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alistair23-linux/drivers/video/via/dvi.c
Florian Tobias Schandinat ebb29fb47e viafb: use information in var for modesetting 
This patch starts to use the information in var for modesetting for
CRT and DVI devices. This is the right thing as it allows us to use
more generic modes than the ones predefined by VIA. We do not yet
allow more generic modes as check_var still limits them to the
predefined ones but with this patch applied it would be really easy
to do so. A problem was VIAs SAMM mode as it has 2 different modes
but just one frame buffer device. This is solved by creating a
pseudo var which contains enough information to use it for
modesetting. Hopefully one day we can use information in var for all
modes that do not involve hardware scaling.
Well I'd like to say that the chance of regressions is low but it is
quite likely that the behaviour in some cases changed especially
when SAMM is involved. I hope we made it better than before in
particular the DVI frequency check was probably broken before and
hopefully works better now.

Signed-off-by: Florian Tobias Schandinat <FlorianSchandinat@gmx.de>
2011-08-07 01:51:41 +00:00

478 lines
13 KiB
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/*
* Copyright 1998-2008 VIA Technologies, Inc. All Rights Reserved.
* Copyright 2001-2008 S3 Graphics, Inc. All Rights Reserved.
* 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, or (at your option) any later version.
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTIES OR REPRESENTATIONS; 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.
*/
#include <linux/via-core.h>
#include <linux/via_i2c.h>
#include "global.h"
static void tmds_register_write(int index, u8 data);
static int tmds_register_read(int index);
static int tmds_register_read_bytes(int index, u8 *buff, int buff_len);
static void __devinit dvi_get_panel_size_from_DDCv1(
struct tmds_chip_information *tmds_chip,
struct tmds_setting_information *tmds_setting);
static int viafb_dvi_query_EDID(void);
static inline bool check_tmds_chip(int device_id_subaddr, int device_id)
{
return tmds_register_read(device_id_subaddr) == device_id;
}
void __devinit viafb_init_dvi_size(struct tmds_chip_information *tmds_chip,
struct tmds_setting_information *tmds_setting)
{
DEBUG_MSG(KERN_INFO "viafb_init_dvi_size()\n");
viafb_dvi_sense();
if (viafb_dvi_query_EDID() == 1)
dvi_get_panel_size_from_DDCv1(tmds_chip, tmds_setting);
return;
}
bool __devinit viafb_tmds_trasmitter_identify(void)
{
unsigned char sr2a = 0, sr1e = 0, sr3e = 0;
/* Turn on ouputting pad */
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_K8M890:
/*=* DFP Low Pad on *=*/
sr2a = viafb_read_reg(VIASR, SR2A);
viafb_write_reg_mask(SR2A, VIASR, 0x03, BIT0 + BIT1);
break;
case UNICHROME_P4M900:
case UNICHROME_P4M890:
/* DFP Low Pad on */
sr2a = viafb_read_reg(VIASR, SR2A);
viafb_write_reg_mask(SR2A, VIASR, 0x03, BIT0 + BIT1);
/* DVP0 Pad on */
sr1e = viafb_read_reg(VIASR, SR1E);
viafb_write_reg_mask(SR1E, VIASR, 0xC0, BIT6 + BIT7);
break;
default:
/* DVP0/DVP1 Pad on */
sr1e = viafb_read_reg(VIASR, SR1E);
viafb_write_reg_mask(SR1E, VIASR, 0xF0, BIT4 +
BIT5 + BIT6 + BIT7);
/* SR3E[1]Multi-function selection:
0 = Emulate I2C and DDC bus by GPIO2/3/4. */
sr3e = viafb_read_reg(VIASR, SR3E);
viafb_write_reg_mask(SR3E, VIASR, 0x0, BIT5);
break;
}
/* Check for VT1632: */
viaparinfo->chip_info->tmds_chip_info.tmds_chip_name = VT1632_TMDS;
viaparinfo->chip_info->
tmds_chip_info.tmds_chip_slave_addr = VT1632_TMDS_I2C_ADDR;
viaparinfo->chip_info->tmds_chip_info.i2c_port = VIA_PORT_31;
if (check_tmds_chip(VT1632_DEVICE_ID_REG, VT1632_DEVICE_ID)) {
/*
* Currently only support 12bits,dual edge,add 24bits mode later
*/
tmds_register_write(0x08, 0x3b);
DEBUG_MSG(KERN_INFO "\n VT1632 TMDS ! \n");
DEBUG_MSG(KERN_INFO "\n %2d",
viaparinfo->chip_info->tmds_chip_info.tmds_chip_name);
DEBUG_MSG(KERN_INFO "\n %2d",
viaparinfo->chip_info->tmds_chip_info.i2c_port);
return true;
} else {
viaparinfo->chip_info->tmds_chip_info.i2c_port = VIA_PORT_2C;
if (check_tmds_chip(VT1632_DEVICE_ID_REG, VT1632_DEVICE_ID)) {
tmds_register_write(0x08, 0x3b);
DEBUG_MSG(KERN_INFO "\n VT1632 TMDS ! \n");
DEBUG_MSG(KERN_INFO "\n %2d",
viaparinfo->chip_info->
tmds_chip_info.tmds_chip_name);
DEBUG_MSG(KERN_INFO "\n %2d",
viaparinfo->chip_info->
tmds_chip_info.i2c_port);
return true;
}
}
viaparinfo->chip_info->tmds_chip_info.tmds_chip_name = INTEGRATED_TMDS;
if ((viaparinfo->chip_info->gfx_chip_name == UNICHROME_CX700) &&
((viafb_display_hardware_layout == HW_LAYOUT_DVI_ONLY) ||
(viafb_display_hardware_layout == HW_LAYOUT_LCD_DVI))) {
DEBUG_MSG(KERN_INFO "\n Integrated TMDS ! \n");
return true;
}
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_K8M890:
viafb_write_reg(SR2A, VIASR, sr2a);
break;
case UNICHROME_P4M900:
case UNICHROME_P4M890:
viafb_write_reg(SR2A, VIASR, sr2a);
viafb_write_reg(SR1E, VIASR, sr1e);
break;
default:
viafb_write_reg(SR1E, VIASR, sr1e);
viafb_write_reg(SR3E, VIASR, sr3e);
break;
}
viaparinfo->chip_info->
tmds_chip_info.tmds_chip_name = NON_TMDS_TRANSMITTER;
viaparinfo->chip_info->tmds_chip_info.
tmds_chip_slave_addr = VT1632_TMDS_I2C_ADDR;
return false;
}
static void tmds_register_write(int index, u8 data)
{
viafb_i2c_writebyte(viaparinfo->chip_info->tmds_chip_info.i2c_port,
viaparinfo->chip_info->tmds_chip_info.tmds_chip_slave_addr,
index, data);
}
static int tmds_register_read(int index)
{
u8 data;
viafb_i2c_readbyte(viaparinfo->chip_info->tmds_chip_info.i2c_port,
(u8) viaparinfo->chip_info->tmds_chip_info.tmds_chip_slave_addr,
(u8) index, &data);
return data;
}
static int tmds_register_read_bytes(int index, u8 *buff, int buff_len)
{
viafb_i2c_readbytes(viaparinfo->chip_info->tmds_chip_info.i2c_port,
(u8) viaparinfo->chip_info->tmds_chip_info.tmds_chip_slave_addr,
(u8) index, buff, buff_len);
return 0;
}
/* DVI Set Mode */
void viafb_dvi_set_mode(const struct fb_var_screeninfo *var, int iga)
{
struct fb_var_screeninfo dvi_var = *var;
struct crt_mode_table *rb_mode;
int maxPixelClock;
maxPixelClock = viaparinfo->shared->tmds_setting_info.max_pixel_clock;
if (maxPixelClock && PICOS2KHZ(var->pixclock) / 1000 > maxPixelClock) {
rb_mode = viafb_get_best_rb_mode(var->xres, var->yres, 60);
if (rb_mode)
viafb_fill_var_timing_info(&dvi_var, rb_mode);
}
viafb_fill_crtc_timing(&dvi_var, iga);
}
/* Sense DVI Connector */
int viafb_dvi_sense(void)
{
u8 RegSR1E = 0, RegSR3E = 0, RegCR6B = 0, RegCR91 = 0,
RegCR93 = 0, RegCR9B = 0, data;
int ret = false;
DEBUG_MSG(KERN_INFO "viafb_dvi_sense!!\n");
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266) {
/* DI1 Pad on */
RegSR1E = viafb_read_reg(VIASR, SR1E);
viafb_write_reg(SR1E, VIASR, RegSR1E | 0x30);
/* CR6B[0]VCK Input Selection: 1 = External clock. */
RegCR6B = viafb_read_reg(VIACR, CR6B);
viafb_write_reg(CR6B, VIACR, RegCR6B | 0x08);
/* CR91[4] VDD On [3] Data On [2] VEE On [1] Back Light Off
[0] Software Control Power Sequence */
RegCR91 = viafb_read_reg(VIACR, CR91);
viafb_write_reg(CR91, VIACR, 0x1D);
/* CR93[7] DI1 Data Source Selection: 1 = DSP2.
CR93[5] DI1 Clock Source: 1 = internal.
CR93[4] DI1 Clock Polarity.
CR93[3:1] DI1 Clock Adjust. CR93[0] DI1 enable */
RegCR93 = viafb_read_reg(VIACR, CR93);
viafb_write_reg(CR93, VIACR, 0x01);
} else {
/* DVP0/DVP1 Pad on */
RegSR1E = viafb_read_reg(VIASR, SR1E);
viafb_write_reg(SR1E, VIASR, RegSR1E | 0xF0);
/* SR3E[1]Multi-function selection:
0 = Emulate I2C and DDC bus by GPIO2/3/4. */
RegSR3E = viafb_read_reg(VIASR, SR3E);
viafb_write_reg(SR3E, VIASR, RegSR3E & (~0x20));
/* CR91[4] VDD On [3] Data On [2] VEE On [1] Back Light Off
[0] Software Control Power Sequence */
RegCR91 = viafb_read_reg(VIACR, CR91);
viafb_write_reg(CR91, VIACR, 0x1D);
/*CR9B[4] DVP1 Data Source Selection: 1 = From secondary
display.CR9B[2:0] DVP1 Clock Adjust */
RegCR9B = viafb_read_reg(VIACR, CR9B);
viafb_write_reg(CR9B, VIACR, 0x01);
}
data = (u8) tmds_register_read(0x09);
if (data & 0x04)
ret = true;
if (ret == false) {
if (viafb_dvi_query_EDID())
ret = true;
}
/* Restore status */
viafb_write_reg(SR1E, VIASR, RegSR1E);
viafb_write_reg(CR91, VIACR, RegCR91);
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266) {
viafb_write_reg(CR6B, VIACR, RegCR6B);
viafb_write_reg(CR93, VIACR, RegCR93);
} else {
viafb_write_reg(SR3E, VIASR, RegSR3E);
viafb_write_reg(CR9B, VIACR, RegCR9B);
}
return ret;
}
/* Query Flat Panel's EDID Table Version Through DVI Connector */
static int viafb_dvi_query_EDID(void)
{
u8 data0, data1;
int restore;
DEBUG_MSG(KERN_INFO "viafb_dvi_query_EDID!!\n");
restore = viaparinfo->chip_info->tmds_chip_info.tmds_chip_slave_addr;
viaparinfo->chip_info->tmds_chip_info.tmds_chip_slave_addr = 0xA0;
data0 = (u8) tmds_register_read(0x00);
data1 = (u8) tmds_register_read(0x01);
if ((data0 == 0) && (data1 == 0xFF)) {
viaparinfo->chip_info->
tmds_chip_info.tmds_chip_slave_addr = restore;
return EDID_VERSION_1; /* Found EDID1 Table */
}
return false;
}
/* Get Panel Size Using EDID1 Table */
static void __devinit dvi_get_panel_size_from_DDCv1(
struct tmds_chip_information *tmds_chip,
struct tmds_setting_information *tmds_setting)
{
int i, restore;
unsigned char EDID_DATA[18];
DEBUG_MSG(KERN_INFO "\n dvi_get_panel_size_from_DDCv1 \n");
restore = tmds_chip->tmds_chip_slave_addr;
tmds_chip->tmds_chip_slave_addr = 0xA0;
for (i = 0x25; i < 0x6D; i++) {
switch (i) {
case 0x36:
case 0x48:
case 0x5A:
case 0x6C:
tmds_register_read_bytes(i, EDID_DATA, 10);
if (!(EDID_DATA[0] || EDID_DATA[1])) {
/* The first two byte must be zero. */
if (EDID_DATA[3] == 0xFD) {
/* To get max pixel clock. */
tmds_setting->max_pixel_clock =
EDID_DATA[9] * 10;
}
}
break;
default:
break;
}
}
DEBUG_MSG(KERN_INFO "DVI max pixelclock = %d\n",
tmds_setting->max_pixel_clock);
tmds_chip->tmds_chip_slave_addr = restore;
}
/* If Disable DVI, turn off pad */
void viafb_dvi_disable(void)
{
if (viaparinfo->chip_info->
tmds_chip_info.output_interface == INTERFACE_TMDS)
/* Turn off TMDS power. */
viafb_write_reg(CRD2, VIACR,
viafb_read_reg(VIACR, CRD2) | 0x08);
}
static void dvi_patch_skew_dvp0(void)
{
/* Reset data driving first: */
viafb_write_reg_mask(SR1B, VIASR, 0, BIT1);
viafb_write_reg_mask(SR2A, VIASR, 0, BIT4);
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_P4M890:
{
if ((viaparinfo->tmds_setting_info->h_active == 1600) &&
(viaparinfo->tmds_setting_info->v_active ==
1200))
viafb_write_reg_mask(CR96, VIACR, 0x03,
BIT0 + BIT1 + BIT2);
else
viafb_write_reg_mask(CR96, VIACR, 0x07,
BIT0 + BIT1 + BIT2);
break;
}
case UNICHROME_P4M900:
{
viafb_write_reg_mask(CR96, VIACR, 0x07,
BIT0 + BIT1 + BIT2 + BIT3);
viafb_write_reg_mask(SR1B, VIASR, 0x02, BIT1);
viafb_write_reg_mask(SR2A, VIASR, 0x10, BIT4);
break;
}
default:
{
break;
}
}
}
static void dvi_patch_skew_dvp_low(void)
{
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_K8M890:
{
viafb_write_reg_mask(CR99, VIACR, 0x03, BIT0 + BIT1);
break;
}
case UNICHROME_P4M900:
{
viafb_write_reg_mask(CR99, VIACR, 0x08,
BIT0 + BIT1 + BIT2 + BIT3);
break;
}
case UNICHROME_P4M890:
{
viafb_write_reg_mask(CR99, VIACR, 0x0F,
BIT0 + BIT1 + BIT2 + BIT3);
break;
}
default:
{
break;
}
}
}
/* If Enable DVI, turn off pad */
void viafb_dvi_enable(void)
{
u8 data;
switch (viaparinfo->chip_info->tmds_chip_info.output_interface) {
case INTERFACE_DVP0:
viafb_write_reg_mask(CR6B, VIACR, 0x01, BIT0);
viafb_write_reg_mask(CR6C, VIACR, 0x21, BIT0 + BIT5);
dvi_patch_skew_dvp0();
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266)
tmds_register_write(0x88, 0x3b);
else
/*clear CR91[5] to direct on display period
in the secondary diplay path */
via_write_reg_mask(VIACR, 0x91, 0x00, 0x20);
break;
case INTERFACE_DVP1:
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266)
viafb_write_reg_mask(CR93, VIACR, 0x21, BIT0 + BIT5);
/*fix dvi cann't be enabled with MB VT5718C4 - Al Zhang */
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266)
tmds_register_write(0x88, 0x3b);
else
/*clear CR91[5] to direct on display period
in the secondary diplay path */
via_write_reg_mask(VIACR, 0x91, 0x00, 0x20);
/*fix DVI cannot enable on EPIA-M board */
if (viafb_platform_epia_dvi == 1) {
viafb_write_reg_mask(CR91, VIACR, 0x1f, 0x1f);
viafb_write_reg_mask(CR88, VIACR, 0x00, BIT6 + BIT0);
if (viafb_bus_width == 24) {
if (viafb_device_lcd_dualedge == 1)
data = 0x3F;
else
data = 0x37;
viafb_i2c_writebyte(viaparinfo->chip_info->
tmds_chip_info.i2c_port,
viaparinfo->chip_info->
tmds_chip_info.tmds_chip_slave_addr,
0x08, data);
}
}
break;
case INTERFACE_DFP_HIGH:
if (viaparinfo->chip_info->gfx_chip_name != UNICHROME_CLE266)
via_write_reg_mask(VIACR, CR97, 0x03, 0x03);
via_write_reg_mask(VIACR, 0x91, 0x00, 0x20);
break;
case INTERFACE_DFP_LOW:
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266)
break;
dvi_patch_skew_dvp_low();
via_write_reg_mask(VIACR, 0x91, 0x00, 0x20);
break;
case INTERFACE_TMDS:
/* Turn on Display period in the panel path. */
viafb_write_reg_mask(CR91, VIACR, 0, BIT7);
/* Turn on TMDS power. */
viafb_write_reg_mask(CRD2, VIACR, 0, BIT3);
break;
}
if (viaparinfo->tmds_setting_info->iga_path == IGA2) {
/* Disable LCD Scaling */
viafb_write_reg_mask(CR79, VIACR, 0x00, BIT0);
}
}
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