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MarlinFirmware/Marlin/src/lcd/dogm/status_screen_lite_ST7920.h

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/**
* Lightweight Status Screen for the RepRapDiscount Full
* Graphics Smart Controller (ST7920-based 128x64 LCD)
*
* (c) 2017 Aleph Objects, Inc.
*
* The code in this page is free software: you can
* redistribute it and/or modify it under the terms of the GNU
* General Public License (GNU GPL) as published by the Free Software
* Foundation, either version 3 of the License, or (at your option)
* any later version. The code is distributed WITHOUT ANY WARRANTY;
* without even the implied warranty of MERCHANTABILITY or FITNESS
* FOR A PARTICULAR PURPOSE. See the GNU GPL for more details.
*
*/
/**
* Implementation of a Status Screen for the RepRapDiscount
* Full Graphics Smart Controller using native ST7920 commands
* instead of U8Glib.
*
* This alternative Status Screen makes use of the built-in character
* generation capabilities of the ST7920 to update the Status Screen
* with less SPI traffic and CPU use. In particular:
*
* - The fan and bed animations are handled using custom characters
* that are stored in CGRAM. This allows for the animation to be
* updated by writing a single character to the text-buffer (DDRAM).
*
* - All the information in the Status Screen is text that is written
* to DDRAM, so the work of generating the bitmaps is offloaded to
* the ST7920 rather than being render by U8Glib on the MCU.
*
* - The graphics buffer (GDRAM) is only used for static graphics
* elements (nozzle and feedrate bitmaps) and for the progress
* bar, so updates are sporadic.
*/
#include "status_screen_lite_ST7920_class.h"
#include "../../libs/duration_t.h"
#define BUFFER_WIDTH 256
#define BUFFER_HEIGHT 32
#define DDRAM_LINE_1 0x00
#define DDRAM_LINE_2 0x10
#define DDRAM_LINE_3 0x08
#define DDRAM_LINE_4 0x18
ST7920_Lite_Status_Screen::st7920_state_t ST7920_Lite_Status_Screen::current_bits;
void ST7920_Lite_Status_Screen::cmd(const uint8_t cmd) {
if (!current_bits.synced || !current_bits.cmd) {
current_bits.synced = true;
current_bits.cmd = true;
sync_cmd();
}
write_byte(cmd);
}
void ST7920_Lite_Status_Screen::begin_data() {
if (!current_bits.synced || current_bits.cmd) {
current_bits.synced = true;
current_bits.cmd = false;
sync_dat();
}
}
void ST7920_Lite_Status_Screen::write_str(const char *str) {
while (*str) write_byte(*str++);
}
void ST7920_Lite_Status_Screen::write_str(const char *str, uint8_t len) {
while (*str && len--) write_byte(*str++);
}
void ST7920_Lite_Status_Screen::write_str_P(const char * const str) {
const char *p_str = (const char *)str;
while (char c = pgm_read_byte_near(p_str++)) write_byte(c);
}
void ST7920_Lite_Status_Screen::write_str(progmem_str str) {
write_str_P((const char*)str);
}
void ST7920_Lite_Status_Screen::write_number(const int16_t value, const uint8_t digits/*=3*/) {
char str[7];
const char *fmt;
switch (digits) {
case 6: fmt = PSTR("%6d"); break;
case 5: fmt = PSTR("%5d"); break;
case 4: fmt = PSTR("%4d"); break;
case 3: fmt = PSTR("%3d"); break;
case 2: fmt = PSTR("%2d"); break;
case 1: fmt = PSTR("%1d"); break;
}
sprintf_P(str, fmt, value);
write_str(str);
}
void ST7920_Lite_Status_Screen::display_status(const bool display_on, const bool cursor_on, const bool blink_on) {
extended_function_set(false);
cmd(0b00001000 |
(display_on ? 0b0100 : 0) |
(cursor_on ? 0b0010 : 0) |
(blink_on ? 0b0001 : 0)
);
}
// Sets the extended and graphics bits simultaneously, regardless of
// the current state. This is a helper function for extended_function_set()
// and graphics()
void ST7920_Lite_Status_Screen::_extended_function_set(const bool extended, const bool graphics) {
cmd( 0b00100000 |
(extended ? 0b00000100 : 0) |
(graphics ? 0b00000010 : 0)
);
current_bits.extended = extended;
current_bits.graphics = graphics;
}
void ST7920_Lite_Status_Screen::extended_function_set(const bool extended) {
if (extended != current_bits.extended)
_extended_function_set(extended, current_bits.graphics);
}
void ST7920_Lite_Status_Screen::graphics(const bool graphics) {
if (graphics != current_bits.graphics)
_extended_function_set(current_bits.extended, graphics);
}
void ST7920_Lite_Status_Screen::entry_mode_select(const bool ac_increase, const bool shift) {
extended_function_set(false);
cmd(0b00000100 |
(ac_increase ? 0b00000010 : 0) |
(shift ? 0b00000001 : 0)
);
}
// Sets the sa bit regardless of the current state. This is a helper
// function for scroll_or_addr_select()
void ST7920_Lite_Status_Screen::_scroll_or_addr_select(const bool sa) {
extended_function_set(true);
cmd(0b00100010 |
(sa ? 0b000001 : 0)
);
current_bits.sa = sa;
}
void ST7920_Lite_Status_Screen::scroll_or_addr_select(const bool sa) {
if (sa != current_bits.sa)
_scroll_or_addr_select(sa);
}
void ST7920_Lite_Status_Screen::set_ddram_address(const uint8_t addr) {
extended_function_set(false);
cmd(0b10000000 | (addr & 0b00111111));
}
void ST7920_Lite_Status_Screen::set_cgram_address(const uint8_t addr) {
extended_function_set(false);
cmd(0b01000000 | (addr & 0b00111111));
}
void ST7920_Lite_Status_Screen::set_gdram_address(const uint8_t x, const uint8_t y) {
extended_function_set(true);
cmd(0b10000000 | (y & 0b01111111));
cmd(0b10000000 | (x & 0b00001111));
}
void ST7920_Lite_Status_Screen::clear() {
extended_function_set(false);
cmd(0x00000001);
delay(15); //delay for CGRAM clear
}
void ST7920_Lite_Status_Screen::home() {
extended_function_set(false);
cmd(0x00000010);
}
/* This fills the entire text buffer with spaces */
void ST7920_Lite_Status_Screen::clear_ddram() {
set_ddram_address(DDRAM_LINE_1);
begin_data();
for (uint8_t i = 64; i--;) write_byte(' ');
}
/* This fills the entire graphics buffer with zeros */
void ST7920_Lite_Status_Screen::clear_gdram() {
for (uint8_t y = 0; y < BUFFER_HEIGHT; y++) {
set_gdram_address(0, y);
begin_data();
for (uint8_t i = (BUFFER_WIDTH) / 16; i--;) write_word(0);
}
}
void ST7920_Lite_Status_Screen::load_cgram_icon(const uint16_t addr, const void *data) {
const uint16_t *p_word = (const uint16_t *)data;
set_cgram_address(addr);
begin_data();
for (uint8_t i = 16; i--;)
write_word(pgm_read_word_near(p_word++));
}
/**
* Draw an icon in GDRAM. Position specified in DDRAM
* coordinates. i.e., X from 1 to 8, Y from 1 to 4.
*/
void ST7920_Lite_Status_Screen::draw_gdram_icon(uint8_t x, uint8_t y, const void *data) {
const uint16_t *p_word = (const uint16_t *)data;
if (y > 2) { // Handle display folding
y -= 2;
x += 8;
}
--x;
--y;
for (int i = 0; i < 16; i++) {
set_gdram_address(x, i + y * 16);
begin_data();
write_word(pgm_read_word_near(p_word++));
}
}
/************************** ICON DEFINITIONS *************************************/
#define CGRAM_ICON_1_ADDR 0x00
#define CGRAM_ICON_2_ADDR 0x10
#define CGRAM_ICON_3_ADDR 0x20
#define CGRAM_ICON_4_ADDR 0x30
#define CGRAM_ICON_1_WORD 0x00
#define CGRAM_ICON_2_WORD 0x02
#define CGRAM_ICON_3_WORD 0x04
#define CGRAM_ICON_4_WORD 0x06
const uint16_t nozzle_icon[] PROGMEM = {
0b0000000000000000,
0b0000000000000000,
0b0000111111110000,
0b0001111111111000,
0b0001111111111000,
0b0001111111111000,
0b0000111111110000,
0b0000111111110000,
0b0001111111111000,
0b0001111111111000,
0b0001111111111000,
0b0000011111100000,
0b0000001111000000,
0b0000000110000000,
0b0000000000000000,
0b0000000000000000
};
const uint16_t bed_icon[] PROGMEM = {
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0111111111111110,
0b0111111111111110,
0b0110000000000110,
0b0000000000000000,
0b0000000000000000
};
const uint16_t heat1_icon[] PROGMEM = {
0b0000000000000000,
0b0010001000100000,
0b0001000100010000,
0b0000100010001000,
0b0000100010001000,
0b0001000100010000,
0b0010001000100000,
0b0010001000100000,
0b0001000100010000,
0b0000100010001000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000
};
const uint16_t heat2_icon[] PROGMEM = {
0b0000000000000000,
0b0000100010001000,
0b0000100010001000,
0b0001000100010000,
0b0010001000100000,
0b0010001000100000,
0b0001000100010000,
0b0000100010001000,
0b0000100010001000,
0b0001000100010000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000,
0b0000000000000000
};
const uint16_t fan1_icon[] PROGMEM = {
0b0000000000000000,
0b0111111111111110,
0b0111000000001110,
0b0110001111000110,
0b0100001111000010,
0b0100000110000010,
0b0101100000011010,
0b0101110110111010,
0b0101100000011010,
0b0100000110000010,
0b0100001111000010,
0b0110001111000110,
0b0111000000001110,
0b0111111111111110,
0b0000000000000000,
0b0000000000000000
};
const uint16_t fan2_icon[] PROGMEM = {
0b0000000000000000,
0b0111111111111110,
0b0111000000001110,
0b0110010000100110,
0b0100111001110010,
0b0101111001111010,
0b0100110000110010,
0b0100000110000010,
0b0100110000110010,
0b0101111001111010,
0b0100111001110010,
0b0110010000100110,
0b0111000000001110,
0b0111111111111110,
0b0000000000000000,
0b0000000000000000
};
const uint16_t feedrate_icon[] PROGMEM = {
0b0000000000000000,
0b0111111000000000,
0b0100000000000000,
0b0100000000000000,
0b0100000000000000,
0b0111111011111000,
0b0100000010000100,
0b0100000010000100,
0b0100000010000100,
0b0100000011111000,
0b0000000010001000,
0b0000000010000100,
0b0000000010000100,
0b0000000010000010,
0b0000000000000000,
0b0000000000000000
};
/************************** MAIN SCREEN *************************************/
void ST7920_Lite_Status_Screen::draw_static_elements() {
scroll_or_addr_select(0);
// Load the animated bed and fan icons
load_cgram_icon(CGRAM_ICON_1_ADDR, heat1_icon);
load_cgram_icon(CGRAM_ICON_2_ADDR, heat2_icon);
load_cgram_icon(CGRAM_ICON_3_ADDR, fan1_icon);
load_cgram_icon(CGRAM_ICON_4_ADDR, fan2_icon);
// Draw the static icons in GDRAM
draw_gdram_icon(1, 1, nozzle_icon);
#if EXTRUDERS == 2
draw_gdram_icon(1,2,nozzle_icon);
draw_gdram_icon(1,3,bed_icon);
#else
draw_gdram_icon(1,2,bed_icon);
#endif
draw_gdram_icon(6,2,feedrate_icon);
// Draw the initial fan icon
draw_fan_icon(false);
}
/**
* Although this is undocumented, the ST7920 allows the character
* data buffer (DDRAM) to be used in conjunction with the graphics
* bitmap buffer (CGRAM). The contents of the graphics buffer is
* XORed with the data from the character generator. This allows
* us to make the progess bar out of graphical data (the bar) and
* text data (the percentage).
*/
void ST7920_Lite_Status_Screen::draw_progress_bar(const uint8_t value) {
#if EXTRUDERS == 1
// If we have only one extruder, draw a long progress bar on the third line
const uint8_t top = 1, // Top in pixels
bottom = 13, // Bottom in pixels
left = 8, // Left edge, in 16-bit words
width = 5; // Width of progress bar, in 16-bit words
#else
const uint8_t top = 16 + 1, // Top in pixels
bottom = 16 + 13, // Bottom in pixels
left = 5, // Left edge, in 16-bit words
width = 3; // Width of progress bar, in 16-bit words
#endif
const uint8_t char_pcnt = 100 / width; // How many percent does each 16-bit word represent?
// Draw the progress bar as a bitmap in CGRAM
for (uint8_t y = top; y <= bottom; y++) {
set_gdram_address(left, y);
begin_data();
for (uint8_t x = 0; x < width; x++) {
uint16_t gfx_word = 0x0000;
if ((x + 1) * char_pcnt <= value)
gfx_word = 0xFFFF; // Draw completely filled bytes
else if ((x * char_pcnt) < value)
gfx_word = int(0x8000) >> (value % char_pcnt) * 16 / char_pcnt; // Draw partially filled bytes
// Draw the frame around the progress bar
if (y == top || y == bottom)
gfx_word = 0xFFFF; // Draw top/bottom border
else if (x == width - 1)
gfx_word |= 0x0001; // Draw right border
else if (x == 0)
gfx_word |= 0x8000; // Draw left border
write_word(gfx_word);
}
}
// Draw the percentage as text in DDRAM
set_ddram_address(
#if EXTRUDERS == 1
DDRAM_LINE_3 + 1
#else
DDRAM_LINE_2 + left
#endif
);
begin_data();
if (value > 9) {
write_number(value, 4);
write_str(F("% "));
}
else {
write_number(value, 3);
write_str(F("% "));
}
}
void ST7920_Lite_Status_Screen::draw_fan_icon(const bool whichIcon) {
set_ddram_address(DDRAM_LINE_1 + 5);
begin_data();
write_word(whichIcon ? CGRAM_ICON_3_WORD : CGRAM_ICON_4_WORD);
}
void ST7920_Lite_Status_Screen::draw_heat_icon(const bool whichIcon, const bool heating) {
set_ddram_address(
#if EXTRUDERS == 1
DDRAM_LINE_2
#else
DDRAM_LINE_3
#endif
);
begin_data();
if (heating)
write_word(whichIcon ? CGRAM_ICON_1_WORD : CGRAM_ICON_2_WORD);
else {
write_byte(' ');
write_byte(' ');
}
}
#define FAR(a,b) (((a > b) ? (a-b) : (b-a)) > 1)
void ST7920_Lite_Status_Screen::draw_extruder_1_temp(const int16_t temp, const int16_t target) {
set_ddram_address(DDRAM_LINE_1 + 1);
begin_data();
write_number(temp);
if (target && FAR(temp, target)) {
write_str(F("\x1A"));
write_number(target);
}
else
write_str(F(" "));
}
void ST7920_Lite_Status_Screen::draw_extruder_2_temp(const int16_t temp, const int16_t target) {
set_ddram_address(DDRAM_LINE_2 + 1);
begin_data();
write_number(temp);
if (target && FAR(temp, target)) {
write_str(F("\x1A"));
write_number(target);
}
else
write_str(F(" "));
}
void ST7920_Lite_Status_Screen::draw_bed_temp(const int16_t temp, const int16_t target) {
set_ddram_address(
#if EXTRUDERS == 1
DDRAM_LINE_2 + 1
#else
DDRAM_LINE_3 + 1
#endif
);
begin_data();
write_number(temp);
if (target && FAR(temp, target)) {
write_str(F("\x1A"));
write_number(target);
}
else
write_str(F(" "));
}
void ST7920_Lite_Status_Screen::draw_fan_speed(const uint8_t value) {
set_ddram_address(DDRAM_LINE_1 + 6);
begin_data();
write_number(value, 4);
}
void ST7920_Lite_Status_Screen::draw_print_time(const uint32_t elapsed) {
const uint8_t hrs = elapsed / 3600,
min = (elapsed / 60) % 60;
char str[7];
sprintf_P(str, hrs > 99 ? PSTR("%03d:%02d") : PSTR(" %02d:%02d"), hrs, min);
set_ddram_address(DDRAM_LINE_3 + 5);
begin_data();
write_str(str);
}
void ST7920_Lite_Status_Screen::draw_feedrate_percentage(const uint8_t percentage) {
// We only have enough room for the feedrate when
// we have one extruder
#if EXTRUDERS == 1
set_ddram_address(DDRAM_LINE_2 + 6);
begin_data();
write_number(percentage, 4);
#endif
}
void ST7920_Lite_Status_Screen::draw_status_message(const char *str) {
set_ddram_address(DDRAM_LINE_4);
begin_data();
#if ENABLED(STATUS_MESSAGE_SCROLLING)
const uint8_t lcd_len = 16;
const uint8_t padding = 2;
uint8_t str_len = strlen(str);
// Trim whitespace at the end of the str, as for some reason
// messages like "Card Inserted" are padded with many spaces
while (str_len > 0 && str[str_len - 1] == ' ') str_len--;
if (str_len <= lcd_len) {
// It all fits on the LCD without scrolling
write_str(str);
}
else {
// Print the message repeatedly until covering the LCD
uint8_t c = status_scroll_pos;
for (uint8_t n = 0; n < lcd_len; n++) {
write_byte(c < str_len ? str[c] : ' ');
c++;
c %= str_len + padding; // Wrap around
}
// Scroll the message
if (status_scroll_pos == str_len + padding)
status_scroll_pos = 0;
else
status_scroll_pos++;
}
#else
write_str(str, 16);
#endif
}
void ST7920_Lite_Status_Screen::draw_position(const float x, const float y, const float z, bool position_known) {
char str[7];
set_ddram_address(DDRAM_LINE_4);
begin_data();
// If position is unknown, flash the labels.
const unsigned char alt_label = position_known ? 0 : (lcd_blink() ? ' ' : 0);
dtostrf(x, -4, 0, str);
write_byte(alt_label ? alt_label : 'X');
write_str(str, 4);
dtostrf(y, -4, 0, str);
write_byte(alt_label ? alt_label : 'Y');
write_str(str, 4);
dtostrf(z, -5, 1, str);
write_byte(alt_label ? alt_label : 'Z');
write_str(str, 5);
}
bool ST7920_Lite_Status_Screen::indicators_changed() {
// We only add the target temperatures to the checksum
// because the actual temps fluctuate so by updating
// them only during blinks we gain a bit of stability.
const bool blink = lcd_blink();
const uint8_t feedrate_perc = feedrate_percentage;
const uint8_t fan_speed = ((fanSpeeds[0] + 1) * 100) / 256;
const float extruder_1_target = thermalManager.degTargetHotend(0);
#if EXTRUDERS == 2
const float extruder_2_target = thermalManager.degTargetHotend(1);
#endif
const float bed_target = thermalManager.degTargetBed();
static uint8_t last_checksum = 0;
const uint8_t checksum =
uint8_t(blink) ^
uint8_t(feedrate_perc) ^
uint8_t(fan_speed) ^
uint8_t(extruder_1_target) ^
#if EXTRUDERS == 2
uint8_t(extruder_2_target) ^
#endif
uint8_t(bed_target);
if (last_checksum == checksum) return false;
last_checksum = checksum;
return true;
}
void ST7920_Lite_Status_Screen::update_indicators(const bool forceUpdate) {
if (forceUpdate || indicators_changed()) {
const bool blink = lcd_blink();
const duration_t elapsed = print_job_timer.duration();
const uint32_t seconds_elapsed = elapsed.value;
const uint8_t feedrate_perc = feedrate_percentage;
const uint8_t fan_speed = ((fanSpeeds[0] + 1) * 100) / 256;
const float extruder_1_temp = thermalManager.degHotend(0);
const float extruder_1_target = thermalManager.degTargetHotend(0);
#if EXTRUDERS == 2
const float extruder_2_temp = thermalManager.degHotend(1);
const float extruder_2_target = thermalManager.degTargetHotend(1);
#endif
const float bed_temp = thermalManager.degBed();
const float bed_target = thermalManager.degTargetBed();
draw_extruder_1_temp(extruder_1_temp, extruder_1_target);
#if EXTRUDERS == 2
draw_extruder_2_temp(extruder_2_temp, extruder_2_target);
#endif
draw_bed_temp(bed_temp, bed_target);
draw_fan_speed(fan_speed);
draw_print_time(seconds_elapsed);
draw_feedrate_percentage(feedrate_perc);
// Update the fan and bed animations
if (fan_speed > 0) draw_fan_icon(blink);
if (bed_target > 0)
draw_heat_icon(blink, true);
else
draw_heat_icon(false, false);
}
}
bool ST7920_Lite_Status_Screen::position_changed() {
const float x_pos = current_position[X_AXIS],
y_pos = current_position[Y_AXIS],
z_pos = current_position[Z_AXIS];
const uint8_t checksum = uint8_t(x_pos) ^ uint8_t(y_pos) ^ uint8_t(z_pos);
static uint8_t last_checksum = 0;
if (last_checksum == checksum) return false;
last_checksum = checksum;
return true;
}
bool ST7920_Lite_Status_Screen::status_changed() {
uint8_t checksum = 0;
for (const char *p = lcd_status_message; *p; p++) checksum ^= *p;
static uint8_t last_checksum = 0;
if (last_checksum == checksum) return false;
last_checksum = checksum;
return true;
}
bool ST7920_Lite_Status_Screen::blink_changed() {
static uint8_t last_blink = 0;
const bool blink = lcd_blink();
if (last_blink == blink) return false;
last_blink = blink;
return true;
}
void ST7920_Lite_Status_Screen::update_status_or_position(bool forceUpdate) {
static uint8_t countdown = 0;
/**
* There is only enough room in the display for either the
* status message or the position, not both, so we choose
* one or another. Whenever the status message changes,
* we show it for a number of consecutive seconds, but
* then go back to showing the position as soon as the
* head moves, i.e:
*
* countdown > 1 -- Show status
* countdown = 1 -- Show status, until movement
* countdown = 0 -- Show position
*/
if (forceUpdate || status_changed()) {
#if ENABLED(STATUS_MESSAGE_SCROLLING)
status_scroll_pos = 0;
#endif
#ifndef STATUS_EXPIRE_SECONDS
#define STATUS_EXPIRE_SECONDS 20
#endif
countdown = lcd_strlen(lcd_status_message) ? STATUS_EXPIRE_SECONDS : 0;
draw_status_message(lcd_status_message);
blink_changed(); // Clear changed flag
}
else if (countdown > 1 && blink_changed()) {
countdown--;
#if ENABLED(STATUS_MESSAGE_SCROLLING)
draw_status_message(lcd_status_message);
#endif
}
else if (countdown > 0 && blink_changed()) {
if (position_changed()) {
countdown--;
forceUpdate = true;
}
#if ENABLED(STATUS_MESSAGE_SCROLLING)
draw_status_message(lcd_status_message);
#endif
}
if (countdown == 0 && (forceUpdate || position_changed() ||
#if DISABLED(DISABLE_REDUCED_ACCURACY_WARNING)
blink_changed()
#endif
)) {
draw_position(
current_position[X_AXIS],
current_position[Y_AXIS],
current_position[Z_AXIS],
#if ENABLED(DISABLE_REDUCED_ACCURACY_WARNING)
true
#else
axis_known_position[X_AXIS] &&
axis_known_position[Y_AXIS] &&
axis_known_position[Z_AXIS]
#endif
);
}
}
void ST7920_Lite_Status_Screen::update_progress(const bool forceUpdate) {
const uint8_t percent_done =
#if ENABLED(SDSUPPORT)
card.percentDone()
#else
0
#endif
;
// Since the progress bar involves writing
// quite a few bytes to GDRAM, only do this
// when an update is actually necessary.
static uint8_t last_progress = 0;
if (!forceUpdate && last_progress == percent_done) return;
last_progress = percent_done;
draw_progress_bar(percent_done);
}
void ST7920_Lite_Status_Screen::update(const bool forceUpdate) {
cs();
update_indicators(forceUpdate);
update_status_or_position(forceUpdate);
update_progress(forceUpdate);
ncs();
}
void ST7920_Lite_Status_Screen::reset_state_from_unknown() {
_extended_function_set(true, true); // Do it twice as only one bit
_extended_function_set(true, true); // get set at a time.
_scroll_or_addr_select(false);
}
void ST7920_Lite_Status_Screen::on_entry() {
cs();
reset_state_from_unknown();
clear();
clear_gdram();
draw_static_elements();
update(true);
ncs();
}
void ST7920_Lite_Status_Screen::on_exit() {
cs();
clear();
_extended_function_set(true, true); // Restore state to what u8g expects.
ncs();
}
// This is called prior to the KILL screen to
// clear the screen so we don't end up with a
// garbled display.
void ST7920_Lite_Status_Screen::clear_text_buffer() {
cs();
reset_state_from_unknown();
clear();
_extended_function_set(true, true); // Restore state to what u8g expects.
ncs();
}
static void lcd_implementation_status_screen() {
ST7920_Lite_Status_Screen::update(false);
}
/**
* In order to properly update the lite Status Screen,
* we must know when we have entered and left the
* Status Screen. Since the ultralcd code is not
* set up for doing this, we call this function before
* each update indicating whether the current screen
* is the Status Screen.
*
* This function keeps track of whether we have left or
* entered the Status Screen and calls the on_entry()
* and on_exit() methods for cleanup.
*/
static void lcd_in_status(const bool inStatus) {
static bool lastInStatus = false;
if (lastInStatus == inStatus) return;
if ((lastInStatus = inStatus))
ST7920_Lite_Status_Screen::on_entry();
else
ST7920_Lite_Status_Screen::on_exit();
}