/*
UTFT.cpp - Multi-Platform library support for Color TFT LCD Boards
Copyright (C)2015 Rinky-Dink Electronics, Henning Karlsen. All right reserved
This library is the continuation of my ITDB02_Graph, ITDB02_Graph16
and RGB_GLCD libraries for Arduino and chipKit. As the number of
supported display modules and controllers started to increase I felt
it was time to make a single, universal library as it will be much
easier to maintain in the future.
Basic functionality of this library was origianlly based on the
demo-code provided by ITead studio (for the ITDB02 modules) and
NKC Electronics (for the RGB GLCD module/shield).
This library supports a number of 8bit, 16bit and serial graphic
displays, and will work with both Arduino, chipKit boards and select
TI LaunchPads. For a full list of tested display modules and controllers,
see the document UTFT_Supported_display_modules_&_controllers.pdf.
When using 8bit and 16bit display modules there are some
requirements you must adhere to. These requirements can be found
in the document UTFT_Requirements.pdf.
There are no special requirements when using serial displays.
You can find the latest version of the library at
http://www.RinkyDinkElectronics.com/
This library is free software; you can redistribute it and/or
modify it under the terms of the CC BY-NC-SA 3.0 license.
Please see the included documents for further information.
Commercial use of this library requires you to buy a license that
will allow commercial use. This includes using the library,
modified or not, as a tool to sell products.
The license applies to all part of the library including the
examples and tools supplied with the library.
*/
#include "UTFT.h"
// Include hardware-specific functions for the correct MCU
#if defined(__AVR__)
#include <avr/pgmspace.h>
#include "hardware/avr/HW_AVR.h"
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
#include "hardware/avr/HW_ATmega1280.h"
#elif defined(__AVR_ATmega328P__)
#include "hardware/avr/HW_ATmega328P.h"
#elif defined(__AVR_ATmega32U4__)
#include "hardware/avr/HW_ATmega32U4.h"
#elif defined(__AVR_ATmega168__)
#error "ATmega168 MCUs are not supported because they have too little flash memory!"
#elif defined(__AVR_ATmega1284P__)
#include "hardware/avr/HW_ATmega1284P.h"
#else
#error "Unsupported AVR MCU!"
#endif
#elif defined(__PIC32MX__)
#include "hardware/pic32/HW_PIC32.h"
#if defined(__32MX320F128H__)
#pragma message("Compiling for chipKIT UNO32 (PIC32MX320F128H)")
#include "hardware/pic32/HW_PIC32MX320F128H.h"
#elif defined(__32MX340F512H__)
#pragma message("Compiling for chipKIT uC32 (PIC32MX340F512H)")
#include "hardware/pic32/HW_PIC32MX340F512H.h"
#elif defined(__32MX795F512L__)
#pragma message("Compiling for chipKIT MAX32 (PIC32MX795F512L)")
#include "hardware/pic32/HW_PIC32MX795F512L.h"
#else
#error "Unsupported PIC32 MCU!"
#endif
#elif defined(__arm__)
#include "hardware/arm/HW_ARM.h"
#if defined(__SAM3X8E__)
#pragma message("Compiling for Arduino Due (AT91SAM3X8E)...")
#include "hardware/arm/HW_SAM3X8E.h"
#elif defined(__MK20DX128__) || defined(__MK20DX256__)
#pragma message("Compiling for Teensy 3.x (MK20DX128VLH7 / MK20DX256VLH7)...")
#include "hardware/arm/HW_MX20DX256.h"
#elif defined(__CC3200R1M1RGC__)
#pragma message("Compiling for TI CC3200 LaunchPad...")
#include "hardware/arm/HW_CC3200.h"
#else
#error "Unsupported ARM MCU!"
#endif
#endif
#include "memorysaver.h"
UTFT::UTFT()
{
}
UTFT::UTFT(byte model, int RS, int WR, int CS, int RST, int SER)
{
word dsx[] = {239, 239, 239, 239, 239, 239, 175, 175, 239, 127, 127, 239, 271, 479, 239, 239, 239, 0, 0, 239, 479, 319, 239, 175, 127, 239, 239, 319, 319, 799, 127, 127};
word dsy[] = {319, 399, 319, 319, 319, 319, 219, 219, 399, 159, 127, 319, 479, 799, 319, 319, 319, 0, 0, 319, 799, 479, 319, 219, 159, 319, 319, 479, 479, 479, 159, 159};
byte dtm[] = {16, 16, 16, 8, 8, 16, 8, SERIAL_4PIN, 16, SERIAL_5PIN, SERIAL_5PIN, 16, 16, 16, 8, 16, LATCHED_16, 0, 0, 8, 16, 16, 16, 8, SERIAL_5PIN, SERIAL_5PIN, SERIAL_4PIN, 16, 16, 16, SERIAL_5PIN, SERIAL_5PIN};
disp_x_size = dsx[model];
disp_y_size = dsy[model];
display_transfer_mode = dtm[model];
display_model = model;
__p1 = RS;
__p2 = WR;
__p3 = CS;
__p4 = RST;
__p5 = SER;
if (display_transfer_mode == SERIAL_4PIN)
{
display_transfer_mode=1;
display_serial_mode=SERIAL_4PIN;
}
if (display_transfer_mode == SERIAL_5PIN)
{
display_transfer_mode=1;
display_serial_mode=SERIAL_5PIN;
}
if (display_transfer_mode!=1)
{
_set_direction_registers(display_transfer_mode);
P_RS = portOutputRegister(digitalPinToPort(RS));
B_RS = digitalPinToBitMask(RS);
P_WR = portOutputRegister(digitalPinToPort(WR));
B_WR = digitalPinToBitMask(WR);
P_CS = portOutputRegister(digitalPinToPort(CS));
B_CS = digitalPinToBitMask(CS);
P_RST = portOutputRegister(digitalPinToPort(RST));
B_RST = digitalPinToBitMask(RST);
if (display_transfer_mode==LATCHED_16)
{
P_ALE = portOutputRegister(digitalPinToPort(SER));
B_ALE = digitalPinToBitMask(SER);
cbi(P_ALE, B_ALE);
pinMode(8,OUTPUT);
digitalWrite(8, LOW);
}
}
else
{
P_SDA = portOutputRegister(digitalPinToPort(RS));
B_SDA = digitalPinToBitMask(RS);
P_SCL = portOutputRegister(digitalPinToPort(WR));
B_SCL = digitalPinToBitMask(WR);
P_CS = portOutputRegister(digitalPinToPort(CS));
B_CS = digitalPinToBitMask(CS);
if (RST != NOTINUSE)
{
P_RST = portOutputRegister(digitalPinToPort(RST));
B_RST = digitalPinToBitMask(RST);
}
if (display_serial_mode!=SERIAL_4PIN)
{
P_RS = portOutputRegister(digitalPinToPort(SER));
B_RS = digitalPinToBitMask(SER);
}
}
}
void UTFT::LCD_Write_COM(char VL)
{
if (display_transfer_mode!=1)
{
cbi(P_RS, B_RS);
LCD_Writ_Bus(0x00,VL,display_transfer_mode);
}
else
LCD_Writ_Bus(0x00,VL,display_transfer_mode);
}
void UTFT::LCD_Write_DATA(char VH,char VL)
{
if (display_transfer_mode!=1)
{
sbi(P_RS, B_RS);
LCD_Writ_Bus(VH,VL,display_transfer_mode);
}
else
{
LCD_Writ_Bus(0x01,VH,display_transfer_mode);
LCD_Writ_Bus(0x01,VL,display_transfer_mode);
}
}
void UTFT::LCD_Write_DATA(char VL)
{
if (display_transfer_mode!=1)
{
sbi(P_RS, B_RS);
LCD_Writ_Bus(0x00,VL,display_transfer_mode);
}
else
LCD_Writ_Bus(0x01,VL,display_transfer_mode);
}
void UTFT::LCD_Write_COM_DATA(char com1,int dat1)
{
LCD_Write_COM(com1);
LCD_Write_DATA(dat1>>8,dat1);
}
void UTFT::clrXY()
{
if (orient==PORTRAIT)
setXY(0,0,disp_x_size,disp_y_size);
else
setXY(0,0,disp_y_size,disp_x_size);
}
void UTFT::drawRect(int x1, int y1, int x2, int y2)
{
if (x1>x2)
{
swap(int, x1, x2);
}
if (y1>y2)
{
swap(int, y1, y2);
}
drawHLine(x1, y1, x2-x1);
drawHLine(x1, y2, x2-x1);
drawVLine(x1, y1, y2-y1);
drawVLine(x2, y1, y2-y1);
}
void UTFT::drawRoundRect(int x1, int y1, int x2, int y2)
{
if (x1>x2)
{
swap(int, x1, x2);
}
if (y1>y2)
{
swap(int, y1, y2);
}
if ((x2-x1)>4 && (y2-y1)>4)
{
drawPixel(x1+1,y1+1);
drawPixel(x2-1,y1+1);
drawPixel(x1+1,y2-1);
drawPixel(x2-1,y2-1);
drawHLine(x1+2, y1, x2-x1-4);
drawHLine(x1+2, y2, x2-x1-4);
drawVLine(x1, y1+2, y2-y1-4);
drawVLine(x2, y1+2, y2-y1-4);
}
}
void UTFT::fillRect(int x1, int y1, int x2, int y2)
{
if (x1>x2)
{
swap(int, x1, x2);
}
if (y1>y2)
{
swap(int, y1, y2);
}
if (display_transfer_mode==16)
{
cbi(P_CS, B_CS);
setXY(x1, y1, x2, y2);
sbi(P_RS, B_RS);
_fast_fill_16(fch,fcl,((long(x2-x1)+1)*(long(y2-y1)+1)));
sbi(P_CS, B_CS);
}
else if ((display_transfer_mode==8) and (fch==fcl))
{
cbi(P_CS, B_CS);
setXY(x1, y1, x2, y2);
sbi(P_RS, B_RS);
_fast_fill_8(fch,((long(x2-x1)+1)*(long(y2-y1)+1)));
sbi(P_CS, B_CS);
}
else
{
if (orient==PORTRAIT)
{
for (int i=0; i<((y2-y1)/2)+1; i++)
{
drawHLine(x1, y1+i, x2-x1);
drawHLine(x1, y2-i, x2-x1);
}
}
else
{
for (int i=0; i<((x2-x1)/2)+1; i++)
{
drawVLine(x1+i, y1, y2-y1);
drawVLine(x2-i, y1, y2-y1);
}
}
}
}
void UTFT::fillRoundRect(int x1, int y1, int x2, int y2)
{
if (x1>x2)
{
swap(int, x1, x2);
}
if (y1>y2)
{
swap(int, y1, y2);
}
if ((x2-x1)>4 && (y2-y1)>4)
{
for (int i=0; i<((y2-y1)/2)+1; i++)
{
switch(i)
{
case 0:
drawHLine(x1+2, y1+i, x2-x1-4);
drawHLine(x1+2, y2-i, x2-x1-4);
break;
case 1:
drawHLine(x1+1, y1+i, x2-x1-2);
drawHLine(x1+1, y2-i, x2-x1-2);
break;
default:
drawHLine(x1, y1+i, x2-x1);
drawHLine(x1, y2-i, x2-x1);
}
}
}
}
void UTFT::drawCircle(int x, int y, int radius)
{
int f = 1 - radius;
int ddF_x = 1;
int ddF_y = -2 * radius;
int x1 = 0;
int y1 = radius;
cbi(P_CS, B_CS);
setXY(x, y + radius, x, y + radius);
LCD_Write_DATA(fch,fcl);
setXY(x, y - radius, x, y - radius);
LCD_Write_DATA(fch,fcl);
setXY(x + radius, y, x + radius, y);
LCD_Write_DATA(fch,fcl);
setXY(x - radius, y, x - radius, y);
LCD_Write_DATA(fch,fcl);
while(x1 < y1)
{
if(f >= 0)
{
y1--;
ddF_y += 2;
f += ddF_y;
}
x1++;
ddF_x += 2;
f += ddF_x;
setXY(x + x1, y + y1, x + x1, y + y1);
LCD_Write_DATA(fch,fcl);
setXY(x - x1, y + y1, x - x1, y + y1);
LCD_Write_DATA(fch,fcl);
setXY(x + x1, y - y1, x + x1, y - y1);
LCD_Write_DATA(fch,fcl);
setXY(x - x1, y - y1, x - x1, y - y1);
LCD_Write_DATA(fch,fcl);
setXY(x + y1, y + x1, x + y1, y + x1);
LCD_Write_DATA(fch,fcl);
setXY(x - y1, y + x1, x - y1, y + x1);
LCD_Write_DATA(fch,fcl);
setXY(x + y1, y - x1, x + y1, y - x1);
LCD_Write_DATA(fch,fcl);
setXY(x - y1, y - x1, x - y1, y - x1);
LCD_Write_DATA(fch,fcl);
}
sbi(P_CS, B_CS);
clrXY();
}
void UTFT::fillCircle(int x, int y, int radius)
{
for(int y1=-radius; y1<=0; y1++)
for(int x1=-radius; x1<=0; x1++)
if(x1*x1+y1*y1 <= radius*radius)
{
drawHLine(x+x1, y+y1, 2*(-x1));
drawHLine(x+x1, y-y1, 2*(-x1));
break;
}
}
void UTFT::clrScr()
{
long i;
cbi(P_CS, B_CS);
clrXY();
if (display_transfer_mode!=1)
sbi(P_RS, B_RS);
if (display_transfer_mode==16)
_fast_fill_16(0,0,((disp_x_size+1)*(disp_y_size+1)));
else if (display_transfer_mode==8)
_fast_fill_8(0,((disp_x_size+1)*(disp_y_size+1)));
else
{
for (i=0; i<((disp_x_size+1)*(disp_y_size+1)); i++)
{
if (display_transfer_mode!=1)
LCD_Writ_Bus(0,0,display_transfer_mode);
else
{
LCD_Writ_Bus(1,0,display_transfer_mode);
LCD_Writ_Bus(1,0,display_transfer_mode);
}
}
}
sbi(P_CS, B_CS);
}
void UTFT::fillScr(byte r, byte g, byte b)
{
word color = ((r&248)<<8 | (g&252)<<3 | (b&248)>>3);
fillScr(color);
}
void UTFT::fillScr(word color)
{
long i;
char ch, cl;
ch=byte(color>>8);
cl=byte(color & 0xFF);
cbi(P_CS, B_CS);
clrXY();
if (display_transfer_mode!=1)
sbi(P_RS, B_RS);
if (display_transfer_mode==16)
_fast_fill_16(ch,cl,((disp_x_size+1)*(disp_y_size+1)));
else if ((display_transfer_mode==8) and (ch==cl))
_fast_fill_8(ch,((disp_x_size+1)*(disp_y_size+1)));
else
{
for (i=0; i<((disp_x_size+1)*(disp_y_size+1)); i++)
{
if (display_transfer_mode!=1)
LCD_Writ_Bus(ch,cl,display_transfer_mode);
else
{
LCD_Writ_Bus(1,ch,display_transfer_mode);
LCD_Writ_Bus(1,cl,display_transfer_mode);
}
}
}
sbi(P_CS, B_CS);
}
void UTFT::setColor(byte r, byte g, byte b)
{
fch=((r&248)|g>>5);
fcl=((g&28)<<3|b>>3);
}
void UTFT::setColor(word color)
{
fch=byte(color>>8);
fcl=byte(color & 0xFF);
}
word UTFT::getColor()
{
return (fch<<8) | fcl;
}
void UTFT::setBackColor(byte r, byte g, byte b)
{
bch=((r&248)|g>>5);
bcl=((g&28)<<3|b>>3);
_transparent=false;
}
void UTFT::setBackColor(uint32_t color)
{
if (color==VGA_TRANSPARENT)
_transparent=true;
else
{
bch=byte(color>>8);
bcl=byte(color & 0xFF);
_transparent=false;
}
}
word UTFT::getBackColor()
{
return (bch<<8) | bcl;
}
void UTFT::setPixel(word color)
{
LCD_Write_DATA((color>>8),(color&0xFF)); // rrrrrggggggbbbbb
}
void UTFT::setPixel(byte h, byte l)
{
LCD_Write_DATA(h, l); // rrrrrggggggbbbbb
}
void UTFT::drawPixel(int x, int y)
{
cbi(P_CS, B_CS);
setXY(x, y, x, y);
setPixel((fch<<8)|fcl);
sbi(P_CS, B_CS);
clrXY();
}
void UTFT::drawLine(int x1, int y1, int x2, int y2)
{
if (y1==y2)
drawHLine(x1, y1, x2-x1);
else if (x1==x2)
drawVLine(x1, y1, y2-y1);
else
{
unsigned int dx = (x2 > x1 ? x2 - x1 : x1 - x2);
short xstep = x2 > x1 ? 1 : -1;
unsigned int dy = (y2 > y1 ? y2 - y1 : y1 - y2);
short ystep = y2 > y1 ? 1 : -1;
int col = x1, row = y1;
cbi(P_CS, B_CS);
if (dx < dy)
{
int t = - (dy >> 1);
while (true)
{
setXY (col, row, col, row);
LCD_Write_DATA (fch, fcl);
if (row == y2)
return;
row += ystep;
t += dx;
if (t >= 0)
{
col += xstep;
t -= dy;
}
}
}
else
{
int t = - (dx >> 1);
while (true)
{
setXY (col, row, col, row);
LCD_Write_DATA (fch, fcl);
if (col == x2)
return;
col += xstep;
t += dy;
if (t >= 0)
{
row += ystep;
t -= dx;
}
}
}
sbi(P_CS, B_CS);
}
clrXY();
}
void UTFT::drawHLine(int x, int y, int l)
{
if (l<0)
{
l = -l;
x -= l;
}
cbi(P_CS, B_CS);
setXY(x, y, x+l, y);
if (display_transfer_mode == 16)
{
sbi(P_RS, B_RS);
_fast_fill_16(fch,fcl,l);
}
else if ((display_transfer_mode==8) and (fch==fcl))
{
sbi(P_RS, B_RS);
_fast_fill_8(fch,l);
}
else
{
for (int i=0; i<l+1; i++)
{
LCD_Write_DATA(fch, fcl);
}
}
sbi(P_CS, B_CS);
clrXY();
}
void UTFT::drawVLine(int x, int y, int l)
{
if (l<0)
{
l = -l;
y -= l;
}
cbi(P_CS, B_CS);
setXY(x, y, x, y+l);
if (display_transfer_mode == 16)
{
sbi(P_RS, B_RS);
_fast_fill_16(fch,fcl,l);
}
else if ((display_transfer_mode==8) and (fch==fcl))
{
sbi(P_RS, B_RS);
_fast_fill_8(fch,l);
}
else
{
for (int i=0; i<l+1; i++)
{
LCD_Write_DATA(fch, fcl);
}
}
sbi(P_CS, B_CS);
clrXY();
}
void UTFT::printChar(byte c, int x, int y)
{
byte i,ch;
word j;
word temp;
cbi(P_CS, B_CS);
if (!_transparent)
{
if (orient==PORTRAIT)
{
setXY(x,y,x+cfont.x_size-1,y+cfont.y_size-1);
temp=((c-cfont.offset)*((cfont.x_size/8)*cfont.y_size))+4;
for(j=0;j<((cfont.x_size/8)*cfont.y_size);j++)
{
ch=pgm_read_byte(&cfont.font[temp]);
for(i=0;i<8;i++)
{
if((ch&(1<<(7-i)))!=0)
{
setPixel((fch<<8)|fcl);
}
else
{
setPixel((bch<<8)|bcl);
}
}
temp++;
}
}
else
{
temp=((c-cfont.offset)*((cfont.x_size/8)*cfont.y_size))+4;
for(j=0;j<((cfont.x_size/8)*cfont.y_size);j+=(cfont.x_size/8))
{
setXY(x,y+(j/(cfont.x_size/8)),x+cfont.x_size-1,y+(j/(cfont.x_size/8)));
for (int zz=(cfont.x_size/8)-1; zz>=0; zz--)
{
ch=pgm_read_byte(&cfont.font[temp+zz]);
for(i=0;i<8;i++)
{
if((ch&(1<<i))!=0)
{
setPixel((fch<<8)|fcl);
}
else
{
setPixel((bch<<8)|bcl);
}
}
}
temp+=(cfont.x_size/8);
}
}
}
else
{
temp=((c-cfont.offset)*((cfont.x_size/8)*cfont.y_size))+4;
for(j=0;j<cfont.y_size;j++)
{
for (int zz=0; zz<(cfont.x_size/8); zz++)
{
ch=pgm_read_byte(&cfont.font[temp+zz]);
for(i=0;i<8;i++)
{
if((ch&(1<<(7-i)))!=0)
{
setXY(x+i+(zz*8),y+j,x+i+(zz*8)+1,y+j+1);
setPixel((fch<<8)|fcl);
}
}
}
temp+=(cfont.x_size/8);
}
}
sbi(P_CS, B_CS);
clrXY();
}
void UTFT::rotateChar(byte c, int x, int y, int pos, int deg)
{
byte i,j,ch;
word temp;
int newx,newy;
double radian;
radian=deg*0.0175;
cbi(P_CS, B_CS);
temp=((c-cfont.offset)*((cfont.x_size/8)*cfont.y_size))+4;
for(j=0;j<cfont.y_size;j++)
{
for (int zz=0; zz<(cfont.x_size/8); zz++)
{
ch=pgm_read_byte(&cfont.font[temp+zz]);
for(i=0;i<8;i++)
{
newx=x+(((i+(zz*8)+(pos*cfont.x_size))*cos(radian))-((j)*sin(radian)));
newy=y+(((j)*cos(radian))+((i+(zz*8)+(pos*cfont.x_size))*sin(radian)));
setXY(newx,newy,newx+1,newy+1);
if((ch&(1<<(7-i)))!=0)
{
setPixel((fch<<8)|fcl);
}
else
{
if (!_transparent)
setPixel((bch<<8)|bcl);
}
}
}
temp+=(cfont.x_size/8);
}
sbi(P_CS, B_CS);
clrXY();
}
void UTFT::print2(char *st, int x, int y, int deg)
{
int stl, i;
stl = strlen(st);
if (orient==PORTRAIT)
{
if (x==RIGHT)
x=(disp_x_size+1)-(stl*cfont.x_size);
if (x==CENTER)
x=((disp_x_size+1)-(stl*cfont.x_size))/2;
}
else
{
if (x==RIGHT)
x=(disp_y_size+1)-(stl*cfont.x_size);
if (x==CENTER)
x=((disp_y_size+1)-(stl*cfont.x_size))/2;
}
for (i=0; i<stl; i++)
if (deg==0)
printChar(*st++, x + (i*(cfont.x_size)), y);
else
rotateChar(*st++, x, y, i, deg);
}
void UTFT::print2(String st, int x, int y, int deg)
{
char buf[st.length()+1];
st.toCharArray(buf, st.length()+1);
print2(buf, x, y, deg);
}
void UTFT::printNumI(long num, int x, int y, int length, char filler)
{
char buf[25];
char st[27];
boolean neg=false;
int c=0, f=0;
if (num==0)
{
if (length!=0)
{
for (c=0; c<(length-1); c++)
st[c]=filler;
st[c]=48;
st[c+1]=0;
}
else
{
st[0]=48;
st[1]=0;
}
}
else
{
if (num<0)
{
neg=true;
num=-num;
}
while (num>0)
{
buf[c]=48+(num % 10);
c++;
num=(num-(num % 10))/10;
}
buf[c]=0;
if (neg)
{
st[0]=45;
}
if (length>(c+neg))
{
for (int i=0; i<(length-c-neg); i++)
{
st[i+neg]=filler;
f++;
}
}
for (int i=0; i<c; i++)
{
st[i+neg+f]=buf[c-i-1];
}
st[c+neg+f]=0;
}
print2(st,x,y);
}
void UTFT::printNumF(double num, byte dec, int x, int y, char divider, int length, char filler)
{
char st[27];
boolean neg=false;
if (dec<1)
dec=1;
else if (dec>5)
dec=5;
if (num<0)
neg = true;
_convert_float(st, num, length, dec);
if (divider != '.')
{
for (int i=0; i<sizeof(st); i++)
if (st[i]=='.')
st[i]=divider;
}
if (filler != ' ')
{
if (neg)
{
st[0]='-';
for (int i=1; i<sizeof(st); i++)
if ((st[i]==' ') || (st[i]=='-'))
st[i]=filler;
}
else
{
for (int i=0; i<sizeof(st); i++)
if (st[i]==' ')
st[i]=filler;
}
}
print2(st,x,y);
}
void UTFT::setFont(uint8_t* font)
{
cfont.font=font;
cfont.x_size=fontbyte(0);
cfont.y_size=fontbyte(1);
cfont.offset=fontbyte(2);
cfont.numchars=fontbyte(3);
}
uint8_t* UTFT::getFont()
{
return cfont.font;
}
uint8_t UTFT::getFontXsize()
{
return cfont.x_size;
}
uint8_t UTFT::getFontYsize()
{
return cfont.y_size;
}
void UTFT::drawBitmap(int x, int y, int sx, int sy, bitmapdatatype data, int scale)
{
unsigned int col;
int tx, ty, tc, tsx, tsy;
if (scale==1)
{
if (orient==PORTRAIT)
{
cbi(P_CS, B_CS);
setXY(x, y, x+sx-1, y+sy-1);
for (tc=0; tc<(sx*sy); tc++)
{
col=pgm_read_word(&data[tc]);
LCD_Write_DATA(col>>8,col & 0xff);
}
sbi(P_CS, B_CS);
}
else
{
cbi(P_CS, B_CS);
for (ty=0; ty<sy; ty++)
{
setXY(x, y+ty, x+sx-1, y+ty);
for (tx=sx-1; tx>=0; tx--)
{
col=pgm_read_word(&data[(ty*sx)+tx]);
LCD_Write_DATA(col>>8,col & 0xff);
}
}
sbi(P_CS, B_CS);
}
}
else
{
if (orient==PORTRAIT)
{
cbi(P_CS, B_CS);
for (ty=0; ty<sy; ty++)
{
setXY(x, y+(ty*scale), x+((sx*scale)-1), y+(ty*scale)+scale);
for (tsy=0; tsy<scale; tsy++)
for (tx=0; tx<sx; tx++)
{
col=pgm_read_word(&data[(ty*sx)+tx]);
for (tsx=0; tsx<scale; tsx++)
LCD_Write_DATA(col>>8,col & 0xff);
}
}
sbi(P_CS, B_CS);
}
else
{
cbi(P_CS, B_CS);
for (ty=0; ty<sy; ty++)
{
for (tsy=0; tsy<scale; tsy++)
{
setXY(x, y+(ty*scale)+tsy, x+((sx*scale)-1), y+(ty*scale)+tsy);
for (tx=sx-1; tx>=0; tx--)
{
col=pgm_read_word(&data[(ty*sx)+tx]);
for (tsx=0; tsx<scale; tsx++)
LCD_Write_DATA(col>>8,col & 0xff);
}
}
}
sbi(P_CS, B_CS);
}
}
clrXY();
}
void UTFT::drawBitmap(int x, int y, int sx, int sy, bitmapdatatype data, int deg, int rox, int roy)
{
unsigned int col;
int tx, ty, newx, newy;
double radian;
radian=deg*0.0175;
if (deg==0)
drawBitmap(x, y, sx, sy, data);
else
{
cbi(P_CS, B_CS);
for (ty=0; ty<sy; ty++)
for (tx=0; tx<sx; tx++)
{
col=pgm_read_word(&data[(ty*sx)+tx]);
newx=x+rox+(((tx-rox)*cos(radian))-((ty-roy)*sin(radian)));
newy=y+roy+(((ty-roy)*cos(radian))+((tx-rox)*sin(radian)));
setXY(newx, newy, newx, newy);
LCD_Write_DATA(col>>8,col & 0xff);
}
sbi(P_CS, B_CS);
}
clrXY();
}
void UTFT::lcdOff()
{
cbi(P_CS, B_CS);
switch (display_model)
{
case PCF8833:
LCD_Write_COM(0x28);
break;
case CPLD:
LCD_Write_COM_DATA(0x01,0x0000);
LCD_Write_COM(0x0F);
break;
}
sbi(P_CS, B_CS);
}
void UTFT::lcdOn()
{
cbi(P_CS, B_CS);
switch (display_model)
{
case PCF8833:
LCD_Write_COM(0x29);
break;
case CPLD:
LCD_Write_COM_DATA(0x01,0x0010);
LCD_Write_COM(0x0F);
break;
}
sbi(P_CS, B_CS);
}
void UTFT::setContrast(char c)
{
cbi(P_CS, B_CS);
switch (display_model)
{
case PCF8833:
if (c>64) c=64;
LCD_Write_COM(0x25);
LCD_Write_DATA(c);
break;
}
sbi(P_CS, B_CS);
}
int UTFT::getDisplayXSize()
{
if (orient==PORTRAIT)
return disp_x_size+1;
else
return disp_y_size+1;
}
int UTFT::getDisplayYSize()
{
if (orient==PORTRAIT)
return disp_y_size+1;
else
return disp_x_size+1;
}
void UTFT::setBrightness(byte br)
{
cbi(P_CS, B_CS);
switch (display_model)
{
case CPLD:
if (br>16) br=16;
LCD_Write_COM_DATA(0x01,br);
LCD_Write_COM(0x0F);
break;
}
sbi(P_CS, B_CS);
}
void UTFT::setDisplayPage(byte page)
{
cbi(P_CS, B_CS);
switch (display_model)
{
case CPLD:
if (page>7) page=7;
LCD_Write_COM_DATA(0x04,page);
LCD_Write_COM(0x0F);
break;
}
sbi(P_CS, B_CS);
}
void UTFT::setWritePage(byte page)
{
cbi(P_CS, B_CS);
switch (display_model)
{
case CPLD:
if (page>7) page=7;
LCD_Write_COM_DATA(0x05,page);
LCD_Write_COM(0x0F);
break;
}
sbi(P_CS, B_CS);
}