 0, 256);
	outb(GET_FARVAR(seg, info->peladdr), VGAREG_DAC_WRITE_ADDRESS);
	}

	int
	stdvga_save_restore(int cmd, u16 seg, void *data)
	{
	void *pos = data;
	if (cmd & SR_HARDWARE) {
	if (cmd & SR_SAVE)
	stdvga_save_hw_state(seg, pos);
	if (cmd & SR_RESTORE)
	stdvga_restore_hw_state(seg, pos);
	pos += sizeof(struct saveVideoHardware);
	}
	pos += bda_save_restore(cmd, seg, pos);
	if (cmd & SR_DAC) {
	if (cmd & SR_SAVE)
	stdvga_save_dac_state(seg, pos);
	if (cmd & SR_RESTORE)
	stdvga_restore_dac_state(seg, pos);
	pos += sizeof(struct saveDACcolors);
	}
	return pos - data;
	}


	/****************************************************************
	* Misc
	****************************************************************/

	void
	stdvga_enable_video_addressing(u8 disable)
	{
	u8 v = (disable & 1) ? 0x00 : 0x02;
	stdvga_misc_mask(0x02, v);
	}

	int
	stdvga_setup(void)
	{
	// switch to color mode and enable CPU access 480 lines
	stdvga_misc_write(0xc3);
	// more than 64k 3C4/04
	stdvga_sequ_write(0x04, 0x02);

	return 0;
	}