kernel-fxtec-pro1x/drivers/video/via/hw.c
Florian Tobias Schandinat eb0536c5e2 viafb: allow some pll calculations
This patch allows calculating the pll multiplier within limits based
on the previous table. All available information supports that it
should be possible/sane to choose the multiplier free within some
ranges.
Storing the multiplier ranges instead of lots of pll configurations
reduces the memory needed and may as well improve the performance.
It is also expected to provide better pll values resulting in better
frequencies for the connected devices.

Signed-off-by: Florian Tobias Schandinat <FlorianSchandinat@gmx.de>
2011-03-23 13:01:37 +00:00

2551 lines
70 KiB
C

/*
* 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 "global.h"
static struct pll_limit cle266_pll_limits[] = {
{19, 19, 4, 0},
{26, 102, 5, 0},
{53, 112, 6, 0},
{41, 100, 7, 0},
{83, 108, 8, 0},
{87, 118, 9, 0},
{95, 115, 12, 0},
{108, 108, 13, 0},
{83, 83, 17, 0},
{67, 98, 20, 0},
{121, 121, 24, 0},
{99, 99, 29, 0},
{33, 33, 3, 1},
{15, 23, 4, 1},
{37, 121, 5, 1},
{82, 82, 6, 1},
{31, 84, 7, 1},
{83, 83, 8, 1},
{76, 127, 9, 1},
{33, 121, 4, 2},
{91, 118, 5, 2},
{83, 109, 6, 2},
{90, 90, 7, 2},
{93, 93, 2, 3},
{53, 53, 3, 3},
{73, 117, 4, 3},
{101, 127, 5, 3},
{99, 99, 7, 3}
};
static struct pll_limit k800_pll_limits[] = {
{22, 22, 2, 0},
{28, 28, 3, 0},
{81, 112, 3, 1},
{86, 166, 4, 1},
{109, 153, 5, 1},
{66, 116, 3, 2},
{93, 137, 4, 2},
{117, 208, 5, 2},
{30, 30, 2, 3},
{69, 125, 3, 3},
{89, 161, 4, 3},
{121, 208, 5, 3},
{66, 66, 2, 4},
{85, 85, 3, 4},
{141, 161, 4, 4},
{177, 177, 5, 4}
};
static struct pll_limit cx700_pll_limits[] = {
{98, 98, 3, 1},
{86, 86, 4, 1},
{109, 208, 5, 1},
{68, 68, 2, 2},
{95, 116, 3, 2},
{93, 166, 4, 2},
{110, 206, 5, 2},
{174, 174, 7, 2},
{82, 109, 3, 3},
{117, 161, 4, 3},
{112, 208, 5, 3},
{141, 202, 5, 4}
};
static struct pll_limit vx855_pll_limits[] = {
{86, 86, 4, 1},
{108, 208, 5, 1},
{110, 208, 5, 2},
{83, 112, 3, 3},
{103, 161, 4, 3},
{112, 209, 5, 3},
{142, 161, 4, 4},
{141, 176, 5, 4}
};
/* according to VIA Technologies these values are based on experiment */
static struct io_reg scaling_parameters[] = {
{VIACR, CR7A, 0xFF, 0x01}, /* LCD Scaling Parameter 1 */
{VIACR, CR7B, 0xFF, 0x02}, /* LCD Scaling Parameter 2 */
{VIACR, CR7C, 0xFF, 0x03}, /* LCD Scaling Parameter 3 */
{VIACR, CR7D, 0xFF, 0x04}, /* LCD Scaling Parameter 4 */
{VIACR, CR7E, 0xFF, 0x07}, /* LCD Scaling Parameter 5 */
{VIACR, CR7F, 0xFF, 0x0A}, /* LCD Scaling Parameter 6 */
{VIACR, CR80, 0xFF, 0x0D}, /* LCD Scaling Parameter 7 */
{VIACR, CR81, 0xFF, 0x13}, /* LCD Scaling Parameter 8 */
{VIACR, CR82, 0xFF, 0x16}, /* LCD Scaling Parameter 9 */
{VIACR, CR83, 0xFF, 0x19}, /* LCD Scaling Parameter 10 */
{VIACR, CR84, 0xFF, 0x1C}, /* LCD Scaling Parameter 11 */
{VIACR, CR85, 0xFF, 0x1D}, /* LCD Scaling Parameter 12 */
{VIACR, CR86, 0xFF, 0x1E}, /* LCD Scaling Parameter 13 */
{VIACR, CR87, 0xFF, 0x1F}, /* LCD Scaling Parameter 14 */
};
static struct fifo_depth_select display_fifo_depth_reg = {
/* IGA1 FIFO Depth_Select */
{IGA1_FIFO_DEPTH_SELECT_REG_NUM, {{SR17, 0, 7} } },
/* IGA2 FIFO Depth_Select */
{IGA2_FIFO_DEPTH_SELECT_REG_NUM,
{{CR68, 4, 7}, {CR94, 7, 7}, {CR95, 7, 7} } }
};
static struct fifo_threshold_select fifo_threshold_select_reg = {
/* IGA1 FIFO Threshold Select */
{IGA1_FIFO_THRESHOLD_REG_NUM, {{SR16, 0, 5}, {SR16, 7, 7} } },
/* IGA2 FIFO Threshold Select */
{IGA2_FIFO_THRESHOLD_REG_NUM, {{CR68, 0, 3}, {CR95, 4, 6} } }
};
static struct fifo_high_threshold_select fifo_high_threshold_select_reg = {
/* IGA1 FIFO High Threshold Select */
{IGA1_FIFO_HIGH_THRESHOLD_REG_NUM, {{SR18, 0, 5}, {SR18, 7, 7} } },
/* IGA2 FIFO High Threshold Select */
{IGA2_FIFO_HIGH_THRESHOLD_REG_NUM, {{CR92, 0, 3}, {CR95, 0, 2} } }
};
static struct display_queue_expire_num display_queue_expire_num_reg = {
/* IGA1 Display Queue Expire Num */
{IGA1_DISPLAY_QUEUE_EXPIRE_NUM_REG_NUM, {{SR22, 0, 4} } },
/* IGA2 Display Queue Expire Num */
{IGA2_DISPLAY_QUEUE_EXPIRE_NUM_REG_NUM, {{CR94, 0, 6} } }
};
/* Definition Fetch Count Registers*/
static struct fetch_count fetch_count_reg = {
/* IGA1 Fetch Count Register */
{IGA1_FETCH_COUNT_REG_NUM, {{SR1C, 0, 7}, {SR1D, 0, 1} } },
/* IGA2 Fetch Count Register */
{IGA2_FETCH_COUNT_REG_NUM, {{CR65, 0, 7}, {CR67, 2, 3} } }
};
static struct iga1_crtc_timing iga1_crtc_reg = {
/* IGA1 Horizontal Total */
{IGA1_HOR_TOTAL_REG_NUM, {{CR00, 0, 7}, {CR36, 3, 3} } },
/* IGA1 Horizontal Addressable Video */
{IGA1_HOR_ADDR_REG_NUM, {{CR01, 0, 7} } },
/* IGA1 Horizontal Blank Start */
{IGA1_HOR_BLANK_START_REG_NUM, {{CR02, 0, 7} } },
/* IGA1 Horizontal Blank End */
{IGA1_HOR_BLANK_END_REG_NUM,
{{CR03, 0, 4}, {CR05, 7, 7}, {CR33, 5, 5} } },
/* IGA1 Horizontal Sync Start */
{IGA1_HOR_SYNC_START_REG_NUM, {{CR04, 0, 7}, {CR33, 4, 4} } },
/* IGA1 Horizontal Sync End */
{IGA1_HOR_SYNC_END_REG_NUM, {{CR05, 0, 4} } },
/* IGA1 Vertical Total */
{IGA1_VER_TOTAL_REG_NUM,
{{CR06, 0, 7}, {CR07, 0, 0}, {CR07, 5, 5}, {CR35, 0, 0} } },
/* IGA1 Vertical Addressable Video */
{IGA1_VER_ADDR_REG_NUM,
{{CR12, 0, 7}, {CR07, 1, 1}, {CR07, 6, 6}, {CR35, 2, 2} } },
/* IGA1 Vertical Blank Start */
{IGA1_VER_BLANK_START_REG_NUM,
{{CR15, 0, 7}, {CR07, 3, 3}, {CR09, 5, 5}, {CR35, 3, 3} } },
/* IGA1 Vertical Blank End */
{IGA1_VER_BLANK_END_REG_NUM, {{CR16, 0, 7} } },
/* IGA1 Vertical Sync Start */
{IGA1_VER_SYNC_START_REG_NUM,
{{CR10, 0, 7}, {CR07, 2, 2}, {CR07, 7, 7}, {CR35, 1, 1} } },
/* IGA1 Vertical Sync End */
{IGA1_VER_SYNC_END_REG_NUM, {{CR11, 0, 3} } }
};
static struct iga2_crtc_timing iga2_crtc_reg = {
/* IGA2 Horizontal Total */
{IGA2_HOR_TOTAL_REG_NUM, {{CR50, 0, 7}, {CR55, 0, 3} } },
/* IGA2 Horizontal Addressable Video */
{IGA2_HOR_ADDR_REG_NUM, {{CR51, 0, 7}, {CR55, 4, 6} } },
/* IGA2 Horizontal Blank Start */
{IGA2_HOR_BLANK_START_REG_NUM, {{CR52, 0, 7}, {CR54, 0, 2} } },
/* IGA2 Horizontal Blank End */
{IGA2_HOR_BLANK_END_REG_NUM,
{{CR53, 0, 7}, {CR54, 3, 5}, {CR5D, 6, 6} } },
/* IGA2 Horizontal Sync Start */
{IGA2_HOR_SYNC_START_REG_NUM,
{{CR56, 0, 7}, {CR54, 6, 7}, {CR5C, 7, 7}, {CR5D, 7, 7} } },
/* IGA2 Horizontal Sync End */
{IGA2_HOR_SYNC_END_REG_NUM, {{CR57, 0, 7}, {CR5C, 6, 6} } },
/* IGA2 Vertical Total */
{IGA2_VER_TOTAL_REG_NUM, {{CR58, 0, 7}, {CR5D, 0, 2} } },
/* IGA2 Vertical Addressable Video */
{IGA2_VER_ADDR_REG_NUM, {{CR59, 0, 7}, {CR5D, 3, 5} } },
/* IGA2 Vertical Blank Start */
{IGA2_VER_BLANK_START_REG_NUM, {{CR5A, 0, 7}, {CR5C, 0, 2} } },
/* IGA2 Vertical Blank End */
{IGA2_VER_BLANK_END_REG_NUM, {{CR5B, 0, 7}, {CR5C, 3, 5} } },
/* IGA2 Vertical Sync Start */
{IGA2_VER_SYNC_START_REG_NUM, {{CR5E, 0, 7}, {CR5F, 5, 7} } },
/* IGA2 Vertical Sync End */
{IGA2_VER_SYNC_END_REG_NUM, {{CR5F, 0, 4} } }
};
static struct rgbLUT palLUT_table[] = {
/* {R,G,B} */
/* Index 0x00~0x03 */
{0x00, 0x00, 0x00}, {0x00, 0x00, 0x2A}, {0x00, 0x2A, 0x00}, {0x00,
0x2A,
0x2A},
/* Index 0x04~0x07 */
{0x2A, 0x00, 0x00}, {0x2A, 0x00, 0x2A}, {0x2A, 0x15, 0x00}, {0x2A,
0x2A,
0x2A},
/* Index 0x08~0x0B */
{0x15, 0x15, 0x15}, {0x15, 0x15, 0x3F}, {0x15, 0x3F, 0x15}, {0x15,
0x3F,
0x3F},
/* Index 0x0C~0x0F */
{0x3F, 0x15, 0x15}, {0x3F, 0x15, 0x3F}, {0x3F, 0x3F, 0x15}, {0x3F,
0x3F,
0x3F},
/* Index 0x10~0x13 */
{0x00, 0x00, 0x00}, {0x05, 0x05, 0x05}, {0x08, 0x08, 0x08}, {0x0B,
0x0B,
0x0B},
/* Index 0x14~0x17 */
{0x0E, 0x0E, 0x0E}, {0x11, 0x11, 0x11}, {0x14, 0x14, 0x14}, {0x18,
0x18,
0x18},
/* Index 0x18~0x1B */
{0x1C, 0x1C, 0x1C}, {0x20, 0x20, 0x20}, {0x24, 0x24, 0x24}, {0x28,
0x28,
0x28},
/* Index 0x1C~0x1F */
{0x2D, 0x2D, 0x2D}, {0x32, 0x32, 0x32}, {0x38, 0x38, 0x38}, {0x3F,
0x3F,
0x3F},
/* Index 0x20~0x23 */
{0x00, 0x00, 0x3F}, {0x10, 0x00, 0x3F}, {0x1F, 0x00, 0x3F}, {0x2F,
0x00,
0x3F},
/* Index 0x24~0x27 */
{0x3F, 0x00, 0x3F}, {0x3F, 0x00, 0x2F}, {0x3F, 0x00, 0x1F}, {0x3F,
0x00,
0x10},
/* Index 0x28~0x2B */
{0x3F, 0x00, 0x00}, {0x3F, 0x10, 0x00}, {0x3F, 0x1F, 0x00}, {0x3F,
0x2F,
0x00},
/* Index 0x2C~0x2F */
{0x3F, 0x3F, 0x00}, {0x2F, 0x3F, 0x00}, {0x1F, 0x3F, 0x00}, {0x10,
0x3F,
0x00},
/* Index 0x30~0x33 */
{0x00, 0x3F, 0x00}, {0x00, 0x3F, 0x10}, {0x00, 0x3F, 0x1F}, {0x00,
0x3F,
0x2F},
/* Index 0x34~0x37 */
{0x00, 0x3F, 0x3F}, {0x00, 0x2F, 0x3F}, {0x00, 0x1F, 0x3F}, {0x00,
0x10,
0x3F},
/* Index 0x38~0x3B */
{0x1F, 0x1F, 0x3F}, {0x27, 0x1F, 0x3F}, {0x2F, 0x1F, 0x3F}, {0x37,
0x1F,
0x3F},
/* Index 0x3C~0x3F */
{0x3F, 0x1F, 0x3F}, {0x3F, 0x1F, 0x37}, {0x3F, 0x1F, 0x2F}, {0x3F,
0x1F,
0x27},
/* Index 0x40~0x43 */
{0x3F, 0x1F, 0x1F}, {0x3F, 0x27, 0x1F}, {0x3F, 0x2F, 0x1F}, {0x3F,
0x3F,
0x1F},
/* Index 0x44~0x47 */
{0x3F, 0x3F, 0x1F}, {0x37, 0x3F, 0x1F}, {0x2F, 0x3F, 0x1F}, {0x27,
0x3F,
0x1F},
/* Index 0x48~0x4B */
{0x1F, 0x3F, 0x1F}, {0x1F, 0x3F, 0x27}, {0x1F, 0x3F, 0x2F}, {0x1F,
0x3F,
0x37},
/* Index 0x4C~0x4F */
{0x1F, 0x3F, 0x3F}, {0x1F, 0x37, 0x3F}, {0x1F, 0x2F, 0x3F}, {0x1F,
0x27,
0x3F},
/* Index 0x50~0x53 */
{0x2D, 0x2D, 0x3F}, {0x31, 0x2D, 0x3F}, {0x36, 0x2D, 0x3F}, {0x3A,
0x2D,
0x3F},
/* Index 0x54~0x57 */
{0x3F, 0x2D, 0x3F}, {0x3F, 0x2D, 0x3A}, {0x3F, 0x2D, 0x36}, {0x3F,
0x2D,
0x31},
/* Index 0x58~0x5B */
{0x3F, 0x2D, 0x2D}, {0x3F, 0x31, 0x2D}, {0x3F, 0x36, 0x2D}, {0x3F,
0x3A,
0x2D},
/* Index 0x5C~0x5F */
{0x3F, 0x3F, 0x2D}, {0x3A, 0x3F, 0x2D}, {0x36, 0x3F, 0x2D}, {0x31,
0x3F,
0x2D},
/* Index 0x60~0x63 */
{0x2D, 0x3F, 0x2D}, {0x2D, 0x3F, 0x31}, {0x2D, 0x3F, 0x36}, {0x2D,
0x3F,
0x3A},
/* Index 0x64~0x67 */
{0x2D, 0x3F, 0x3F}, {0x2D, 0x3A, 0x3F}, {0x2D, 0x36, 0x3F}, {0x2D,
0x31,
0x3F},
/* Index 0x68~0x6B */
{0x00, 0x00, 0x1C}, {0x07, 0x00, 0x1C}, {0x0E, 0x00, 0x1C}, {0x15,
0x00,
0x1C},
/* Index 0x6C~0x6F */
{0x1C, 0x00, 0x1C}, {0x1C, 0x00, 0x15}, {0x1C, 0x00, 0x0E}, {0x1C,
0x00,
0x07},
/* Index 0x70~0x73 */
{0x1C, 0x00, 0x00}, {0x1C, 0x07, 0x00}, {0x1C, 0x0E, 0x00}, {0x1C,
0x15,
0x00},
/* Index 0x74~0x77 */
{0x1C, 0x1C, 0x00}, {0x15, 0x1C, 0x00}, {0x0E, 0x1C, 0x00}, {0x07,
0x1C,
0x00},
/* Index 0x78~0x7B */
{0x00, 0x1C, 0x00}, {0x00, 0x1C, 0x07}, {0x00, 0x1C, 0x0E}, {0x00,
0x1C,
0x15},
/* Index 0x7C~0x7F */
{0x00, 0x1C, 0x1C}, {0x00, 0x15, 0x1C}, {0x00, 0x0E, 0x1C}, {0x00,
0x07,
0x1C},
/* Index 0x80~0x83 */
{0x0E, 0x0E, 0x1C}, {0x11, 0x0E, 0x1C}, {0x15, 0x0E, 0x1C}, {0x18,
0x0E,
0x1C},
/* Index 0x84~0x87 */
{0x1C, 0x0E, 0x1C}, {0x1C, 0x0E, 0x18}, {0x1C, 0x0E, 0x15}, {0x1C,
0x0E,
0x11},
/* Index 0x88~0x8B */
{0x1C, 0x0E, 0x0E}, {0x1C, 0x11, 0x0E}, {0x1C, 0x15, 0x0E}, {0x1C,
0x18,
0x0E},
/* Index 0x8C~0x8F */
{0x1C, 0x1C, 0x0E}, {0x18, 0x1C, 0x0E}, {0x15, 0x1C, 0x0E}, {0x11,
0x1C,
0x0E},
/* Index 0x90~0x93 */
{0x0E, 0x1C, 0x0E}, {0x0E, 0x1C, 0x11}, {0x0E, 0x1C, 0x15}, {0x0E,
0x1C,
0x18},
/* Index 0x94~0x97 */
{0x0E, 0x1C, 0x1C}, {0x0E, 0x18, 0x1C}, {0x0E, 0x15, 0x1C}, {0x0E,
0x11,
0x1C},
/* Index 0x98~0x9B */
{0x14, 0x14, 0x1C}, {0x16, 0x14, 0x1C}, {0x18, 0x14, 0x1C}, {0x1A,
0x14,
0x1C},
/* Index 0x9C~0x9F */
{0x1C, 0x14, 0x1C}, {0x1C, 0x14, 0x1A}, {0x1C, 0x14, 0x18}, {0x1C,
0x14,
0x16},
/* Index 0xA0~0xA3 */
{0x1C, 0x14, 0x14}, {0x1C, 0x16, 0x14}, {0x1C, 0x18, 0x14}, {0x1C,
0x1A,
0x14},
/* Index 0xA4~0xA7 */
{0x1C, 0x1C, 0x14}, {0x1A, 0x1C, 0x14}, {0x18, 0x1C, 0x14}, {0x16,
0x1C,
0x14},
/* Index 0xA8~0xAB */
{0x14, 0x1C, 0x14}, {0x14, 0x1C, 0x16}, {0x14, 0x1C, 0x18}, {0x14,
0x1C,
0x1A},
/* Index 0xAC~0xAF */
{0x14, 0x1C, 0x1C}, {0x14, 0x1A, 0x1C}, {0x14, 0x18, 0x1C}, {0x14,
0x16,
0x1C},
/* Index 0xB0~0xB3 */
{0x00, 0x00, 0x10}, {0x04, 0x00, 0x10}, {0x08, 0x00, 0x10}, {0x0C,
0x00,
0x10},
/* Index 0xB4~0xB7 */
{0x10, 0x00, 0x10}, {0x10, 0x00, 0x0C}, {0x10, 0x00, 0x08}, {0x10,
0x00,
0x04},
/* Index 0xB8~0xBB */
{0x10, 0x00, 0x00}, {0x10, 0x04, 0x00}, {0x10, 0x08, 0x00}, {0x10,
0x0C,
0x00},
/* Index 0xBC~0xBF */
{0x10, 0x10, 0x00}, {0x0C, 0x10, 0x00}, {0x08, 0x10, 0x00}, {0x04,
0x10,
0x00},
/* Index 0xC0~0xC3 */
{0x00, 0x10, 0x00}, {0x00, 0x10, 0x04}, {0x00, 0x10, 0x08}, {0x00,
0x10,
0x0C},
/* Index 0xC4~0xC7 */
{0x00, 0x10, 0x10}, {0x00, 0x0C, 0x10}, {0x00, 0x08, 0x10}, {0x00,
0x04,
0x10},
/* Index 0xC8~0xCB */
{0x08, 0x08, 0x10}, {0x0A, 0x08, 0x10}, {0x0C, 0x08, 0x10}, {0x0E,
0x08,
0x10},
/* Index 0xCC~0xCF */
{0x10, 0x08, 0x10}, {0x10, 0x08, 0x0E}, {0x10, 0x08, 0x0C}, {0x10,
0x08,
0x0A},
/* Index 0xD0~0xD3 */
{0x10, 0x08, 0x08}, {0x10, 0x0A, 0x08}, {0x10, 0x0C, 0x08}, {0x10,
0x0E,
0x08},
/* Index 0xD4~0xD7 */
{0x10, 0x10, 0x08}, {0x0E, 0x10, 0x08}, {0x0C, 0x10, 0x08}, {0x0A,
0x10,
0x08},
/* Index 0xD8~0xDB */
{0x08, 0x10, 0x08}, {0x08, 0x10, 0x0A}, {0x08, 0x10, 0x0C}, {0x08,
0x10,
0x0E},
/* Index 0xDC~0xDF */
{0x08, 0x10, 0x10}, {0x08, 0x0E, 0x10}, {0x08, 0x0C, 0x10}, {0x08,
0x0A,
0x10},
/* Index 0xE0~0xE3 */
{0x0B, 0x0B, 0x10}, {0x0C, 0x0B, 0x10}, {0x0D, 0x0B, 0x10}, {0x0F,
0x0B,
0x10},
/* Index 0xE4~0xE7 */
{0x10, 0x0B, 0x10}, {0x10, 0x0B, 0x0F}, {0x10, 0x0B, 0x0D}, {0x10,
0x0B,
0x0C},
/* Index 0xE8~0xEB */
{0x10, 0x0B, 0x0B}, {0x10, 0x0C, 0x0B}, {0x10, 0x0D, 0x0B}, {0x10,
0x0F,
0x0B},
/* Index 0xEC~0xEF */
{0x10, 0x10, 0x0B}, {0x0F, 0x10, 0x0B}, {0x0D, 0x10, 0x0B}, {0x0C,
0x10,
0x0B},
/* Index 0xF0~0xF3 */
{0x0B, 0x10, 0x0B}, {0x0B, 0x10, 0x0C}, {0x0B, 0x10, 0x0D}, {0x0B,
0x10,
0x0F},
/* Index 0xF4~0xF7 */
{0x0B, 0x10, 0x10}, {0x0B, 0x0F, 0x10}, {0x0B, 0x0D, 0x10}, {0x0B,
0x0C,
0x10},
/* Index 0xF8~0xFB */
{0x00, 0x00, 0x00}, {0x00, 0x00, 0x00}, {0x00, 0x00, 0x00}, {0x00,
0x00,
0x00},
/* Index 0xFC~0xFF */
{0x00, 0x00, 0x00}, {0x00, 0x00, 0x00}, {0x00, 0x00, 0x00}, {0x00,
0x00,
0x00}
};
static struct via_device_mapping device_mapping[] = {
{VIA_LDVP0, "LDVP0"},
{VIA_LDVP1, "LDVP1"},
{VIA_DVP0, "DVP0"},
{VIA_CRT, "CRT"},
{VIA_DVP1, "DVP1"},
{VIA_LVDS1, "LVDS1"},
{VIA_LVDS2, "LVDS2"}
};
static void load_fix_bit_crtc_reg(void);
static void __devinit init_gfx_chip_info(int chip_type);
static void __devinit init_tmds_chip_info(void);
static void __devinit init_lvds_chip_info(void);
static void device_screen_off(void);
static void device_screen_on(void);
static void set_display_channel(void);
static void device_off(void);
static void device_on(void);
static void enable_second_display_channel(void);
static void disable_second_display_channel(void);
void viafb_lock_crt(void)
{
viafb_write_reg_mask(CR11, VIACR, BIT7, BIT7);
}
void viafb_unlock_crt(void)
{
viafb_write_reg_mask(CR11, VIACR, 0, BIT7);
viafb_write_reg_mask(CR47, VIACR, 0, BIT0);
}
static void write_dac_reg(u8 index, u8 r, u8 g, u8 b)
{
outb(index, LUT_INDEX_WRITE);
outb(r, LUT_DATA);
outb(g, LUT_DATA);
outb(b, LUT_DATA);
}
static u32 get_dvi_devices(int output_interface)
{
switch (output_interface) {
case INTERFACE_DVP0:
return VIA_DVP0 | VIA_LDVP0;
case INTERFACE_DVP1:
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266)
return VIA_LDVP1;
else
return VIA_DVP1;
case INTERFACE_DFP_HIGH:
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266)
return 0;
else
return VIA_LVDS2 | VIA_DVP0;
case INTERFACE_DFP_LOW:
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266)
return 0;
else
return VIA_DVP1 | VIA_LVDS1;
case INTERFACE_TMDS:
return VIA_LVDS1;
}
return 0;
}
static u32 get_lcd_devices(int output_interface)
{
switch (output_interface) {
case INTERFACE_DVP0:
return VIA_DVP0;
case INTERFACE_DVP1:
return VIA_DVP1;
case INTERFACE_DFP_HIGH:
return VIA_LVDS2 | VIA_DVP0;
case INTERFACE_DFP_LOW:
return VIA_LVDS1 | VIA_DVP1;
case INTERFACE_DFP:
return VIA_LVDS1 | VIA_LVDS2;
case INTERFACE_LVDS0:
case INTERFACE_LVDS0LVDS1:
return VIA_LVDS1;
case INTERFACE_LVDS1:
return VIA_LVDS2;
}
return 0;
}
/*Set IGA path for each device*/
void viafb_set_iga_path(void)
{
if (viafb_SAMM_ON == 1) {
if (viafb_CRT_ON) {
if (viafb_primary_dev == CRT_Device)
viaparinfo->crt_setting_info->iga_path = IGA1;
else
viaparinfo->crt_setting_info->iga_path = IGA2;
}
if (viafb_DVI_ON) {
if (viafb_primary_dev == DVI_Device)
viaparinfo->tmds_setting_info->iga_path = IGA1;
else
viaparinfo->tmds_setting_info->iga_path = IGA2;
}
if (viafb_LCD_ON) {
if (viafb_primary_dev == LCD_Device) {
if (viafb_dual_fb &&
(viaparinfo->chip_info->gfx_chip_name ==
UNICHROME_CLE266)) {
viaparinfo->
lvds_setting_info->iga_path = IGA2;
viaparinfo->
crt_setting_info->iga_path = IGA1;
viaparinfo->
tmds_setting_info->iga_path = IGA1;
} else
viaparinfo->
lvds_setting_info->iga_path = IGA1;
} else {
viaparinfo->lvds_setting_info->iga_path = IGA2;
}
}
if (viafb_LCD2_ON) {
if (LCD2_Device == viafb_primary_dev)
viaparinfo->lvds_setting_info2->iga_path = IGA1;
else
viaparinfo->lvds_setting_info2->iga_path = IGA2;
}
} else {
viafb_SAMM_ON = 0;
if (viafb_CRT_ON && viafb_LCD_ON) {
viaparinfo->crt_setting_info->iga_path = IGA1;
viaparinfo->lvds_setting_info->iga_path = IGA2;
} else if (viafb_CRT_ON && viafb_DVI_ON) {
viaparinfo->crt_setting_info->iga_path = IGA1;
viaparinfo->tmds_setting_info->iga_path = IGA2;
} else if (viafb_LCD_ON && viafb_DVI_ON) {
viaparinfo->tmds_setting_info->iga_path = IGA1;
viaparinfo->lvds_setting_info->iga_path = IGA2;
} else if (viafb_LCD_ON && viafb_LCD2_ON) {
viaparinfo->lvds_setting_info->iga_path = IGA2;
viaparinfo->lvds_setting_info2->iga_path = IGA2;
} else if (viafb_CRT_ON) {
viaparinfo->crt_setting_info->iga_path = IGA1;
} else if (viafb_LCD_ON) {
viaparinfo->lvds_setting_info->iga_path = IGA2;
} else if (viafb_DVI_ON) {
viaparinfo->tmds_setting_info->iga_path = IGA1;
}
}
viaparinfo->shared->iga1_devices = 0;
viaparinfo->shared->iga2_devices = 0;
if (viafb_CRT_ON) {
if (viaparinfo->crt_setting_info->iga_path == IGA1)
viaparinfo->shared->iga1_devices |= VIA_CRT;
else
viaparinfo->shared->iga2_devices |= VIA_CRT;
}
if (viafb_DVI_ON) {
if (viaparinfo->tmds_setting_info->iga_path == IGA1)
viaparinfo->shared->iga1_devices |= get_dvi_devices(
viaparinfo->chip_info->
tmds_chip_info.output_interface);
else
viaparinfo->shared->iga2_devices |= get_dvi_devices(
viaparinfo->chip_info->
tmds_chip_info.output_interface);
}
if (viafb_LCD_ON) {
if (viaparinfo->lvds_setting_info->iga_path == IGA1)
viaparinfo->shared->iga1_devices |= get_lcd_devices(
viaparinfo->chip_info->
lvds_chip_info.output_interface);
else
viaparinfo->shared->iga2_devices |= get_lcd_devices(
viaparinfo->chip_info->
lvds_chip_info.output_interface);
}
if (viafb_LCD2_ON) {
if (viaparinfo->lvds_setting_info2->iga_path == IGA1)
viaparinfo->shared->iga1_devices |= get_lcd_devices(
viaparinfo->chip_info->
lvds_chip_info2.output_interface);
else
viaparinfo->shared->iga2_devices |= get_lcd_devices(
viaparinfo->chip_info->
lvds_chip_info2.output_interface);
}
}
static void set_color_register(u8 index, u8 red, u8 green, u8 blue)
{
outb(0xFF, 0x3C6); /* bit mask of palette */
outb(index, 0x3C8);
outb(red, 0x3C9);
outb(green, 0x3C9);
outb(blue, 0x3C9);
}
void viafb_set_primary_color_register(u8 index, u8 red, u8 green, u8 blue)
{
viafb_write_reg_mask(0x1A, VIASR, 0x00, 0x01);
set_color_register(index, red, green, blue);
}
void viafb_set_secondary_color_register(u8 index, u8 red, u8 green, u8 blue)
{
viafb_write_reg_mask(0x1A, VIASR, 0x01, 0x01);
set_color_register(index, red, green, blue);
}
static void set_source_common(u8 index, u8 offset, u8 iga)
{
u8 value, mask = 1 << offset;
switch (iga) {
case IGA1:
value = 0x00;
break;
case IGA2:
value = mask;
break;
default:
printk(KERN_WARNING "viafb: Unsupported source: %d\n", iga);
return;
}
via_write_reg_mask(VIACR, index, value, mask);
}
static void set_crt_source(u8 iga)
{
u8 value;
switch (iga) {
case IGA1:
value = 0x00;
break;
case IGA2:
value = 0x40;
break;
default:
printk(KERN_WARNING "viafb: Unsupported source: %d\n", iga);
return;
}
via_write_reg_mask(VIASR, 0x16, value, 0x40);
}
static inline void set_ldvp0_source(u8 iga)
{
set_source_common(0x6C, 7, iga);
}
static inline void set_ldvp1_source(u8 iga)
{
set_source_common(0x93, 7, iga);
}
static inline void set_dvp0_source(u8 iga)
{
set_source_common(0x96, 4, iga);
}
static inline void set_dvp1_source(u8 iga)
{
set_source_common(0x9B, 4, iga);
}
static inline void set_lvds1_source(u8 iga)
{
set_source_common(0x99, 4, iga);
}
static inline void set_lvds2_source(u8 iga)
{
set_source_common(0x97, 4, iga);
}
void via_set_source(u32 devices, u8 iga)
{
if (devices & VIA_LDVP0)
set_ldvp0_source(iga);
if (devices & VIA_LDVP1)
set_ldvp1_source(iga);
if (devices & VIA_DVP0)
set_dvp0_source(iga);
if (devices & VIA_CRT)
set_crt_source(iga);
if (devices & VIA_DVP1)
set_dvp1_source(iga);
if (devices & VIA_LVDS1)
set_lvds1_source(iga);
if (devices & VIA_LVDS2)
set_lvds2_source(iga);
}
static void set_crt_state(u8 state)
{
u8 value;
switch (state) {
case VIA_STATE_ON:
value = 0x00;
break;
case VIA_STATE_STANDBY:
value = 0x10;
break;
case VIA_STATE_SUSPEND:
value = 0x20;
break;
case VIA_STATE_OFF:
value = 0x30;
break;
default:
return;
}
via_write_reg_mask(VIACR, 0x36, value, 0x30);
}
static void set_dvp0_state(u8 state)
{
u8 value;
switch (state) {
case VIA_STATE_ON:
value = 0xC0;
break;
case VIA_STATE_OFF:
value = 0x00;
break;
default:
return;
}
via_write_reg_mask(VIASR, 0x1E, value, 0xC0);
}
static void set_dvp1_state(u8 state)
{
u8 value;
switch (state) {
case VIA_STATE_ON:
value = 0x30;
break;
case VIA_STATE_OFF:
value = 0x00;
break;
default:
return;
}
via_write_reg_mask(VIASR, 0x1E, value, 0x30);
}
static void set_lvds1_state(u8 state)
{
u8 value;
switch (state) {
case VIA_STATE_ON:
value = 0x03;
break;
case VIA_STATE_OFF:
value = 0x00;
break;
default:
return;
}
via_write_reg_mask(VIASR, 0x2A, value, 0x03);
}
static void set_lvds2_state(u8 state)
{
u8 value;
switch (state) {
case VIA_STATE_ON:
value = 0x0C;
break;
case VIA_STATE_OFF:
value = 0x00;
break;
default:
return;
}
via_write_reg_mask(VIASR, 0x2A, value, 0x0C);
}
void via_set_state(u32 devices, u8 state)
{
/*
TODO: Can we enable/disable these devices? How?
if (devices & VIA_LDVP0)
if (devices & VIA_LDVP1)
*/
if (devices & VIA_DVP0)
set_dvp0_state(state);
if (devices & VIA_CRT)
set_crt_state(state);
if (devices & VIA_DVP1)
set_dvp1_state(state);
if (devices & VIA_LVDS1)
set_lvds1_state(state);
if (devices & VIA_LVDS2)
set_lvds2_state(state);
}
void via_set_sync_polarity(u32 devices, u8 polarity)
{
if (polarity & ~(VIA_HSYNC_NEGATIVE | VIA_VSYNC_NEGATIVE)) {
printk(KERN_WARNING "viafb: Unsupported polarity: %d\n",
polarity);
return;
}
if (devices & VIA_CRT)
via_write_misc_reg_mask(polarity << 6, 0xC0);
if (devices & VIA_DVP1)
via_write_reg_mask(VIACR, 0x9B, polarity << 5, 0x60);
if (devices & VIA_LVDS1)
via_write_reg_mask(VIACR, 0x99, polarity << 5, 0x60);
if (devices & VIA_LVDS2)
via_write_reg_mask(VIACR, 0x97, polarity << 5, 0x60);
}
u32 via_parse_odev(char *input, char **end)
{
char *ptr = input;
u32 odev = 0;
bool next = true;
int i, len;
while (next) {
next = false;
for (i = 0; i < ARRAY_SIZE(device_mapping); i++) {
len = strlen(device_mapping[i].name);
if (!strncmp(ptr, device_mapping[i].name, len)) {
odev |= device_mapping[i].device;
ptr += len;
if (*ptr == ',') {
ptr++;
next = true;
}
}
}
}
*end = ptr;
return odev;
}
void via_odev_to_seq(struct seq_file *m, u32 odev)
{
int i, count = 0;
for (i = 0; i < ARRAY_SIZE(device_mapping); i++) {
if (odev & device_mapping[i].device) {
if (count > 0)
seq_putc(m, ',');
seq_puts(m, device_mapping[i].name);
count++;
}
}
seq_putc(m, '\n');
}
static void load_fix_bit_crtc_reg(void)
{
/* always set to 1 */
viafb_write_reg_mask(CR03, VIACR, 0x80, BIT7);
/* line compare should set all bits = 1 (extend modes) */
viafb_write_reg(CR18, VIACR, 0xff);
/* line compare should set all bits = 1 (extend modes) */
viafb_write_reg_mask(CR07, VIACR, 0x10, BIT4);
/* line compare should set all bits = 1 (extend modes) */
viafb_write_reg_mask(CR09, VIACR, 0x40, BIT6);
/* line compare should set all bits = 1 (extend modes) */
viafb_write_reg_mask(CR35, VIACR, 0x10, BIT4);
/* line compare should set all bits = 1 (extend modes) */
viafb_write_reg_mask(CR33, VIACR, 0x06, BIT0 + BIT1 + BIT2);
/*viafb_write_reg_mask(CR32, VIACR, 0x01, BIT0); */
/* extend mode always set to e3h */
viafb_write_reg(CR17, VIACR, 0xe3);
/* extend mode always set to 0h */
viafb_write_reg(CR08, VIACR, 0x00);
/* extend mode always set to 0h */
viafb_write_reg(CR14, VIACR, 0x00);
/* If K8M800, enable Prefetch Mode. */
if ((viaparinfo->chip_info->gfx_chip_name == UNICHROME_K800)
|| (viaparinfo->chip_info->gfx_chip_name == UNICHROME_K8M890))
viafb_write_reg_mask(CR33, VIACR, 0x08, BIT3);
if ((viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266)
&& (viaparinfo->chip_info->gfx_chip_revision == CLE266_REVISION_AX))
viafb_write_reg_mask(SR1A, VIASR, 0x02, BIT1);
}
void viafb_load_reg(int timing_value, int viafb_load_reg_num,
struct io_register *reg,
int io_type)
{
int reg_mask;
int bit_num = 0;
int data;
int i, j;
int shift_next_reg;
int start_index, end_index, cr_index;
u16 get_bit;
for (i = 0; i < viafb_load_reg_num; i++) {
reg_mask = 0;
data = 0;
start_index = reg[i].start_bit;
end_index = reg[i].end_bit;
cr_index = reg[i].io_addr;
shift_next_reg = bit_num;
for (j = start_index; j <= end_index; j++) {
/*if (bit_num==8) timing_value = timing_value >>8; */
reg_mask = reg_mask | (BIT0 << j);
get_bit = (timing_value & (BIT0 << bit_num));
data =
data | ((get_bit >> shift_next_reg) << start_index);
bit_num++;
}
if (io_type == VIACR)
viafb_write_reg_mask(cr_index, VIACR, data, reg_mask);
else
viafb_write_reg_mask(cr_index, VIASR, data, reg_mask);
}
}
/* Write Registers */
void viafb_write_regx(struct io_reg RegTable[], int ItemNum)
{
int i;
/*DEBUG_MSG(KERN_INFO "Table Size : %x!!\n",ItemNum ); */
for (i = 0; i < ItemNum; i++)
via_write_reg_mask(RegTable[i].port, RegTable[i].index,
RegTable[i].value, RegTable[i].mask);
}
void viafb_load_fetch_count_reg(int h_addr, int bpp_byte, int set_iga)
{
int reg_value;
int viafb_load_reg_num;
struct io_register *reg = NULL;
switch (set_iga) {
case IGA1:
reg_value = IGA1_FETCH_COUNT_FORMULA(h_addr, bpp_byte);
viafb_load_reg_num = fetch_count_reg.
iga1_fetch_count_reg.reg_num;
reg = fetch_count_reg.iga1_fetch_count_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIASR);
break;
case IGA2:
reg_value = IGA2_FETCH_COUNT_FORMULA(h_addr, bpp_byte);
viafb_load_reg_num = fetch_count_reg.
iga2_fetch_count_reg.reg_num;
reg = fetch_count_reg.iga2_fetch_count_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIACR);
break;
}
}
void viafb_load_FIFO_reg(int set_iga, int hor_active, int ver_active)
{
int reg_value;
int viafb_load_reg_num;
struct io_register *reg = NULL;
int iga1_fifo_max_depth = 0, iga1_fifo_threshold =
0, iga1_fifo_high_threshold = 0, iga1_display_queue_expire_num = 0;
int iga2_fifo_max_depth = 0, iga2_fifo_threshold =
0, iga2_fifo_high_threshold = 0, iga2_display_queue_expire_num = 0;
if (set_iga == IGA1) {
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_K800) {
iga1_fifo_max_depth = K800_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = K800_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
K800_IGA1_FIFO_HIGH_THRESHOLD;
/* If resolution > 1280x1024, expire length = 64, else
expire length = 128 */
if ((hor_active > 1280) && (ver_active > 1024))
iga1_display_queue_expire_num = 16;
else
iga1_display_queue_expire_num =
K800_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_PM800) {
iga1_fifo_max_depth = P880_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = P880_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
P880_IGA1_FIFO_HIGH_THRESHOLD;
iga1_display_queue_expire_num =
P880_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
/* If resolution > 1280x1024, expire length = 64, else
expire length = 128 */
if ((hor_active > 1280) && (ver_active > 1024))
iga1_display_queue_expire_num = 16;
else
iga1_display_queue_expire_num =
P880_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CN700) {
iga1_fifo_max_depth = CN700_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = CN700_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
CN700_IGA1_FIFO_HIGH_THRESHOLD;
/* If resolution > 1280x1024, expire length = 64,
else expire length = 128 */
if ((hor_active > 1280) && (ver_active > 1024))
iga1_display_queue_expire_num = 16;
else
iga1_display_queue_expire_num =
CN700_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CX700) {
iga1_fifo_max_depth = CX700_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = CX700_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
CX700_IGA1_FIFO_HIGH_THRESHOLD;
iga1_display_queue_expire_num =
CX700_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_K8M890) {
iga1_fifo_max_depth = K8M890_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = K8M890_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
K8M890_IGA1_FIFO_HIGH_THRESHOLD;
iga1_display_queue_expire_num =
K8M890_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_P4M890) {
iga1_fifo_max_depth = P4M890_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = P4M890_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
P4M890_IGA1_FIFO_HIGH_THRESHOLD;
iga1_display_queue_expire_num =
P4M890_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_P4M900) {
iga1_fifo_max_depth = P4M900_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = P4M900_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
P4M900_IGA1_FIFO_HIGH_THRESHOLD;
iga1_display_queue_expire_num =
P4M900_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_VX800) {
iga1_fifo_max_depth = VX800_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = VX800_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
VX800_IGA1_FIFO_HIGH_THRESHOLD;
iga1_display_queue_expire_num =
VX800_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_VX855) {
iga1_fifo_max_depth = VX855_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = VX855_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
VX855_IGA1_FIFO_HIGH_THRESHOLD;
iga1_display_queue_expire_num =
VX855_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_VX900) {
iga1_fifo_max_depth = VX900_IGA1_FIFO_MAX_DEPTH;
iga1_fifo_threshold = VX900_IGA1_FIFO_THRESHOLD;
iga1_fifo_high_threshold =
VX900_IGA1_FIFO_HIGH_THRESHOLD;
iga1_display_queue_expire_num =
VX900_IGA1_DISPLAY_QUEUE_EXPIRE_NUM;
}
/* Set Display FIFO Depath Select */
reg_value = IGA1_FIFO_DEPTH_SELECT_FORMULA(iga1_fifo_max_depth);
viafb_load_reg_num =
display_fifo_depth_reg.iga1_fifo_depth_select_reg.reg_num;
reg = display_fifo_depth_reg.iga1_fifo_depth_select_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIASR);
/* Set Display FIFO Threshold Select */
reg_value = IGA1_FIFO_THRESHOLD_FORMULA(iga1_fifo_threshold);
viafb_load_reg_num =
fifo_threshold_select_reg.
iga1_fifo_threshold_select_reg.reg_num;
reg =
fifo_threshold_select_reg.
iga1_fifo_threshold_select_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIASR);
/* Set FIFO High Threshold Select */
reg_value =
IGA1_FIFO_HIGH_THRESHOLD_FORMULA(iga1_fifo_high_threshold);
viafb_load_reg_num =
fifo_high_threshold_select_reg.
iga1_fifo_high_threshold_select_reg.reg_num;
reg =
fifo_high_threshold_select_reg.
iga1_fifo_high_threshold_select_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIASR);
/* Set Display Queue Expire Num */
reg_value =
IGA1_DISPLAY_QUEUE_EXPIRE_NUM_FORMULA
(iga1_display_queue_expire_num);
viafb_load_reg_num =
display_queue_expire_num_reg.
iga1_display_queue_expire_num_reg.reg_num;
reg =
display_queue_expire_num_reg.
iga1_display_queue_expire_num_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIASR);
} else {
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_K800) {
iga2_fifo_max_depth = K800_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = K800_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
K800_IGA2_FIFO_HIGH_THRESHOLD;
/* If resolution > 1280x1024, expire length = 64,
else expire length = 128 */
if ((hor_active > 1280) && (ver_active > 1024))
iga2_display_queue_expire_num = 16;
else
iga2_display_queue_expire_num =
K800_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_PM800) {
iga2_fifo_max_depth = P880_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = P880_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
P880_IGA2_FIFO_HIGH_THRESHOLD;
/* If resolution > 1280x1024, expire length = 64,
else expire length = 128 */
if ((hor_active > 1280) && (ver_active > 1024))
iga2_display_queue_expire_num = 16;
else
iga2_display_queue_expire_num =
P880_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CN700) {
iga2_fifo_max_depth = CN700_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = CN700_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
CN700_IGA2_FIFO_HIGH_THRESHOLD;
/* If resolution > 1280x1024, expire length = 64,
else expire length = 128 */
if ((hor_active > 1280) && (ver_active > 1024))
iga2_display_queue_expire_num = 16;
else
iga2_display_queue_expire_num =
CN700_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CX700) {
iga2_fifo_max_depth = CX700_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = CX700_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
CX700_IGA2_FIFO_HIGH_THRESHOLD;
iga2_display_queue_expire_num =
CX700_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_K8M890) {
iga2_fifo_max_depth = K8M890_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = K8M890_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
K8M890_IGA2_FIFO_HIGH_THRESHOLD;
iga2_display_queue_expire_num =
K8M890_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_P4M890) {
iga2_fifo_max_depth = P4M890_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = P4M890_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
P4M890_IGA2_FIFO_HIGH_THRESHOLD;
iga2_display_queue_expire_num =
P4M890_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_P4M900) {
iga2_fifo_max_depth = P4M900_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = P4M900_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
P4M900_IGA2_FIFO_HIGH_THRESHOLD;
iga2_display_queue_expire_num =
P4M900_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_VX800) {
iga2_fifo_max_depth = VX800_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = VX800_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
VX800_IGA2_FIFO_HIGH_THRESHOLD;
iga2_display_queue_expire_num =
VX800_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_VX855) {
iga2_fifo_max_depth = VX855_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = VX855_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
VX855_IGA2_FIFO_HIGH_THRESHOLD;
iga2_display_queue_expire_num =
VX855_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_VX900) {
iga2_fifo_max_depth = VX900_IGA2_FIFO_MAX_DEPTH;
iga2_fifo_threshold = VX900_IGA2_FIFO_THRESHOLD;
iga2_fifo_high_threshold =
VX900_IGA2_FIFO_HIGH_THRESHOLD;
iga2_display_queue_expire_num =
VX900_IGA2_DISPLAY_QUEUE_EXPIRE_NUM;
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_K800) {
/* Set Display FIFO Depath Select */
reg_value =
IGA2_FIFO_DEPTH_SELECT_FORMULA(iga2_fifo_max_depth)
- 1;
/* Patch LCD in IGA2 case */
viafb_load_reg_num =
display_fifo_depth_reg.
iga2_fifo_depth_select_reg.reg_num;
reg =
display_fifo_depth_reg.
iga2_fifo_depth_select_reg.reg;
viafb_load_reg(reg_value,
viafb_load_reg_num, reg, VIACR);
} else {
/* Set Display FIFO Depath Select */
reg_value =
IGA2_FIFO_DEPTH_SELECT_FORMULA(iga2_fifo_max_depth);
viafb_load_reg_num =
display_fifo_depth_reg.
iga2_fifo_depth_select_reg.reg_num;
reg =
display_fifo_depth_reg.
iga2_fifo_depth_select_reg.reg;
viafb_load_reg(reg_value,
viafb_load_reg_num, reg, VIACR);
}
/* Set Display FIFO Threshold Select */
reg_value = IGA2_FIFO_THRESHOLD_FORMULA(iga2_fifo_threshold);
viafb_load_reg_num =
fifo_threshold_select_reg.
iga2_fifo_threshold_select_reg.reg_num;
reg =
fifo_threshold_select_reg.
iga2_fifo_threshold_select_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIACR);
/* Set FIFO High Threshold Select */
reg_value =
IGA2_FIFO_HIGH_THRESHOLD_FORMULA(iga2_fifo_high_threshold);
viafb_load_reg_num =
fifo_high_threshold_select_reg.
iga2_fifo_high_threshold_select_reg.reg_num;
reg =
fifo_high_threshold_select_reg.
iga2_fifo_high_threshold_select_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIACR);
/* Set Display Queue Expire Num */
reg_value =
IGA2_DISPLAY_QUEUE_EXPIRE_NUM_FORMULA
(iga2_display_queue_expire_num);
viafb_load_reg_num =
display_queue_expire_num_reg.
iga2_display_queue_expire_num_reg.reg_num;
reg =
display_queue_expire_num_reg.
iga2_display_queue_expire_num_reg.reg;
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIACR);
}
}
static u32 cle266_encode_pll(struct pll_config pll)
{
return (pll.multiplier << 8)
| (pll.rshift << 6)
| pll.divisor;
}
static u32 k800_encode_pll(struct pll_config pll)
{
return ((pll.divisor - 2) << 16)
| (pll.rshift << 10)
| (pll.multiplier - 2);
}
static u32 vx855_encode_pll(struct pll_config pll)
{
return (pll.divisor << 16)
| (pll.rshift << 10)
| pll.multiplier;
}
static inline u32 get_pll_internal_frequency(u32 ref_freq,
struct pll_config pll)
{
return ref_freq / pll.divisor * pll.multiplier;
}
static inline u32 get_pll_output_frequency(u32 ref_freq, struct pll_config pll)
{
return get_pll_internal_frequency(ref_freq, pll)>>pll.rshift;
}
static struct pll_config get_pll_config(struct pll_limit *limits, int size,
int clk)
{
struct pll_config cur, up, down, best = {0, 1, 0};
const u32 f0 = 14318180; /* X1 frequency */
int i, f;
for (i = 0; i < size; i++) {
cur.rshift = limits[i].rshift;
cur.divisor = limits[i].divisor;
cur.multiplier = clk / ((f0 / cur.divisor)>>cur.rshift);
f = abs(get_pll_output_frequency(f0, cur) - clk);
up = down = cur;
up.multiplier++;
down.multiplier--;
if (abs(get_pll_output_frequency(f0, up) - clk) < f)
cur = up;
else if (abs(get_pll_output_frequency(f0, down) - clk) < f)
cur = down;
if (cur.multiplier < limits[i].multiplier_min)
cur.multiplier = limits[i].multiplier_min;
else if (cur.multiplier > limits[i].multiplier_max)
cur.multiplier = limits[i].multiplier_max;
f = abs(get_pll_output_frequency(f0, cur) - clk);
if (f < abs(get_pll_output_frequency(f0, best) - clk))
best = cur;
}
return best;
}
u32 viafb_get_clk_value(int clk)
{
u32 value = 0;
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_CLE266:
case UNICHROME_K400:
value = cle266_encode_pll(get_pll_config(cle266_pll_limits,
ARRAY_SIZE(cle266_pll_limits), clk));
break;
case UNICHROME_K800:
case UNICHROME_PM800:
case UNICHROME_CN700:
value = k800_encode_pll(get_pll_config(k800_pll_limits,
ARRAY_SIZE(k800_pll_limits), clk));
break;
case UNICHROME_CX700:
case UNICHROME_CN750:
case UNICHROME_K8M890:
case UNICHROME_P4M890:
case UNICHROME_P4M900:
case UNICHROME_VX800:
value = k800_encode_pll(get_pll_config(cx700_pll_limits,
ARRAY_SIZE(cx700_pll_limits), clk));
break;
case UNICHROME_VX855:
case UNICHROME_VX900:
value = vx855_encode_pll(get_pll_config(vx855_pll_limits,
ARRAY_SIZE(vx855_pll_limits), clk));
break;
}
return value;
}
/* Set VCLK*/
void viafb_set_vclock(u32 clk, int set_iga)
{
/* H.W. Reset : ON */
viafb_write_reg_mask(CR17, VIACR, 0x00, BIT7);
if (set_iga == IGA1) {
/* Change D,N FOR VCLK */
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_CLE266:
case UNICHROME_K400:
via_write_reg(VIASR, SR46, (clk & 0x00FF));
via_write_reg(VIASR, SR47, (clk & 0xFF00) >> 8);
break;
case UNICHROME_K800:
case UNICHROME_PM800:
case UNICHROME_CN700:
case UNICHROME_CX700:
case UNICHROME_CN750:
case UNICHROME_K8M890:
case UNICHROME_P4M890:
case UNICHROME_P4M900:
case UNICHROME_VX800:
case UNICHROME_VX855:
case UNICHROME_VX900:
via_write_reg(VIASR, SR44, (clk & 0x0000FF));
via_write_reg(VIASR, SR45, (clk & 0x00FF00) >> 8);
via_write_reg(VIASR, SR46, (clk & 0xFF0000) >> 16);
break;
}
}
if (set_iga == IGA2) {
/* Change D,N FOR LCK */
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_CLE266:
case UNICHROME_K400:
via_write_reg(VIASR, SR44, (clk & 0x00FF));
via_write_reg(VIASR, SR45, (clk & 0xFF00) >> 8);
break;
case UNICHROME_K800:
case UNICHROME_PM800:
case UNICHROME_CN700:
case UNICHROME_CX700:
case UNICHROME_CN750:
case UNICHROME_K8M890:
case UNICHROME_P4M890:
case UNICHROME_P4M900:
case UNICHROME_VX800:
case UNICHROME_VX855:
case UNICHROME_VX900:
via_write_reg(VIASR, SR4A, (clk & 0x0000FF));
via_write_reg(VIASR, SR4B, (clk & 0x00FF00) >> 8);
via_write_reg(VIASR, SR4C, (clk & 0xFF0000) >> 16);
break;
}
}
/* H.W. Reset : OFF */
viafb_write_reg_mask(CR17, VIACR, 0x80, BIT7);
/* Reset PLL */
if (set_iga == IGA1) {
viafb_write_reg_mask(SR40, VIASR, 0x02, BIT1);
viafb_write_reg_mask(SR40, VIASR, 0x00, BIT1);
}
if (set_iga == IGA2) {
viafb_write_reg_mask(SR40, VIASR, 0x04, BIT2);
viafb_write_reg_mask(SR40, VIASR, 0x00, BIT2);
}
/* Fire! */
via_write_misc_reg_mask(0x0C, 0x0C); /* select external clock */
}
void viafb_load_crtc_timing(struct display_timing device_timing,
int set_iga)
{
int i;
int viafb_load_reg_num = 0;
int reg_value = 0;
struct io_register *reg = NULL;
viafb_unlock_crt();
for (i = 0; i < 12; i++) {
if (set_iga == IGA1) {
switch (i) {
case H_TOTAL_INDEX:
reg_value =
IGA1_HOR_TOTAL_FORMULA(device_timing.
hor_total);
viafb_load_reg_num =
iga1_crtc_reg.hor_total.reg_num;
reg = iga1_crtc_reg.hor_total.reg;
break;
case H_ADDR_INDEX:
reg_value =
IGA1_HOR_ADDR_FORMULA(device_timing.
hor_addr);
viafb_load_reg_num =
iga1_crtc_reg.hor_addr.reg_num;
reg = iga1_crtc_reg.hor_addr.reg;
break;
case H_BLANK_START_INDEX:
reg_value =
IGA1_HOR_BLANK_START_FORMULA
(device_timing.hor_blank_start);
viafb_load_reg_num =
iga1_crtc_reg.hor_blank_start.reg_num;
reg = iga1_crtc_reg.hor_blank_start.reg;
break;
case H_BLANK_END_INDEX:
reg_value =
IGA1_HOR_BLANK_END_FORMULA
(device_timing.hor_blank_start,
device_timing.hor_blank_end);
viafb_load_reg_num =
iga1_crtc_reg.hor_blank_end.reg_num;
reg = iga1_crtc_reg.hor_blank_end.reg;
break;
case H_SYNC_START_INDEX:
reg_value =
IGA1_HOR_SYNC_START_FORMULA
(device_timing.hor_sync_start);
viafb_load_reg_num =
iga1_crtc_reg.hor_sync_start.reg_num;
reg = iga1_crtc_reg.hor_sync_start.reg;
break;
case H_SYNC_END_INDEX:
reg_value =
IGA1_HOR_SYNC_END_FORMULA
(device_timing.hor_sync_start,
device_timing.hor_sync_end);
viafb_load_reg_num =
iga1_crtc_reg.hor_sync_end.reg_num;
reg = iga1_crtc_reg.hor_sync_end.reg;
break;
case V_TOTAL_INDEX:
reg_value =
IGA1_VER_TOTAL_FORMULA(device_timing.
ver_total);
viafb_load_reg_num =
iga1_crtc_reg.ver_total.reg_num;
reg = iga1_crtc_reg.ver_total.reg;
break;
case V_ADDR_INDEX:
reg_value =
IGA1_VER_ADDR_FORMULA(device_timing.
ver_addr);
viafb_load_reg_num =
iga1_crtc_reg.ver_addr.reg_num;
reg = iga1_crtc_reg.ver_addr.reg;
break;
case V_BLANK_START_INDEX:
reg_value =
IGA1_VER_BLANK_START_FORMULA
(device_timing.ver_blank_start);
viafb_load_reg_num =
iga1_crtc_reg.ver_blank_start.reg_num;
reg = iga1_crtc_reg.ver_blank_start.reg;
break;
case V_BLANK_END_INDEX:
reg_value =
IGA1_VER_BLANK_END_FORMULA
(device_timing.ver_blank_start,
device_timing.ver_blank_end);
viafb_load_reg_num =
iga1_crtc_reg.ver_blank_end.reg_num;
reg = iga1_crtc_reg.ver_blank_end.reg;
break;
case V_SYNC_START_INDEX:
reg_value =
IGA1_VER_SYNC_START_FORMULA
(device_timing.ver_sync_start);
viafb_load_reg_num =
iga1_crtc_reg.ver_sync_start.reg_num;
reg = iga1_crtc_reg.ver_sync_start.reg;
break;
case V_SYNC_END_INDEX:
reg_value =
IGA1_VER_SYNC_END_FORMULA
(device_timing.ver_sync_start,
device_timing.ver_sync_end);
viafb_load_reg_num =
iga1_crtc_reg.ver_sync_end.reg_num;
reg = iga1_crtc_reg.ver_sync_end.reg;
break;
}
}
if (set_iga == IGA2) {
switch (i) {
case H_TOTAL_INDEX:
reg_value =
IGA2_HOR_TOTAL_FORMULA(device_timing.
hor_total);
viafb_load_reg_num =
iga2_crtc_reg.hor_total.reg_num;
reg = iga2_crtc_reg.hor_total.reg;
break;
case H_ADDR_INDEX:
reg_value =
IGA2_HOR_ADDR_FORMULA(device_timing.
hor_addr);
viafb_load_reg_num =
iga2_crtc_reg.hor_addr.reg_num;
reg = iga2_crtc_reg.hor_addr.reg;
break;
case H_BLANK_START_INDEX:
reg_value =
IGA2_HOR_BLANK_START_FORMULA
(device_timing.hor_blank_start);
viafb_load_reg_num =
iga2_crtc_reg.hor_blank_start.reg_num;
reg = iga2_crtc_reg.hor_blank_start.reg;
break;
case H_BLANK_END_INDEX:
reg_value =
IGA2_HOR_BLANK_END_FORMULA
(device_timing.hor_blank_start,
device_timing.hor_blank_end);
viafb_load_reg_num =
iga2_crtc_reg.hor_blank_end.reg_num;
reg = iga2_crtc_reg.hor_blank_end.reg;
break;
case H_SYNC_START_INDEX:
reg_value =
IGA2_HOR_SYNC_START_FORMULA
(device_timing.hor_sync_start);
if (UNICHROME_CN700 <=
viaparinfo->chip_info->gfx_chip_name)
viafb_load_reg_num =
iga2_crtc_reg.hor_sync_start.
reg_num;
else
viafb_load_reg_num = 3;
reg = iga2_crtc_reg.hor_sync_start.reg;
break;
case H_SYNC_END_INDEX:
reg_value =
IGA2_HOR_SYNC_END_FORMULA
(device_timing.hor_sync_start,
device_timing.hor_sync_end);
viafb_load_reg_num =
iga2_crtc_reg.hor_sync_end.reg_num;
reg = iga2_crtc_reg.hor_sync_end.reg;
break;
case V_TOTAL_INDEX:
reg_value =
IGA2_VER_TOTAL_FORMULA(device_timing.
ver_total);
viafb_load_reg_num =
iga2_crtc_reg.ver_total.reg_num;
reg = iga2_crtc_reg.ver_total.reg;
break;
case V_ADDR_INDEX:
reg_value =
IGA2_VER_ADDR_FORMULA(device_timing.
ver_addr);
viafb_load_reg_num =
iga2_crtc_reg.ver_addr.reg_num;
reg = iga2_crtc_reg.ver_addr.reg;
break;
case V_BLANK_START_INDEX:
reg_value =
IGA2_VER_BLANK_START_FORMULA
(device_timing.ver_blank_start);
viafb_load_reg_num =
iga2_crtc_reg.ver_blank_start.reg_num;
reg = iga2_crtc_reg.ver_blank_start.reg;
break;
case V_BLANK_END_INDEX:
reg_value =
IGA2_VER_BLANK_END_FORMULA
(device_timing.ver_blank_start,
device_timing.ver_blank_end);
viafb_load_reg_num =
iga2_crtc_reg.ver_blank_end.reg_num;
reg = iga2_crtc_reg.ver_blank_end.reg;
break;
case V_SYNC_START_INDEX:
reg_value =
IGA2_VER_SYNC_START_FORMULA
(device_timing.ver_sync_start);
viafb_load_reg_num =
iga2_crtc_reg.ver_sync_start.reg_num;
reg = iga2_crtc_reg.ver_sync_start.reg;
break;
case V_SYNC_END_INDEX:
reg_value =
IGA2_VER_SYNC_END_FORMULA
(device_timing.ver_sync_start,
device_timing.ver_sync_end);
viafb_load_reg_num =
iga2_crtc_reg.ver_sync_end.reg_num;
reg = iga2_crtc_reg.ver_sync_end.reg;
break;
}
}
viafb_load_reg(reg_value, viafb_load_reg_num, reg, VIACR);
}
viafb_lock_crt();
}
void viafb_fill_crtc_timing(struct crt_mode_table *crt_table,
struct VideoModeTable *video_mode, int bpp_byte, int set_iga)
{
struct display_timing crt_reg;
int i;
int index = 0;
int h_addr, v_addr;
u32 pll_D_N, clock, refresh = viafb_refresh;
if (viafb_SAMM_ON && set_iga == IGA2)
refresh = viafb_refresh1;
for (i = 0; i < video_mode->mode_array; i++) {
index = i;
if (crt_table[i].refresh_rate == refresh)
break;
}
crt_reg = crt_table[index].crtc;
/* Mode 640x480 has border, but LCD/DFP didn't have border. */
/* So we would delete border. */
if ((viafb_LCD_ON | viafb_DVI_ON)
&& video_mode->crtc[0].crtc.hor_addr == 640
&& video_mode->crtc[0].crtc.ver_addr == 480
&& refresh == 60) {
/* The border is 8 pixels. */
crt_reg.hor_blank_start = crt_reg.hor_blank_start - 8;
/* Blanking time should add left and right borders. */
crt_reg.hor_blank_end = crt_reg.hor_blank_end + 16;
}
h_addr = crt_reg.hor_addr;
v_addr = crt_reg.ver_addr;
if (set_iga == IGA1) {
viafb_unlock_crt();
viafb_write_reg(CR09, VIACR, 0x00); /*initial CR09=0 */
viafb_write_reg_mask(CR11, VIACR, 0x00, BIT4 + BIT5 + BIT6);
viafb_write_reg_mask(CR17, VIACR, 0x00, BIT7);
}
switch (set_iga) {
case IGA1:
viafb_load_crtc_timing(crt_reg, IGA1);
break;
case IGA2:
viafb_load_crtc_timing(crt_reg, IGA2);
break;
}
load_fix_bit_crtc_reg();
viafb_lock_crt();
viafb_write_reg_mask(CR17, VIACR, 0x80, BIT7);
viafb_load_fetch_count_reg(h_addr, bpp_byte, set_iga);
/* load FIFO */
if ((viaparinfo->chip_info->gfx_chip_name != UNICHROME_CLE266)
&& (viaparinfo->chip_info->gfx_chip_name != UNICHROME_K400))
viafb_load_FIFO_reg(set_iga, h_addr, v_addr);
clock = crt_reg.hor_total * crt_reg.ver_total
* crt_table[index].refresh_rate;
pll_D_N = viafb_get_clk_value(clock);
DEBUG_MSG(KERN_INFO "PLL=%x", pll_D_N);
viafb_set_vclock(pll_D_N, set_iga);
}
void __devinit viafb_init_chip_info(int chip_type)
{
init_gfx_chip_info(chip_type);
init_tmds_chip_info();
init_lvds_chip_info();
viaparinfo->crt_setting_info->iga_path = IGA1;
/*Set IGA path for each device */
viafb_set_iga_path();
viaparinfo->lvds_setting_info->display_method = viafb_lcd_dsp_method;
viaparinfo->lvds_setting_info->lcd_mode = viafb_lcd_mode;
viaparinfo->lvds_setting_info2->display_method =
viaparinfo->lvds_setting_info->display_method;
viaparinfo->lvds_setting_info2->lcd_mode =
viaparinfo->lvds_setting_info->lcd_mode;
}
void viafb_update_device_setting(int hres, int vres, int bpp, int flag)
{
if (flag == 0) {
viaparinfo->tmds_setting_info->h_active = hres;
viaparinfo->tmds_setting_info->v_active = vres;
viaparinfo->lvds_setting_info->h_active = hres;
viaparinfo->lvds_setting_info->v_active = vres;
viaparinfo->lvds_setting_info->bpp = bpp;
viaparinfo->lvds_setting_info2->h_active = hres;
viaparinfo->lvds_setting_info2->v_active = vres;
viaparinfo->lvds_setting_info2->bpp = bpp;
} else {
if (viaparinfo->tmds_setting_info->iga_path == IGA2) {
viaparinfo->tmds_setting_info->h_active = hres;
viaparinfo->tmds_setting_info->v_active = vres;
}
if (viaparinfo->lvds_setting_info->iga_path == IGA2) {
viaparinfo->lvds_setting_info->h_active = hres;
viaparinfo->lvds_setting_info->v_active = vres;
viaparinfo->lvds_setting_info->bpp = bpp;
}
if (IGA2 == viaparinfo->lvds_setting_info2->iga_path) {
viaparinfo->lvds_setting_info2->h_active = hres;
viaparinfo->lvds_setting_info2->v_active = vres;
viaparinfo->lvds_setting_info2->bpp = bpp;
}
}
}
static void __devinit init_gfx_chip_info(int chip_type)
{
u8 tmp;
viaparinfo->chip_info->gfx_chip_name = chip_type;
/* Check revision of CLE266 Chip */
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266) {
/* CR4F only define in CLE266.CX chip */
tmp = viafb_read_reg(VIACR, CR4F);
viafb_write_reg(CR4F, VIACR, 0x55);
if (viafb_read_reg(VIACR, CR4F) != 0x55)
viaparinfo->chip_info->gfx_chip_revision =
CLE266_REVISION_AX;
else
viaparinfo->chip_info->gfx_chip_revision =
CLE266_REVISION_CX;
/* restore orignal CR4F value */
viafb_write_reg(CR4F, VIACR, tmp);
}
if (viaparinfo->chip_info->gfx_chip_name == UNICHROME_CX700) {
tmp = viafb_read_reg(VIASR, SR43);
DEBUG_MSG(KERN_INFO "SR43:%X\n", tmp);
if (tmp & 0x02) {
viaparinfo->chip_info->gfx_chip_revision =
CX700_REVISION_700M2;
} else if (tmp & 0x40) {
viaparinfo->chip_info->gfx_chip_revision =
CX700_REVISION_700M;
} else {
viaparinfo->chip_info->gfx_chip_revision =
CX700_REVISION_700;
}
}
/* Determine which 2D engine we have */
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_VX800:
case UNICHROME_VX855:
case UNICHROME_VX900:
viaparinfo->chip_info->twod_engine = VIA_2D_ENG_M1;
break;
case UNICHROME_K8M890:
case UNICHROME_P4M900:
viaparinfo->chip_info->twod_engine = VIA_2D_ENG_H5;
break;
default:
viaparinfo->chip_info->twod_engine = VIA_2D_ENG_H2;
break;
}
}
static void __devinit init_tmds_chip_info(void)
{
viafb_tmds_trasmitter_identify();
if (INTERFACE_NONE == viaparinfo->chip_info->tmds_chip_info.
output_interface) {
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_CX700:
{
/* we should check support by hardware layout.*/
if ((viafb_display_hardware_layout ==
HW_LAYOUT_DVI_ONLY)
|| (viafb_display_hardware_layout ==
HW_LAYOUT_LCD_DVI)) {
viaparinfo->chip_info->tmds_chip_info.
output_interface = INTERFACE_TMDS;
} else {
viaparinfo->chip_info->tmds_chip_info.
output_interface =
INTERFACE_NONE;
}
break;
}
case UNICHROME_K8M890:
case UNICHROME_P4M900:
case UNICHROME_P4M890:
/* TMDS on PCIE, we set DFPLOW as default. */
viaparinfo->chip_info->tmds_chip_info.output_interface =
INTERFACE_DFP_LOW;
break;
default:
{
/* set DVP1 default for DVI */
viaparinfo->chip_info->tmds_chip_info
.output_interface = INTERFACE_DVP1;
}
}
}
DEBUG_MSG(KERN_INFO "TMDS Chip = %d\n",
viaparinfo->chip_info->tmds_chip_info.tmds_chip_name);
viafb_init_dvi_size(&viaparinfo->shared->chip_info.tmds_chip_info,
&viaparinfo->shared->tmds_setting_info);
}
static void __devinit init_lvds_chip_info(void)
{
viafb_lvds_trasmitter_identify();
viafb_init_lcd_size();
viafb_init_lvds_output_interface(&viaparinfo->chip_info->lvds_chip_info,
viaparinfo->lvds_setting_info);
if (viaparinfo->chip_info->lvds_chip_info2.lvds_chip_name) {
viafb_init_lvds_output_interface(&viaparinfo->chip_info->
lvds_chip_info2, viaparinfo->lvds_setting_info2);
}
/*If CX700,two singel LCD, we need to reassign
LCD interface to different LVDS port */
if ((UNICHROME_CX700 == viaparinfo->chip_info->gfx_chip_name)
&& (HW_LAYOUT_LCD1_LCD2 == viafb_display_hardware_layout)) {
if ((INTEGRATED_LVDS == viaparinfo->chip_info->lvds_chip_info.
lvds_chip_name) && (INTEGRATED_LVDS ==
viaparinfo->chip_info->
lvds_chip_info2.lvds_chip_name)) {
viaparinfo->chip_info->lvds_chip_info.output_interface =
INTERFACE_LVDS0;
viaparinfo->chip_info->lvds_chip_info2.
output_interface =
INTERFACE_LVDS1;
}
}
DEBUG_MSG(KERN_INFO "LVDS Chip = %d\n",
viaparinfo->chip_info->lvds_chip_info.lvds_chip_name);
DEBUG_MSG(KERN_INFO "LVDS1 output_interface = %d\n",
viaparinfo->chip_info->lvds_chip_info.output_interface);
DEBUG_MSG(KERN_INFO "LVDS2 output_interface = %d\n",
viaparinfo->chip_info->lvds_chip_info.output_interface);
}
void __devinit viafb_init_dac(int set_iga)
{
int i;
u8 tmp;
if (set_iga == IGA1) {
/* access Primary Display's LUT */
viafb_write_reg_mask(SR1A, VIASR, 0x00, BIT0);
/* turn off LCK */
viafb_write_reg_mask(SR1B, VIASR, 0x00, BIT7 + BIT6);
for (i = 0; i < 256; i++) {
write_dac_reg(i, palLUT_table[i].red,
palLUT_table[i].green,
palLUT_table[i].blue);
}
/* turn on LCK */
viafb_write_reg_mask(SR1B, VIASR, 0xC0, BIT7 + BIT6);
} else {
tmp = viafb_read_reg(VIACR, CR6A);
/* access Secondary Display's LUT */
viafb_write_reg_mask(CR6A, VIACR, 0x40, BIT6);
viafb_write_reg_mask(SR1A, VIASR, 0x01, BIT0);
for (i = 0; i < 256; i++) {
write_dac_reg(i, palLUT_table[i].red,
palLUT_table[i].green,
palLUT_table[i].blue);
}
/* set IGA1 DAC for default */
viafb_write_reg_mask(SR1A, VIASR, 0x00, BIT0);
viafb_write_reg(CR6A, VIACR, tmp);
}
}
static void device_screen_off(void)
{
/* turn off CRT screen (IGA1) */
viafb_write_reg_mask(SR01, VIASR, 0x20, BIT5);
}
static void device_screen_on(void)
{
/* turn on CRT screen (IGA1) */
viafb_write_reg_mask(SR01, VIASR, 0x00, BIT5);
}
static void set_display_channel(void)
{
/*If viafb_LCD2_ON, on cx700, internal lvds's information
is keeped on lvds_setting_info2 */
if (viafb_LCD2_ON &&
viaparinfo->lvds_setting_info2->device_lcd_dualedge) {
/* For dual channel LCD: */
/* Set to Dual LVDS channel. */
viafb_write_reg_mask(CRD2, VIACR, 0x20, BIT4 + BIT5);
} else if (viafb_LCD_ON && viafb_DVI_ON) {
/* For LCD+DFP: */
/* Set to LVDS1 + TMDS channel. */
viafb_write_reg_mask(CRD2, VIACR, 0x10, BIT4 + BIT5);
} else if (viafb_DVI_ON) {
/* Set to single TMDS channel. */
viafb_write_reg_mask(CRD2, VIACR, 0x30, BIT4 + BIT5);
} else if (viafb_LCD_ON) {
if (viaparinfo->lvds_setting_info->device_lcd_dualedge) {
/* For dual channel LCD: */
/* Set to Dual LVDS channel. */
viafb_write_reg_mask(CRD2, VIACR, 0x20, BIT4 + BIT5);
} else {
/* Set to LVDS0 + LVDS1 channel. */
viafb_write_reg_mask(CRD2, VIACR, 0x00, BIT4 + BIT5);
}
}
}
static u8 get_sync(struct fb_info *info)
{
u8 polarity = 0;
if (!(info->var.sync & FB_SYNC_HOR_HIGH_ACT))
polarity |= VIA_HSYNC_NEGATIVE;
if (!(info->var.sync & FB_SYNC_VERT_HIGH_ACT))
polarity |= VIA_VSYNC_NEGATIVE;
return polarity;
}
int viafb_setmode(struct VideoModeTable *vmode_tbl, int video_bpp,
struct VideoModeTable *vmode_tbl1, int video_bpp1)
{
int i, j;
int port;
u32 devices = viaparinfo->shared->iga1_devices
| viaparinfo->shared->iga2_devices;
u8 value, index, mask;
struct crt_mode_table *crt_timing;
struct crt_mode_table *crt_timing1 = NULL;
device_screen_off();
crt_timing = vmode_tbl->crtc;
if (viafb_SAMM_ON == 1) {
crt_timing1 = vmode_tbl1->crtc;
}
inb(VIAStatus);
outb(0x00, VIAAR);
/* Write Common Setting for Video Mode */
switch (viaparinfo->chip_info->gfx_chip_name) {
case UNICHROME_CLE266:
viafb_write_regx(CLE266_ModeXregs, NUM_TOTAL_CLE266_ModeXregs);
break;
case UNICHROME_K400:
viafb_write_regx(KM400_ModeXregs, NUM_TOTAL_KM400_ModeXregs);
break;
case UNICHROME_K800:
case UNICHROME_PM800:
viafb_write_regx(CN400_ModeXregs, NUM_TOTAL_CN400_ModeXregs);
break;
case UNICHROME_CN700:
case UNICHROME_K8M890:
case UNICHROME_P4M890:
case UNICHROME_P4M900:
viafb_write_regx(CN700_ModeXregs, NUM_TOTAL_CN700_ModeXregs);
break;
case UNICHROME_CX700:
case UNICHROME_VX800:
viafb_write_regx(CX700_ModeXregs, NUM_TOTAL_CX700_ModeXregs);
break;
case UNICHROME_VX855:
case UNICHROME_VX900:
viafb_write_regx(VX855_ModeXregs, NUM_TOTAL_VX855_ModeXregs);
break;
}
viafb_write_regx(scaling_parameters, ARRAY_SIZE(scaling_parameters));
device_off();
via_set_state(devices, VIA_STATE_OFF);
/* Fill VPIT Parameters */
/* Write Misc Register */
outb(VPIT.Misc, VIA_MISC_REG_WRITE);
/* Write Sequencer */
for (i = 1; i <= StdSR; i++)
via_write_reg(VIASR, i, VPIT.SR[i - 1]);
viafb_write_reg_mask(0x15, VIASR, 0xA2, 0xA2);
/* Write CRTC */
viafb_fill_crtc_timing(crt_timing, vmode_tbl, video_bpp / 8, IGA1);
/* Write Graphic Controller */
for (i = 0; i < StdGR; i++)
via_write_reg(VIAGR, i, VPIT.GR[i]);
/* Write Attribute Controller */
for (i = 0; i < StdAR; i++) {
inb(VIAStatus);
outb(i, VIAAR);
outb(VPIT.AR[i], VIAAR);
}
inb(VIAStatus);
outb(0x20, VIAAR);
/* Update Patch Register */
if ((viaparinfo->chip_info->gfx_chip_name == UNICHROME_CLE266
|| viaparinfo->chip_info->gfx_chip_name == UNICHROME_K400)
&& vmode_tbl->crtc[0].crtc.hor_addr == 1024
&& vmode_tbl->crtc[0].crtc.ver_addr == 768) {
for (j = 0; j < res_patch_table[0].table_length; j++) {
index = res_patch_table[0].io_reg_table[j].index;
port = res_patch_table[0].io_reg_table[j].port;
value = res_patch_table[0].io_reg_table[j].value;
mask = res_patch_table[0].io_reg_table[j].mask;
viafb_write_reg_mask(index, port, value, mask);
}
}
via_set_primary_pitch(viafbinfo->fix.line_length);
via_set_secondary_pitch(viafb_dual_fb ? viafbinfo1->fix.line_length
: viafbinfo->fix.line_length);
via_set_primary_color_depth(viaparinfo->depth);
via_set_secondary_color_depth(viafb_dual_fb ? viaparinfo1->depth
: viaparinfo->depth);
via_set_source(viaparinfo->shared->iga1_devices, IGA1);
via_set_source(viaparinfo->shared->iga2_devices, IGA2);
if (viaparinfo->shared->iga2_devices)
enable_second_display_channel();
else
disable_second_display_channel();
/* Update Refresh Rate Setting */
/* Clear On Screen */
/* CRT set mode */
if (viafb_CRT_ON) {
if (viafb_SAMM_ON && (viaparinfo->crt_setting_info->iga_path ==
IGA2)) {
viafb_fill_crtc_timing(crt_timing1, vmode_tbl1,
video_bpp1 / 8,
viaparinfo->crt_setting_info->iga_path);
} else {
viafb_fill_crtc_timing(crt_timing, vmode_tbl,
video_bpp / 8,
viaparinfo->crt_setting_info->iga_path);
}
/* Patch if set_hres is not 8 alignment (1366) to viafb_setmode
to 8 alignment (1368),there is several pixels (2 pixels)
on right side of screen. */
if (vmode_tbl->crtc[0].crtc.hor_addr % 8) {
viafb_unlock_crt();
viafb_write_reg(CR02, VIACR,
viafb_read_reg(VIACR, CR02) - 1);
viafb_lock_crt();
}
}
if (viafb_DVI_ON) {
if (viafb_SAMM_ON &&
(viaparinfo->tmds_setting_info->iga_path == IGA2)) {
viafb_dvi_set_mode(viafb_get_mode
(viaparinfo->tmds_setting_info->h_active,
viaparinfo->tmds_setting_info->
v_active),
video_bpp1, viaparinfo->
tmds_setting_info->iga_path);
} else {
viafb_dvi_set_mode(viafb_get_mode
(viaparinfo->tmds_setting_info->h_active,
viaparinfo->
tmds_setting_info->v_active),
video_bpp, viaparinfo->
tmds_setting_info->iga_path);
}
}
if (viafb_LCD_ON) {
if (viafb_SAMM_ON &&
(viaparinfo->lvds_setting_info->iga_path == IGA2)) {
viaparinfo->lvds_setting_info->bpp = video_bpp1;
viafb_lcd_set_mode(crt_timing1, viaparinfo->
lvds_setting_info,
&viaparinfo->chip_info->lvds_chip_info);
} else {
/* IGA1 doesn't have LCD scaling, so set it center. */
if (viaparinfo->lvds_setting_info->iga_path == IGA1) {
viaparinfo->lvds_setting_info->display_method =
LCD_CENTERING;
}
viaparinfo->lvds_setting_info->bpp = video_bpp;
viafb_lcd_set_mode(crt_timing, viaparinfo->
lvds_setting_info,
&viaparinfo->chip_info->lvds_chip_info);
}
}
if (viafb_LCD2_ON) {
if (viafb_SAMM_ON &&
(viaparinfo->lvds_setting_info2->iga_path == IGA2)) {
viaparinfo->lvds_setting_info2->bpp = video_bpp1;
viafb_lcd_set_mode(crt_timing1, viaparinfo->
lvds_setting_info2,
&viaparinfo->chip_info->lvds_chip_info2);
} else {
/* IGA1 doesn't have LCD scaling, so set it center. */
if (viaparinfo->lvds_setting_info2->iga_path == IGA1) {
viaparinfo->lvds_setting_info2->display_method =
LCD_CENTERING;
}
viaparinfo->lvds_setting_info2->bpp = video_bpp;
viafb_lcd_set_mode(crt_timing, viaparinfo->
lvds_setting_info2,
&viaparinfo->chip_info->lvds_chip_info2);
}
}
if ((viaparinfo->chip_info->gfx_chip_name == UNICHROME_CX700)
&& (viafb_LCD_ON || viafb_DVI_ON))
set_display_channel();
/* If set mode normally, save resolution information for hot-plug . */
if (!viafb_hotplug) {
viafb_hotplug_Xres = vmode_tbl->crtc[0].crtc.hor_addr;
viafb_hotplug_Yres = vmode_tbl->crtc[0].crtc.ver_addr;
viafb_hotplug_bpp = video_bpp;
viafb_hotplug_refresh = viafb_refresh;
if (viafb_DVI_ON)
viafb_DeviceStatus = DVI_Device;
else
viafb_DeviceStatus = CRT_Device;
}
device_on();
if (!viafb_dual_fb)
via_set_sync_polarity(devices, get_sync(viafbinfo));
else {
via_set_sync_polarity(viaparinfo->shared->iga1_devices,
get_sync(viafbinfo));
via_set_sync_polarity(viaparinfo->shared->iga2_devices,
get_sync(viafbinfo1));
}
via_set_state(devices, VIA_STATE_ON);
device_screen_on();
return 1;
}
int viafb_get_pixclock(int hres, int vres, int vmode_refresh)
{
int i;
struct crt_mode_table *best;
struct VideoModeTable *vmode = viafb_get_mode(hres, vres);
if (!vmode)
return RES_640X480_60HZ_PIXCLOCK;
best = &vmode->crtc[0];
for (i = 1; i < vmode->mode_array; i++) {
if (abs(vmode->crtc[i].refresh_rate - vmode_refresh)
< abs(best->refresh_rate - vmode_refresh))
best = &vmode->crtc[i];
}
return 1000000000 / (best->crtc.hor_total * best->crtc.ver_total)
* 1000 / best->refresh_rate;
}
int viafb_get_refresh(int hres, int vres, u32 long_refresh)
{
int i;
struct crt_mode_table *best;
struct VideoModeTable *vmode = viafb_get_mode(hres, vres);
if (!vmode)
return 60;
best = &vmode->crtc[0];
for (i = 1; i < vmode->mode_array; i++) {
if (abs(vmode->crtc[i].refresh_rate - long_refresh)
< abs(best->refresh_rate - long_refresh))
best = &vmode->crtc[i];
}
if (abs(best->refresh_rate - long_refresh) > 3)
return 60;
return best->refresh_rate;
}
static void device_off(void)
{
viafb_dvi_disable();
viafb_lcd_disable();
}
static void device_on(void)
{
if (viafb_DVI_ON == 1)
viafb_dvi_enable();
if (viafb_LCD_ON == 1)
viafb_lcd_enable();
}
static void enable_second_display_channel(void)
{
/* to enable second display channel. */
viafb_write_reg_mask(CR6A, VIACR, 0x00, BIT6);
viafb_write_reg_mask(CR6A, VIACR, BIT7, BIT7);
viafb_write_reg_mask(CR6A, VIACR, BIT6, BIT6);
}
static void disable_second_display_channel(void)
{
/* to disable second display channel. */
viafb_write_reg_mask(CR6A, VIACR, 0x00, BIT6);
viafb_write_reg_mask(CR6A, VIACR, 0x00, BIT7);
viafb_write_reg_mask(CR6A, VIACR, BIT6, BIT6);
}
void viafb_set_dpa_gfx(int output_interface, struct GFX_DPA_SETTING\
*p_gfx_dpa_setting)
{
switch (output_interface) {
case INTERFACE_DVP0:
{
/* DVP0 Clock Polarity and Adjust: */
viafb_write_reg_mask(CR96, VIACR,
p_gfx_dpa_setting->DVP0, 0x0F);
/* DVP0 Clock and Data Pads Driving: */
viafb_write_reg_mask(SR1E, VIASR,
p_gfx_dpa_setting->DVP0ClockDri_S, BIT2);
viafb_write_reg_mask(SR2A, VIASR,
p_gfx_dpa_setting->DVP0ClockDri_S1,
BIT4);
viafb_write_reg_mask(SR1B, VIASR,
p_gfx_dpa_setting->DVP0DataDri_S, BIT1);
viafb_write_reg_mask(SR2A, VIASR,
p_gfx_dpa_setting->DVP0DataDri_S1, BIT5);
break;
}
case INTERFACE_DVP1:
{
/* DVP1 Clock Polarity and Adjust: */
viafb_write_reg_mask(CR9B, VIACR,
p_gfx_dpa_setting->DVP1, 0x0F);
/* DVP1 Clock and Data Pads Driving: */
viafb_write_reg_mask(SR65, VIASR,
p_gfx_dpa_setting->DVP1Driving, 0x0F);
break;
}
case INTERFACE_DFP_HIGH:
{
viafb_write_reg_mask(CR97, VIACR,
p_gfx_dpa_setting->DFPHigh, 0x0F);
break;
}
case INTERFACE_DFP_LOW:
{
viafb_write_reg_mask(CR99, VIACR,
p_gfx_dpa_setting->DFPLow, 0x0F);
break;
}
case INTERFACE_DFP:
{
viafb_write_reg_mask(CR97, VIACR,
p_gfx_dpa_setting->DFPHigh, 0x0F);
viafb_write_reg_mask(CR99, VIACR,
p_gfx_dpa_setting->DFPLow, 0x0F);
break;
}
}
}
/*According var's xres, yres fill var's other timing information*/
void viafb_fill_var_timing_info(struct fb_var_screeninfo *var, int refresh,
struct VideoModeTable *vmode_tbl)
{
struct crt_mode_table *crt_timing = NULL;
struct display_timing crt_reg;
int i = 0, index = 0;
crt_timing = vmode_tbl->crtc;
for (i = 0; i < vmode_tbl->mode_array; i++) {
index = i;
if (crt_timing[i].refresh_rate == refresh)
break;
}
crt_reg = crt_timing[index].crtc;
var->pixclock = viafb_get_pixclock(var->xres, var->yres, refresh);
var->left_margin =
crt_reg.hor_total - (crt_reg.hor_sync_start + crt_reg.hor_sync_end);
var->right_margin = crt_reg.hor_sync_start - crt_reg.hor_addr;
var->hsync_len = crt_reg.hor_sync_end;
var->upper_margin =
crt_reg.ver_total - (crt_reg.ver_sync_start + crt_reg.ver_sync_end);
var->lower_margin = crt_reg.ver_sync_start - crt_reg.ver_addr;
var->vsync_len = crt_reg.ver_sync_end;
var->sync = 0;
if (crt_timing[index].h_sync_polarity == POSITIVE)
var->sync |= FB_SYNC_HOR_HIGH_ACT;
if (crt_timing[index].v_sync_polarity == POSITIVE)
var->sync |= FB_SYNC_VERT_HIGH_ACT;
}