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/*
uDisplay . cpp - universal display driver support for Tasmota
Copyright ( C ) 2021 Gerhard Mutz and Theo Arends
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 3 of the License , or
( at your option ) any later version .
This program 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 General Public License for more details .
You should have received a copy of the GNU General Public License
along with this program . If not , see < http : //www.gnu.org/licenses/>.
*/
# include <Arduino.h>
# include "uDisplay.h"
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# ifdef ESP32
# include "esp8266toEsp32.h"
# endif
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// #define UDSP_DEBUG
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const uint16_t udisp_colors [ ] = { UDISP_BLACK , UDISP_WHITE , UDISP_RED , UDISP_GREEN , UDISP_BLUE , UDISP_CYAN , UDISP_MAGENTA , \
UDISP_YELLOW , UDISP_NAVY , UDISP_DARKGREEN , UDISP_DARKCYAN , UDISP_MAROON , UDISP_PURPLE , UDISP_OLIVE , \
UDISP_LIGHTGREY , UDISP_DARKGREY , UDISP_ORANGE , UDISP_GREENYELLOW , UDISP_PINK } ;
uint16_t uDisplay : : GetColorFromIndex ( uint8_t index ) {
if ( index > = sizeof ( udisp_colors ) / 2 ) index = 0 ;
return udisp_colors [ index ] ;
}
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uint16_t uDisplay : : fgcol ( void ) {
return fg_col ;
}
uint16_t uDisplay : : bgcol ( void ) {
return bg_col ;
}
int8_t uDisplay : : color_type ( void ) {
return col_type ;
}
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uDisplay : : ~ uDisplay ( void ) {
if ( framebuffer ) {
free ( framebuffer ) ;
}
}
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uDisplay : : uDisplay ( char * lp ) : Renderer ( 800 , 600 ) {
// analyse decriptor
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pwr_cbp = 0 ;
dim_cbp = 0 ;
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framebuffer = 0 ;
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col_mode = 16 ;
sa_mode = 16 ;
saw_3 = 0xff ;
dim_op = 0xff ;
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dsp_off = 0xff ;
dsp_on = 0xff ;
lutpsize = 0 ;
lutfsize = 0 ;
lutptime = 35 ;
lutftime = 350 ;
lut3time = 10 ;
ep_mode = 0 ;
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fg_col = 1 ;
bg_col = 0 ;
splash_font = - 1 ;
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rotmap_xmin = - 1 ;
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bpanel = - 1 ;
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allcmd_mode = 0 ;
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startline = 0xA1 ;
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uint8_t section = 0 ;
dsp_ncmds = 0 ;
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lut_num = 0 ;
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lvgl_param . data = 0 ;
lvgl_param . fluslines = 40 ;
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for ( uint32_t cnt = 0 ; cnt < 5 ; cnt + + ) {
lut_cnt [ cnt ] = 0 ;
lut_cmd [ cnt ] = 0xff ;
}
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char linebuff [ 128 ] ;
while ( * lp ) {
uint16_t llen = strlen_ln ( lp ) ;
strncpy ( linebuff , lp , llen ) ;
linebuff [ llen ] = 0 ;
lp + = llen ;
char * lp1 = linebuff ;
if ( * lp1 = = ' # ' ) break ;
if ( * lp1 = = ' \n ' ) lp1 + + ;
while ( * lp1 = = ' ' ) lp1 + + ;
//Serial.printf(">> %s\n",lp1);
if ( * lp1 ! = ' ; ' ) {
// check ids:
if ( * lp1 = = ' : ' ) {
// id line
lp1 + + ;
section = * lp1 + + ;
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if ( section = = ' I ' ) {
if ( * lp1 = = ' C ' ) {
allcmd_mode = 1 ;
lp1 + + ;
}
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} else if ( section = = ' L ' ) {
if ( * lp1 > = ' 1 ' & & * lp1 < = ' 5 ' ) {
lut_num = ( * lp1 & 0x07 ) ;
lp1 + = 2 ;
lut_cmd [ lut_num - 1 ] = next_hex ( & lp1 ) ;
}
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}
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if ( * lp1 = = ' , ' ) lp1 + + ;
}
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if ( * lp1 ! = ' : ' & & * lp1 ! = ' \n ' & & * lp1 ! = ' ' ) { // Add space char
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switch ( section ) {
case ' H ' :
// header line
// SD1306,128,64,1,I2C,5a,*,*,*
str2c ( & lp1 , dname , sizeof ( dname ) ) ;
char ibuff [ 16 ] ;
gxs = next_val ( & lp1 ) ;
setwidth ( gxs ) ;
gys = next_val ( & lp1 ) ;
setheight ( gys ) ;
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disp_bpp = next_val ( & lp1 ) ;
bpp = abs ( disp_bpp ) ;
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if ( bpp = = 1 ) {
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col_type = uCOLOR_BW ;
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} else {
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col_type = uCOLOR_COLOR ;
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}
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str2c ( & lp1 , ibuff , sizeof ( ibuff ) ) ;
if ( ! strncmp ( ibuff , " I2C " , 3 ) ) {
interface = _UDSP_I2C ;
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wire_n = 0 ;
if ( ! strncmp ( ibuff , " I2C2 " , 4 ) ) {
wire_n = 1 ;
}
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i2caddr = next_hex ( & lp1 ) ;
i2c_scl = next_val ( & lp1 ) ;
i2c_sda = next_val ( & lp1 ) ;
reset = next_val ( & lp1 ) ;
section = 0 ;
} else if ( ! strncmp ( ibuff , " SPI " , 3 ) ) {
interface = _UDSP_SPI ;
spi_nr = next_val ( & lp1 ) ;
spi_cs = next_val ( & lp1 ) ;
spi_clk = next_val ( & lp1 ) ;
spi_mosi = next_val ( & lp1 ) ;
spi_dc = next_val ( & lp1 ) ;
bpanel = next_val ( & lp1 ) ;
reset = next_val ( & lp1 ) ;
spi_miso = next_val ( & lp1 ) ;
spi_speed = next_val ( & lp1 ) ;
section = 0 ;
}
break ;
case ' S ' :
splash_font = next_val ( & lp1 ) ;
splash_size = next_val ( & lp1 ) ;
fg_col = next_val ( & lp1 ) ;
if ( bpp = = 16 ) {
fg_col = GetColorFromIndex ( fg_col ) ;
}
bg_col = next_val ( & lp1 ) ;
if ( bpp = = 16 ) {
bg_col = GetColorFromIndex ( bg_col ) ;
}
splash_xp = next_val ( & lp1 ) ;
splash_yp = next_val ( & lp1 ) ;
break ;
case ' I ' :
// init data
if ( interface = = _UDSP_I2C ) {
dsp_cmds [ dsp_ncmds + + ] = next_hex ( & lp1 ) ;
if ( ! str2c ( & lp1 , ibuff , sizeof ( ibuff ) ) ) {
dsp_cmds [ dsp_ncmds + + ] = strtol ( ibuff , 0 , 16 ) ;
}
} else {
while ( 1 ) {
if ( ! str2c ( & lp1 , ibuff , sizeof ( ibuff ) ) ) {
dsp_cmds [ dsp_ncmds + + ] = strtol ( ibuff , 0 , 16 ) ;
} else {
break ;
}
if ( dsp_ncmds > = sizeof ( dsp_cmds ) ) break ;
}
}
break ;
case ' o ' :
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dsp_off = next_hex ( & lp1 ) ;
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break ;
case ' O ' :
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dsp_on = next_hex ( & lp1 ) ;
break ;
case ' R ' :
madctrl = next_hex ( & lp1 ) ;
startline = next_hex ( & lp1 ) ;
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break ;
case ' 0 ' :
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rot [ 0 ] = next_hex ( & lp1 ) ;
x_addr_offs [ 0 ] = next_hex ( & lp1 ) ;
y_addr_offs [ 0 ] = next_hex ( & lp1 ) ;
rot_t [ 0 ] = next_hex ( & lp1 ) ;
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break ;
case ' 1 ' :
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rot [ 1 ] = next_hex ( & lp1 ) ;
x_addr_offs [ 1 ] = next_hex ( & lp1 ) ;
y_addr_offs [ 1 ] = next_hex ( & lp1 ) ;
rot_t [ 1 ] = next_hex ( & lp1 ) ;
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break ;
case ' 2 ' :
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rot [ 2 ] = next_hex ( & lp1 ) ;
x_addr_offs [ 2 ] = next_hex ( & lp1 ) ;
y_addr_offs [ 2 ] = next_hex ( & lp1 ) ;
rot_t [ 2 ] = next_hex ( & lp1 ) ;
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break ;
case ' 3 ' :
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rot [ 3 ] = next_hex ( & lp1 ) ;
x_addr_offs [ 3 ] = next_hex ( & lp1 ) ;
y_addr_offs [ 3 ] = next_hex ( & lp1 ) ;
rot_t [ 3 ] = next_hex ( & lp1 ) ;
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break ;
case ' A ' :
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if ( interface = = _UDSP_I2C | | bpp = = 1 ) {
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saw_1 = next_hex ( & lp1 ) ;
i2c_page_start = next_hex ( & lp1 ) ;
i2c_page_end = next_hex ( & lp1 ) ;
saw_2 = next_hex ( & lp1 ) ;
i2c_col_start = next_hex ( & lp1 ) ;
i2c_col_end = next_hex ( & lp1 ) ;
saw_3 = next_hex ( & lp1 ) ;
} else {
saw_1 = next_hex ( & lp1 ) ;
saw_2 = next_hex ( & lp1 ) ;
saw_3 = next_hex ( & lp1 ) ;
sa_mode = next_val ( & lp1 ) ;
}
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break ;
case ' P ' :
col_mode = next_val ( & lp1 ) ;
break ;
case ' i ' :
inv_off = next_hex ( & lp1 ) ;
inv_on = next_hex ( & lp1 ) ;
break ;
case ' D ' :
dim_op = next_hex ( & lp1 ) ;
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break ;
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case ' L ' :
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if ( ! lut_num ) {
while ( 1 ) {
if ( ! str2c ( & lp1 , ibuff , sizeof ( ibuff ) ) ) {
lut_full [ lutfsize + + ] = strtol ( ibuff , 0 , 16 ) ;
} else {
break ;
}
if ( lutfsize > = LUTMAXSIZE ) break ;
}
} else {
uint8_t index = lut_num - 1 ;
while ( 1 ) {
if ( ! str2c ( & lp1 , ibuff , sizeof ( ibuff ) ) ) {
lut_array [ lut_cnt [ index ] + + ] [ index ] = strtol ( ibuff , 0 , 16 ) ;
} else {
break ;
}
if ( lut_cnt [ index ] > = LUTMAXSIZE ) break ;
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}
}
break ;
case ' l ' :
while ( 1 ) {
if ( ! str2c ( & lp1 , ibuff , sizeof ( ibuff ) ) ) {
lut_partial [ lutpsize + + ] = strtol ( ibuff , 0 , 16 ) ;
} else {
break ;
}
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if ( lutpsize > = LUTMAXSIZE ) break ;
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}
break ;
case ' T ' :
lutftime = next_val ( & lp1 ) ;
lutptime = next_val ( & lp1 ) ;
lut3time = next_val ( & lp1 ) ;
break ;
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case ' B ' :
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lvgl_param . fluslines = next_val ( & lp1 ) ;
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lvgl_param . data = next_val ( & lp1 ) ;
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break ;
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case ' M ' :
rotmap_xmin = next_val ( & lp1 ) ;
rotmap_xmax = next_val ( & lp1 ) ;
rotmap_ymin = next_val ( & lp1 ) ;
rotmap_ymax = next_val ( & lp1 ) ;
break ;
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}
}
}
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if ( * lp = = ' \n ' | | * lp = = ' ' ) { // Add space char
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lp + + ;
} else {
lp = strchr ( lp , ' \n ' ) ;
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if ( ! lp ) {
lp = strchr ( lp , ' ' ) ;
if ( ! lp ) {
break ;
}
}
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lp + + ;
}
}
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if ( lutfsize & & lutpsize ) {
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// 2 table mode
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ep_mode = 1 ;
}
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if ( lut_cnt [ 0 ] > 0 & & lut_cnt [ 1 ] = = lut_cnt [ 2 ] & & lut_cnt [ 1 ] = = lut_cnt [ 3 ] & & lut_cnt [ 1 ] = = lut_cnt [ 4 ] ) {
// 5 table mode
ep_mode = 2 ;
}
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# ifdef UDSP_DEBUG
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Serial . printf ( " xs : %d \n " , gxs ) ;
Serial . printf ( " ys : %d \n " , gys ) ;
Serial . printf ( " bpp: %d \n " , bpp ) ;
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if ( interface = = _UDSP_SPI ) {
Serial . printf ( " Nr. : %d \n " , spi_nr ) ;
Serial . printf ( " CS : %d \n " , spi_cs ) ;
Serial . printf ( " CLK : %d \n " , spi_clk ) ;
Serial . printf ( " MOSI: %d \n " , spi_mosi ) ;
Serial . printf ( " DC : %d \n " , spi_dc ) ;
Serial . printf ( " BPAN: %d \n " , bpanel ) ;
Serial . printf ( " RES : %d \n " , reset ) ;
Serial . printf ( " MISO: %d \n " , spi_miso ) ;
Serial . printf ( " SPED: %d \n " , spi_speed * 1000000 ) ;
Serial . printf ( " Pixels: %d \n " , col_mode ) ;
Serial . printf ( " SaMode: %d \n " , sa_mode ) ;
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Serial . printf ( " DMA-Mode: %d \n " , lvgl_param . use_dma ) ;
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Serial . printf ( " opts: %02x,%02x,%02x \n " , saw_3 , dim_op , startline ) ;
Serial . printf ( " SetAddr : %x,%x,%x \n " , saw_1 , saw_2 , saw_3 ) ;
Serial . printf ( " Rot 0: %x,%x - %d - %d \n " , madctrl , rot [ 0 ] , x_addr_offs [ 0 ] , y_addr_offs [ 0 ] ) ;
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if ( ep_mode = = 1 ) {
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Serial . printf ( " LUT_Partial : %d \n " , lutpsize ) ;
Serial . printf ( " LUT_Full : %d \n " , lutfsize ) ;
}
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if ( ep_mode = = 2 ) {
Serial . printf ( " LUT_SIZE 1: %d \n " , lut_cnt [ 0 ] ) ;
Serial . printf ( " LUT_SIZE 2: %d \n " , lut_cnt [ 1 ] ) ;
Serial . printf ( " LUT_SIZE 3: %d \n " , lut_cnt [ 2 ] ) ;
Serial . printf ( " LUT_SIZE 4: %d \n " , lut_cnt [ 3 ] ) ;
Serial . printf ( " LUT_SIZE 5: %d \n " , lut_cnt [ 4 ] ) ;
Serial . printf ( " LUT_CMDS %02x-%02x-%02x-%02x-%02x \n " , lut_cmd [ 0 ] , lut_cmd [ 1 ] , lut_cmd [ 2 ] , lut_cmd [ 3 ] , lut_cmd [ 4 ] ) ;
}
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}
if ( interface = = _UDSP_I2C ) {
Serial . printf ( " Addr : %02x \n " , i2caddr ) ;
Serial . printf ( " SCL : %d \n " , i2c_scl ) ;
Serial . printf ( " SDA : %d \n " , i2c_sda ) ;
Serial . printf ( " SPA : %x \n " , saw_1 ) ;
Serial . printf ( " pa_sta: %x \n " , i2c_page_start ) ;
Serial . printf ( " pa_end: %x \n " , i2c_page_end ) ;
Serial . printf ( " SCA : %x \n " , saw_2 ) ;
Serial . printf ( " ca_sta: %x \n " , i2c_col_start ) ;
Serial . printf ( " pa_end: %x \n " , i2c_col_end ) ;
Serial . printf ( " WRA : %x \n " , saw_3 ) ;
}
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# endif
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}
Renderer * uDisplay : : Init ( void ) {
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extern bool UsePSRAM ( void ) ;
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// for any bpp below native 16 bits, we allocate a local framebuffer to copy into
if ( ep_mode | | bpp < 16 ) {
if ( framebuffer ) free ( framebuffer ) ;
# ifdef ESP8266
framebuffer = ( uint8_t * ) calloc ( ( gxs * gys * bpp ) / 8 , 1 ) ;
# else
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if ( UsePSRAM ( ) ) {
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framebuffer = ( uint8_t * ) heap_caps_malloc ( ( gxs * gys * bpp ) / 8 , MALLOC_CAP_SPIRAM | MALLOC_CAP_8BIT ) ;
} else {
framebuffer = ( uint8_t * ) calloc ( ( gxs * gys * bpp ) / 8 , 1 ) ;
}
# endif
}
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if ( interface = = _UDSP_I2C ) {
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if ( wire_n = = 0 ) {
wire = & Wire ;
}
# ifdef ESP32
if ( wire_n = = 1 ) {
wire = & Wire1 ;
}
# endif
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wire - > begin ( i2c_sda , i2c_scl ) ; // TODO: aren't I2C buses already initialized? Shouldn't this be moved to display driver?
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# ifdef UDSP_DEBUG
Serial . printf ( " I2C cmds: %d \n " , dsp_ncmds ) ;
# endif
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for ( uint32_t cnt = 0 ; cnt < dsp_ncmds ; cnt + + ) {
i2c_command ( dsp_cmds [ cnt ] ) ;
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# ifdef UDSP_DEBUG
Serial . printf ( " cmd = %x \n " , dsp_cmds [ cnt ] ) ;
# endif
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}
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}
if ( interface = = _UDSP_SPI ) {
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if ( bpanel > = 0 ) {
# ifdef ESP32
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analogWrite ( bpanel , 32 ) ;
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# else
pinMode ( bpanel , OUTPUT ) ;
digitalWrite ( bpanel , HIGH ) ;
# endif // ESP32
}
if ( spi_dc > = 0 ) {
pinMode ( spi_dc , OUTPUT ) ;
digitalWrite ( spi_dc , HIGH ) ;
}
if ( spi_cs > = 0 ) {
pinMode ( spi_cs , OUTPUT ) ;
digitalWrite ( spi_cs , HIGH ) ;
}
# ifdef ESP8266
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if ( spi_nr < = 1 ) {
SPI . begin ( ) ;
uspi = & SPI ;
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} else {
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pinMode ( spi_clk , OUTPUT ) ;
digitalWrite ( spi_clk , LOW ) ;
pinMode ( spi_mosi , OUTPUT ) ;
digitalWrite ( spi_mosi , LOW ) ;
}
# endif // ESP8266
# ifdef ESP32
if ( spi_nr = = 1 ) {
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uspi = & SPI ;
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uspi - > begin ( spi_clk , spi_miso , spi_mosi , - 1 ) ;
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if ( lvgl_param . use_dma ) {
spi_host = VSPI_HOST ;
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initDMA ( lvgl_param . async_dma ? spi_cs : - 1 ) ; // disable DMA CS if sync, we control it directly
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}
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} else if ( spi_nr = = 2 ) {
uspi = new SPIClass ( HSPI ) ;
uspi - > begin ( spi_clk , spi_miso , spi_mosi , - 1 ) ;
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if ( lvgl_param . use_dma ) {
spi_host = HSPI_HOST ;
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initDMA ( lvgl_param . async_dma ? spi_cs : - 1 ) ; // disable DMA CS if sync, we control it directly
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}
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} else {
pinMode ( spi_clk , OUTPUT ) ;
digitalWrite ( spi_clk , LOW ) ;
pinMode ( spi_mosi , OUTPUT ) ;
digitalWrite ( spi_mosi , LOW ) ;
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}
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# endif // ESP32
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spiSettings = SPISettings ( ( uint32_t ) spi_speed * 1000000 , MSBFIRST , SPI_MODE3 ) ;
SPI_BEGIN_TRANSACTION
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if ( reset > = 0 ) {
pinMode ( reset , OUTPUT ) ;
digitalWrite ( reset , HIGH ) ;
delay ( 50 ) ;
digitalWrite ( reset , LOW ) ;
delay ( 50 ) ;
digitalWrite ( reset , HIGH ) ;
delay ( 200 ) ;
}
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uint16_t index = 0 ;
while ( 1 ) {
uint8_t iob ;
SPI_CS_LOW
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iob = dsp_cmds [ index + + ] ;
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spi_command ( iob ) ;
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uint8_t args = dsp_cmds [ index + + ] ;
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# ifdef UDSP_DEBUG
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Serial . printf ( " cmd, args %02x, %d " , iob , args & 0x1f ) ;
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# endif
for ( uint32_t cnt = 0 ; cnt < ( args & 0x1f ) ; cnt + + ) {
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iob = dsp_cmds [ index + + ] ;
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# ifdef UDSP_DEBUG
Serial . printf ( " %02x " , iob ) ;
# endif
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if ( ! allcmd_mode ) {
spi_data8 ( iob ) ;
} else {
spi_command ( iob ) ;
}
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}
SPI_CS_HIGH
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# ifdef UDSP_DEBUG
Serial . printf ( " \n " ) ;
# endif
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if ( args & 0x80 ) { // delay after the command
uint32_t delay_ms = 0 ;
switch ( args & 0xE0 ) {
case 0x80 : delay_ms = 150 ; break ;
case 0xA0 : delay_ms = 10 ; break ;
case 0xE0 : delay_ms = 500 ; break ;
}
if ( delay_ms > 0 ) {
delay ( delay_ms ) ;
# ifdef UDSP_DEBUG
Serial . printf ( " delay %d ms \n " , delay_ms ) ;
# endif
}
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}
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if ( index > = dsp_ncmds ) break ;
}
SPI_END_TRANSACTION
}
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// must init luts on epaper
if ( ep_mode ) {
Init_EPD ( DISPLAY_INIT_FULL ) ;
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if ( ep_mode = = 1 ) Init_EPD ( DISPLAY_INIT_PARTIAL ) ;
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}
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return this ;
}
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void uDisplay : : DisplayInit ( int8_t p , int8_t size , int8_t rot , int8_t font ) {
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if ( p ! = DISPLAY_INIT_MODE & & ep_mode ) {
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if ( p = = DISPLAY_INIT_PARTIAL ) {
if ( lutpsize ) {
SetLut ( lut_partial ) ;
Updateframe_EPD ( ) ;
delay ( lutptime * 10 ) ;
}
return ;
} else if ( p = = DISPLAY_INIT_FULL ) {
if ( lutfsize ) {
SetLut ( lut_full ) ;
Updateframe_EPD ( ) ;
}
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if ( ep_mode = = 2 ) {
ClearFrame_42 ( ) ;
DisplayFrame_42 ( ) ;
}
delay ( lutftime * 10 ) ;
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return ;
}
} else {
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setRotation ( rot ) ;
invertDisplay ( false ) ;
setTextWrap ( false ) ;
cp437 ( true ) ;
setTextFont ( font ) ;
setTextSize ( size ) ;
setTextColor ( fg_col , bg_col ) ;
setCursor ( 0 , 0 ) ;
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if ( splash_font > = 0 ) {
fillScreen ( bg_col ) ;
Updateframe ( ) ;
}
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# ifdef UDSP_DEBUG
Serial . printf ( " Dsp Init complete \n " ) ;
# endif
}
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}
void uDisplay : : spi_command ( uint8_t val ) {
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if ( spi_dc < 0 ) {
if ( spi_nr > 2 ) {
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if ( spi_nr = = 3 ) {
write9 ( val , 0 ) ;
} else {
write9_slow ( val , 0 ) ;
}
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} else {
hw_write9 ( val , 0 ) ;
}
} else {
SPI_DC_LOW
if ( spi_nr > 2 ) {
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if ( spi_nr = = 3 ) {
write8 ( val ) ;
} else {
write8_slow ( val ) ;
}
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} else {
uspi - > write ( val ) ;
}
SPI_DC_HIGH
}
}
void uDisplay : : spi_data8 ( uint8_t val ) {
if ( spi_dc < 0 ) {
if ( spi_nr > 2 ) {
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if ( spi_nr = = 3 ) {
write9 ( val , 1 ) ;
} else {
write9_slow ( val , 1 ) ;
}
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} else {
hw_write9 ( val , 1 ) ;
}
} else {
if ( spi_nr > 2 ) {
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if ( spi_nr = = 3 ) {
write8 ( val ) ;
} else {
write8_slow ( val ) ;
}
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} else {
uspi - > write ( val ) ;
}
}
}
void uDisplay : : spi_data16 ( uint16_t val ) {
if ( spi_dc < 0 ) {
if ( spi_nr > 2 ) {
write9 ( val > > 8 , 1 ) ;
write9 ( val , 1 ) ;
} else {
hw_write9 ( val > > 8 , 1 ) ;
hw_write9 ( val , 1 ) ;
}
} else {
if ( spi_nr > 2 ) {
write16 ( val ) ;
} else {
uspi - > write16 ( val ) ;
}
}
}
void uDisplay : : spi_data32 ( uint32_t val ) {
if ( spi_dc < 0 ) {
if ( spi_nr > 2 ) {
write9 ( val > > 24 , 1 ) ;
write9 ( val > > 16 , 1 ) ;
write9 ( val > > 8 , 1 ) ;
write9 ( val , 1 ) ;
} else {
hw_write9 ( val > > 24 , 1 ) ;
hw_write9 ( val > > 16 , 1 ) ;
hw_write9 ( val > > 8 , 1 ) ;
hw_write9 ( val , 1 ) ;
}
} else {
if ( spi_nr > 2 ) {
write32 ( val ) ;
} else {
uspi - > write32 ( val ) ;
}
}
}
void uDisplay : : spi_command_one ( uint8_t val ) {
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SPI_BEGIN_TRANSACTION
SPI_CS_LOW
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spi_command ( val ) ;
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SPI_CS_HIGH
SPI_END_TRANSACTION
}
void uDisplay : : i2c_command ( uint8_t val ) {
//Serial.printf("%02x\n",val );
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wire - > beginTransmission ( i2caddr ) ;
wire - > write ( 0 ) ;
wire - > write ( val ) ;
wire - > endTransmission ( ) ;
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}
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# define WIRE_MAX 32
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void uDisplay : : Updateframe ( void ) {
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if ( ep_mode ) {
Updateframe_EPD ( ) ;
return ;
}
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if ( interface = = _UDSP_I2C ) {
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#if 0
i2c_command ( saw_1 ) ;
i2c_command ( i2c_page_start ) ;
i2c_command ( i2c_page_end ) ;
i2c_command ( saw_2 ) ;
i2c_command ( i2c_col_start ) ;
i2c_command ( i2c_col_end ) ;
uint16_t count = gxs * ( ( gys + 7 ) / 8 ) ;
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uint8_t * ptr = framebuffer ;
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wire - > beginTransmission ( i2caddr ) ;
i2c_command ( saw_3 ) ;
uint8_t bytesOut = 1 ;
while ( count - - ) {
if ( bytesOut > = WIRE_MAX ) {
wire - > endTransmission ( ) ;
wire - > beginTransmission ( i2caddr ) ;
i2c_command ( saw_3 ) ;
bytesOut = 1 ;
}
i2c_command ( * ptr + + ) ;
bytesOut + + ;
}
wire - > endTransmission ( ) ;
# else
i2c_command ( saw_1 | 0x0 ) ; // set low col = 0, 0x00
i2c_command ( i2c_page_start | 0x0 ) ; // set hi col = 0, 0x10
i2c_command ( i2c_page_end | 0x0 ) ; // set startline line #0, 0x40
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uint8_t ys = gys > > 3 ;
uint8_t xs = gxs > > 3 ;
//uint8_t xs = 132 >> 3;
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uint8_t m_row = saw_2 ;
uint8_t m_col = i2c_col_start ;
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uint16_t p = 0 ;
uint8_t i , j , k = 0 ;
for ( i = 0 ; i < ys ; i + + ) {
// send a bunch of data in one xmission
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i2c_command ( 0xB0 + i + m_row ) ; //set page address
i2c_command ( m_col & 0xf ) ; //set lower column address
i2c_command ( 0x10 | ( m_col > > 4 ) ) ; //set higher column address
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for ( j = 0 ; j < 8 ; j + + ) {
wire - > beginTransmission ( i2caddr ) ;
wire - > write ( 0x40 ) ;
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for ( k = 0 ; k < xs ; k + + , p + + ) {
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wire - > write ( framebuffer [ p ] ) ;
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}
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wire - > endTransmission ( ) ;
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}
}
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# endif
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}
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if ( interface = = _UDSP_SPI ) {
if ( framebuffer = = nullptr ) { return ; }
SPI_BEGIN_TRANSACTION
SPI_CS_LOW
// below commands are not needed for SH1107
// spi_command(saw_1 | 0x0); // set low col = 0, 0x00
// spi_command(i2c_page_start | 0x0); // set hi col = 0, 0x10
// spi_command(i2c_page_end | 0x0); // set startline line #0, 0x40
uint8_t ys = gys > > 3 ;
uint8_t xs = gxs > > 3 ;
//uint8_t xs = 132 >> 3;
uint8_t m_row = saw_2 ;
uint8_t m_col = i2c_col_start ;
// Serial.printf("m_row=%d m_col=%d xs=%d ys=%d\n", m_row, m_col, xs, ys);
uint16_t p = 0 ;
uint8_t i , j , k = 0 ;
for ( i = 0 ; i < ys ; i + + ) { // i = line from 0 to ys
// send a bunch of data in one xmission
spi_command ( 0xB0 + i + m_row ) ; //set page address
spi_command ( m_col & 0xf ) ; //set lower column address
spi_command ( 0x10 | ( m_col > > 4 ) ) ; //set higher column address
for ( j = 0 ; j < 8 ; j + + ) {
for ( k = 0 ; k < xs ; k + + , p + + ) {
spi_data8 ( framebuffer [ p ] ) ;
}
}
}
SPI_CS_HIGH
SPI_END_TRANSACTION
}
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}
void uDisplay : : drawFastVLine ( int16_t x , int16_t y , int16_t h , uint16_t color ) {
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if ( ep_mode ) {
drawFastVLine_EPD ( x , y , h , color ) ;
return ;
}
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if ( interface ! = _UDSP_SPI ) {
Renderer : : drawFastVLine ( x , y , h , color ) ;
return ;
}
// Rudimentary clipping
if ( ( x > = _width ) | | ( y > = _height ) ) return ;
if ( ( y + h - 1 ) > = _height ) h = _height - y ;
SPI_BEGIN_TRANSACTION
SPI_CS_LOW
setAddrWindow_int ( x , y , 1 , h ) ;
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if ( col_mode = = 18 ) {
uint8_t r = ( color & 0xF800 ) > > 11 ;
uint8_t g = ( color & 0x07E0 ) > > 5 ;
uint8_t b = color & 0x001F ;
r = ( r * 255 ) / 31 ;
g = ( g * 255 ) / 63 ;
b = ( b * 255 ) / 31 ;
while ( h - - ) {
spi_data8 ( r ) ;
spi_data8 ( g ) ;
spi_data8 ( b ) ;
}
} else {
while ( h - - ) {
WriteColor ( color ) ;
}
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}
SPI_CS_HIGH
SPI_END_TRANSACTION
}
void uDisplay : : drawFastHLine ( int16_t x , int16_t y , int16_t w , uint16_t color ) {
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if ( ep_mode ) {
drawFastHLine_EPD ( x , y , w , color ) ;
return ;
}
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if ( interface ! = _UDSP_SPI ) {
Renderer : : drawFastHLine ( x , y , w , color ) ;
return ;
}
// Rudimentary clipping
if ( ( x > = _width ) | | ( y > = _height ) ) return ;
if ( ( x + w - 1 ) > = _width ) w = _width - x ;
SPI_BEGIN_TRANSACTION
SPI_CS_LOW
setAddrWindow_int ( x , y , w , 1 ) ;
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if ( col_mode = = 18 ) {
uint8_t r = ( color & 0xF800 ) > > 11 ;
uint8_t g = ( color & 0x07E0 ) > > 5 ;
uint8_t b = color & 0x001F ;
r = ( r * 255 ) / 31 ;
g = ( g * 255 ) / 63 ;
b = ( b * 255 ) / 31 ;
while ( w - - ) {
spi_data8 ( r ) ;
spi_data8 ( g ) ;
spi_data8 ( b ) ;
}
} else {
while ( w - - ) {
WriteColor ( color ) ;
}
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}
SPI_CS_HIGH
SPI_END_TRANSACTION
}
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//#define CD_XS gxs
//#define CD_YS gys
# define CD_XS width()
# define CD_YS height()
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void uDisplay : : fillScreen ( uint16_t color ) {
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fillRect ( 0 , 0 , CD_XS , CD_YS , color ) ;
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}
// fill a rectangle
void uDisplay : : fillRect ( int16_t x , int16_t y , int16_t w , int16_t h , uint16_t color ) {
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if ( ep_mode ) {
fillRect_EPD ( x , y , w , h , color ) ;
return ;
}
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if ( interface ! = _UDSP_SPI ) {
Renderer : : fillRect ( x , y , w , h , color ) ;
return ;
}
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if ( ( x > = CD_XS ) | | ( y > = CD_YS ) ) return ;
if ( ( x + w - 1 ) > = CD_XS ) w = CD_XS - x ;
if ( ( y + h - 1 ) > = CD_YS ) h = CD_YS - y ;
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SPI_BEGIN_TRANSACTION
SPI_CS_LOW
setAddrWindow_int ( x , y , w , h ) ;
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if ( col_mode = = 18 ) {
uint8_t r = ( color & 0xF800 ) > > 11 ;
uint8_t g = ( color & 0x07E0 ) > > 5 ;
uint8_t b = color & 0x001F ;
r = ( r * 255 ) / 31 ;
g = ( g * 255 ) / 63 ;
b = ( b * 255 ) / 31 ;
for ( y = h ; y > 0 ; y - - ) {
for ( x = w ; x > 0 ; x - - ) {
spi_data8 ( r ) ;
spi_data8 ( g ) ;
spi_data8 ( b ) ;
}
}
} else {
for ( y = h ; y > 0 ; y - - ) {
for ( x = w ; x > 0 ; x - - ) {
WriteColor ( color ) ;
}
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}
}
SPI_CS_HIGH
SPI_END_TRANSACTION
}
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/*
// pack RGB into uint32
uint32_t pack_rgb ( uint32_t r , uint32_t g , uint32_t b ) {
uint32_t data ;
data = r < < 23 ;
data | = g < < 14 ;
data | = b < < 5 ;
data | = 0b10000000010000000010000000000000 ;
return ulswap ( data ) ;
}
// init 27 bit mode
uint32_t data = pack_rgb ( r , g , b ) ;
REG_SET_BIT ( SPI_USER_REG ( 3 ) , SPI_USR_MOSI ) ;
REG_WRITE ( SPI_MOSI_DLEN_REG ( 3 ) , 27 - 1 ) ;
uint32_t * dp = ( uint32_t * ) SPI_W0_REG ( 3 ) ;
digitalWrite ( _cs , LOW ) ;
for ( y = h ; y > 0 ; y - - ) {
for ( x = w ; x > 0 ; x - - ) {
while ( REG_GET_FIELD ( SPI_CMD_REG ( 3 ) , SPI_USR ) ) ;
* dp = data ;
REG_SET_BIT ( SPI_CMD_REG ( 3 ) , SPI_USR ) ;
}
}
*/
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void uDisplay : : Splash ( void ) {
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if ( splash_font < 0 ) return ;
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if ( ep_mode ) {
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Updateframe ( ) ;
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delay ( lut3time * 10 ) ;
}
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setTextFont ( splash_font ) ;
setTextSize ( splash_size ) ;
DrawStringAt ( splash_xp , splash_yp , dname , fg_col , 0 ) ;
Updateframe ( ) ;
}
void uDisplay : : setAddrWindow ( uint16_t x0 , uint16_t y0 , uint16_t x1 , uint16_t y1 ) {
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if ( bpp ! = 16 ) {
// just save params or update frame
if ( ! x0 & & ! y0 & & ! x1 & & ! y1 ) {
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if ( ! ep_mode ) {
Updateframe ( ) ;
}
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} else {
seta_xp1 = x0 ;
seta_xp2 = x1 ;
seta_yp1 = y0 ;
seta_yp2 = y1 ;
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// Serial.printf("xp1=%d xp2=%d yp1=%d yp2=%d\n", seta_xp1, seta_xp2, seta_yp1, seta_yp2);
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}
return ;
}
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if ( ! x0 & & ! y0 & & ! x1 & & ! y1 ) {
SPI_CS_HIGH
SPI_END_TRANSACTION
} else {
SPI_BEGIN_TRANSACTION
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SPI_CS_LOW
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setAddrWindow_int ( x0 , y0 , x1 - x0 , y1 - y0 ) ;
}
}
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# define udisp_swap(a, b) (((a) ^= (b)), ((b) ^= (a)), ((a) ^= (b))) ///< No-temp-var swap operation
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void uDisplay : : setAddrWindow_int ( uint16_t x , uint16_t y , uint16_t w , uint16_t h ) {
x + = x_addr_offs [ cur_rot ] ;
y + = y_addr_offs [ cur_rot ] ;
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if ( sa_mode ! = 8 ) {
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uint32_t xa = ( ( uint32_t ) x < < 16 ) | ( x + w - 1 ) ;
uint32_t ya = ( ( uint32_t ) y < < 16 ) | ( y + h - 1 ) ;
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spi_command ( saw_1 ) ;
spi_data32 ( xa ) ;
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spi_command ( saw_2 ) ;
spi_data32 ( ya ) ;
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if ( saw_3 ! = 0xff ) {
spi_command ( saw_3 ) ; // write to RAM
}
} else {
uint16_t x2 = x + w - 1 ,
y2 = y + h - 1 ;
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if ( cur_rot & 1 ) { // Vertical address increment mode
udisp_swap ( x , y ) ;
udisp_swap ( x2 , y2 ) ;
}
spi_command ( saw_1 ) ;
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if ( allcmd_mode ) {
spi_data8 ( x ) ;
spi_data8 ( x2 ) ;
} else {
spi_command ( x ) ;
spi_command ( x2 ) ;
}
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spi_command ( saw_2 ) ;
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if ( allcmd_mode ) {
spi_data8 ( y ) ;
spi_data8 ( y2 ) ;
} else {
spi_command ( y ) ;
spi_command ( y2 ) ;
}
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if ( saw_3 ! = 0xff ) {
spi_command ( saw_3 ) ; // write to RAM
}
}
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}
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# define RGB16_TO_MONO 0x8410
# define RGB16_SWAP_TO_MONO 0x1084
// #define CNV_B1_OR ((0x10<<11) | (0x20<<5) | 0x10)
// static inline uint8_t ulv_color_to1(uint16_t color) {
// if (color & CNV_B1_OR) {
// return 1;
// }
// else {
// return 0;
// }
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/*
// this needs optimization
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if ( ( ( color > > 11 ) & 0x10 ) | | ( ( color > > 5 ) & 0x20 ) | | ( color & 0x10 ) ) {
return 1 ;
}
else {
return 0 ;
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} */
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// }
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// convert to mono, these are framebuffer based
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void uDisplay : : pushColorsMono ( uint16_t * data , uint16_t len , bool rgb16_swap ) {
// pixel is white if at least one of the 3 components is above 50%
// this is tested with a simple mask, swapped if needed
uint16_t rgb16_to_mono_mask = rgb16_swap ? RGB16_SWAP_TO_MONO : RGB16_TO_MONO ;
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for ( uint32_t y = seta_yp1 ; y < seta_yp2 ; y + + ) {
for ( uint32_t x = seta_xp1 ; x < seta_xp2 ; x + + ) {
uint16_t color = * data + + ;
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if ( bpp = = 1 ) color = ( color & rgb16_to_mono_mask ) ? 1 : 0 ;
drawPixel ( x , y , color ) ; // todo - inline the method to save speed
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len - - ;
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if ( ! len ) return ; // failsafe - exist if len (pixel number) is exhausted
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}
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}
}
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// swap high low byte
static inline void lvgl_color_swap ( uint16_t * data , uint16_t len ) { for ( uint32_t i = 0 ; i < len ; i + + ) ( data [ i ] = data [ i ] < < 8 | data [ i ] > > 8 ) ; }
void uDisplay : : pushColors ( uint16_t * data , uint16_t len , boolean not_swapped ) {
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uint16_t color ;
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if ( lvgl_param . swap_color ) {
not_swapped = ! not_swapped ;
}
//Serial.printf("push %x - %d - %d - %d\n", (uint32_t)data, len, not_swapped,lvgl_param.data);
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if ( not_swapped = = false ) {
// called from LVGL bytes are swapped
if ( bpp ! = 16 ) {
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// lvgl_color_swap(data, len); -- no need to swap anymore, we have inverted the mask
pushColorsMono ( data , len , true ) ;
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return ;
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}
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if ( ( col_mode ! = 18 ) & & ( spi_dc > = 0 ) & & ( spi_nr < = 2 ) ) {
// special version 8 bit spi I or II
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# ifdef ESP8266
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lvgl_color_swap ( data , len ) ;
while ( len - - ) {
uspi - > write ( * data + + ) ;
}
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# else
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if ( lvgl_param . use_dma ) {
pushPixelsDMA ( data , len ) ;
} else {
uspi - > writeBytes ( ( uint8_t * ) data , len * 2 ) ;
}
# endif
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} else {
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# ifdef ESP32
if ( ( col_mode = = 18 ) & & ( spi_dc > = 0 ) & & ( spi_nr < = 2 ) ) {
uint8_t * line = ( uint8_t * ) malloc ( len * 3 ) ;
uint8_t * lp = line ;
if ( line ) {
for ( uint32_t cnt = 0 ; cnt < len ; cnt + + ) {
color = * data + + ;
color = ( color < < 8 ) | ( color > > 8 ) ;
uint8_t r = ( color & 0xF800 ) > > 11 ;
uint8_t g = ( color & 0x07E0 ) > > 5 ;
uint8_t b = color & 0x001F ;
r = ( r * 255 ) / 31 ;
g = ( g * 255 ) / 63 ;
b = ( b * 255 ) / 31 ;
* lp + + = r ;
* lp + + = g ;
* lp + + = b ;
}
if ( lvgl_param . use_dma ) {
pushPixels3DMA ( line , len ) ;
} else {
uspi - > writeBytes ( line , len * 3 ) ;
}
free ( line ) ;
}
} else {
// 9 bit and others
lvgl_color_swap ( data , len ) ;
while ( len - - ) {
WriteColor ( * data + + ) ;
}
}
# endif // ESP32
# ifdef ESP8266
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lvgl_color_swap ( data , len ) ;
while ( len - - ) {
WriteColor ( * data + + ) ;
}
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# endif
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}
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} else {
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// called from displaytext, no byte swap, currently no dma here
if ( bpp ! = 16 ) {
pushColorsMono ( data , len ) ;
return ;
}
if ( ( col_mode ! = 18 ) & & ( spi_dc > = 0 ) & & ( spi_nr < = 2 ) ) {
// special version 8 bit spi I or II
# ifdef ESP8266
while ( len - - ) {
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//uspi->write(*data++);
WriteColor ( * data + + ) ;
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}
# else
uspi - > writePixels ( data , len * 2 ) ;
# endif
} else {
// 9 bit and others
while ( len - - ) {
WriteColor ( * data + + ) ;
}
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}
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}
}
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void uDisplay : : WriteColor ( uint16_t color ) {
if ( col_mode = = 18 ) {
uint8_t r = ( color & 0xF800 ) > > 11 ;
uint8_t g = ( color & 0x07E0 ) > > 5 ;
uint8_t b = color & 0x001F ;
r = ( r * 255 ) / 31 ;
g = ( g * 255 ) / 63 ;
b = ( b * 255 ) / 31 ;
spi_data8 ( r ) ;
spi_data8 ( g ) ;
spi_data8 ( b ) ;
} else {
spi_data16 ( color ) ;
}
}
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void uDisplay : : drawPixel ( int16_t x , int16_t y , uint16_t color ) {
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if ( ep_mode ) {
drawPixel_EPD ( x , y , color ) ;
return ;
}
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if ( interface ! = _UDSP_SPI | | bpp < 16 ) {
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Renderer : : drawPixel ( x , y , color ) ;
return ;
}
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if ( ( x < 0 ) | | ( x > = _width ) | | ( y < 0 ) | | ( y > = _height ) ) return ;
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SPI_BEGIN_TRANSACTION
SPI_CS_LOW
setAddrWindow_int ( x , y , 1 , 1 ) ;
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WriteColor ( color ) ;
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SPI_CS_HIGH
SPI_END_TRANSACTION
}
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void uDisplay : : setRotation ( uint8_t rotation ) {
cur_rot = rotation ;
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if ( interface ! = _UDSP_SPI | | bpp < 16 ) {
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Renderer : : setRotation ( cur_rot ) ;
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return ;
}
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if ( interface = = _UDSP_SPI ) {
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if ( ep_mode ) {
Renderer : : setRotation ( cur_rot ) ;
return ;
}
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SPI_BEGIN_TRANSACTION
SPI_CS_LOW
spi_command ( madctrl ) ;
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if ( ! allcmd_mode ) {
spi_data8 ( rot [ cur_rot ] ) ;
} else {
spi_command ( rot [ cur_rot ] ) ;
}
if ( ( sa_mode = = 8 ) & & ! allcmd_mode ) {
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spi_command ( startline ) ;
spi_data8 ( ( cur_rot < 2 ) ? height ( ) : 0 ) ;
}
SPI_CS_HIGH
SPI_END_TRANSACTION
}
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switch ( rotation ) {
case 0 :
_width = gxs ;
_height = gys ;
break ;
case 1 :
_width = gys ;
_height = gxs ;
break ;
case 2 :
_width = gxs ;
_height = gys ;
break ;
case 3 :
_width = gys ;
_height = gxs ;
break ;
}
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}
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void udisp_bpwr ( uint8_t on ) ;
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void uDisplay : : DisplayOnff ( int8_t on ) {
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if ( ep_mode ) {
return ;
}
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if ( pwr_cbp ) {
pwr_cbp ( on ) ;
}
// udisp_bpwr(on);
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if ( interface = = _UDSP_I2C ) {
if ( on ) {
i2c_command ( dsp_on ) ;
} else {
i2c_command ( dsp_off ) ;
}
} else {
if ( on ) {
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if ( dsp_on ! = 0xff ) spi_command_one ( dsp_on ) ;
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if ( bpanel > = 0 ) {
# ifdef ESP32
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analogWrite ( bpanel , dimmer10_gamma ) ;
// ledcWrite(ESP32_PWM_CHANNEL, dimmer8_gamma);
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# else
digitalWrite ( bpanel , HIGH ) ;
# endif
}
} else {
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if ( dsp_off ! = 0xff ) spi_command_one ( dsp_off ) ;
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if ( bpanel > = 0 ) {
# ifdef ESP32
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analogWrite ( bpanel , 0 ) ;
// ledcWrite(ESP32_PWM_CHANNEL, 0);
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# else
digitalWrite ( bpanel , LOW ) ;
# endif
}
}
}
}
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void uDisplay : : invertDisplay ( boolean i ) {
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if ( ep_mode ) {
return ;
}
if ( interface = = _UDSP_SPI ) {
if ( i ) {
spi_command_one ( inv_on ) ;
} else {
spi_command_one ( inv_off ) ;
}
}
if ( interface = = _UDSP_I2C ) {
if ( i ) {
i2c_command ( inv_on ) ;
} else {
i2c_command ( inv_off ) ;
}
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}
}
void udisp_dimm ( uint8_t dim ) ;
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// input value is 0..15
// void uDisplay::dim(uint8_t dim) {
// dim8(((uint32_t)dim * 255) / 15);
// }
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// dim is 0..255
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void uDisplay : : dim10 ( uint8_t dim , uint16_t dim_gamma ) { // dimmer with 8 bits resolution, 0..255. Gamma correction must be done by caller
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dimmer8 = dim ;
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dimmer10_gamma = dim_gamma ;
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if ( ep_mode ) {
return ;
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}
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# ifdef ESP32 // TODO should we also add a ESP8266 version for bpanel?
if ( bpanel > = 0 ) { // is the BaclPanel GPIO configured
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analogWrite ( bpanel , dimmer10_gamma ) ;
// ledcWrite(ESP32_PWM_CHANNEL, dimmer8_gamma);
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} else if ( dim_cbp ) {
dim_cbp ( dim ) ;
}
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# endif
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if ( interface = = _UDSP_SPI ) {
if ( dim_op ! = 0xff ) { // send SPI command if dim configured
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SPI_BEGIN_TRANSACTION
SPI_CS_LOW
spi_command ( dim_op ) ;
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spi_data8 ( dimmer8 ) ;
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SPI_CS_HIGH
SPI_END_TRANSACTION
}
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}
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}
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// the cases are PSEUDO_OPCODES from MODULE_DESCRIPTOR
// and may be exapnded with more opcodes
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void uDisplay : : TS_RotConvert ( int16_t * x , int16_t * y ) {
int16_t temp ;
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if ( rot_t [ cur_rot ] & 0x80 ) {
temp = * y ;
* y = * x ;
* x = temp ;
}
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if ( rotmap_xmin > = 0 ) {
* y = map ( * y , rotmap_ymin , rotmap_ymax , 0 , gys ) ;
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* x = map ( * x , rotmap_xmin , rotmap_xmax , 0 , gxs ) ;
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* x = constrain ( * x , 0 , gxs ) ;
* y = constrain ( * y , 0 , gys ) ;
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}
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// *x = constrain(*x, 0, gxs);
// *y = constrain(*y, 0, gys);
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//Serial.printf("rot 1 %d - %d\n",*x,*y );
switch ( rot_t [ cur_rot ] & 0xf ) {
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case 0 :
break ;
case 1 :
temp = * y ;
* y = height ( ) - * x ;
* x = temp ;
break ;
case 2 :
* x = width ( ) - * x ;
* y = height ( ) - * y ;
break ;
case 3 :
temp = * y ;
* y = * x ;
* x = width ( ) - temp ;
break ;
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case 4 :
* x = width ( ) - * x ;
break ;
case 5 :
* y = height ( ) - * y ;
break ;
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}
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//Serial.printf("rot 2 %d - %d\n",*x,*y );
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}
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uint8_t uDisplay : : strlen_ln ( char * str ) {
for ( uint32_t cnt = 0 ; cnt < 256 ; cnt + + ) {
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if ( ! str [ cnt ] | | str [ cnt ] = = ' \n ' | | str [ cnt ] = = ' ' ) return cnt ;
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}
return 0 ;
}
char * uDisplay : : devname ( void ) {
return dname ;
}
uint32_t uDisplay : : str2c ( char * * sp , char * vp , uint32_t len ) {
char * lp = * sp ;
if ( len ) len - - ;
char * cp = strchr ( lp , ' , ' ) ;
if ( cp ) {
while ( 1 ) {
if ( * lp = = ' , ' ) {
* vp = 0 ;
* sp = lp + 1 ;
return 0 ;
}
if ( len ) {
* vp + + = * lp + + ;
len - - ;
} else {
lp + + ;
}
}
} else {
uint8_t slen = strlen ( lp ) ;
if ( slen ) {
strlcpy ( vp , * sp , len ) ;
* sp = lp + slen ;
return 0 ;
}
}
return 1 ;
}
int32_t uDisplay : : next_val ( char * * sp ) {
char ibuff [ 16 ] ;
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if ( ! str2c ( sp , ibuff , sizeof ( ibuff ) ) ) {
return atoi ( ibuff ) ;
}
return 0xff ;
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}
uint32_t uDisplay : : next_hex ( char * * sp ) {
char ibuff [ 16 ] ;
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if ( ! str2c ( sp , ibuff , sizeof ( ibuff ) ) ) {
return strtol ( ibuff , 0 , 16 ) ;
}
return 0xff ;
}
# ifdef ESP32
# include "soc/spi_reg.h"
# include "soc/spi_struct.h"
# include "esp32-hal-spi.h"
# include "esp32-hal.h"
# include "soc/spi_struct.h"
// since ardunio transferBits ia completely disfunctional
// we use our own hardware driver for 9 bit spi
void uDisplay : : hw_write9 ( uint8_t val , uint8_t dc ) {
uint32_t regvalue = val > > 1 ;
if ( dc ) regvalue | = 0x80 ;
else regvalue & = 0x7f ;
if ( val & 1 ) regvalue | = 0x8000 ;
REG_SET_BIT ( SPI_USER_REG ( 3 ) , SPI_USR_MOSI ) ;
REG_WRITE ( SPI_MOSI_DLEN_REG ( 3 ) , 9 - 1 ) ;
uint32_t * dp = ( uint32_t * ) SPI_W0_REG ( 3 ) ;
* dp = regvalue ;
REG_SET_BIT ( SPI_CMD_REG ( 3 ) , SPI_USR ) ;
while ( REG_GET_FIELD ( SPI_CMD_REG ( 3 ) , SPI_USR ) ) ;
}
# else
# include "spi_register.h"
void uDisplay : : hw_write9 ( uint8_t val , uint8_t dc ) {
uint32_t regvalue ;
uint8_t bytetemp ;
if ( ! dc ) {
bytetemp = ( val > > 1 ) & 0x7f ;
} else {
bytetemp = ( val > > 1 ) | 0x80 ;
}
regvalue = ( ( 8 & SPI_USR_COMMAND_BITLEN ) < < SPI_USR_COMMAND_BITLEN_S ) | ( ( uint32 ) bytetemp ) ; //configure transmission variable,9bit transmission length and first 8 command bit
if ( val & 0x01 ) regvalue | = BIT15 ; //write the 9th bit
while ( READ_PERI_REG ( SPI_CMD ( 1 ) ) & SPI_USR ) ; //waiting for spi module available
WRITE_PERI_REG ( SPI_USER2 ( 1 ) , regvalue ) ; //write command and command length into spi reg
SET_PERI_REG_MASK ( SPI_CMD ( 1 ) , SPI_USR ) ; //transmission start
}
# endif
# define USECACHE ICACHE_RAM_ATTR
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// slow software spi needed for displays with max 10 Mhz clck
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void USECACHE uDisplay : : write8 ( uint8_t val ) {
for ( uint8_t bit = 0x80 ; bit ; bit > > = 1 ) {
GPIO_CLR ( spi_clk ) ;
if ( val & bit ) GPIO_SET ( spi_mosi ) ;
else GPIO_CLR ( spi_mosi ) ;
GPIO_SET ( spi_clk ) ;
}
}
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void uDisplay : : write8_slow ( uint8_t val ) {
for ( uint8_t bit = 0x80 ; bit ; bit > > = 1 ) {
GPIO_CLR_SLOW ( spi_clk ) ;
if ( val & bit ) GPIO_SET_SLOW ( spi_mosi ) ;
else GPIO_CLR_SLOW ( spi_mosi ) ;
GPIO_SET_SLOW ( spi_clk ) ;
}
}
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void USECACHE uDisplay : : write9 ( uint8_t val , uint8_t dc ) {
GPIO_CLR ( spi_clk ) ;
if ( dc ) GPIO_SET ( spi_mosi ) ;
else GPIO_CLR ( spi_mosi ) ;
GPIO_SET ( spi_clk ) ;
for ( uint8_t bit = 0x80 ; bit ; bit > > = 1 ) {
GPIO_CLR ( spi_clk ) ;
if ( val & bit ) GPIO_SET ( spi_mosi ) ;
else GPIO_CLR ( spi_mosi ) ;
GPIO_SET ( spi_clk ) ;
}
}
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void uDisplay : : write9_slow ( uint8_t val , uint8_t dc ) {
GPIO_CLR_SLOW ( spi_clk ) ;
if ( dc ) GPIO_SET_SLOW ( spi_mosi ) ;
else GPIO_CLR_SLOW ( spi_mosi ) ;
GPIO_SET_SLOW ( spi_clk ) ;
for ( uint8_t bit = 0x80 ; bit ; bit > > = 1 ) {
GPIO_CLR_SLOW ( spi_clk ) ;
if ( val & bit ) GPIO_SET_SLOW ( spi_mosi ) ;
else GPIO_CLR_SLOW ( spi_mosi ) ;
GPIO_SET_SLOW ( spi_clk ) ;
}
}
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void USECACHE uDisplay : : write16 ( uint16_t val ) {
for ( uint16_t bit = 0x8000 ; bit ; bit > > = 1 ) {
GPIO_CLR ( spi_clk ) ;
if ( val & bit ) GPIO_SET ( spi_mosi ) ;
else GPIO_CLR ( spi_mosi ) ;
GPIO_SET ( spi_clk ) ;
}
}
void USECACHE uDisplay : : write32 ( uint32_t val ) {
for ( uint32_t bit = 0x80000000 ; bit ; bit > > = 1 ) {
GPIO_CLR ( spi_clk ) ;
if ( val & bit ) GPIO_SET ( spi_mosi ) ;
else GPIO_CLR ( spi_mosi ) ;
GPIO_SET ( spi_clk ) ;
}
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}
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// epaper section
// EPD2IN9 commands
# define DRIVER_OUTPUT_CONTROL 0x01
# define BOOSTER_SOFT_START_CONTROL 0x0C
# define GATE_SCAN_START_POSITION 0x0F
# define DEEP_SLEEP_MODE 0x10
# define DATA_ENTRY_MODE_SETTING 0x11
# define SW_RESET 0x12
# define TEMPERATURE_SENSOR_CONTROL 0x1A
# define MASTER_ACTIVATION 0x20
# define DISPLAY_UPDATE_CONTROL_1 0x21
# define DISPLAY_UPDATE_CONTROL_2 0x22
# define WRITE_RAM 0x24
# define WRITE_VCOM_REGISTER 0x2C
# define WRITE_LUT_REGISTER 0x32
# define SET_DUMMY_LINE_PERIOD 0x3A
# define SET_GATE_TIME 0x3B
# define BORDER_WAVEFORM_CONTROL 0x3C
# define SET_RAM_X_ADDRESS_START_END_POSITION 0x44
# define SET_RAM_Y_ADDRESS_START_END_POSITION 0x45
# define SET_RAM_X_ADDRESS_COUNTER 0x4E
# define SET_RAM_Y_ADDRESS_COUNTER 0x4F
# define TERMINATE_FRAME_READ_WRITE 0xFF
void uDisplay : : spi_data8_EPD ( uint8_t val ) {
SPI_BEGIN_TRANSACTION
SPI_CS_LOW
spi_data8 ( val ) ;
SPI_CS_HIGH
SPI_END_TRANSACTION
}
void uDisplay : : spi_command_EPD ( uint8_t val ) {
SPI_BEGIN_TRANSACTION
SPI_CS_LOW
spi_command ( val ) ;
SPI_CS_HIGH
SPI_END_TRANSACTION
}
void uDisplay : : Init_EPD ( int8_t p ) {
if ( p = = DISPLAY_INIT_PARTIAL ) {
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if ( lutpsize ) {
SetLut ( lut_partial ) ;
}
} else {
if ( lutfsize ) {
SetLut ( lut_full ) ;
}
if ( lut_cnt [ 0 ] ) {
SetLuts ( ) ;
}
}
if ( ep_mode = = 1 ) {
ClearFrameMemory ( 0xFF ) ;
Updateframe_EPD ( ) ;
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} else {
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ClearFrame_42 ( ) ;
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}
if ( p = = DISPLAY_INIT_PARTIAL ) {
delay ( lutptime * 10 ) ;
} else {
delay ( lutftime * 10 ) ;
}
}
void uDisplay : : ClearFrameMemory ( unsigned char color ) {
SetMemoryArea ( 0 , 0 , gxs - 1 , gys - 1 ) ;
SetMemoryPointer ( 0 , 0 ) ;
spi_command_EPD ( WRITE_RAM ) ;
/* send the color data */
for ( int i = 0 ; i < gxs / 8 * gys ; i + + ) {
spi_data8_EPD ( color ) ;
}
}
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void uDisplay : : SetLuts ( void ) {
uint8_t index , count ;
for ( index = 0 ; index < 5 ; index + + ) {
spi_command_EPD ( lut_cmd [ index ] ) ; //vcom
for ( count = 0 ; count < lut_cnt [ index ] ; count + + ) {
spi_data8_EPD ( lut_array [ count ] [ index ] ) ;
}
}
}
void uDisplay : : DisplayFrame_42 ( void ) {
uint16_t Width , Height ;
Width = ( gxs % 8 = = 0 ) ? ( gxs / 8 ) : ( gxs / 8 + 1 ) ;
Height = gys ;
spi_command_EPD ( saw_2 ) ;
for ( uint16_t j = 0 ; j < Height ; j + + ) {
for ( uint16_t i = 0 ; i < Width ; i + + ) {
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spi_data8_EPD ( framebuffer [ i + j * Width ] ^ 0xff ) ;
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}
}
spi_command_EPD ( saw_3 ) ;
delay ( 100 ) ;
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Serial . printf ( " EPD Diplayframe \n " ) ;
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}
void uDisplay : : ClearFrame_42 ( void ) {
uint16_t Width , Height ;
Width = ( gxs % 8 = = 0 ) ? ( gxs / 8 ) : ( gxs / 8 + 1 ) ;
Height = gys ;
spi_command_EPD ( saw_1 ) ;
for ( uint16_t j = 0 ; j < Height ; j + + ) {
for ( uint16_t i = 0 ; i < Width ; i + + ) {
spi_data8_EPD ( 0xFF ) ;
}
}
spi_command_EPD ( saw_2 ) ;
for ( uint16_t j = 0 ; j < Height ; j + + ) {
for ( uint16_t i = 0 ; i < Width ; i + + ) {
spi_data8_EPD ( 0xFF ) ;
}
}
spi_command_EPD ( saw_3 ) ;
delay ( 100 ) ;
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Serial . printf ( " EPD Clearframe \n " ) ;
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}
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void uDisplay : : SetLut ( const unsigned char * lut ) {
spi_command_EPD ( WRITE_LUT_REGISTER ) ;
/* the length of look-up table is 30 bytes */
for ( int i = 0 ; i < lutfsize ; i + + ) {
spi_data8_EPD ( lut [ i ] ) ;
}
}
void uDisplay : : Updateframe_EPD ( void ) {
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if ( ep_mode = = 1 ) {
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SetFrameMemory ( framebuffer , 0 , 0 , gxs , gys ) ;
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DisplayFrame_29 ( ) ;
} else {
DisplayFrame_42 ( ) ;
}
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}
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void uDisplay : : DisplayFrame_29 ( void ) {
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spi_command_EPD ( DISPLAY_UPDATE_CONTROL_2 ) ;
spi_data8_EPD ( 0xC4 ) ;
spi_command_EPD ( MASTER_ACTIVATION ) ;
spi_data8_EPD ( TERMINATE_FRAME_READ_WRITE ) ;
}
void uDisplay : : SetMemoryArea ( int x_start , int y_start , int x_end , int y_end ) {
spi_command_EPD ( SET_RAM_X_ADDRESS_START_END_POSITION ) ;
/* x point must be the multiple of 8 or the last 3 bits will be ignored */
spi_data8_EPD ( ( x_start > > 3 ) & 0xFF ) ;
spi_data8_EPD ( ( x_end > > 3 ) & 0xFF ) ;
spi_command_EPD ( SET_RAM_Y_ADDRESS_START_END_POSITION ) ;
spi_data8_EPD ( y_start & 0xFF ) ;
spi_data8_EPD ( ( y_start > > 8 ) & 0xFF ) ;
spi_data8_EPD ( y_end & 0xFF ) ;
spi_data8_EPD ( ( y_end > > 8 ) & 0xFF ) ;
}
void uDisplay : : SetFrameMemory ( const unsigned char * image_buffer ) {
SetMemoryArea ( 0 , 0 , gxs - 1 , gys - 1 ) ;
SetMemoryPointer ( 0 , 0 ) ;
spi_command_EPD ( WRITE_RAM ) ;
/* send the image data */
for ( int i = 0 ; i < gxs / 8 * gys ; i + + ) {
spi_data8_EPD ( image_buffer [ i ] ^ 0xff ) ;
}
}
void uDisplay : : SetMemoryPointer ( int x , int y ) {
spi_command_EPD ( SET_RAM_X_ADDRESS_COUNTER ) ;
/* x point must be the multiple of 8 or the last 3 bits will be ignored */
spi_data8_EPD ( ( x > > 3 ) & 0xFF ) ;
spi_command_EPD ( SET_RAM_Y_ADDRESS_COUNTER ) ;
spi_data8_EPD ( y & 0xFF ) ;
spi_data8_EPD ( ( y > > 8 ) & 0xFF ) ;
}
void uDisplay : : SetFrameMemory (
const unsigned char * image_buffer ,
uint16_t x ,
uint16_t y ,
uint16_t image_width ,
uint16_t image_height
) {
uint16_t x_end ;
uint16_t y_end ;
if (
image_buffer = = NULL | |
x < 0 | | image_width < 0 | |
y < 0 | | image_height < 0
) {
return ;
}
/* x point must be the multiple of 8 or the last 3 bits will be ignored */
x & = 0xFFF8 ;
image_width & = 0xFFF8 ;
if ( x + image_width > = gxs ) {
x_end = gxs - 1 ;
} else {
x_end = x + image_width - 1 ;
}
if ( y + image_height > = gys ) {
y_end = gys - 1 ;
} else {
y_end = y + image_height - 1 ;
}
if ( ! x & & ! y & & image_width = = gxs & & image_height = = gys ) {
SetFrameMemory ( image_buffer ) ;
return ;
}
SetMemoryArea ( x , y , x_end , y_end ) ;
SetMemoryPointer ( x , y ) ;
spi_command_EPD ( WRITE_RAM ) ;
/* send the image data */
for ( uint16_t j = 0 ; j < y_end - y + 1 ; j + + ) {
for ( uint16_t i = 0 ; i < ( x_end - x + 1 ) / 8 ; i + + ) {
spi_data8_EPD ( image_buffer [ i + j * ( image_width / 8 ) ] ^ 0xff ) ;
}
}
}
# define IF_INVERT_COLOR 1
# define renderer_swap(a, b) { int16_t t = a; a = b; b = t; }
/**
* @ brief : this draws a pixel by absolute coordinates .
* this function won ' t be affected by the rotate parameter .
* we must use this for epaper because these displays have a strange and different bit pattern
*/
void uDisplay : : DrawAbsolutePixel ( int x , int y , int16_t color ) {
int16_t w = width ( ) , h = height ( ) ;
if ( cur_rot = = 1 | | cur_rot = = 3 ) {
renderer_swap ( w , h ) ;
}
if ( x < 0 | | x > = w | | y < 0 | | y > = h ) {
return ;
}
if ( IF_INVERT_COLOR ) {
if ( color ) {
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framebuffer [ ( x + y * w ) / 8 ] | = 0x80 > > ( x % 8 ) ;
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} else {
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framebuffer [ ( x + y * w ) / 8 ] & = ~ ( 0x80 > > ( x % 8 ) ) ;
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}
} else {
if ( color ) {
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framebuffer [ ( x + y * w ) / 8 ] & = ~ ( 0x80 > > ( x % 8 ) ) ;
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} else {
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framebuffer [ ( x + y * w ) / 8 ] | = 0x80 > > ( x % 8 ) ;
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}
}
}
void uDisplay : : drawPixel_EPD ( int16_t x , int16_t y , uint16_t color ) {
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if ( ! framebuffer ) return ;
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if ( ( x < 0 ) | | ( x > = width ( ) ) | | ( y < 0 ) | | ( y > = height ( ) ) )
return ;
// check rotation, move pixel around if necessary
switch ( cur_rot ) {
case 1 :
renderer_swap ( x , y ) ;
x = gxs - x - 1 ;
break ;
case 2 :
x = gxs - x - 1 ;
y = gys - y - 1 ;
break ;
case 3 :
renderer_swap ( x , y ) ;
y = gys - y - 1 ;
break ;
}
// x is which column
DrawAbsolutePixel ( x , y , color ) ;
}
void uDisplay : : fillRect_EPD ( int16_t x , int16_t y , int16_t w , int16_t h , uint16_t color ) {
for ( uint32_t yp = y ; yp < y + h ; yp + + ) {
for ( uint32_t xp = x ; xp < x + w ; xp + + ) {
drawPixel_EPD ( xp , yp , color ) ;
}
}
}
void uDisplay : : drawFastVLine_EPD ( int16_t x , int16_t y , int16_t h , uint16_t color ) {
while ( h - - ) {
drawPixel_EPD ( x , y , color ) ;
y + + ;
}
}
void uDisplay : : drawFastHLine_EPD ( int16_t x , int16_t y , int16_t w , uint16_t color ) {
while ( w - - ) {
drawPixel_EPD ( x , y , color ) ;
x + + ;
}
}
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void uDisplay : : beginTransaction ( SPISettings s ) {
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# ifdef ESP32
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if ( lvgl_param . use_dma ) {
dmaWait ( ) ;
}
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# endif
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uspi - > beginTransaction ( s ) ;
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}
void uDisplay : : endTransaction ( void ) {
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uspi - > endTransaction ( ) ;
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}
// ESP 32 DMA section , derived from TFT_eSPI
# ifdef ESP32
/***************************************************************************************
* * Function name : initDMA
* * Description : Initialise the DMA engine - returns true if init OK
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
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bool uDisplay : : initDMA ( int32_t ctrl_cs )
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{
if ( DMA_Enabled ) return false ;
esp_err_t ret ;
spi_bus_config_t buscfg = {
. mosi_io_num = spi_mosi ,
. miso_io_num = - 1 ,
. sclk_io_num = spi_clk ,
. quadwp_io_num = - 1 ,
. quadhd_io_num = - 1 ,
. max_transfer_sz = width ( ) * height ( ) * 2 + 8 , // TFT screen size
. flags = 0 ,
. intr_flags = 0
} ;
spi_device_interface_config_t devcfg = {
. command_bits = 0 ,
. address_bits = 0 ,
. dummy_bits = 0 ,
. mode = SPI_MODE3 ,
. duty_cycle_pos = 0 ,
. cs_ena_pretrans = 0 ,
. cs_ena_posttrans = 0 ,
. clock_speed_hz = spi_speed * 1000000 ,
. input_delay_ns = 0 ,
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. spics_io_num = ctrl_cs ,
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. flags = SPI_DEVICE_NO_DUMMY , //0,
. queue_size = 1 ,
. pre_cb = 0 , //dc_callback, //Callback to handle D/C line
. post_cb = 0
} ;
ret = spi_bus_initialize ( spi_host , & buscfg , 1 ) ;
ESP_ERROR_CHECK ( ret ) ;
ret = spi_bus_add_device ( spi_host , & devcfg , & dmaHAL ) ;
ESP_ERROR_CHECK ( ret ) ;
DMA_Enabled = true ;
spiBusyCheck = 0 ;
return true ;
}
/***************************************************************************************
* * Function name : deInitDMA
* * Description : Disconnect the DMA engine from SPI
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
void uDisplay : : deInitDMA ( void ) {
if ( ! DMA_Enabled ) return ;
spi_bus_remove_device ( dmaHAL ) ;
spi_bus_free ( spi_host ) ;
DMA_Enabled = false ;
}
/***************************************************************************************
* * Function name : dmaBusy
* * Description : Check if DMA is busy
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
bool uDisplay : : dmaBusy ( void ) {
if ( ! DMA_Enabled | | ! spiBusyCheck ) return false ;
spi_transaction_t * rtrans ;
esp_err_t ret ;
uint8_t checks = spiBusyCheck ;
for ( int i = 0 ; i < checks ; + + i ) {
ret = spi_device_get_trans_result ( dmaHAL , & rtrans , 0 ) ;
if ( ret = = ESP_OK ) spiBusyCheck - - ;
}
//Serial.print("spiBusyCheck=");Serial.println(spiBusyCheck);
if ( spiBusyCheck = = 0 ) return false ;
return true ;
}
/***************************************************************************************
* * Function name : dmaWait
* * Description : Wait until DMA is over ( blocking ! )
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
void uDisplay : : dmaWait ( void ) {
if ( ! DMA_Enabled | | ! spiBusyCheck ) return ;
spi_transaction_t * rtrans ;
esp_err_t ret ;
for ( int i = 0 ; i < spiBusyCheck ; + + i ) {
ret = spi_device_get_trans_result ( dmaHAL , & rtrans , portMAX_DELAY ) ;
assert ( ret = = ESP_OK ) ;
}
spiBusyCheck = 0 ;
}
/***************************************************************************************
* * Function name : pushPixelsDMA
* * Description : Push pixels to TFT ( len must be less than 32767 )
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// This will byte swap the original image if setSwapBytes(true) was called by sketch.
void uDisplay : : pushPixelsDMA ( uint16_t * image , uint32_t len ) {
if ( ( len = = 0 ) | | ( ! DMA_Enabled ) ) return ;
dmaWait ( ) ;
esp_err_t ret ;
memset ( & trans , 0 , sizeof ( spi_transaction_t ) ) ;
trans . user = ( void * ) 1 ;
trans . tx_buffer = image ; //finally send the line data
trans . length = len * 16 ; //Data length, in bits
trans . flags = 0 ; //SPI_TRANS_USE_TXDATA flag
ret = spi_device_queue_trans ( dmaHAL , & trans , portMAX_DELAY ) ;
assert ( ret = = ESP_OK ) ;
spiBusyCheck + + ;
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if ( ! lvgl_param . async_dma ) {
dmaWait ( ) ;
}
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}
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/***************************************************************************************
* * Function name : pushPixelsDMA
* * Description : Push pixels to TFT ( len must be less than 32767 )
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// This will byte swap the original image if setSwapBytes(true) was called by sketch.
void uDisplay : : pushPixels3DMA ( uint8_t * image , uint32_t len ) {
if ( ( len = = 0 ) | | ( ! DMA_Enabled ) ) return ;
dmaWait ( ) ;
esp_err_t ret ;
memset ( & trans , 0 , sizeof ( spi_transaction_t ) ) ;
trans . user = ( void * ) 1 ;
trans . tx_buffer = image ; //finally send the line data
trans . length = len * 24 ; //Data length, in bits
trans . flags = 0 ; //SPI_TRANS_USE_TXDATA flag
ret = spi_device_queue_trans ( dmaHAL , & trans , portMAX_DELAY ) ;
assert ( ret = = ESP_OK ) ;
spiBusyCheck + + ;
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if ( ! lvgl_param . async_dma ) {
dmaWait ( ) ;
}
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}
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# endif // ESP32