en 129
TFTLCD with FastIO
ili9328.cpp
- Committer:
- nameless129
- Date:
- 2015-07-30
- Revision:
- 30:1e9905bdfd15
- Parent:
- 28:45e8aa1fc420
File content as of revision 30:1e9905bdfd15:
/*
* Copyright (C)2010-2012 Henning Karlsen. All right reserved.
* Copyright (C)2012-2013 Todor Todorov.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to:
*
* Free Software Foundation, Inc.
* 51 Franklin St, 5th Floor, Boston, MA 02110-1301, USA
*
*********************************************************************/
#include "ili9328.h"
#include "helpers.h"
#include "FastIO.h"
FastOut<P1_28> _D0;
FastOut<P2_3> _D1;
FastOut<P1_18> _D2;
FastOut<P1_24> _D3;
FastOut<P1_19> _D4;
FastOut<P1_26> _D5;
FastOut<P1_27> _D6;
FastOut<P1_25> _D7;
ILI9328_LCD::ILI9328_LCD( PinName CS, PinName RESET, PinName RS, PinName WR, BusOut* DATA_PORT, PinName BL, PinName RD, backlight_t blType, float defaultBackLightLevel )
: LCD( 240, 320, CS, RS, RESET, BL, blType, defaultBackLightLevel ), _lcd_pin_wr( WR )
{
_lcd_port = DATA_PORT;
if ( RD != NC ) _lcd_pin_rd = new DigitalOut( RD );
else _lcd_pin_rd = 0;
}
void ILI9328_LCD::Initialize( orientation_t orientation, colordepth_t colors )
{
_orientation = orientation;
_colorDepth = colors;
_lcd_pin_reset = HIGH;
wait_ms( 50 );
_lcd_pin_reset = LOW;
wait_ms( 100 );
_lcd_pin_reset = HIGH;
wait_ms( 1000 );
_lcd_pin_cs = HIGH;
if ( _lcd_pin_bl != 0 )
*_lcd_pin_bl = HIGH;
else if ( _bl_pwm != 0 )
*_bl_pwm = _bl_pwm_default;
if ( _lcd_pin_rd != 0 )
*_lcd_pin_rd = HIGH;
_lcd_pin_wr = HIGH;
wait_ms( 15 );
Activate();
short drivOut = 0;
short entryMod = 0;
short gateScan = 0x2700;
switch ( _orientation )
{
case LANDSCAPE:
drivOut = 0x0100;
entryMod |= 0x0038;
gateScan |= 0x0000;
break;
case LANDSCAPE_REV:
drivOut = 0x0000;
entryMod |= 0x0038;
gateScan |= 0x8000;
break;
case PORTRAIT_REV:
drivOut = 0x0000;
entryMod |= 0x0030;
gateScan |= 0x0000;
break;
case PORTRAIT:
default:
drivOut = 0x0100;
entryMod |= 0x0030;
gateScan |= 0x8000;
break;
}
switch ( _colorDepth )
{
case RGB18:
entryMod |= 0x9000;
break;
case RGB16:
default:
entryMod |= 0x1000;
break;
}
WriteCmdData( ILI932X_DRIV_OUT_CTRL, drivOut ); // set Driver Output Control
WriteCmdData( ILI932X_DRIV_WAV_CTRL, 0x0700 ); // set 1 line inversion
WriteCmdData( ILI932X_ENTRY_MOD, entryMod ); // set GRAM write direction and BGR=1.
WriteCmdData( ILI932X_RESIZE_CTRL, 0x0000 ); // Resize register
WriteCmdData( ILI932X_DISP_CTRL2, 0x0202 ); // set the back porch and front porch
WriteCmdData( ILI932X_DISP_CTRL3, 0x0000 ); // set non-display area refresh cycle ISC[3:0]
WriteCmdData( ILI932X_DISP_CTRL4, 0x0000 ); // FMARK function
WriteCmdData( ILI932X_RGB_DISP_IF_CTRL1, 0x0000 ); // RGB interface setting
WriteCmdData( ILI932X_FRM_MARKER_POS, 0x0000 ); // Frame marker Position
WriteCmdData( ILI932X_RGB_DISP_IF_CTRL2, 0x0000 ); // RGB interface polarity
// ----------- Power On sequence ----------- //
WriteCmdData( ILI932X_POW_CTRL1, 0x0000 ); // SAP, BT[3:0], AP, DSTB, SLP, STB
WriteCmdData( ILI932X_POW_CTRL2, 0x0007 ); // DC1[2:0], DC0[2:0], VC[2:0]
WriteCmdData( ILI932X_POW_CTRL3, 0x0000 ); // VREG1OUT voltage
WriteCmdData( ILI932X_POW_CTRL4, 0x0000 ); // VDV[4:0] for VCOM amplitude
wait_ms( 200 ); // Dis-charge capacitor power voltage
WriteCmdData( ILI932X_POW_CTRL1, 0x1690 ); // SAP, BT[3:0], AP, DSTB, SLP, STB
WriteCmdData( ILI932X_POW_CTRL2, 0x0227 ); // Set DC1[2:0], DC0[2:0], VC[2:0]
wait_ms( 50 ); // Delay 50ms
WriteCmdData( ILI932X_POW_CTRL3, 0x001A ); // 0012
wait_ms( 50 ); // Delay 50ms
WriteCmdData( ILI932X_POW_CTRL4, 0x1800 ); // VDV[4:0] for VCOM amplitude
WriteCmdData( ILI932X_POW_CTRL7, 0x002A ); // 04 VCM[5:0] for VCOMH
wait_ms( 50 ); // Delay 50ms
WriteCmdData( ILI932X_GRAM_HOR_AD, 0x0000 ); // GRAM horizontal Address
WriteCmdData( ILI932X_GRAM_VER_AD, 0x0000 ); // GRAM Vertical Address
// ----------- Adjust the Gamma Curve ----------//
WriteCmdData( ILI932X_GAMMA_CTRL1, 0x0000 );
WriteCmdData( ILI932X_GAMMA_CTRL2, 0x0000 );
WriteCmdData( ILI932X_GAMMA_CTRL3, 0x0000 );
WriteCmdData( ILI932X_GAMMA_CTRL4, 0x0206 );
WriteCmdData( ILI932X_GAMMA_CTRL5, 0x0808 );
WriteCmdData( ILI932X_GAMMA_CTRL6, 0x0007 );
WriteCmdData( ILI932X_GAMMA_CTRL7, 0x0201 );
WriteCmdData( ILI932X_GAMMA_CTRL8, 0x0000 );
WriteCmdData( ILI932X_GAMMA_CTRL9, 0x0000 );
WriteCmdData( ILI932X_GAMMA_CTRL10, 0x0000 );
//------------------ Set GRAM area ---------------//
WriteCmdData( ILI932X_HOR_END_AD, 0x00EF ); // Horizontal GRAM End Address
WriteCmdData( ILI932X_VER_START_AD, 0x0000 ); // Vertical GRAM Start Address
WriteCmdData( ILI932X_VER_END_AD, 0x013F ); // Vertical GRAM Start Address
WriteCmdData( ILI932X_GATE_SCAN_CTRL1, gateScan ); // Gate Scan Line (0xA700)
WriteCmdData( ILI932X_GATE_SCAN_CTRL2, 0x0003 ); // NDL,VLE, REV
WriteCmdData( ILI932X_GATE_SCAN_CTRL3, 0x0000 ); // set scrolling line
//-------------- Panel Control -------------------//
WriteCmdData( ILI932X_PANEL_IF_CTRL1, 0x0010 );
WriteCmdData( ILI932X_PANEL_IF_CTRL2, 0x0000 );
WriteCmdData( ILI932X_PANEL_IF_CTRL4, 0X1100 );
WriteCmdData( ILI932X_DISP_CTRL1, 0x0133 ); // 262K color and display ON
Deactivate();
}
void ILI9328_LCD::Sleep( void )
{
Activate();
WriteCmdData( 0x10, 0x1692 ); // enter sleep mode
wait_ms( 200 );
LCD::Sleep();
Deactivate();
}
void ILI9328_LCD::WakeUp( void )
{
Activate();
WriteCmdData( 0x10, 0x1690 ); // exit sleep mode
wait_ms( 200 );
LCD::WakeUp();
Deactivate();
}
//fix to 8bit mode
void ILI9328_LCD::WriteCmd( unsigned short cmd )
{
_lcd_pin_rs = LOW;
// _lcd_port->write( 0 );
_D0 = 0;
_D1 = 0;
_D2 = 0;
_D3 = 0;
_D4 = 0;
_D5 = 0;
_D6 = 0;
_D7 = 0;
pulseLow( _lcd_pin_wr );
// _lcd_port->write( cmd );
_D0 = cmd&0x01;
_D1 = cmd&0x02;
_D2 = cmd&0x04;
_D3 = cmd&0x08;
_D4 = cmd&0x10;
_D5 = cmd&0x20;
_D6 = cmd&0x40;
_D7 = cmd&0x80;
pulseLow( _lcd_pin_wr );
}
//fix to 8bit mode
void ILI9328_LCD::WriteData( unsigned short data )
{
_lcd_pin_rs = HIGH;
// _lcd_port->write( data>>8 );
_D0 = data&0x0100;
_D1 = data&0x0200;
_D2 = data&0x0400;
_D3 = data&0x0800;
_D4 = data&0x1000;
_D5 = data&0x2000;
_D6 = data&0x4000;
_D7 = data&0x8000;
pulseLow( _lcd_pin_wr );
// _lcd_port->write( data&0xff );
_D0 = data&0x01;
_D1 = data&0x02;
_D2 = data&0x04;
_D3 = data&0x08;
_D4 = data&0x10;
_D5 = data&0x20;
_D6 = data&0x40;
_D7 = data&0x80;
pulseLow( _lcd_pin_wr );
}
void ILI9328_LCD::SetXY( unsigned short x1, unsigned short y1, unsigned short x2, unsigned short y2 )
{
switch ( _orientation )
{
case LANDSCAPE:
case LANDSCAPE_REV:
WriteCmdData( 0x20, y1 );
WriteCmdData( 0x21, x1 );
WriteCmdData( 0x50, y1 );
WriteCmdData( 0x52, x1 );
WriteCmdData( 0x51, y2 );
WriteCmdData( 0x53, x2 );
break;
case PORTRAIT_REV:
case PORTRAIT:
default:
WriteCmdData( 0x20, x1 );
WriteCmdData( 0x21, y1 );
WriteCmdData( 0x50, x1 );
WriteCmdData( 0x52, y1 );
WriteCmdData( 0x51, x2 );
WriteCmdData( 0x53, y2 );
break;
}
WriteCmd( 0x22 );
}
void ILI9328_LCD::SetPixelColor( unsigned int color, colordepth_t mode )
{
unsigned char r, g, b;
unsigned short clr;
r = g = b = 0;
if ( _colorDepth == RGB16 )
{
switch ( mode )
{
case RGB16:
WriteData( color & 0xFFFF );
break;
case RGB18:
r = ( color >> 10 ) & 0xF8;
g = ( color >> 4 ) & 0xFC;
b = ( color >> 1 ) & 0x1F;
clr = ( ( r | ( g >> 5 ) ) << 8 ) | ( ( g << 3 ) | b );
WriteData( clr );
break;
case RGB24:
r = ( color >> 16 ) & 0xF8;
g = ( color >> 8 ) & 0xFC;
b = color & 0xF8;
clr = ( ( r | ( g >> 5 ) ) << 8 ) | ( ( g << 3 ) | ( b >> 3 ) );
WriteData( clr );
break;
}
}
else if ( _colorDepth == RGB18 )
{
switch ( mode )
{
case RGB16:
r = ( ( color >> 8 ) & 0xF8 ) | ( ( color & 0x8000 ) >> 13 );
g = ( color >> 3 ) & 0xFC;
b = ( ( color << 3 ) & 0xFC ) | ( ( color >> 3 ) & 0x01 );
break;
case RGB18:
b = ( color << 2 ) & 0xFC;
g = ( color >> 4 ) & 0xFC;
r = ( color >> 10 ) & 0xFC;
break;
case RGB24:
r = ( color >> 16 ) & 0xFC;
g = ( color >> 8 ) & 0xFC;
b = color & 0xFC;
break;
}
clr = ( r << 8 ) | ( g << 2 ) | ( b >> 4 );
WriteData( clr );
WriteData( b << 4 );
}
}