1b093cf297
git-svn-id: svn://svn.rockbox.org/rockbox/trunk@28719 a1c6a512-1295-4272-9138-f99709370657
659 lines
17 KiB
C
659 lines
17 KiB
C
/***************************************************************************
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* __________ __ ___.
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* Open \______ \ ____ ____ | | _\_ |__ _______ ___
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* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
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* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
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* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
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* \/ \/ \/ \/ \/
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* $Id$
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*
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* Copyright (C) 2009 by Dave Chapman
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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*
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* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
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* KIND, either express or implied.
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*
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****************************************************************************/
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#include "config.h"
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#include "hwcompat.h"
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#include "kernel.h"
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#include "lcd.h"
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#include "system.h"
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#include "cpu.h"
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#include "pmu-target.h"
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#include "power.h"
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/* The Nano 2G has two different LCD types. What we call "type 0"
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appears to be similar to the ILI9320 and "type 1" is similar to the
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LDS176.
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*/
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/* LCD type 0 register defines */
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#define R_ENTRY_MODE 0x03
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#define R_DISPLAY_CONTROL_1 0x07
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#define R_POWER_CONTROL_1 0x10
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#define R_POWER_CONTROL_2 0x12
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#define R_POWER_CONTROL_3 0x13
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#define R_HORIZ_GRAM_ADDR_SET 0x20
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#define R_VERT_GRAM_ADDR_SET 0x21
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#define R_WRITE_DATA_TO_GRAM 0x22
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#define R_HORIZ_ADDR_START_POS 0x50
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#define R_HORIZ_ADDR_END_POS 0x51
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#define R_VERT_ADDR_START_POS 0x52
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#define R_VERT_ADDR_END_POS 0x53
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/* LCD type 1 register defines */
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#define R_SLEEP_IN 0x10
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#define R_DISPLAY_OFF 0x28
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#define R_COLUMN_ADDR_SET 0x2a
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#define R_ROW_ADDR_SET 0x2b
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#define R_MEMORY_WRITE 0x2c
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/** globals **/
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int lcd_type; /* also needed in debug-s5l8700.c */
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static int xoffset; /* needed for flip */
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static bool lcd_ispowered;
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#ifdef HAVE_LCD_SLEEP
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#define SLEEP 0
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#define CMD8 1
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#define CMD16 2
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#define DATA8 3
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#define DATA16 4
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unsigned short lcd_init_sequence_0[] = {
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CMD16, 0x00a4,
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DATA16, 0x0001,
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SLEEP, 0x0000,
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CMD16, 0x0001,
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DATA16, 0x0100,
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CMD16, 0x0002,
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DATA16, 0x0300,
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CMD16, 0x0003,
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DATA16, 0x1230,
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CMD16, 0x0008,
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DATA16, 0x0404,
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CMD16, 0x0008,
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DATA16, 0x0404,
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CMD16, 0x000e,
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DATA16, 0x0010,
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CMD16, 0x0070,
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DATA16, 0x1000,
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CMD16, 0x0071,
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DATA16, 0x0001,
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CMD16, 0x0030,
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DATA16, 0x0002,
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CMD16, 0x0031,
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DATA16, 0x0400,
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CMD16, 0x0032,
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DATA16, 0x0007,
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CMD16, 0x0033,
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DATA16, 0x0500,
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CMD16, 0x0034,
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DATA16, 0x0007,
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CMD16, 0x0035,
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DATA16, 0x0703,
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CMD16, 0x0036,
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DATA16, 0x0507,
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CMD16, 0x0037,
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DATA16, 0x0005,
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CMD16, 0x0038,
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DATA16, 0x0407,
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CMD16, 0x0039,
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DATA16, 0x000e,
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CMD16, 0x0040,
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DATA16, 0x0202,
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CMD16, 0x0041,
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DATA16, 0x0003,
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CMD16, 0x0042,
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DATA16, 0x0000,
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CMD16, 0x0043,
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DATA16, 0x0200,
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CMD16, 0x0044,
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DATA16, 0x0707,
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CMD16, 0x0045,
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DATA16, 0x0407,
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CMD16, 0x0046,
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DATA16, 0x0505,
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CMD16, 0x0047,
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DATA16, 0x0002,
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CMD16, 0x0048,
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DATA16, 0x0004,
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CMD16, 0x0049,
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DATA16, 0x0004,
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CMD16, 0x0060,
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DATA16, 0x0202,
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CMD16, 0x0061,
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DATA16, 0x0003,
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CMD16, 0x0062,
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DATA16, 0x0000,
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CMD16, 0x0063,
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DATA16, 0x0200,
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CMD16, 0x0064,
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DATA16, 0x0707,
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CMD16, 0x0065,
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DATA16, 0x0407,
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CMD16, 0x0066,
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DATA16, 0x0505,
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CMD16, 0x0068,
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DATA16, 0x0004,
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CMD16, 0x0069,
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DATA16, 0x0004,
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CMD16, 0x0007,
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DATA16, 0x0001,
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CMD16, 0x0018,
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DATA16, 0x0001,
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CMD16, 0x0010,
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DATA16, 0x1690,
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CMD16, 0x0011,
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DATA16, 0x0100,
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CMD16, 0x0012,
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DATA16, 0x0117,
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CMD16, 0x0013,
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DATA16, 0x0f80,
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CMD16, 0x0012,
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DATA16, 0x0137,
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CMD16, 0x0020,
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DATA16, 0x0000,
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CMD16, 0x0021,
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DATA16, 0x0000,
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CMD16, 0x0050,
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DATA16, 0x0000,
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CMD16, 0x0051,
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DATA16, 0x00af,
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CMD16, 0x0052,
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DATA16, 0x0000,
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CMD16, 0x0053,
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DATA16, 0x0083,
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CMD16, 0x0090,
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DATA16, 0x0003,
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CMD16, 0x0091,
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DATA16, 0x0000,
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CMD16, 0x0092,
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DATA16, 0x0101,
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CMD16, 0x0098,
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DATA16, 0x0400,
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CMD16, 0x0099,
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DATA16, 0x1302,
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CMD16, 0x009a,
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DATA16, 0x0202,
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CMD16, 0x009b,
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DATA16, 0x0200,
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SLEEP, 0x0000,
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CMD16, 0x0007,
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DATA16, 0x0021,
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CMD16, 0x0012,
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DATA16, 0x0137,
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SLEEP, 0x0000,
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CMD16, 0x0007,
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DATA16, 0x0021,
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CMD16, 0x0012,
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DATA16, 0x1137,
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SLEEP, 0x0000,
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CMD16, 0x0007,
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DATA16, 0x0233,
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};
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unsigned short lcd_init_sequence_1[] = {
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CMD8, 0x11,
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DATA16, 0x00,
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CMD8, 0x29,
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DATA16, 0x00,
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};
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#endif /* HAVE_LCD_SLEEP */
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static inline void s5l_lcd_write_cmd_data(int cmd, int data)
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{
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while (LCD_STATUS & 0x10);
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LCD_WCMD = cmd >> 8;
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while (LCD_STATUS & 0x10);
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LCD_WCMD = cmd & 0xff;
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while (LCD_STATUS & 0x10);
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LCD_WDATA = data >> 8;
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while (LCD_STATUS & 0x10);
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LCD_WDATA = data & 0xff;
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}
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static inline void s5l_lcd_write_cmd(unsigned short cmd)
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{
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while (LCD_STATUS & 0x10);
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LCD_WCMD = cmd;
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}
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static inline void s5l_lcd_write_wcmd(unsigned short cmd)
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{
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while (LCD_STATUS & 0x10);
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LCD_WCMD = cmd >> 8;
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while (LCD_STATUS & 0x10);
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LCD_WCMD = cmd & 0xff;
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}
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static inline void s5l_lcd_write_data(unsigned short data)
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{
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while (LCD_STATUS & 0x10);
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LCD_WDATA = data & 0xff;
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}
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static inline void s5l_lcd_write_wdata(unsigned short data)
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{
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while (LCD_STATUS & 0x10);
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LCD_WDATA = data >> 8;
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while (LCD_STATUS & 0x10);
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LCD_WDATA = data & 0xff;
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}
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/*** hardware configuration ***/
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int lcd_default_contrast(void)
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{
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return 0x1f;
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}
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void lcd_set_contrast(int val)
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{
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(void)val;
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}
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void lcd_set_invert_display(bool yesno)
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{
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(void)yesno;
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}
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/* turn the display upside down (call lcd_update() afterwards) */
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void lcd_set_flip(bool yesno)
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{
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/* TODO: flip mode isn't working. The commands in the else part of
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this function are how the original firmware inits the LCD */
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if (yesno)
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{
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xoffset = 132 - LCD_WIDTH; /* 132 colums minus the 128 we have */
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}
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else
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{
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xoffset = 0;
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}
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}
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bool lcd_active(void)
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{
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return lcd_ispowered;
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}
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#ifdef HAVE_LCD_SLEEP
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void lcd_wakeup(void)
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{
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unsigned short *lcd_init_sequence;
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unsigned int lcd_init_sequence_length;
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PWRCONEXT &= ~0x80;
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PCON13 &= ~0xf; /* Set pin 0 to input */
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PCON14 &= ~0xf0; /* Set pin 1 to input */
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pmu_write(0x2b, 1);
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if (lcd_type == 0)
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{
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/* reset the lcd chip */
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LCD_RST_TIME = 0x7FFF;
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LCD_DRV_RST = 0;
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sleep(0);
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LCD_DRV_RST = 1;
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sleep(HZ / 100);
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lcd_init_sequence = lcd_init_sequence_0;
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lcd_init_sequence_length = (sizeof(lcd_init_sequence_0) - 1)/sizeof(unsigned short);
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}
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else
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{
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lcd_init_sequence = lcd_init_sequence_1;
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lcd_init_sequence_length = (sizeof(lcd_init_sequence_1) - 1)/sizeof(unsigned short);
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}
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for(unsigned int i=0;i<lcd_init_sequence_length;i+=2)
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{
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switch(lcd_init_sequence[i])
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{
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case CMD8:
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s5l_lcd_write_cmd(lcd_init_sequence[i+1]);
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break;
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case DATA8:
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s5l_lcd_write_data(lcd_init_sequence[i+1]);
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break;
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case CMD16:
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s5l_lcd_write_wcmd(lcd_init_sequence[i+1]);
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break;
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case DATA16:
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s5l_lcd_write_wdata(lcd_init_sequence[i+1]);
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break;
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case SLEEP:
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sleep(lcd_init_sequence[i+1]);
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break;
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default:
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break;
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}
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}
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lcd_ispowered = true;
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send_event(LCD_EVENT_ACTIVATION, NULL);
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}
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void lcd_awake(void)
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{
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if(!lcd_active()) lcd_wakeup();
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}
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#endif
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void lcd_shutdown(void)
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{
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pmu_write(0x2b, 0); /* Kill the backlight, instantly. */
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pmu_write(0x29, 0);
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if (lcd_type == 0)
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{
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s5l_lcd_write_cmd_data(R_DISPLAY_CONTROL_1, 0x232);
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s5l_lcd_write_cmd_data(R_POWER_CONTROL_3, 0x1137);
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s5l_lcd_write_cmd_data(R_DISPLAY_CONTROL_1, 0x201);
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s5l_lcd_write_cmd_data(R_POWER_CONTROL_3, 0x137);
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s5l_lcd_write_cmd_data(R_DISPLAY_CONTROL_1, 0x200);
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s5l_lcd_write_cmd_data(R_POWER_CONTROL_1, 0x680);
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s5l_lcd_write_cmd_data(R_POWER_CONTROL_2, 0x160);
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s5l_lcd_write_cmd_data(R_POWER_CONTROL_3, 0x127);
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s5l_lcd_write_cmd_data(R_POWER_CONTROL_1, 0x600);
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}
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else
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{
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s5l_lcd_write_cmd(R_DISPLAY_OFF);
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s5l_lcd_write_wdata(0);
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s5l_lcd_write_wdata(0);
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s5l_lcd_write_cmd(R_SLEEP_IN);
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s5l_lcd_write_wdata(0);
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s5l_lcd_write_wdata(0);
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}
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PWRCONEXT |= 0x80;
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lcd_ispowered = false;
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}
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void lcd_sleep(void)
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{
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lcd_shutdown();
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}
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/* LCD init */
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void lcd_init_device(void)
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{
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/* Detect lcd type */
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PCON13 &= ~0xf; /* Set pin 0 to input */
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PCON14 &= ~0xf0; /* Set pin 1 to input */
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if (((PDAT13 & 1) == 0) && ((PDAT14 & 2) == 2))
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lcd_type = 0; /* Similar to ILI9320 - aka "type 2" */
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else
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lcd_type = 1; /* Similar to LDS176 - aka "type 7" */
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lcd_ispowered = true;
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}
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/*** Update functions ***/
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static inline void lcd_write_pixel(fb_data pixel)
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{
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while (LCD_STATUS & 0x10);
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LCD_WDATA = (pixel & 0xff00) >> 8;
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while (LCD_STATUS & 0x10);
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LCD_WDATA = pixel & 0xff;
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}
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/* Update the display.
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This must be called after all other LCD functions that change the display. */
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void lcd_update(void) ICODE_ATTR;
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void lcd_update(void)
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{
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int x,y;
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fb_data* p = &lcd_framebuffer[0][0];
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if (lcd_type==0) {
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s5l_lcd_write_cmd_data(R_HORIZ_ADDR_START_POS, 0);
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s5l_lcd_write_cmd_data(R_HORIZ_ADDR_END_POS, LCD_WIDTH-1);
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s5l_lcd_write_cmd_data(R_VERT_ADDR_START_POS, 0);
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s5l_lcd_write_cmd_data(R_VERT_ADDR_END_POS, LCD_HEIGHT-1);
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s5l_lcd_write_cmd_data(R_HORIZ_GRAM_ADDR_SET, 0);
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s5l_lcd_write_cmd_data(R_VERT_GRAM_ADDR_SET, 0);
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s5l_lcd_write_cmd(0);
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s5l_lcd_write_cmd(R_WRITE_DATA_TO_GRAM);
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} else {
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s5l_lcd_write_cmd(R_COLUMN_ADDR_SET);
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s5l_lcd_write_wdata(0); /* Start column */
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s5l_lcd_write_wdata(LCD_WIDTH-1); /* End column */
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s5l_lcd_write_cmd(R_ROW_ADDR_SET);
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s5l_lcd_write_wdata(0); /* Start row */
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s5l_lcd_write_wdata(LCD_HEIGHT-1); /* End row */
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s5l_lcd_write_cmd(R_MEMORY_WRITE);
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}
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/* Copy display bitmap to hardware */
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for (y = 0; y < LCD_HEIGHT; y++) {
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for (x = 0; x < LCD_WIDTH; x++) {
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lcd_write_pixel(*(p++));
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}
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}
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}
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/* Update a fraction of the display. */
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void lcd_update_rect(int, int, int, int) ICODE_ATTR;
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void lcd_update_rect(int x, int y, int width, int height)
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{
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int xx,yy;
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int y0, x0, y1, x1;
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fb_data* p;
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x0 = x; /* start horiz */
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y0 = y; /* start vert */
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x1 = (x + width) - 1; /* max horiz */
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y1 = (y + height) - 1; /* max vert */
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if (lcd_type==0) {
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s5l_lcd_write_cmd_data(R_HORIZ_ADDR_START_POS, x0);
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s5l_lcd_write_cmd_data(R_HORIZ_ADDR_END_POS, x1);
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s5l_lcd_write_cmd_data(R_VERT_ADDR_START_POS, y0);
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s5l_lcd_write_cmd_data(R_VERT_ADDR_END_POS, y1);
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s5l_lcd_write_cmd_data(R_HORIZ_GRAM_ADDR_SET, (x1 << 8) | x0);
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s5l_lcd_write_cmd_data(R_VERT_GRAM_ADDR_SET, (y1 << 8) | y0);
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s5l_lcd_write_cmd(0);
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s5l_lcd_write_cmd(R_WRITE_DATA_TO_GRAM);
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} else {
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s5l_lcd_write_cmd(R_COLUMN_ADDR_SET);
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s5l_lcd_write_wdata(x0); /* Start column */
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s5l_lcd_write_wdata(x1); /* End column */
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s5l_lcd_write_cmd(R_ROW_ADDR_SET);
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s5l_lcd_write_wdata(y0); /* Start row */
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s5l_lcd_write_wdata(y1); /* End row */
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s5l_lcd_write_cmd(R_MEMORY_WRITE);
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}
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/* Copy display bitmap to hardware */
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p = &lcd_framebuffer[y0][x0];
|
|
yy = height;
|
|
for (yy = y0; yy <= y1; yy++) {
|
|
for (xx = x0; xx <= x1; xx++) {
|
|
lcd_write_pixel(*(p++));
|
|
}
|
|
p += LCD_WIDTH - width;
|
|
}
|
|
}
|
|
|
|
/*** update functions ***/
|
|
|
|
#define CSUB_X 2
|
|
#define CSUB_Y 2
|
|
|
|
/* YUV- > RGB565 conversion
|
|
* |R| |1.000000 -0.000001 1.402000| |Y'|
|
|
* |G| = |1.000000 -0.334136 -0.714136| |Pb|
|
|
* |B| |1.000000 1.772000 0.000000| |Pr|
|
|
* Scaled, normalized, rounded and tweaked to yield RGB 565:
|
|
* |R| |74 0 101| |Y' - 16| >> 9
|
|
* |G| = |74 -24 -51| |Cb - 128| >> 8
|
|
* |B| |74 128 0| |Cr - 128| >> 9
|
|
*/
|
|
|
|
#define RGBYFAC 74 /* 1.0 */
|
|
#define RVFAC 101 /* 1.402 */
|
|
#define GVFAC (-51) /* -0.714136 */
|
|
#define GUFAC (-24) /* -0.334136 */
|
|
#define BUFAC 128 /* 1.772 */
|
|
|
|
/* ROUNDOFFS contain constant for correct round-offs as well as
|
|
constant parts of the conversion matrix (e.g. (Y'-16)*RGBYFAC
|
|
-> constant part = -16*RGBYFAC). Through extraction of these
|
|
constant parts we save at leat 4 substractions in the conversion
|
|
loop */
|
|
#define ROUNDOFFSR (256 - 16*RGBYFAC - 128*RVFAC)
|
|
#define ROUNDOFFSG (128 - 16*RGBYFAC - 128*GVFAC - 128*GUFAC)
|
|
#define ROUNDOFFSB (256 - 16*RGBYFAC - 128*BUFAC)
|
|
|
|
#define MAX_5BIT 0x1f
|
|
#define MAX_6BIT 0x3f
|
|
|
|
/* Performance function to blit a YUV bitmap directly to the LCD */
|
|
void lcd_blit_yuv(unsigned char * const src[3],
|
|
int src_x, int src_y, int stride,
|
|
int x, int y, int width, int height)
|
|
{
|
|
int h;
|
|
int y0, x0, y1, x1;
|
|
|
|
width = (width + 1) & ~1;
|
|
|
|
x0 = x; /* start horiz */
|
|
y0 = y; /* start vert */
|
|
x1 = (x + width) - 1; /* max horiz */
|
|
y1 = (y + height) - 1; /* max vert */
|
|
|
|
if (lcd_type==0) {
|
|
s5l_lcd_write_cmd_data(R_HORIZ_ADDR_START_POS, x0);
|
|
s5l_lcd_write_cmd_data(R_HORIZ_ADDR_END_POS, x1);
|
|
s5l_lcd_write_cmd_data(R_VERT_ADDR_START_POS, y0);
|
|
s5l_lcd_write_cmd_data(R_VERT_ADDR_END_POS, y1);
|
|
|
|
s5l_lcd_write_cmd_data(R_HORIZ_GRAM_ADDR_SET, (x1 << 8) | x0);
|
|
s5l_lcd_write_cmd_data(R_VERT_GRAM_ADDR_SET, (y1 << 8) | y0);
|
|
|
|
s5l_lcd_write_cmd(0);
|
|
s5l_lcd_write_cmd(R_WRITE_DATA_TO_GRAM);
|
|
} else {
|
|
s5l_lcd_write_cmd(R_COLUMN_ADDR_SET);
|
|
s5l_lcd_write_wdata(x0); /* Start column */
|
|
s5l_lcd_write_wdata(x1); /* End column */
|
|
|
|
s5l_lcd_write_cmd(R_ROW_ADDR_SET);
|
|
s5l_lcd_write_wdata(y0); /* Start row */
|
|
s5l_lcd_write_wdata(y1); /* End row */
|
|
|
|
s5l_lcd_write_cmd(R_MEMORY_WRITE);
|
|
}
|
|
|
|
const int stride_div_csub_x = stride/CSUB_X;
|
|
|
|
h = height;
|
|
while (h > 0) {
|
|
/* upsampling, YUV->RGB conversion and reduction to RGB565 in one go */
|
|
const unsigned char *ysrc = src[0] + stride * src_y + src_x;
|
|
|
|
const int uvoffset = stride_div_csub_x * (src_y/CSUB_Y) +
|
|
(src_x/CSUB_X);
|
|
|
|
const unsigned char *usrc = src[1] + uvoffset;
|
|
const unsigned char *vsrc = src[2] + uvoffset;
|
|
const unsigned char *row_end = ysrc + width;
|
|
|
|
int yp, up, vp;
|
|
int red1, green1, blue1;
|
|
int red2, green2, blue2;
|
|
|
|
int rc, gc, bc;
|
|
|
|
do
|
|
{
|
|
up = *usrc++;
|
|
vp = *vsrc++;
|
|
rc = RVFAC * vp + ROUNDOFFSR;
|
|
gc = GVFAC * vp + GUFAC * up + ROUNDOFFSG;
|
|
bc = BUFAC * up + ROUNDOFFSB;
|
|
|
|
/* Pixel 1 -> RGB565 */
|
|
yp = *ysrc++ * RGBYFAC;
|
|
red1 = (yp + rc) >> 9;
|
|
green1 = (yp + gc) >> 8;
|
|
blue1 = (yp + bc) >> 9;
|
|
|
|
/* Pixel 2 -> RGB565 */
|
|
yp = *ysrc++ * RGBYFAC;
|
|
red2 = (yp + rc) >> 9;
|
|
green2 = (yp + gc) >> 8;
|
|
blue2 = (yp + bc) >> 9;
|
|
|
|
/* Since out of bounds errors are relatively rare, we check two
|
|
pixels at once to see if any components are out of bounds, and
|
|
then fix whichever is broken. This works due to high values and
|
|
negative values both being !=0 when bitmasking them.
|
|
We first check for red and blue components (5bit range). */
|
|
if ((red1 | blue1 | red2 | blue2) & ~MAX_5BIT)
|
|
{
|
|
if (red1 & ~MAX_5BIT)
|
|
red1 = (red1 >> 31) ? 0 : MAX_5BIT;
|
|
if (blue1 & ~MAX_5BIT)
|
|
blue1 = (blue1 >> 31) ? 0 : MAX_5BIT;
|
|
if (red2 & ~MAX_5BIT)
|
|
red2 = (red2 >> 31) ? 0 : MAX_5BIT;
|
|
if (blue2 & ~MAX_5BIT)
|
|
blue2 = (blue2 >> 31) ? 0 : MAX_5BIT;
|
|
}
|
|
/* We second check for green component (6bit range) */
|
|
if ((green1 | green2) & ~MAX_6BIT)
|
|
{
|
|
if (green1 & ~MAX_6BIT)
|
|
green1 = (green1 >> 31) ? 0 : MAX_6BIT;
|
|
if (green2 & ~MAX_6BIT)
|
|
green2 = (green2 >> 31) ? 0 : MAX_6BIT;
|
|
}
|
|
|
|
/* output 2 pixels */
|
|
lcd_write_pixel((red1 << 11) | (green1 << 5) | blue1);
|
|
lcd_write_pixel((red2 << 11) | (green2 << 5) | blue2);
|
|
}
|
|
while (ysrc < row_end);
|
|
|
|
src_y++;
|
|
h--;
|
|
}
|
|
}
|