rockbox/firmware/target/arm/as3525/sansa-e200v2/lcd-e200v2.c

/***************************************************************************
 *             __________               __   ___.
 *   Open      \______   \ ____   ____ |  | _\_ |__   _______  ___
 *   Source     |       _//  _ \_/ ___\|  |/ /| __ \ /  _ \  \/  /
 *   Jukebox    |    |   (  <_> )  \___|    < | \_\ (  <_> > <  <
 *   Firmware   |____|_  /\____/ \___  >__|_ \|___  /\____/__/\_ \
 *                     \/            \/     \/    \/            \/
 * $Id$
 *
 * Copyright (C) 2004 by Linus Nielsen Feltzing
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
 * KIND, either express or implied.
 *
 ****************************************************************************/
#include "config.h"

#include "cpu.h"
#include "lcd.h"
#include "kernel.h"
#include "thread.h"
#include <string.h>
#include <stdlib.h>
#include "file.h"
#include "debug.h"
#include "system.h"
#include "font.h"
#include "bidi.h"
#include "clock-target.h"

static bool display_on = false; /* is the display turned on? */
static bool display_flipped = false;
static int y_offset = 0; /* needed for flip */
/* we need to write a red pixel for correct button reads
 * (see lcd_button_support()), but that must not happen while the lcd is updating
 * so block lcd_button_support the during updates */
static volatile bool lcd_busy = false;

/* register defines */
#define R_START_OSC             0x00
#define R_DRV_OUTPUT_CONTROL    0x01
#define R_DRV_WAVEFORM_CONTROL  0x02
#define R_ENTRY_MODE            0x03
#define R_COMPARE_REG1          0x04
#define R_COMPARE_REG2          0x05

#define R_DISP_CONTROL1     0x07
#define R_DISP_CONTROL2     0x08
#define R_DISP_CONTROL3     0x09

#define R_FRAME_CYCLE_CONTROL 0x0b
#define R_EXT_DISP_IF_CONTROL 0x0c

#define R_POWER_CONTROL1    0x10
#define R_POWER_CONTROL2    0x11
#define R_POWER_CONTROL3    0x12
#define R_POWER_CONTROL4    0x13

#define R_RAM_ADDR_SET  0x21
#define R_WRITE_DATA_2_GRAM 0x22

#define R_GAMMA_FINE_ADJ_POS1   0x30
#define R_GAMMA_FINE_ADJ_POS2   0x31
#define R_GAMMA_FINE_ADJ_POS3   0x32
#define R_GAMMA_GRAD_ADJ_POS    0x33

#define R_GAMMA_FINE_ADJ_NEG1   0x34
#define R_GAMMA_FINE_ADJ_NEG2   0x35
#define R_GAMMA_FINE_ADJ_NEG3   0x36
#define R_GAMMA_GRAD_ADJ_NEG    0x37

#define R_GAMMA_AMP_ADJ_RES_POS     0x38
#define R_GAMMA_AMP_AVG_ADJ_RES_NEG 0x39 

#define R_GATE_SCAN_POS         0x40
#define R_VERT_SCROLL_CONTROL   0x41
#define R_1ST_SCR_DRV_POS       0x42
#define R_2ND_SCR_DRV_POS       0x43
#define R_HORIZ_RAM_ADDR_POS    0x44
#define R_VERT_RAM_ADDR_POS     0x45

#define R_ENTRY_MODE_HORZ_NORMAL 0x7030
#define R_ENTRY_MODE_HORZ_FLIPPED 0x7000
#define R_ENTRY_MODE_VERT 0x7038
#define R_ENTRY_MODE_SOLID_VERT  0x1038
static unsigned short r_entry_mode = R_ENTRY_MODE_HORZ_NORMAL;

/* Reverse Flag */
#define R_DISP_CONTROL_NORMAL 0x0004
#define R_DISP_CONTROL_REV    0x0000
static unsigned short r_disp_control_rev = R_DISP_CONTROL_NORMAL;

/* TODO: Implement this function */
static void lcd_delay(int x)
{
    /* This is just arbitrary - the OF does something more complex */
    x *= 1024;
    while (x--);
}

/* DBOP initialisation, do what OF does */
static void ams3525_dbop_init(void)
{
    CGU_DBOP = (1<<3) | CLK_DIV(AS3525_PCLK_FREQ, AS3525_DBOP_FREQ);

    DBOP_TIMPOL_01 = 0xe167e167;
    DBOP_TIMPOL_23 = 0xe167006e;
    DBOP_CTRL = (1<<18)|(1<<12)|(8<<0);  /* short count, 16bit write, read-timing =8 */

    GPIOB_AFSEL = 0xfc;
    GPIOC_AFSEL = 0xff;

    DBOP_TIMPOL_23 = 0x6000e;
    DBOP_CTRL = (1<<18)|(1<<16)|(1<<12)|(8<<0);/* short count,write enable, 16bit write, read-timing =8 */
    DBOP_TIMPOL_01 = 0x6e167;
    DBOP_TIMPOL_23 = 0xa167e06f;

    /* TODO: The OF calls some other functions here, but maybe not important */
}


static void lcd_write_cmd(int cmd)
{
    /* Write register */
    DBOP_CTRL &= ~(1<<14);

    DBOP_TIMPOL_23 = 0xa167006e;

    DBOP_DOUT = cmd;

    /* Wait for fifo to empty */
    while ((DBOP_STAT & (1<<10)) == 0);

    DBOP_TIMPOL_23 = 0xa167e06f;
}

void lcd_write_data(const fb_data* p_bytes, int count)
{
    while (count--)
    {
        DBOP_DOUT = *p_bytes++;

        /* Wait for fifo to empty */
        while ((DBOP_STAT & (1<<10)) == 0);
    }
}

static void lcd_write_reg(int reg, int value)
{
    fb_data data = value;

    lcd_write_cmd(reg);
    lcd_write_data(&data, 1);
}

/*** hardware configuration ***/

void lcd_set_contrast(int val)
{
    (void)val;
}

void lcd_set_invert_display(bool yesno)
{
    r_disp_control_rev = yesno ? R_DISP_CONTROL_REV :
                                 R_DISP_CONTROL_NORMAL;

    if (display_on)
    {
        lcd_write_reg(R_DISP_CONTROL1, 0x0033 | r_disp_control_rev);
    }

}

/* turn the display upside down (call lcd_update() afterwards) */
void lcd_set_flip(bool yesno)
{
    display_flipped = yesno;
 
    r_entry_mode = yesno ? R_ENTRY_MODE_HORZ_FLIPPED :
                           R_ENTRY_MODE_HORZ_NORMAL;
}

static void lcd_window(int xmin, int ymin, int xmax, int ymax)
{
    ymin += y_offset;
    ymax += y_offset;
    if (!display_flipped)
    {
        lcd_write_reg(R_HORIZ_RAM_ADDR_POS, (xmax << 8) | xmin);
        lcd_write_reg(R_VERT_RAM_ADDR_POS,  (ymax << 8) | ymin);
        lcd_write_reg(R_RAM_ADDR_SET,       (ymin << 8) | xmin);
    }
    else
    {
        lcd_write_reg(R_HORIZ_RAM_ADDR_POS, ((LCD_WIDTH-1 - xmin) << 8) | (LCD_WIDTH-1 - xmax));
        lcd_write_reg(R_VERT_RAM_ADDR_POS,  ((LCD_HEIGHT-1 - ymin) << 8) | (LCD_HEIGHT-1 - ymax));
        lcd_write_reg(R_RAM_ADDR_SET,       ((LCD_HEIGHT-1 - ymin) << 8) | (LCD_WIDTH-1 - xmin));
    }
}

static void _display_on(void)
{
    /* Initialisation the display the same way as the original firmware */

    lcd_write_reg(R_START_OSC, 0x0001); /* Start Oscilation */

    lcd_write_reg(R_DRV_OUTPUT_CONTROL, 0x011b); /* 220 lines, GS=0, SS=1 */

    /* B/C = 1: n-line inversion form
     * EOR = 1: polarity inversion occurs by applying an EOR to odd/even
     *          frame select signal and an n-line inversion signal.
     * FLD = 01b: 1 field interlaced scan, external display iface */
    lcd_write_reg(R_DRV_WAVEFORM_CONTROL, 0x0700);

    /* Address counter updated in horizontal direction; left to right;
     * vertical increment horizontal increment.
     * data format for 8bit transfer or spi = 65k (5,6,5) */
    lcd_write_reg(R_ENTRY_MODE, r_entry_mode);

    /* Replace data on writing to GRAM */
    lcd_write_reg(R_COMPARE_REG1, 0);
    lcd_write_reg(R_COMPARE_REG2, 0);

    lcd_write_reg(R_DISP_CONTROL1, 0x0000 | r_disp_control_rev);  /* GON = 0, DTE = 0, D1-0 = 00b */

    /* Front porch lines: 2; Back porch lines: 2; */
    lcd_write_reg(R_DISP_CONTROL2, 0x0203);

    /* Scan cycle = 0 frames */
    lcd_write_reg(R_DISP_CONTROL3, 0x0000);

    /* 16 clocks */
    lcd_write_reg(R_FRAME_CYCLE_CONTROL, 0x0000);

    /* 18-bit RGB interface (one transfer/pixel)
     * internal clock operation;
     * System interface/VSYNC interface */
    lcd_write_reg(R_EXT_DISP_IF_CONTROL, 0x0000);


    /* zero everything*/
    lcd_write_reg(R_POWER_CONTROL1, 0x0000); /* STB = 0, SLP = 0 */

    lcd_delay(10);

    /* initialise power supply */

    /* DC12-10 = 000b: Step-up1 = clock/8,
     * DC02-00 = 000b: Step-up2 = clock/16,
     * VC2-0   = 010b: VciOUT = 0.87 * VciLVL */
    lcd_write_reg(R_POWER_CONTROL2, 0x0002); 

    /* VRH3-0 = 1000b: Vreg1OUT = REGP * 1.90 */
    lcd_write_reg(R_POWER_CONTROL3, 0x0008);

    lcd_delay(40);
    
    lcd_write_reg(R_POWER_CONTROL4, 0x0000); /* VCOMG = 0 */

    /* This register is unknown */
    lcd_write_reg(0x56, 0x80f);


    lcd_write_reg(R_POWER_CONTROL1, 0x4140);

    lcd_delay(10);

    lcd_write_reg(R_POWER_CONTROL2, 0x0000); 
    lcd_write_reg(R_POWER_CONTROL3, 0x0013); 

    lcd_delay(20);

    lcd_write_reg(R_POWER_CONTROL4, 0x6d0e);

    lcd_delay(20);

    lcd_write_reg(R_POWER_CONTROL4, 0x6d0e);

    lcd_write_reg(R_GAMMA_FINE_ADJ_POS1, 0x0002);
    lcd_write_reg(R_GAMMA_FINE_ADJ_POS2, 0x0707);
    lcd_write_reg(R_GAMMA_FINE_ADJ_POS3, 0x0182);
    lcd_write_reg(R_GAMMA_GRAD_ADJ_POS, 0x0203);
    lcd_write_reg(R_GAMMA_FINE_ADJ_NEG1, 0x0706);
    lcd_write_reg(R_GAMMA_FINE_ADJ_NEG2, 0x0006);
    lcd_write_reg(R_GAMMA_FINE_ADJ_NEG3, 0x0706);
    lcd_write_reg(R_GAMMA_GRAD_ADJ_NEG, 0x0000);
    lcd_write_reg(R_GAMMA_AMP_ADJ_RES_POS, 0x030f);
    lcd_write_reg(R_GAMMA_AMP_AVG_ADJ_RES_NEG, 0x0f08);


    lcd_write_reg(R_GATE_SCAN_POS, 0);
    lcd_write_reg(R_VERT_SCROLL_CONTROL, 0);

    lcd_window(0, 0, LCD_WIDTH-1, LCD_HEIGHT-1);    
    lcd_write_reg(R_1ST_SCR_DRV_POS, (LCD_HEIGHT-1) << 8);
    lcd_write_reg(R_2ND_SCR_DRV_POS, (LCD_HEIGHT-1) << 8);

    lcd_write_reg(R_DISP_CONTROL1, 0x0033 | r_disp_control_rev);

    display_on=true;  /* must be done before calling lcd_update() */
    lcd_update();
}

/* LCD init */
void lcd_init_device(void)
{
    ams3525_dbop_init();

    /* Init GPIOs the same as the OF */

    GPIOA_DIR |= (1<<5);
    GPIOA_PIN(5) = 0;

    GPIOA_PIN(4) = 0;  /*c80b0040 := 0;*/

    lcd_delay(1);

    GPIOA_PIN(5) = (1<<5);

    lcd_delay(1);

    _display_on();
}

#if defined(HAVE_LCD_ENABLE)
void lcd_enable(bool on)
{
    if(display_on!=on)
    {
        if(on)
        {
            _display_on();
            lcd_activation_call_hook();
        }
        else
        {
            display_on=false;
            lcd_write_reg(R_POWER_CONTROL1, 0x0001);
        }
    }
}
#endif

#if defined(HAVE_LCD_ENABLE) || defined(HAVE_LCD_SLEEP)
bool lcd_active(void)
{
    return display_on;
}

#endif

/*** update functions ***/

/* Performance function to blit a YUV bitmap directly to the LCD
 * src_x, src_y, width and height should be even
 * x, y, width and height have to be within LCD bounds
 */
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)
{
    (void)src;
    (void)src_x;
    (void)src_y;
    (void)stride;
    (void)x;
    (void)y;
    (void)width;
    (void)height;
}

/* Update the display.
   This must be called after all other LCD functions that change the display. */
void lcd_update(void)
{
    if (!display_on)
        return;

    lcd_write_reg(R_ENTRY_MODE, r_entry_mode);

    lcd_busy = true;
    /* Set start position and window */
    lcd_window(0, 0, LCD_WIDTH-1, LCD_HEIGHT-1);

    lcd_write_cmd(R_WRITE_DATA_2_GRAM);

    lcd_write_data((fb_data*)lcd_framebuffer, LCD_WIDTH*LCD_HEIGHT);

    lcd_busy = false;
} /* lcd_update */


/* Update a fraction of the display. */
void lcd_update_rect(int x, int y, int width, int height)
{
    const fb_data *ptr;
    int ymax, xmax;


    if (!display_on)
        return;

    xmax = x + width;
    if (xmax >= LCD_WIDTH)
        xmax = LCD_WIDTH - 1; /* Clip right */
    if (x < 0)
        x = 0;                /* Clip left */
    if (x >= xmax)
        return; /* nothing left to do */

    width = xmax - x + 1;     /* Fix width */

    ymax = y + height;
    if (ymax >= LCD_HEIGHT)
        ymax = LCD_HEIGHT - 1; /* Clip bottom */
    if (y < 0)
        y = 0; /* Clip top */
    if (y >= ymax)
        return; /* nothing left to do */

    lcd_write_reg(R_ENTRY_MODE, r_entry_mode);
    lcd_busy = true;
    lcd_window(x, y, xmax, ymax);
    lcd_write_cmd(R_WRITE_DATA_2_GRAM);

    ptr = (fb_data*)&lcd_framebuffer[y][x];

    do
    {
        lcd_write_data(ptr, width);
        ptr += LCD_WIDTH;
    }
    while (++y <= ymax);

    lcd_busy = false;
} /* lcd_update_rect */

/* writes one read pixel outside the visible area, needed for correct dbop reads */
bool lcd_button_support(void)
{
    fb_data data = (0xf<<12);

    if (lcd_busy)
        return false;

    lcd_write_reg(R_ENTRY_MODE, r_entry_mode);
    /* Set start position and window */
    lcd_window(LCD_WIDTH+1, LCD_HEIGHT+1, LCD_WIDTH+2, LCD_HEIGHT+2);

    lcd_write_cmd(R_WRITE_DATA_2_GRAM);

    lcd_write_data(&data, 1);
    return true;
}