// Copyright (C) 2024, Mark Qvist
// 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 <https://www.gnu.org/licenses/>.
# include "Graphics.h"
# include <Adafruit_GFX.h>
# if BOARD_MODEL == BOARD_TDECK
# include <Adafruit_ST7789.h>
# elif BOARD_MODEL == BOARD_HELTEC_T114
# include "ST7789Spi.h"
# define COLOR565(r, g, b) (((r & 0xF8) << 8) | ((g & 0xFC) << 3) | ((b & 0xF8) >> 3))
# elif BOARD_MODEL == BOARD_TBEAM_S_V1
# include <Adafruit_SH110X.h>
# else
# include <Wire.h>
# include <Adafruit_SSD1306.h>
# endif
# include "Fonts/Org_01.h"
# define DISP_W 128
# define DISP_H 64
# if BOARD_MODEL == BOARD_RNODE_NG_20 || BOARD_MODEL == BOARD_LORA32_V2_0
# define DISP_RST -1
# define DISP_ADDR 0x3C
# elif BOARD_MODEL == BOARD_TBEAM
# define DISP_RST 13
# define DISP_ADDR 0x3C
# define DISP_CUSTOM_ADDR true
# elif BOARD_MODEL == BOARD_HELTEC32_V2 || BOARD_MODEL == BOARD_LORA32_V1_0
# define DISP_RST 16
# define DISP_ADDR 0x3C
# define SCL_OLED 15
# define SDA_OLED 4
# elif BOARD_MODEL == BOARD_HELTEC32_V3
# define DISP_RST 21
# define DISP_ADDR 0x3C
# define SCL_OLED 18
# define SDA_OLED 17
# elif BOARD_MODEL == BOARD_RAK4631
// RAK1921/SSD1306
# define DISP_RST -1
# define DISP_ADDR 0x3C
# define SCL_OLED 14
# define SDA_OLED 13
# elif BOARD_MODEL == BOARD_RNODE_NG_21
# define DISP_RST -1
# define DISP_ADDR 0x3C
# elif BOARD_MODEL == BOARD_RNODE_NG_22
# define DISP_RST 21
# define DISP_ADDR 0x3C
# define SCL_OLED 17
# define SDA_OLED 18
# elif BOARD_MODEL == BOARD_TBEAM_S_V1
# define DISP_RST -1
# define DISP_ADDR 0x3C
# define SCL_OLED 18
# define SDA_OLED 17
# define DISP_CUSTOM_ADDR false
# else
# define DISP_RST -1
# define DISP_ADDR 0x3C
# define DISP_CUSTOM_ADDR true
# endif
# define SMALL_FONT &Org_01
# if BOARD_MODEL == BOARD_TDECK
Adafruit_ST7789 display = Adafruit_ST7789 ( DISPLAY_CS , DISPLAY_DC , - 1 ) ;
# define SSD1306_WHITE ST77XX_WHITE
# define SSD1306_BLACK ST77XX_BLACK
# elif BOARD_MODEL == BOARD_HELTEC_T114
ST7789Spi display ( & SPI1 , DISPLAY_RST , DISPLAY_DC , DISPLAY_CS ) ;
# define SSD1306_WHITE ST77XX_WHITE
# define SSD1306_BLACK ST77XX_BLACK
# elif BOARD_MODEL == BOARD_TBEAM_S_V1
Adafruit_SH1106G display = Adafruit_SH1106G ( 128 , 64 , & Wire , - 1 ) ;
# define SSD1306_WHITE SH110X_WHITE
# define SSD1306_BLACK SH110X_BLACK
# else
Adafruit_SSD1306 display ( DISP_W , DISP_H , & Wire , DISP_RST ) ;
# endif
# define DISP_MODE_UNKNOWN 0x00
# define DISP_MODE_LANDSCAPE 0x01
# define DISP_MODE_PORTRAIT 0x02
# define DISP_PIN_SIZE 6
# define DISPLAY_BLANKING_TIMEOUT 15*1000
uint8_t disp_mode = DISP_MODE_UNKNOWN ;
uint8_t disp_ext_fb = false ;
unsigned char fb [ 512 ] ;
uint32_t last_disp_update = 0 ;
uint32_t last_unblank_event = 0 ;
uint32_t display_blanking_timeout = DISPLAY_BLANKING_TIMEOUT ;
uint8_t display_unblank_intensity = display_intensity ;
bool display_blanked = false ;
bool display_tx = false ;
bool recondition_display = false ;
uint8_t disp_target_fps = 7 ;
int disp_update_interval = 1000 / disp_target_fps ;
uint32_t last_page_flip = 0 ;
int page_interval = 4000 ;
bool device_signatures_ok ( ) ;
bool device_firmware_ok ( ) ;
# define WATERFALL_SIZE 46
int waterfall [ WATERFALL_SIZE ] ;
int waterfall_head = 0 ;
int p_ad_x = 0 ;
int p_ad_y = 0 ;
int p_as_x = 0 ;
int p_as_y = 0 ;
GFXcanvas1 stat_area ( 64 , 64 ) ;
GFXcanvas1 disp_area ( 64 , 64 ) ;
void update_area_positions ( ) {
if ( disp_mode = = DISP_MODE_PORTRAIT ) {
p_ad_x = 0 * DISPLAY_SCALE ;
p_ad_y = 0 * DISPLAY_SCALE ;
p_as_x = 0 * DISPLAY_SCALE ;
p_as_y = 64 * DISPLAY_SCALE ;
} else if ( disp_mode = = DISP_MODE_LANDSCAPE ) {
p_ad_x = 0 * DISPLAY_SCALE ;
p_ad_y = 0 * DISPLAY_SCALE ;
p_as_x = 64 * DISPLAY_SCALE ;
p_as_y = 0 * DISPLAY_SCALE ;
}
}
uint8_t display_contrast = 0x00 ;
# if BOARD_MODEL == BOARD_TBEAM_S_V1
void set_contrast ( Adafruit_SH1106G * display , uint8_t value ) {
}
# elif BOARD_MODEL == BOARD_HELTEC_T114
void set_contrast ( ST7789Spi * display , uint8_t value ) {
}
# elif BOARD_MODEL == BOARD_TDECK
void set_contrast ( Adafruit_ST7789 * display , uint8_t value ) {
static uint8_t level = 0 ;
static uint8_t steps = 16 ;
if ( value > 15 ) value = 15 ;
if ( value = = 0 ) {
digitalWrite ( DISPLAY_BL_PIN , 0 ) ;
delay ( 3 ) ;
level = 0 ;
return ;
}
if ( level = = 0 ) {
digitalWrite ( DISPLAY_BL_PIN , 1 ) ;
level = steps ;
delayMicroseconds ( 30 ) ;
}
int from = steps - level ;
int to = steps - value ;
int num = ( steps + to - from ) % steps ;
for ( int i = 0 ; i < num ; i + + ) {
digitalWrite ( DISPLAY_BL_PIN , 0 ) ;
digitalWrite ( DISPLAY_BL_PIN , 1 ) ;
}
level = value ;
}
# else
void set_contrast ( Adafruit_SSD1306 * display , uint8_t contrast ) {
display - > ssd1306_command ( SSD1306_SETCONTRAST ) ;
display - > ssd1306_command ( contrast ) ;
}
# endif
bool display_init ( ) {
# if HAS_DISPLAY
# if BOARD_MODEL == BOARD_RNODE_NG_20 || BOARD_MODEL == BOARD_LORA32_V2_0
int pin_display_en = 16 ;
digitalWrite ( pin_display_en , LOW ) ;
delay ( 50 ) ;
digitalWrite ( pin_display_en , HIGH ) ;
# elif BOARD_MODEL == BOARD_RNODE_NG_22
Wire . begin ( SDA_OLED , SCL_OLED ) ;
# elif BOARD_MODEL == BOARD_HELTEC32_V2
Wire . begin ( SDA_OLED , SCL_OLED ) ;
# elif BOARD_MODEL == BOARD_HELTEC32_V3
// enable vext / pin 36
pinMode ( Vext , OUTPUT ) ;
digitalWrite ( Vext , LOW ) ;
delay ( 50 ) ;
int pin_display_en = 21 ;
pinMode ( pin_display_en , OUTPUT ) ;
digitalWrite ( pin_display_en , LOW ) ;
delay ( 50 ) ;
digitalWrite ( pin_display_en , HIGH ) ;
delay ( 50 ) ;
Wire . begin ( SDA_OLED , SCL_OLED ) ;
# elif BOARD_MODEL == BOARD_LORA32_V1_0
int pin_display_en = 16 ;
digitalWrite ( pin_display_en , LOW ) ;
delay ( 50 ) ;
digitalWrite ( pin_display_en , HIGH ) ;
Wire . begin ( SDA_OLED , SCL_OLED ) ;
# elif BOARD_MODEL == BOARD_HELTEC_T114
// enable vext (not required for screen to work, but is done in Heltec example)
digitalWrite ( PIN_T114_VEXT_EN , HIGH ) ;
pinMode ( PIN_T114_VEXT_EN , OUTPUT ) ;
// enable power to display
digitalWrite ( PIN_T114_TFT_EN , LOW ) ;
pinMode ( PIN_T114_TFT_EN , OUTPUT ) ;
// enable backlight led (display is always black without this)
digitalWrite ( PIN_T114_TFT_BLGT , LOW ) ;
pinMode ( PIN_T114_TFT_BLGT , OUTPUT ) ;
// enable adc (not required for screen to work, but is done in Heltec example)
digitalWrite ( PIN_T114_ADC_EN , HIGH ) ;
pinMode ( PIN_T114_ADC_EN , OUTPUT ) ;
# elif BOARD_MODEL == BOARD_TBEAM_S_V1
Wire . begin ( SDA_OLED , SCL_OLED ) ;
# endif
# if HAS_EEPROM
uint8_t display_rotation = EEPROM . read ( eeprom_addr ( ADDR_CONF_DROT ) ) ;
# elif MCU_VARIANT == MCU_NRF52
uint8_t display_rotation = eeprom_read ( eeprom_addr ( ADDR_CONF_DROT ) ) ;
# endif
if ( display_rotation < 0 or display_rotation > 3 ) display_rotation = 0xFF ;
# if DISP_CUSTOM_ADDR == true
# if HAS_EEPROM
uint8_t display_address = EEPROM . read ( eeprom_addr ( ADDR_CONF_DADR ) ) ;
# elif MCU_VARIANT == MCU_NRF52
uint8_t display_address = eeprom_read ( eeprom_addr ( ADDR_CONF_DADR ) ) ;
# endif
if ( display_address = = 0xFF ) display_address = DISP_ADDR ;
# else
uint8_t display_address = DISP_ADDR ;
# endif
# if HAS_EEPROM
if ( EEPROM . read ( eeprom_addr ( ADDR_CONF_BSET ) ) = = CONF_OK_BYTE ) {
uint8_t db_timeout = EEPROM . read ( eeprom_addr ( ADDR_CONF_DBLK ) ) ;
if ( db_timeout = = 0x00 ) {
display_blanking_enabled = false ;
} else {
display_blanking_enabled = true ;
display_blanking_timeout = db_timeout * 1000 ;
}
}
# endif
# if BOARD_MODEL == BOARD_TDECK
display . init ( 240 , 320 ) ;
display . setSPISpeed ( 80e6 ) ;
# elif BOARD_MODEL == BOARD_HELTEC_T114
display . init ( ) ;
// set white as default pixel colour for Heltec T114
display . setRGB ( COLOR565 ( 0xFF , 0xFF , 0xFF ) ) ;
if ( false ) {
# elif BOARD_MODEL == BOARD_TBEAM_S_V1
if ( ! display . begin ( display_address , true ) ) {
# else
if ( ! display . begin ( SSD1306_SWITCHCAPVCC , display_address ) ) {
# endif
return false ;
} else {
set_contrast ( & display , display_contrast ) ;
if ( display_rotation ! = 0xFF ) {
if ( display_rotation = = 0 | | display_rotation = = 2 ) {
disp_mode = DISP_MODE_LANDSCAPE ;
} else {
disp_mode = DISP_MODE_PORTRAIT ;
}
# if BOARD_MODEL != BOARD_HELTEC_T114
display . setRotation ( display_rotation ) ;
# endif
} else {
# if BOARD_MODEL == BOARD_RNODE_NG_20
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 3 ) ;
# elif BOARD_MODEL == BOARD_RNODE_NG_21
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 3 ) ;
# elif BOARD_MODEL == BOARD_LORA32_V1_0
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 3 ) ;
# elif BOARD_MODEL == BOARD_LORA32_V2_0
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 3 ) ;
# elif BOARD_MODEL == BOARD_LORA32_V2_1
disp_mode = DISP_MODE_LANDSCAPE ;
display . setRotation ( 0 ) ;
# elif BOARD_MODEL == BOARD_TBEAM
disp_mode = DISP_MODE_LANDSCAPE ;
display . setRotation ( 0 ) ;
# elif BOARD_MODEL == BOARD_TBEAM_S_V1
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 1 ) ;
# elif BOARD_MODEL == BOARD_HELTEC32_V2
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 1 ) ;
# elif BOARD_MODEL == BOARD_HELTEC32_V3
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 1 ) ;
# elif BOARD_MODEL == BOARD_HELTEC_T114
disp_mode = DISP_MODE_LANDSCAPE ;
# elif BOARD_MODEL == BOARD_RAK4631
disp_mode = DISP_MODE_LANDSCAPE ;
display . setRotation ( 0 ) ;
# elif BOARD_MODEL == BOARD_TDECK
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 3 ) ;
# else
disp_mode = DISP_MODE_PORTRAIT ;
display . setRotation ( 3 ) ;
# endif
}
update_area_positions ( ) ;
for ( int i = 0 ; i < WATERFALL_SIZE ; i + + ) {
waterfall [ i ] = 0 ;
}
last_page_flip = millis ( ) ;
stat_area . cp437 ( true ) ;
disp_area . cp437 ( true ) ;
# if BOARD_MODEL != BOARD_HELTEC_T114
display . cp437 ( true ) ;
# endif
# if HAS_EEPROM
# if MCU_VARIANT != MCU_NRF52
display_intensity = EEPROM . read ( eeprom_addr ( ADDR_CONF_DINT ) ) ;
# else
display_intensity = eeprom_read ( eeprom_addr ( ADDR_CONF_DINT ) ) ;
# endif
# endif
# if BOARD_MODEL == BOARD_TDECK
display . fillScreen ( SSD1306_BLACK ) ;
# endif
return true ;
}
# else
return false ;
# endif
}
// draws a line on the screen
void drawLine ( int16_t x , int16_t y , int16_t width , int16_t height , uint16_t colour ) {
# if BOARD_MODEL == BOARD_HELTEC_T114
if ( colour = = SSD1306_WHITE ) {
display . setColor ( WHITE ) ;
} else if ( colour = = SSD1306_BLACK ) {
display . setColor ( BLACK ) ;
}
display . drawLine ( x , y , width , height ) ;
# else
display . drawLine ( x , y , width , height , colour ) ;
# endif
}
// draws a filled rectangle on the screen
void fillRect ( int16_t x , int16_t y , int16_t width , int16_t height , uint16_t colour ) {
# if BOARD_MODEL == BOARD_HELTEC_T114
if ( colour = = SSD1306_WHITE ) {
display . setColor ( WHITE ) ;
} else if ( colour = = SSD1306_BLACK ) {
display . setColor ( BLACK ) ;
}
display . fillRect ( x , y , width , height ) ;
# else
display . fillRect ( x , y , width , height , colour ) ;
# endif
}
// draws a bitmap to the display and auto scales it based on the boards configured DISPLAY_SCALE
void drawBitmap ( int16_t startX , int16_t startY , const uint8_t * bitmap , int16_t bitmapWidth , int16_t bitmapHeight , uint16_t foregroundColour , uint16_t backgroundColour ) {
# if DISPLAY_SCALE == 1
display . drawBitmap ( startX , startY , bitmap , bitmapWidth , bitmapHeight , foregroundColour , backgroundColour ) ;
# else
for ( int16_t row = 0 ; row < bitmapHeight ; row + + ) {
for ( int16_t col = 0 ; col < bitmapWidth ; col + + ) {
// determine index and bitmask
int16_t index = row * ( ( bitmapWidth + 7 ) / 8 ) + ( col / 8 ) ;
uint8_t bitmask = 1 < < ( 7 - ( col % 8 ) ) ;
// check if the current pixel is set in the bitmap
if ( bitmap [ index ] & bitmask ) {
// draw a scaled rectangle for the foreground pixel
fillRect ( startX + col * DISPLAY_SCALE , startY + row * DISPLAY_SCALE , DISPLAY_SCALE , DISPLAY_SCALE , foregroundColour ) ;
} else {
// draw a scaled rectangle for the background pixel
fillRect ( startX + col * DISPLAY_SCALE , startY + row * DISPLAY_SCALE , DISPLAY_SCALE , DISPLAY_SCALE , backgroundColour ) ;
}
}
}
# endif
}
void draw_cable_icon ( int px , int py ) {
if ( cable_state = = CABLE_STATE_DISCONNECTED ) {
stat_area . drawBitmap ( px , py , bm_cable + 0 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else if ( cable_state = = CABLE_STATE_CONNECTED ) {
stat_area . drawBitmap ( px , py , bm_cable + 1 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
void draw_bt_icon ( int px , int py ) {
if ( bt_state = = BT_STATE_OFF ) {
stat_area . drawBitmap ( px , py , bm_bt + 0 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else if ( bt_state = = BT_STATE_ON ) {
stat_area . drawBitmap ( px , py , bm_bt + 1 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else if ( bt_state = = BT_STATE_PAIRING ) {
stat_area . drawBitmap ( px , py , bm_bt + 2 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else if ( bt_state = = BT_STATE_CONNECTED ) {
stat_area . drawBitmap ( px , py , bm_bt + 3 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
stat_area . drawBitmap ( px , py , bm_bt + 0 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
void draw_lora_icon ( int px , int py ) {
if ( radio_online ) {
stat_area . drawBitmap ( px , py , bm_rf + 1 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
stat_area . drawBitmap ( px , py , bm_rf + 0 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
void draw_mw_icon ( int px , int py ) {
if ( mw_radio_online ) {
stat_area . drawBitmap ( px , py , bm_rf + 3 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
stat_area . drawBitmap ( px , py , bm_rf + 2 * 32 , 16 , 16 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
uint8_t charge_tick = 0 ;
void draw_battery_bars ( int px , int py ) {
if ( pmu_ready ) {
if ( battery_ready ) {
if ( battery_installed ) {
float battery_value = battery_percent ;
// Disable charging state display for now, since
// boards without dedicated PMU are completely
// unreliable for determining actual charging state.
bool disable_charge_status = false ;
if ( battery_indeterminate & & battery_state = = BATTERY_STATE_CHARGING ) {
disable_charge_status = true ;
}
if ( battery_state = = BATTERY_STATE_CHARGING & & ! disable_charge_status ) {
battery_value = charge_tick ;
charge_tick + = 3 ;
if ( charge_tick > 100 ) charge_tick = 0 ;
}
if ( battery_indeterminate & & battery_state = = BATTERY_STATE_CHARGING & & ! disable_charge_status ) {
stat_area . fillRect ( px - 2 , py - 2 , 18 , 7 , SSD1306_BLACK ) ;
stat_area . drawBitmap ( px - 2 , py - 2 , bm_plug , 17 , 7 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
if ( battery_state = = BATTERY_STATE_CHARGED ) {
stat_area . fillRect ( px - 2 , py - 2 , 18 , 7 , SSD1306_BLACK ) ;
stat_area . drawBitmap ( px - 2 , py - 2 , bm_plug , 17 , 7 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
// stat_area.fillRect(px, py, 14, 3, SSD1306_BLACK);
stat_area . fillRect ( px - 2 , py - 2 , 18 , 7 , SSD1306_BLACK ) ;
stat_area . drawRect ( px - 2 , py - 2 , 17 , 7 , SSD1306_WHITE ) ;
stat_area . drawLine ( px + 15 , py , px + 15 , py + 3 , SSD1306_WHITE ) ;
if ( battery_value > 7 ) stat_area . drawLine ( px , py , px , py + 2 , SSD1306_WHITE ) ;
if ( battery_value > 20 ) stat_area . drawLine ( px + 1 * 2 , py , px + 1 * 2 , py + 2 , SSD1306_WHITE ) ;
if ( battery_value > 33 ) stat_area . drawLine ( px + 2 * 2 , py , px + 2 * 2 , py + 2 , SSD1306_WHITE ) ;
if ( battery_value > 46 ) stat_area . drawLine ( px + 3 * 2 , py , px + 3 * 2 , py + 2 , SSD1306_WHITE ) ;
if ( battery_value > 59 ) stat_area . drawLine ( px + 4 * 2 , py , px + 4 * 2 , py + 2 , SSD1306_WHITE ) ;
if ( battery_value > 72 ) stat_area . drawLine ( px + 5 * 2 , py , px + 5 * 2 , py + 2 , SSD1306_WHITE ) ;
if ( battery_value > 85 ) stat_area . drawLine ( px + 6 * 2 , py , px + 6 * 2 , py + 2 , SSD1306_WHITE ) ;
}
}
} else {
stat_area . fillRect ( px - 2 , py - 2 , 18 , 7 , SSD1306_BLACK ) ;
stat_area . drawBitmap ( px - 2 , py - 2 , bm_plug , 17 , 7 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
} else {
stat_area . fillRect ( px - 2 , py - 2 , 18 , 7 , SSD1306_BLACK ) ;
stat_area . drawBitmap ( px - 2 , py - 2 , bm_plug , 17 , 7 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
# define Q_SNR_STEP 2.0
# define Q_SNR_MIN_BASE -9.0
# define Q_SNR_MAX 6.0
void draw_quality_bars ( int px , int py ) {
stat_area . fillRect ( px , py , 13 , 7 , SSD1306_BLACK ) ;
if ( radio_online ) {
signed char t_snr = ( signed int ) last_snr_raw ;
int snr_int = ( int ) t_snr ;
float snr_min = Q_SNR_MIN_BASE - ( int ) lora_sf * Q_SNR_STEP ;
float snr_span = ( Q_SNR_MAX - snr_min ) ;
float snr = ( ( int ) snr_int ) * 0.25 ;
float quality = ( ( snr - snr_min ) / ( snr_span ) ) * 100 ;
if ( quality > 100.0 ) quality = 100.0 ;
if ( quality < 0.0 ) quality = 0.0 ;
// Serial.printf("Last SNR: %.2f\n, quality: %.2f\n", snr, quality);
if ( quality > 0 ) stat_area . drawLine ( px + 0 * 2 , py + 7 , px + 0 * 2 , py + 6 , SSD1306_WHITE ) ;
if ( quality > 15 ) stat_area . drawLine ( px + 1 * 2 , py + 7 , px + 1 * 2 , py + 5 , SSD1306_WHITE ) ;
if ( quality > 30 ) stat_area . drawLine ( px + 2 * 2 , py + 7 , px + 2 * 2 , py + 4 , SSD1306_WHITE ) ;
if ( quality > 45 ) stat_area . drawLine ( px + 3 * 2 , py + 7 , px + 3 * 2 , py + 3 , SSD1306_WHITE ) ;
if ( quality > 60 ) stat_area . drawLine ( px + 4 * 2 , py + 7 , px + 4 * 2 , py + 2 , SSD1306_WHITE ) ;
if ( quality > 75 ) stat_area . drawLine ( px + 5 * 2 , py + 7 , px + 5 * 2 , py + 1 , SSD1306_WHITE ) ;
if ( quality > 90 ) stat_area . drawLine ( px + 6 * 2 , py + 7 , px + 6 * 2 , py + 0 , SSD1306_WHITE ) ;
}
}
# define S_RSSI_MIN -135.0
# define S_RSSI_MAX -75.0
# define S_RSSI_SPAN (S_RSSI_MAX-S_RSSI_MIN)
void draw_signal_bars ( int px , int py ) {
stat_area . fillRect ( px , py , 13 , 7 , SSD1306_BLACK ) ;
if ( radio_online ) {
int rssi_val = last_rssi ;
if ( rssi_val < S_RSSI_MIN ) rssi_val = S_RSSI_MIN ;
if ( rssi_val > S_RSSI_MAX ) rssi_val = S_RSSI_MAX ;
int signal = ( ( rssi_val - S_RSSI_MIN ) * ( 1.0 / S_RSSI_SPAN ) ) * 100.0 ;
if ( signal > 100.0 ) signal = 100.0 ;
if ( signal < 0.0 ) signal = 0.0 ;
// Serial.printf("Last SNR: %.2f\n, quality: %.2f\n", snr, quality);
if ( signal > 85 ) stat_area . drawLine ( px + 0 * 2 , py + 7 , px + 0 * 2 , py + 0 , SSD1306_WHITE ) ;
if ( signal > 72 ) stat_area . drawLine ( px + 1 * 2 , py + 7 , px + 1 * 2 , py + 1 , SSD1306_WHITE ) ;
if ( signal > 59 ) stat_area . drawLine ( px + 2 * 2 , py + 7 , px + 2 * 2 , py + 2 , SSD1306_WHITE ) ;
if ( signal > 46 ) stat_area . drawLine ( px + 3 * 2 , py + 7 , px + 3 * 2 , py + 3 , SSD1306_WHITE ) ;
if ( signal > 33 ) stat_area . drawLine ( px + 4 * 2 , py + 7 , px + 4 * 2 , py + 4 , SSD1306_WHITE ) ;
if ( signal > 20 ) stat_area . drawLine ( px + 5 * 2 , py + 7 , px + 5 * 2 , py + 5 , SSD1306_WHITE ) ;
if ( signal > 7 ) stat_area . drawLine ( px + 6 * 2 , py + 7 , px + 6 * 2 , py + 6 , SSD1306_WHITE ) ;
}
}
# if MODEM == SX1280
# define WF_TX_SIZE 3
# else
# define WF_TX_SIZE 5
# endif
# define WF_RSSI_MAX -60
# define WF_RSSI_MIN -135
# define WF_RSSI_SPAN (WF_RSSI_MAX-WF_RSSI_MIN)
# define WF_PIXEL_WIDTH 10
void draw_waterfall ( int px , int py ) {
int rssi_val = current_rssi ;
if ( rssi_val < WF_RSSI_MIN ) rssi_val = WF_RSSI_MIN ;
if ( rssi_val > WF_RSSI_MAX ) rssi_val = WF_RSSI_MAX ;
int rssi_normalised = ( ( rssi_val - WF_RSSI_MIN ) * ( 1.0 / WF_RSSI_SPAN ) ) * WF_PIXEL_WIDTH ;
if ( display_tx ) {
for ( uint8_t i ; i < WF_TX_SIZE ; i + + ) {
waterfall [ waterfall_head + + ] = - 1 ;
if ( waterfall_head > = WATERFALL_SIZE ) waterfall_head = 0 ;
}
display_tx = false ;
} else {
waterfall [ waterfall_head + + ] = rssi_normalised ;
if ( waterfall_head > = WATERFALL_SIZE ) waterfall_head = 0 ;
}
stat_area . fillRect ( px , py , WF_PIXEL_WIDTH , WATERFALL_SIZE , SSD1306_BLACK ) ;
for ( int i = 0 ; i < WATERFALL_SIZE ; i + + ) {
int wi = ( waterfall_head + i ) % WATERFALL_SIZE ;
int ws = waterfall [ wi ] ;
if ( ws > 0 ) {
stat_area . drawLine ( px , py + i , px + ws - 1 , py + i , SSD1306_WHITE ) ;
} else if ( ws = = - 1 ) {
uint8_t o = i % 2 ;
for ( uint8_t ti = 0 ; ti < WF_PIXEL_WIDTH / 2 ; ti + + ) {
stat_area . drawPixel ( px + ti * 2 + o , py + i , SSD1306_WHITE ) ;
}
}
}
}
bool stat_area_intialised = false ;
void draw_stat_area ( ) {
if ( device_init_done ) {
if ( ! stat_area_intialised ) {
stat_area . drawBitmap ( 0 , 0 , bm_frame , 64 , 64 , SSD1306_WHITE , SSD1306_BLACK ) ;
stat_area_intialised = true ;
}
draw_cable_icon ( 3 , 8 ) ;
draw_bt_icon ( 3 , 30 ) ;
draw_lora_icon ( 45 , 8 ) ;
draw_mw_icon ( 45 , 30 ) ;
draw_battery_bars ( 4 , 58 ) ;
draw_quality_bars ( 28 , 56 ) ;
draw_signal_bars ( 44 , 56 ) ;
if ( radio_online ) {
draw_waterfall ( 27 , 4 ) ;
}
}
}
void update_stat_area ( ) {
if ( eeprom_ok & & ! firmware_update_mode & & ! console_active ) {
draw_stat_area ( ) ;
if ( disp_mode = = DISP_MODE_PORTRAIT ) {
drawBitmap ( p_as_x , p_as_y , stat_area . getBuffer ( ) , stat_area . width ( ) , stat_area . height ( ) , SSD1306_WHITE , SSD1306_BLACK ) ;
} else if ( disp_mode = = DISP_MODE_LANDSCAPE ) {
drawBitmap ( p_as_x + 2 , p_as_y , stat_area . getBuffer ( ) , stat_area . width ( ) , stat_area . height ( ) , SSD1306_WHITE , SSD1306_BLACK ) ;
if ( device_init_done & & ! disp_ext_fb ) drawLine ( p_as_x , 0 , p_as_x , 64 , SSD1306_WHITE ) ;
}
} else {
if ( firmware_update_mode ) {
drawBitmap ( p_as_x , p_as_y , bm_updating , stat_area . width ( ) , stat_area . height ( ) , SSD1306_BLACK , SSD1306_WHITE ) ;
} else if ( console_active & & device_init_done ) {
drawBitmap ( p_as_x , p_as_y , bm_console , stat_area . width ( ) , stat_area . height ( ) , SSD1306_BLACK , SSD1306_WHITE ) ;
if ( disp_mode = = DISP_MODE_LANDSCAPE ) {
drawLine ( p_as_x , 0 , p_as_x , 64 , SSD1306_WHITE ) ;
}
}
}
}
# define START_PAGE 0
const uint8_t pages = 3 ;
uint8_t disp_page = START_PAGE ;
void draw_disp_area ( ) {
if ( ! device_init_done | | firmware_update_mode ) {
uint8_t p_by = 37 ;
if ( disp_mode = = DISP_MODE_LANDSCAPE | | firmware_update_mode ) {
p_by = 18 ;
disp_area . fillRect ( 0 , 0 , disp_area . width ( ) , disp_area . height ( ) , SSD1306_BLACK ) ;
}
if ( ! device_init_done ) disp_area . drawBitmap ( 0 , p_by , bm_boot , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
if ( firmware_update_mode ) disp_area . drawBitmap ( 0 , p_by , bm_fw_update , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
if ( ! disp_ext_fb or bt_ssp_pin ! = 0 ) {
if ( radio_online & & display_diagnostics ) {
disp_area . fillRect ( 0 , 8 , disp_area . width ( ) , 37 , SSD1306_BLACK ) ; disp_area . fillRect ( 0 , 37 , disp_area . width ( ) , 27 , SSD1306_WHITE ) ;
disp_area . setFont ( SMALL_FONT ) ; disp_area . setTextWrap ( false ) ; disp_area . setTextColor ( SSD1306_WHITE ) ;
disp_area . setCursor ( 2 , 13 ) ;
disp_area . print ( " On " ) ;
disp_area . setCursor ( 14 , 13 ) ;
disp_area . print ( " @ " ) ;
disp_area . setCursor ( 21 , 13 ) ;
disp_area . printf ( " %.1fKbps " , ( float ) lora_bitrate / 1000.0 ) ;
//disp_area.setCursor(31, 23-1);
disp_area . setCursor ( 2 , 23 - 1 ) ;
disp_area . print ( " Airtime: " ) ;
disp_area . setCursor ( 11 , 33 - 1 ) ;
if ( total_channel_util < 0.099 ) {
//disp_area.printf("%.1f%%", total_channel_util*100.0);
disp_area . printf ( " %.1f%% " , airtime * 100.0 ) ;
} else {
//disp_area.printf("%.0f%%", total_channel_util*100.0);
disp_area . printf ( " %.0f%% " , airtime * 100.0 ) ;
}
disp_area . drawBitmap ( 2 , 26 - 1 , bm_hg_low , 5 , 9 , SSD1306_WHITE , SSD1306_BLACK ) ;
disp_area . setCursor ( 32 + 11 , 33 - 1 ) ;
if ( longterm_channel_util < 0.099 ) {
//disp_area.printf("%.1f%%", longterm_channel_util*100.0);
disp_area . printf ( " %.1f%% " , longterm_airtime * 100.0 ) ;
} else {
//disp_area.printf("%.0f%%", longterm_channel_util*100.0);
disp_area . printf ( " %.0f%% " , longterm_airtime * 100.0 ) ;
}
disp_area . drawBitmap ( 32 + 2 , 26 - 1 , bm_hg_high , 5 , 9 , SSD1306_WHITE , SSD1306_BLACK ) ;
disp_area . setTextColor ( SSD1306_BLACK ) ;
disp_area . setCursor ( 2 , 46 ) ;
disp_area . print ( " Channel " ) ;
disp_area . setCursor ( 38 , 46 ) ;
disp_area . print ( " Load: " ) ;
disp_area . setCursor ( 11 , 57 ) ;
if ( total_channel_util < 0.099 ) {
//disp_area.printf("%.1f%%", airtime*100.0);
disp_area . printf ( " %.1f%% " , total_channel_util * 100.0 ) ;
} else {
//disp_area.printf("%.0f%%", airtime*100.0);
disp_area . printf ( " %.0f%% " , total_channel_util * 100.0 ) ;
}
disp_area . drawBitmap ( 2 , 50 , bm_hg_low , 5 , 9 , SSD1306_BLACK , SSD1306_WHITE ) ;
disp_area . setCursor ( 32 + 11 , 57 ) ;
if ( longterm_channel_util < 0.099 ) {
//disp_area.printf("%.1f%%", longterm_airtime*100.0);
disp_area . printf ( " %.1f%% " , longterm_channel_util * 100.0 ) ;
} else {
//disp_area.printf("%.0f%%", longterm_airtime*100.0);
disp_area . printf ( " %.0f%% " , longterm_channel_util * 100.0 ) ;
}
disp_area . drawBitmap ( 32 + 2 , 50 , bm_hg_high , 5 , 9 , SSD1306_BLACK , SSD1306_WHITE ) ;
} else {
if ( device_signatures_ok ( ) ) {
disp_area . drawBitmap ( 0 , 0 , bm_def_lc , disp_area . width ( ) , 37 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
disp_area . drawBitmap ( 0 , 0 , bm_def , disp_area . width ( ) , 37 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
if ( ! hw_ready | | radio_error | | ! device_firmware_ok ( ) ) {
if ( ! device_firmware_ok ( ) ) {
disp_area . drawBitmap ( 0 , 37 , bm_fw_corrupt , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
if ( ! modem_installed ) {
disp_area . drawBitmap ( 0 , 37 , bm_no_radio , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
disp_area . drawBitmap ( 0 , 37 , bm_hwfail , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
} else if ( bt_state = = BT_STATE_PAIRING and bt_ssp_pin ! = 0 ) {
char * pin_str = ( char * ) malloc ( DISP_PIN_SIZE + 1 ) ;
sprintf ( pin_str , " %06d " , bt_ssp_pin ) ;
disp_area . drawBitmap ( 0 , 37 , bm_pairing , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
for ( int i = 0 ; i < DISP_PIN_SIZE ; i + + ) {
uint8_t numeric = pin_str [ i ] - 48 ;
uint8_t offset = numeric * 5 ;
disp_area . drawBitmap ( 7 + 9 * i , 37 + 16 , bm_n_uh + offset , 8 , 5 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
free ( pin_str ) ;
} else {
if ( millis ( ) - last_page_flip > = page_interval ) {
disp_page = ( + + disp_page % pages ) ;
last_page_flip = millis ( ) ;
if ( not community_fw and disp_page = = 0 ) disp_page = 1 ;
}
if ( radio_online ) {
if ( ! display_diagnostics ) {
disp_area . drawBitmap ( 0 , 37 , bm_online , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
} else {
if ( disp_page = = 0 ) {
if ( true | | device_signatures_ok ( ) ) {
disp_area . drawBitmap ( 0 , 37 , bm_checks , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
disp_area . drawBitmap ( 0 , 37 , bm_nfr , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
} else if ( disp_page = = 1 ) {
if ( ! console_active ) {
disp_area . drawBitmap ( 0 , 37 , bm_hwok , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
} else {
disp_area . drawBitmap ( 0 , 37 , bm_console_active , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
} else if ( disp_page = = 2 ) {
disp_area . drawBitmap ( 0 , 37 , bm_version , disp_area . width ( ) , 27 , SSD1306_WHITE , SSD1306_BLACK ) ;
char * v_str = ( char * ) malloc ( 3 + 1 ) ;
sprintf ( v_str , " %01d%02d " , MAJ_VERS , MIN_VERS ) ;
for ( int i = 0 ; i < 3 ; i + + ) {
uint8_t numeric = v_str [ i ] - 48 ; uint8_t bm_offset = numeric * 5 ;
uint8_t dxp = 20 ;
if ( i = = 1 ) dxp + = 9 * 1 + 4 ;
if ( i = = 2 ) dxp + = 9 * 2 + 4 ;
disp_area . drawBitmap ( dxp , 37 + 16 , bm_n_uh + bm_offset , 8 , 5 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
free ( v_str ) ;
disp_area . drawLine ( 27 , 37 + 19 , 28 , 37 + 19 , SSD1306_BLACK ) ;
disp_area . drawLine ( 27 , 37 + 20 , 28 , 37 + 20 , SSD1306_BLACK ) ;
}
}
}
} else {
disp_area . drawBitmap ( 0 , 0 , fb , disp_area . width ( ) , disp_area . height ( ) , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
}
void update_disp_area ( ) {
draw_disp_area ( ) ;
drawBitmap ( p_ad_x , p_ad_y , disp_area . getBuffer ( ) , disp_area . width ( ) , disp_area . height ( ) , SSD1306_WHITE , SSD1306_BLACK ) ;
if ( disp_mode = = DISP_MODE_LANDSCAPE ) {
if ( device_init_done & & ! firmware_update_mode & & ! disp_ext_fb ) {
drawLine ( 0 , 0 , 0 , 63 , SSD1306_WHITE ) ;
}
}
}
void display_recondition ( ) {
for ( uint8_t iy = 0 ; iy < disp_area . height ( ) ; iy + + ) {
unsigned char rand_seg [ ] = { random ( 0xFF ) , random ( 0xFF ) , random ( 0xFF ) , random ( 0xFF ) , random ( 0xFF ) , random ( 0xFF ) , random ( 0xFF ) , random ( 0xFF ) } ;
stat_area . drawBitmap ( 0 , iy , rand_seg , 64 , 1 , SSD1306_WHITE , SSD1306_BLACK ) ;
disp_area . drawBitmap ( 0 , iy , rand_seg , 64 , 1 , SSD1306_WHITE , SSD1306_BLACK ) ;
}
drawBitmap ( p_ad_x , p_ad_y , disp_area . getBuffer ( ) , disp_area . width ( ) , disp_area . height ( ) , SSD1306_WHITE , SSD1306_BLACK ) ;
if ( disp_mode = = DISP_MODE_PORTRAIT ) {
drawBitmap ( p_as_x , p_as_y , stat_area . getBuffer ( ) , stat_area . width ( ) , stat_area . height ( ) , SSD1306_WHITE , SSD1306_BLACK ) ;
} else if ( disp_mode = = DISP_MODE_LANDSCAPE ) {
drawBitmap ( p_as_x , p_as_y , stat_area . getBuffer ( ) , stat_area . width ( ) , stat_area . height ( ) , SSD1306_WHITE , SSD1306_BLACK ) ;
}
}
void update_display ( bool blank = false ) {
if ( blank = = true ) {
last_disp_update = millis ( ) - disp_update_interval - 1 ;
} else {
if ( display_blanking_enabled & & millis ( ) - last_unblank_event > = display_blanking_timeout ) {
blank = true ;
display_blanked = true ;
if ( display_intensity ! = 0 ) {
display_unblank_intensity = display_intensity ;
}
display_intensity = 0 ;
} else {
display_blanked = false ;
if ( display_unblank_intensity ! = 0x00 ) {
display_intensity = display_unblank_intensity ;
display_unblank_intensity = 0x00 ;
}
}
}
if ( blank ) {
if ( millis ( ) - last_disp_update > = disp_update_interval ) {
if ( display_contrast ! = display_intensity ) {
display_contrast = display_intensity ;
set_contrast ( & display , display_contrast ) ;
}
# if BOARD_MODEL == BOARD_HELTEC_T114
display . clear ( ) ;
display . display ( ) ;
# elif BOARD_MODEL != BOARD_TDECK
display . clearDisplay ( ) ;
display . display ( ) ;
# else
// TODO: Clear screen
# endif
last_disp_update = millis ( ) ;
}
} else {
if ( millis ( ) - last_disp_update > = disp_update_interval ) {
if ( display_contrast ! = display_intensity ) {
display_contrast = display_intensity ;
set_contrast ( & display , display_contrast ) ;
}
# if BOARD_MODEL == BOARD_HELTEC_T114
display . clear ( ) ;
# elif BOARD_MODEL != BOARD_TDECK
display . clearDisplay ( ) ;
# endif
if ( recondition_display ) {
disp_target_fps = 30 ;
disp_update_interval = 1000 / disp_target_fps ;
display_recondition ( ) ;
} else {
update_stat_area ( ) ;
update_disp_area ( ) ;
}
# if BOARD_MODEL != BOARD_TDECK
display . display ( ) ;
# endif
last_disp_update = millis ( ) ;
}
}
}
void display_unblank ( ) {
last_unblank_event = millis ( ) ;
}
void ext_fb_enable ( ) {
disp_ext_fb = true ;
}
void ext_fb_disable ( ) {
disp_ext_fb = false ;
}
