Masato YAMANISHI
LCD library for Akizuki AQM1248A graphic LCD module
Dependents: FRDM_MAG3110 Nucleo_AQM1248A Nucleo_AQM1248A_GT20L16J1Y
Fork of
C12832_lcd
by 
Peter Drescher
see http://mbed.org/users/masato/code/Nucleo_AQM1248A/
aqm1248a_lcd.cpp
- Committer:
- masato
- Date:
- 2015-06-02
- Revision:
- 13:3a94a79194b6
- Parent:
- 12:cecd70424890
File content as of revision 13:3a94a79194b6:
/*
* mbed library for the Akizuki AQM1248A 128*48 pixel LCD
* derived from C12832_lcd
* Copyright (c) 2014 Masato YAMANISHI
* Released under the MIT License: http://mbed.org/license/mit
*/
/* mbed library for the mbed Lab Board 128*32 pixel LCD
* use C12832 controller
* Copyright (c) 2012 Peter Drescher - DC2PD
* Released under the MIT License: http://mbed.org/license/mit
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
// 13.10.12 initial design
// 25.10.12 add autorefresh of screen
// 25.10.12 add standart font
// 20.12.12 add bitmap graphics
// optional defines :
// #define debug_lcd 1
#include "aqm1248a_lcd.h"
#include "mbed.h"
#include "stdio.h"
#include "Small_7.h"
aqm1248a_lcd::aqm1248a_lcd(const char* name)
#if defined(TARGET_LPC1768)
: _spi(p5,NC,p7),_reset(p6),_A0(p8),_CS(p11),GraphicsDisplay(name) // for mbed LPC1768
#else // defined(TARGET_NUCLEO_L152RE) || defined(TARGET_KL05Z)
: _spi(D11,D12,D13),_reset(D9),_A0(D8),_CS(D10),GraphicsDisplay(name) // for nucleo L152RE or other
#endif
{
orientation = 1;
draw_mode = NORMAL;
char_x = 0;
lcd_reset();
}
int aqm1248a_lcd::width()
{
if (orientation == 0 || orientation == 2) return HEIGHT; // 32;
else return WIDTH;
}
int aqm1248a_lcd::height()
{
if (orientation == 0 || orientation == 2) return WIDTH;
else return HEIGHT; // 32;
}
/*void aqm1248a_lcd::set_orientation(unsigned int o)
{
orientation = o;
switch (o) {
case (0):
wr_cmd(0xA0);
wr_cmd(0xC0);
break;
case (1):
wr_cmd(0xA0);
wr_cmd(0xC8);
break;
case (2):
wr_cmd(0xA1);
wr_cmd(0xC8);
break;
case (3):
wr_cmd(0xA1);
wr_cmd(0xC0);
break;
}
}
*/
void aqm1248a_lcd::invert(unsigned int o)
{
if(o == 0) wr_cmd(0xA6);
else wr_cmd(0xA7);
}
void aqm1248a_lcd::set_contrast(unsigned int o)
{
contrast = o;
wr_cmd(0x81); // set volume
wr_cmd(o & 0x3F);
}
unsigned int aqm1248a_lcd::get_contrast(void)
{
return(contrast);
}
// write command to lcd controller
void aqm1248a_lcd::wr_cmd(unsigned char cmd)
{
_A0 = 0;
_CS = 0;
#if defined TARGET_LPC1768 // fast without mbed lib
LPC_SSP1->DR = cmd;
do {
} while ((LPC_SSP1->SR & 0x10) == 0x10); // wait for SPI1 idle
#else
_spi.write(cmd);
#endif
_CS = 1;
}
// write data to lcd controller
void aqm1248a_lcd::wr_dat(unsigned char dat)
{
_A0 = 1;
_CS = 0;
#if defined TARGET_LPC1768 // fast without mbed lib
LPC_SSP1->DR = dat;
do {
} while ((LPC_SSP1->SR & 0x10) == 0x10); // wait for SPI1 idle
#else
_spi.write(dat);
#endif
_CS = 1;
}
// reset and init the lcd controller
void aqm1248a_lcd::lcd_reset()
{
_spi.format(8,3); // 8 bit spi mode 3
_spi.frequency(20000000); // 19,2 Mhz SPI clock
#if 0
#if defined TARGET_LPC1768
DigitalOut _reset(p6);
#else
DigitalOut _reset(D9);
#endif
#endif
_A0 = 0;
_CS = 1;
_reset = 0; // display reset
wait_us(50);
_reset = 1; // end reset
wait_ms(5);
/* Start Initial Sequence ----------------------------------------------------*/
wr_cmd(0xAE); // display off
wr_cmd(0xA0);
wr_cmd(0xC8); // colum normal
wr_cmd(0xA3); // bias voltage
wr_cmd(0x2c); wait_ms(2);
wr_cmd(0x2e); wait_ms(2);
wr_cmd(0x2F); // power on
wr_cmd(0x23);
wr_cmd(0x81);
wr_cmd(0x1c);
wr_cmd(0xA4); // LCD display ram
wr_cmd(0x40); // start line = 0
wr_cmd(0xa6);
wr_cmd(0xAF); // display ON
#if defined TARGET_LPC1768 //setup DMA channel 0
LPC_SC->PCONP |= (1UL << 29); // Power up the GPDMA
LPC_GPDMA->DMACConfig = 1; // enable DMA controller
LPC_GPDMA->DMACIntTCClear = 0x1;
LPC_GPDMA->DMACIntErrClr = 0x1;
LPC_GPDMACH0->DMACCLLI = 0;
#endif
// clear and update LCD
memset(buffer,0x00,BUFFER_SIZE); // clear display buffer
copy_to_lcd();
auto_up = 1; // switch on auto update
// dont do this by default. Make the user call
//claim(stdout); // redirekt printf to lcd
locate(0,0);
set_font((unsigned char*)Small_7); // standart font
}
// set one pixel in buffer
void aqm1248a_lcd::pixel(int x, int y, int color)
{
// first check parameter
if(x > WIDTH || y > HEIGHT || x < 0 || y < 0) return;
if(draw_mode == NORMAL) {
if(color == 0)
buffer[x + ((y/8) * WIDTH)] &= ~(1 << (y%8)); // erase pixel
else
buffer[x + ((y/8) * WIDTH)] |= (1 << (y%8)); // set pixel
} else { // XOR mode
if(color == 1)
buffer[x + ((y/8) * WIDTH)] ^= (1 << (y%8)); // xor pixel
}
}
// update lcd
void aqm1248a_lcd::copy_to_lcd(void)
{
#ifndef TARGET_LPC1768
int i;
#endif
for (int page = 0; page < PAGES; page++) {
//page 0
wr_cmd(0x00); // set column low nibble 0
wr_cmd(0x10); // set column hi nibble 0
wr_cmd(0xB0 + page); // set page address 0 to PAGES-1
_A0 = 1;
#if defined TARGET_LPC1768
_CS = 0;
if (page == 0) {
// start 128 byte DMA transfer to SPI1
LPC_GPDMACH0->DMACCDestAddr = (uint32_t)&LPC_SSP1->DR; // we send to SSP1
LPC_SSP1->DMACR = 0x2; // Enable SSP1 for DMA.
}
LPC_GPDMA->DMACIntTCClear = 0x1;
LPC_GPDMA->DMACIntErrClr = 0x1;
LPC_GPDMACH0->DMACCSrcAddr = (uint32_t) (buffer + 128*page);
LPC_GPDMACH0->DMACCControl = 128 | (1UL << 31) | DMA_CHANNEL_SRC_INC ; // 8 bit transfer , address increment, interrupt
LPC_GPDMACH0->DMACCConfig = DMA_CHANNEL_ENABLE | DMA_TRANSFER_TYPE_M2P | DMA_DEST_SSP1_TX;
LPC_GPDMA->DMACSoftSReq = 0x1;
do {
} while ((LPC_GPDMA->DMACRawIntTCStat & 0x01) == 0); // DMA is running
do {
} while ((LPC_SSP1->SR & 0x10) == 0x10); // SPI1 not idle
_CS = 1;
#else // no DMA
for(i=WIDTH*page; i<WIDTH*(page+1); i++) {
wr_dat(buffer[i]);
}
#endif
}
}
void aqm1248a_lcd::cls(void)
{
memset(buffer,0x00,BUFFER_SIZE); // clear display buffer
copy_to_lcd();
}
void aqm1248a_lcd::line(int x0, int y0, int x1, int y1, int color)
{
int dx = 0, dy = 0;
int dx_sym = 0, dy_sym = 0;
int dx_x2 = 0, dy_x2 = 0;
int di = 0;
dx = x1-x0;
dy = y1-y0;
// if (dx == 0) { /* vertical line */
// if (y1 > y0) vline(x0,y0,y1,color);
// else vline(x0,y1,y0,color);
// return;
// }
if (dx > 0) {
dx_sym = 1;
} else {
dx_sym = -1;
}
// if (dy == 0) { /* horizontal line */
// if (x1 > x0) hline(x0,x1,y0,color);
// else hline(x1,x0,y0,color);
// return;
// }
if (dy > 0) {
dy_sym = 1;
} else {
dy_sym = -1;
}
dx = dx_sym*dx;
dy = dy_sym*dy;
dx_x2 = dx*2;
dy_x2 = dy*2;
if (dx >= dy) {
di = dy_x2 - dx;
while (x0 != x1) {
pixel(x0, y0, color);
x0 += dx_sym;
if (di<0) {
di += dy_x2;
} else {
di += dy_x2 - dx_x2;
y0 += dy_sym;
}
}
pixel(x0, y0, color);
} else {
di = dx_x2 - dy;
while (y0 != y1) {
pixel(x0, y0, color);
y0 += dy_sym;
if (di < 0) {
di += dx_x2;
} else {
di += dx_x2 - dy_x2;
x0 += dx_sym;
}
}
pixel(x0, y0, color);
}
if(auto_up) copy_to_lcd();
}
void aqm1248a_lcd::rect(int x0, int y0, int x1, int y1, int color)
{
if (x1 > x0) line(x0,y0,x1,y0,color);
else line(x1,y0,x0,y0,color);
if (y1 > y0) line(x0,y0,x0,y1,color);
else line(x0,y1,x0,y0,color);
if (x1 > x0) line(x0,y1,x1,y1,color);
else line(x1,y1,x0,y1,color);
if (y1 > y0) line(x1,y0,x1,y1,color);
else line(x1,y1,x1,y0,color);
if(auto_up) copy_to_lcd();
}
void aqm1248a_lcd::fillrect(int x0, int y0, int x1, int y1, int color)
{
int l,c,i;
if(x0 > x1) {
i = x0;
x0 = x1;
x1 = i;
}
if(y0 > y1) {
i = y0;
y0 = y1;
y1 = i;
}
for(l = x0; l<= x1; l ++) {
for(c = y0; c<= y1; c++) {
pixel(l,c,color);
}
}
if(auto_up) copy_to_lcd();
}
void aqm1248a_lcd::circle(int x0, int y0, int r, int color)
{
int draw_x0, draw_y0;
int draw_x1, draw_y1;
int draw_x2, draw_y2;
int draw_x3, draw_y3;
int draw_x4, draw_y4;
int draw_x5, draw_y5;
int draw_x6, draw_y6;
int draw_x7, draw_y7;
int xx, yy;
int di;
//WindowMax();
if (r == 0) { /* no radius */
return;
}
draw_x0 = draw_x1 = x0;
draw_y0 = draw_y1 = y0 + r;
if (draw_y0 < height()) {
pixel(draw_x0, draw_y0, color); /* 90 degree */
}
draw_x2 = draw_x3 = x0;
draw_y2 = draw_y3 = y0 - r;
if (draw_y2 >= 0) {
pixel(draw_x2, draw_y2, color); /* 270 degree */
}
draw_x4 = draw_x6 = x0 + r;
draw_y4 = draw_y6 = y0;
if (draw_x4 < width()) {
pixel(draw_x4, draw_y4, color); /* 0 degree */
}
draw_x5 = draw_x7 = x0 - r;
draw_y5 = draw_y7 = y0;
if (draw_x5>=0) {
pixel(draw_x5, draw_y5, color); /* 180 degree */
}
if (r == 1) {
return;
}
di = 3 - 2*r;
xx = 0;
yy = r;
while (xx < yy) {
if (di < 0) {
di += 4*xx + 6;
} else {
di += 4*(xx - yy) + 10;
yy--;
draw_y0--;
draw_y1--;
draw_y2++;
draw_y3++;
draw_x4--;
draw_x5++;
draw_x6--;
draw_x7++;
}
xx++;
draw_x0++;
draw_x1--;
draw_x2++;
draw_x3--;
draw_y4++;
draw_y5++;
draw_y6--;
draw_y7--;
if ( (draw_x0 <= width()) && (draw_y0>=0) ) {
pixel(draw_x0, draw_y0, color);
}
if ( (draw_x1 >= 0) && (draw_y1 >= 0) ) {
pixel(draw_x1, draw_y1, color);
}
if ( (draw_x2 <= width()) && (draw_y2 <= height()) ) {
pixel(draw_x2, draw_y2, color);
}
if ( (draw_x3 >=0 ) && (draw_y3 <= height()) ) {
pixel(draw_x3, draw_y3, color);
}
if ( (draw_x4 <= width()) && (draw_y4 >= 0) ) {
pixel(draw_x4, draw_y4, color);
}
if ( (draw_x5 >= 0) && (draw_y5 >= 0) ) {
pixel(draw_x5, draw_y5, color);
}
if ( (draw_x6 <=width()) && (draw_y6 <= height()) ) {
pixel(draw_x6, draw_y6, color);
}
if ( (draw_x7 >= 0) && (draw_y7 <= height()) ) {
pixel(draw_x7, draw_y7, color);
}
}
if(auto_up) copy_to_lcd();
}
void aqm1248a_lcd::fillcircle(int x, int y, int r, int color)
{
int i,up;
up = auto_up;
auto_up = 0; // off
for (i = 0; i <= r; i++)
circle(x,y,i,color);
auto_up = up;
if(auto_up) copy_to_lcd();
}
void aqm1248a_lcd::setmode(int mode)
{
draw_mode = mode;
}
void aqm1248a_lcd::locate(int x, int y)
{
char_x = x;
char_y = y;
}
int aqm1248a_lcd::columns()
{
return width() / font[1];
}
int aqm1248a_lcd::rows()
{
return height() / font[2];
}
int aqm1248a_lcd::_putc(int value)
{
if (value == '\n') { // new line
char_x = 0;
char_y = char_y + font[2];
if (char_y >= height() - font[2]) {
char_y = 0;
}
} else {
character(char_x, char_y, value);
if(auto_up) copy_to_lcd();
}
return value;
}
void aqm1248a_lcd::character(int x, int y, int c)
{
unsigned int hor,vert,offset,bpl,j,i,b;
unsigned char* zeichen;
unsigned char z,w;
if ((c < 31) || (c > 127)) return; // test char range
// read font parameter from start of array
offset = font[0]; // bytes / char
hor = font[1]; // get hor size of font
vert = font[2]; // get vert size of font
bpl = font[3]; // bytes per line
if (char_x + hor > width()) {
char_x = 0;
char_y = char_y + vert;
if (char_y >= height() - font[2]) {
char_y = 0;
}
}
zeichen = &font[((c -32) * offset) + 4]; // start of char bitmap
w = zeichen[0]; // width of actual char
// construct the char into the buffer
for (j=0; j<vert; j++) { // vert line
for (i=0; i<hor; i++) { // horz line
z = zeichen[bpl * i + ((j & 0xF8) >> 3)+1];
b = 1 << (j & 0x07);
if (( z & b ) == 0x00) {
pixel(x+i,y+j,0);
} else {
pixel(x+i,y+j,1);
}
}
}
char_x += w;
}
void aqm1248a_lcd::set_font(unsigned char* f)
{
font = f;
}
void aqm1248a_lcd::set_auto_up(unsigned int up)
{
if(up ) auto_up = 1;
else auto_up = 0;
}
unsigned int aqm1248a_lcd::get_auto_up(void)
{
return (auto_up);
}
void aqm1248a_lcd::print_bm(Bitmap bm, int x, int y)
{
int h,v,b;
char d;
for(v=0; v < bm.ySize; v++) { // lines
for(h=0; h < bm.xSize; h++) { // pixel
if(h + x > WIDTH-1) break;
if(v + y > HEIGHT-1) break;
d = bm.data[bm.Byte_in_Line * v + ((h & 0xF8) >> 3)];
b = 0x80 >> (h & 0x07);
if((d & b) == 0) {
pixel(x+h,y+v,0);
} else {
pixel(x+h,y+v,1);
}
}
}
}