/** * Marlin 3D Printer Firmware * Copyright (c) 2020 MarlinFirmware [https://github.com/MarlinFirmware/Marlin] * * Based on Sprinter and grbl. * Copyright (c) 2011 Camiel Gubbels / Erik van der Zalm * * 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 . * */ // // status_screen_DOGM.cpp // Standard Status Screen for Graphical Display // #include "../../inc/MarlinConfigPre.h" #if HAS_MARLINUI_U8GLIB && DISABLED(LIGHTWEIGHT_UI) #include "dogm_Statusscreen.h" #include "marlinui_DOGM.h" #include "../marlinui.h" #include "../lcdprint.h" #include "../../libs/numtostr.h" #include "../../module/motion.h" #include "../../module/temperature.h" #include "../../gcode/parser.h" // for units (and volumetric) #if ENABLED(LCD_SHOW_E_TOTAL) #include "../../MarlinCore.h" // for printingIsActive(), marlin_state and MF_SD_COMPLETE #endif #if ENABLED(FILAMENT_LCD_DISPLAY) #include "../../feature/filwidth.h" #include "../../module/planner.h" #endif #if HAS_CUTTER #include "../../feature/spindle_laser.h" #endif #if EITHER(HAS_COOLER, LASER_COOLANT_FLOW_METER) #include "../../feature/cooler.h" #endif #if HAS_POWER_MONITOR #include "../../feature/power_monitor.h" #endif #if ENABLED(SDSUPPORT) #include "../../sd/cardreader.h" #endif #if HAS_PRINT_PROGRESS #include "../../module/printcounter.h" #endif #if HAS_DUAL_MIXING #include "../../feature/mixing.h" #endif #define X_LABEL_POS 3 #define X_VALUE_POS 11 #define XYZ_SPACING 37 #define X_LABEL_POS_IN (X_LABEL_POS - 2) #define X_VALUE_POS_IN (X_VALUE_POS - 5) #define XYZ_SPACING_IN (XYZ_SPACING + 9) #define XYZ_BASELINE (30 + INFO_FONT_ASCENT) #define EXTRAS_BASELINE (40 + INFO_FONT_ASCENT) #define STATUS_BASELINE (LCD_PIXEL_HEIGHT - INFO_FONT_DESCENT) #if ANIM_HBCC enum HeatBits : uint8_t { DRAWBIT_HOTEND, DRAWBIT_BED = HOTENDS, DRAWBIT_CHAMBER, DRAWBIT_CUTTER }; IF<(DRAWBIT_CUTTER > 7), uint16_t, uint8_t>::type draw_bits; #endif #if ANIM_HOTEND #define HOTEND_ALT(N) TEST(draw_bits, DRAWBIT_HOTEND + N) #else #define HOTEND_ALT(N) false #endif #if ANIM_BED #define BED_ALT() TEST(draw_bits, DRAWBIT_BED) #else #define BED_ALT() false #endif #if ANIM_CHAMBER #define CHAMBER_ALT() TEST(draw_bits, DRAWBIT_CHAMBER) #else #define CHAMBER_ALT() false #endif #if ANIM_CUTTER #define CUTTER_ALT(N) TEST(draw_bits, DRAWBIT_CUTTER) #else #define CUTTER_ALT() false #endif #if DO_DRAW_HOTENDS #define MAX_HOTEND_DRAW _MIN(HOTENDS, ((LCD_PIXEL_WIDTH - (STATUS_LOGO_BYTEWIDTH + STATUS_FAN_BYTEWIDTH) * 8) / (STATUS_HEATERS_XSPACE))) #endif #if EITHER(DO_DRAW_BED, DO_DRAW_HOTENDS) #define STATUS_HEATERS_BOT (STATUS_HEATERS_Y + STATUS_HEATERS_HEIGHT - 1) #endif #if HAS_POWER_MONITOR void display_power_monitor(const uint8_t x, const uint8_t y) { lcd_moveto(x, y); #if HAS_POWER_MONITOR_WATTS const bool wflag = power_monitor.power_display_enabled(); #endif #if ENABLED(POWER_MONITOR_CURRENT) const bool iflag = power_monitor.current_display_enabled(); #endif #if ENABLED(POWER_MONITOR_VOLTAGE) const bool vflag = power_monitor.voltage_display_enabled(); #endif #if HAS_POWER_MONITOR_WATTS // Cycle between current, voltage, and power if (ELAPSED(millis(), power_monitor.display_item_ms)) { power_monitor.display_item_ms = millis() + 1000UL; ++power_monitor.display_item; } #elif ENABLED(POWER_MONITOR_CURRENT) power_monitor.display_item = 0; #elif ENABLED(POWER_MONITOR_VOLTAGE) power_monitor.display_item = 1; #endif // ensure we have the right one selected for display for (uint8_t i = 0; i < 3; i++) { #if ENABLED(POWER_MONITOR_CURRENT) if (power_monitor.display_item == 0 && !iflag) ++power_monitor.display_item; #endif #if ENABLED(POWER_MONITOR_VOLTAGE) if (power_monitor.display_item == 1 && !vflag) ++power_monitor.display_item; #endif #if HAS_POWER_MONITOR_WATTS if (power_monitor.display_item == 2 && !wflag) ++power_monitor.display_item; #endif if (power_monitor.display_item >= 3) power_monitor.display_item = 0; } switch (power_monitor.display_item) { #if ENABLED(POWER_MONITOR_CURRENT) // Current case 0: if (iflag) power_monitor.draw_current(); break; #endif #if ENABLED(POWER_MONITOR_VOLTAGE) // Voltage case 1: if (vflag) power_monitor.draw_voltage(); break; #endif #if HAS_POWER_MONITOR_WATTS // Power case 2: if (wflag) power_monitor.draw_power(); break; #endif default: break; } } #endif #define PROGRESS_BAR_X 54 #define PROGRESS_BAR_Y (EXTRAS_BASELINE + 1) #define PROGRESS_BAR_WIDTH (LCD_PIXEL_WIDTH - PROGRESS_BAR_X) FORCE_INLINE void _draw_centered_temp(const celsius_t temp, const uint8_t tx, const uint8_t ty) { if (temp < 0) lcd_put_u8str(tx - 3 * (INFO_FONT_WIDTH) / 2 + 1, ty, "err"); else { const char *str = i16tostr3rj(temp); const uint8_t len = str[0] != ' ' ? 3 : str[1] != ' ' ? 2 : 1; lcd_put_u8str(tx - len * (INFO_FONT_WIDTH) / 2 + 1, ty, &str[3-len]); lcd_put_wchar(LCD_STR_DEGREE[0]); } } #if DO_DRAW_FLOWMETER FORCE_INLINE void _draw_centered_flowrate(const float flow, const uint8_t tx, const uint8_t ty) { const char *str = ftostr11ns(flow); const uint8_t len = str[0] != ' ' ? 3 : str[1] != ' ' ? 2 : 1; lcd_put_u8str(tx - len * (INFO_FONT_WIDTH) / 2 + 1, ty, &str[3-len]); lcd_put_u8str("L"); } #endif #if DO_DRAW_HOTENDS // Draw hotend bitmap with current and target temperatures FORCE_INLINE void _draw_hotend_status(const heater_id_t heater_id, const bool blink) { #if !HEATER_IDLE_HANDLER UNUSED(blink); #endif const bool isHeat = HOTEND_ALT(heater_id); const uint8_t tx = STATUS_HOTEND_TEXT_X(heater_id); const celsius_t temp = thermalManager.wholeDegHotend(heater_id), target = thermalManager.degTargetHotend(heater_id); #if DISABLED(STATUS_HOTEND_ANIM) #define STATIC_HOTEND true #define HOTEND_DOT isHeat #else #define STATIC_HOTEND false #define HOTEND_DOT false #endif #if ANIM_HOTEND && BOTH(STATUS_HOTEND_INVERTED, STATUS_HOTEND_NUMBERLESS) #define OFF_BMP(N) status_hotend_b_bmp #define ON_BMP(N) status_hotend_a_bmp #elif ANIM_HOTEND && DISABLED(STATUS_HOTEND_INVERTED) && ENABLED(STATUS_HOTEND_NUMBERLESS) #define OFF_BMP(N) status_hotend_a_bmp #define ON_BMP(N) status_hotend_b_bmp #elif BOTH(ANIM_HOTEND, STATUS_HOTEND_INVERTED) #define OFF_BMP(N) status_hotend##N##_b_bmp #define ON_BMP(N) status_hotend##N##_a_bmp #else #define OFF_BMP(N) status_hotend##N##_a_bmp #define ON_BMP(N) status_hotend##N##_b_bmp #endif #if STATUS_HOTEND_BITMAPS > 1 #define _OFF_BMP(N) OFF_BMP(N), #define _ON_BMP(N) ON_BMP(N), static const unsigned char* const status_hotend_gfx[STATUS_HOTEND_BITMAPS] PROGMEM = { REPEAT_1(STATUS_HOTEND_BITMAPS, _OFF_BMP) }; #if ANIM_HOTEND static const unsigned char* const status_hotend_on_gfx[STATUS_HOTEND_BITMAPS] PROGMEM = { REPEAT_1(STATUS_HOTEND_BITMAPS, _ON_BMP) }; #define HOTEND_BITMAP(N,S) (unsigned char*)pgm_read_ptr((S) ? &status_hotend_on_gfx[(N) % (STATUS_HOTEND_BITMAPS)] : &status_hotend_gfx[(N) % (STATUS_HOTEND_BITMAPS)]) #else #define HOTEND_BITMAP(N,S) (unsigned char*)pgm_read_ptr(&status_hotend_gfx[(N) % (STATUS_HOTEND_BITMAPS)]) #endif #elif ANIM_HOTEND #define HOTEND_BITMAP(N,S) ((S) ? ON_BMP() : OFF_BMP()) #else #define HOTEND_BITMAP(N,S) status_hotend_a_bmp #endif if (PAGE_CONTAINS(STATUS_HEATERS_Y, STATUS_HEATERS_BOT)) { #define BAR_TALL (STATUS_HEATERS_HEIGHT - 2) const float prop = target - 20, perc = prop > 0 && temp >= 20 ? (temp - 20) / prop : 0; uint8_t tall = uint8_t(perc * BAR_TALL + 0.5f); NOMORE(tall, BAR_TALL); #if ANIM_HOTEND // Draw hotend bitmap, either whole or split by the heating percent const uint8_t hx = STATUS_HOTEND_X(heater_id), bw = STATUS_HOTEND_BYTEWIDTH(heater_id); #if ENABLED(STATUS_HEAT_PERCENT) if (isHeat && tall <= BAR_TALL) { const uint8_t ph = STATUS_HEATERS_HEIGHT - 1 - tall; u8g.drawBitmapP(hx, STATUS_HEATERS_Y, bw, ph, HOTEND_BITMAP(heater_id, false)); u8g.drawBitmapP(hx, STATUS_HEATERS_Y + ph, bw, tall + 1, HOTEND_BITMAP(heater_id, true) + ph * bw); } else #endif u8g.drawBitmapP(hx, STATUS_HEATERS_Y, bw, STATUS_HEATERS_HEIGHT, HOTEND_BITMAP(heater_id, isHeat)); #endif } // PAGE_CONTAINS if (PAGE_UNDER(7)) { #if HEATER_IDLE_HANDLER const bool dodraw = (blink || !thermalManager.heater_idle[heater_id].timed_out); #else constexpr bool dodraw = true; #endif if (dodraw) _draw_centered_temp(target, tx, 7); } if (PAGE_CONTAINS(28 - INFO_FONT_ASCENT, 28 - 1)) _draw_centered_temp(temp, tx, 28); if (STATIC_HOTEND && HOTEND_DOT && PAGE_CONTAINS(17, 19)) { u8g.setColorIndex(0); // set to white on black u8g.drawBox(tx, 20 - 3, 2, 2); u8g.setColorIndex(1); // restore black on white } } #endif // DO_DRAW_HOTENDS #if DO_DRAW_BED // Draw bed bitmap with current and target temperatures FORCE_INLINE void _draw_bed_status(const bool blink) { #if !HEATER_IDLE_HANDLER UNUSED(blink); #endif const uint8_t tx = STATUS_BED_TEXT_X; const celsius_t temp = thermalManager.wholeDegBed(), target = thermalManager.degTargetBed(); #if ENABLED(STATUS_HEAT_PERCENT) || DISABLED(STATUS_BED_ANIM) const bool isHeat = BED_ALT(); #endif #if DISABLED(STATUS_BED_ANIM) #define STATIC_BED true #define BED_DOT isHeat #else #define STATIC_BED false #define BED_DOT false #endif if (PAGE_CONTAINS(STATUS_HEATERS_Y, STATUS_HEATERS_BOT)) { #define BAR_TALL (STATUS_HEATERS_HEIGHT - 2) const float prop = target - 20, perc = prop > 0 && temp >= 20 ? (temp - 20) / prop : 0; uint8_t tall = uint8_t(perc * BAR_TALL + 0.5f); NOMORE(tall, BAR_TALL); // Draw a heating progress bar, if specified #if ENABLED(STATUS_HEAT_PERCENT) if (isHeat) { const uint8_t bx = STATUS_BED_X + STATUS_BED_WIDTH; u8g.drawFrame(bx, STATUS_HEATERS_Y, 3, STATUS_HEATERS_HEIGHT); if (tall) { const uint8_t ph = STATUS_HEATERS_HEIGHT - 1 - tall; if (PAGE_OVER(STATUS_HEATERS_Y + ph)) u8g.drawVLine(bx + 1, STATUS_HEATERS_Y + ph, tall); } } #endif } // PAGE_CONTAINS if (PAGE_UNDER(7)) { #if HEATER_IDLE_HANDLER const bool dodraw = (blink || !thermalManager.heater_idle[thermalManager.IDLE_INDEX_BED].timed_out); #else constexpr bool dodraw = true; #endif if (dodraw) _draw_centered_temp(target, tx, 7); } if (PAGE_CONTAINS(28 - INFO_FONT_ASCENT, 28 - 1)) _draw_centered_temp(temp, tx, 28); if (STATIC_BED && BED_DOT && PAGE_CONTAINS(17, 19)) { u8g.setColorIndex(0); // set to white on black u8g.drawBox(tx, 20 - 2, 2, 2); u8g.setColorIndex(1); // restore black on white } } #endif // DO_DRAW_BED #if DO_DRAW_CHAMBER FORCE_INLINE void _draw_chamber_status() { #if HAS_HEATED_CHAMBER if (PAGE_UNDER(7)) _draw_centered_temp(thermalManager.degTargetChamber(), STATUS_CHAMBER_TEXT_X, 7); #endif if (PAGE_CONTAINS(28 - INFO_FONT_ASCENT, 28 - 1)) _draw_centered_temp(thermalManager.wholeDegChamber(), STATUS_CHAMBER_TEXT_X, 28); } #endif #if DO_DRAW_COOLER FORCE_INLINE void _draw_cooler_status() { if (PAGE_CONTAINS(28 - INFO_FONT_ASCENT, 28 - 1)) _draw_centered_temp(thermalManager.wholeDegCooler(), STATUS_COOLER_TEXT_X, 28); } #endif #if DO_DRAW_FLOWMETER FORCE_INLINE void _draw_flowmeter_status() { if (PAGE_CONTAINS(28 - INFO_FONT_ASCENT, 28 - 1)) _draw_centered_flowrate(cooler.flowrate, STATUS_FLOWMETER_TEXT_X, 28); } #endif // // Before homing, blink '123' <-> '???'. // Homed but unknown... '123' <-> ' '. // Homed and known, display constantly. // FORCE_INLINE void _draw_axis_value(const AxisEnum axis, const char *value, const bool blink) { const bool is_inch = parser.using_inch_units(); const AxisEnum a = TERN(LCD_SHOW_E_TOTAL, axis == E_AXIS ? X_AXIS : axis, axis); const uint8_t offs = a * (is_inch ? XYZ_SPACING_IN : XYZ_SPACING); lcd_put_wchar((is_inch ? X_LABEL_POS_IN : X_LABEL_POS) + offs, XYZ_BASELINE, axis_codes[axis]); lcd_moveto((is_inch ? X_VALUE_POS_IN : X_VALUE_POS) + offs, XYZ_BASELINE); if (blink) lcd_put_u8str(value); else if (axis_should_home(axis)) while (const char c = *value++) lcd_put_wchar(c <= '.' ? c : '?'); else if (NONE(HOME_AFTER_DEACTIVATE, DISABLE_REDUCED_ACCURACY_WARNING) && !axis_is_trusted(axis)) lcd_put_u8str_P(axis == Z_AXIS ? PSTR(" ") : PSTR(" ")); else lcd_put_u8str(value); } /** * Draw the Status Screen for a 128x64 DOGM (U8glib) display. * * Called as needed to update the current display stripe. * Use the PAGE_CONTAINS macros to avoid pointless draw calls. */ void MarlinUI::draw_status_screen() { constexpr int xystorage = TERN(INCH_MODE_SUPPORT, 8, 5); static char xstring[TERN(LCD_SHOW_E_TOTAL, 12, xystorage)], ystring[xystorage], zstring[8]; #if ENABLED(FILAMENT_LCD_DISPLAY) static char wstring[5], mstring[4]; #endif #if HAS_PRINT_PROGRESS #if DISABLED(DOGM_SD_PERCENT) #define _SD_INFO_X(len) (PROGRESS_BAR_X + (PROGRESS_BAR_WIDTH) / 2 - (len) * (MENU_FONT_WIDTH) / 2) #else #define _SD_INFO_X(len) (LCD_PIXEL_WIDTH - (len) * (MENU_FONT_WIDTH)) #endif #if ENABLED(DOGM_SD_PERCENT) static char progress_string[5]; #endif static uint8_t lastElapsed = 0xFF, lastProgress = 0xFF; static u8g_uint_t elapsed_x_pos = 0, progress_bar_solid_width = 0; static char elapsed_string[16]; #if ENABLED(SHOW_REMAINING_TIME) static u8g_uint_t estimation_x_pos = 0; static char estimation_string[10]; #if BOTH(DOGM_SD_PERCENT, ROTATE_PROGRESS_DISPLAY) static u8g_uint_t progress_x_pos = 0; static uint8_t progress_state = 0; static bool prev_blink = 0; #endif #endif #endif const bool show_e_total = TERN0(LCD_SHOW_E_TOTAL, printingIsActive() || marlin_state == MF_SD_COMPLETE); // At the first page, generate new display values if (first_page) { #if ANIM_HBCC uint8_t new_bits = 0; #if ANIM_HOTEND HOTEND_LOOP() if (thermalManager.isHeatingHotend(e)) SBI(new_bits, DRAWBIT_HOTEND + e); #endif if (TERN0(ANIM_BED, thermalManager.isHeatingBed())) SBI(new_bits, DRAWBIT_BED); #if DO_DRAW_CHAMBER && HAS_HEATED_CHAMBER if (thermalManager.isHeatingChamber()) SBI(new_bits, DRAWBIT_CHAMBER); #endif if (TERN0(ANIM_CUTTER, cutter.enabled())) SBI(new_bits, DRAWBIT_CUTTER); draw_bits = new_bits; #endif const xyz_pos_t lpos = current_position.asLogical(); const bool is_inch = parser.using_inch_units(); strcpy(zstring, is_inch ? ftostr42_52(LINEAR_UNIT(lpos.z)) : ftostr52sp(lpos.z)); if (show_e_total) { #if ENABLED(LCD_SHOW_E_TOTAL) const uint8_t escale = e_move_accumulator >= 100000.0f ? 10 : 1; // After 100m switch to cm sprintf_P(xstring, PSTR("%ld%cm"), uint32_t(_MAX(e_move_accumulator, 0.0f)) / escale, escale == 10 ? 'c' : 'm'); // 1234567mm #endif } else { strcpy(xstring, is_inch ? ftostr53_63(LINEAR_UNIT(lpos.x)) : ftostr4sign(lpos.x)); strcpy(ystring, is_inch ? ftostr53_63(LINEAR_UNIT(lpos.y)) : ftostr4sign(lpos.y)); } #if ENABLED(FILAMENT_LCD_DISPLAY) strcpy(wstring, ftostr12ns(filwidth.measured_mm)); strcpy(mstring, i16tostr3rj(planner.volumetric_percent(parser.volumetric_enabled))); #endif // Progress / elapsed / estimation updates and string formatting to avoid float math on each LCD draw #if HAS_PRINT_PROGRESS const progress_t progress = TERN(HAS_PRINT_PROGRESS_PERMYRIAD, get_progress_permyriad, get_progress_percent)(); duration_t elapsed = print_job_timer.duration(); const uint8_t p = progress & 0xFF, ev = elapsed.value & 0xFF; if (p != lastProgress) { lastProgress = p; progress_bar_solid_width = u8g_uint_t((PROGRESS_BAR_WIDTH - 2) * (progress / (PROGRESS_SCALE)) * 0.01f); #if ENABLED(DOGM_SD_PERCENT) if (progress == 0) { progress_string[0] = '\0'; #if ENABLED(SHOW_REMAINING_TIME) estimation_string[0] = '\0'; estimation_x_pos = _SD_INFO_X(0); #endif } else strcpy(progress_string, TERN(PRINT_PROGRESS_SHOW_DECIMALS, permyriadtostr4(progress), ui8tostr3rj(progress / (PROGRESS_SCALE)))); #if BOTH(SHOW_REMAINING_TIME, ROTATE_PROGRESS_DISPLAY) // Tri-state progress display mode progress_x_pos = _SD_INFO_X(strlen(progress_string) + 1); #endif #endif } constexpr bool can_show_days = DISABLED(DOGM_SD_PERCENT) || ENABLED(ROTATE_PROGRESS_DISPLAY); if (ev != lastElapsed) { lastElapsed = ev; const uint8_t len = elapsed.toDigital(elapsed_string, can_show_days && elapsed.value >= 60*60*24L); elapsed_x_pos = _SD_INFO_X(len); #if ENABLED(SHOW_REMAINING_TIME) if (!(ev & 0x3)) { uint32_t timeval = (0 #if BOTH(LCD_SET_PROGRESS_MANUALLY, USE_M73_REMAINING_TIME) + get_remaining_time() #endif ); if (!timeval && progress > 0) timeval = elapsed.value * (100 * (PROGRESS_SCALE) - progress) / progress; if (!timeval) { estimation_string[0] = '\0'; estimation_x_pos = _SD_INFO_X(0); } else { duration_t estimation = timeval; const uint8_t len = estimation.toDigital(estimation_string, can_show_days && estimation.value >= 60*60*24L); estimation_x_pos = _SD_INFO_X(len #if !BOTH(DOGM_SD_PERCENT, ROTATE_PROGRESS_DISPLAY) + 1 #endif ); } } #endif } #endif } const bool blink = get_blink(); // Status Menu Font set_font(FONT_STATUSMENU); #if DO_DRAW_LOGO if (PAGE_CONTAINS(STATUS_LOGO_Y, STATUS_LOGO_Y + STATUS_LOGO_HEIGHT - 1)) u8g.drawBitmapP(STATUS_LOGO_X, STATUS_LOGO_Y, STATUS_LOGO_BYTEWIDTH, STATUS_LOGO_HEIGHT, status_logo_bmp); #endif #if STATUS_HEATERS_WIDTH // Draw all heaters (and maybe the bed) in one go if (PAGE_CONTAINS(STATUS_HEATERS_Y, STATUS_HEATERS_Y + STATUS_HEATERS_HEIGHT - 1)) u8g.drawBitmapP(STATUS_HEATERS_X, STATUS_HEATERS_Y, STATUS_HEATERS_BYTEWIDTH, STATUS_HEATERS_HEIGHT, status_heaters_bmp); #endif #if DO_DRAW_CUTTER && DISABLED(STATUS_COMBINE_HEATERS) #if ANIM_CUTTER #define CUTTER_BITMAP(S) ((S) ? status_cutter_on_bmp : status_cutter_bmp) #else #define CUTTER_BITMAP(S) status_cutter_bmp #endif const uint8_t cuttery = STATUS_CUTTER_Y(CUTTER_ALT()), cutterh = STATUS_CUTTER_HEIGHT(CUTTER_ALT()); if (PAGE_CONTAINS(cuttery, cuttery + cutterh - 1)) u8g.drawBitmapP(STATUS_CUTTER_X, cuttery, STATUS_CUTTER_BYTEWIDTH, cutterh, CUTTER_BITMAP(CUTTER_ALT())); #endif #if DO_DRAW_BED && DISABLED(STATUS_COMBINE_HEATERS) #if ANIM_BED #define BED_BITMAP(S) ((S) ? status_bed_on_bmp : status_bed_bmp) #else #define BED_BITMAP(S) status_bed_bmp #endif const uint8_t bedy = STATUS_BED_Y(BED_ALT()), bedh = STATUS_BED_HEIGHT(BED_ALT()); if (PAGE_CONTAINS(bedy, bedy + bedh - 1)) u8g.drawBitmapP(STATUS_BED_X, bedy, STATUS_BED_BYTEWIDTH, bedh, BED_BITMAP(BED_ALT())); #endif #if DO_DRAW_CHAMBER && DISABLED(STATUS_COMBINE_HEATERS) #if ANIM_CHAMBER #define CHAMBER_BITMAP(S) ((S) ? status_chamber_on_bmp : status_chamber_bmp) #else #define CHAMBER_BITMAP(S) status_chamber_bmp #endif const uint8_t chambery = STATUS_CHAMBER_Y(CHAMBER_ALT()), chamberh = STATUS_CHAMBER_HEIGHT(CHAMBER_ALT()); if (PAGE_CONTAINS(chambery, chambery + chamberh - 1)) u8g.drawBitmapP(STATUS_CHAMBER_X, chambery, STATUS_CHAMBER_BYTEWIDTH, chamberh, CHAMBER_BITMAP(CHAMBER_ALT())); #endif #if DO_DRAW_FAN #if STATUS_FAN_FRAMES > 2 static bool old_blink; static uint8_t fan_frame; if (old_blink != blink) { old_blink = blink; if (!thermalManager.fan_speed[0] || ++fan_frame >= STATUS_FAN_FRAMES) fan_frame = 0; } #endif if (PAGE_CONTAINS(STATUS_FAN_Y, STATUS_FAN_Y + STATUS_FAN_HEIGHT - 1)) u8g.drawBitmapP(STATUS_FAN_X, STATUS_FAN_Y, STATUS_FAN_BYTEWIDTH, STATUS_FAN_HEIGHT, #if STATUS_FAN_FRAMES > 2 fan_frame == 1 ? status_fan1_bmp : fan_frame == 2 ? status_fan2_bmp : #if STATUS_FAN_FRAMES > 3 fan_frame == 3 ? status_fan3_bmp : #endif #elif STATUS_FAN_FRAMES > 1 blink && thermalManager.fan_speed[0] ? status_fan1_bmp : #endif status_fan0_bmp ); #endif // // Temperature Graphics and Info // if (PAGE_UNDER(6 + 1 + 12 + 1 + 6 + 1)) { // Extruders #if DO_DRAW_HOTENDS LOOP_L_N(e, MAX_HOTEND_DRAW) _draw_hotend_status((heater_id_t)e, blink); #endif // Laser / Spindle #if DO_DRAW_CUTTER if (cutter.isReady && PAGE_CONTAINS(STATUS_CUTTER_TEXT_Y - INFO_FONT_ASCENT, STATUS_CUTTER_TEXT_Y - 1)) { #if CUTTER_UNIT_IS(PERCENT) lcd_put_u8str(STATUS_CUTTER_TEXT_X, STATUS_CUTTER_TEXT_Y, cutter_power2str(cutter.unitPower)); #elif CUTTER_UNIT_IS(RPM) lcd_put_u8str(STATUS_CUTTER_TEXT_X - 2, STATUS_CUTTER_TEXT_Y, ftostr51rj(float(cutter.unitPower) / 1000)); lcd_put_wchar('K'); #else lcd_put_u8str(STATUS_CUTTER_TEXT_X, STATUS_CUTTER_TEXT_Y, cutter_power2str(cutter.unitPower)); #endif } #endif // Laser Cooler #if DO_DRAW_COOLER const uint8_t coolery = STATUS_COOLER_Y(status_cooler_bmp1), coolerh = STATUS_COOLER_HEIGHT(status_cooler_bmp1); if (PAGE_CONTAINS(coolery, coolery + coolerh - 1)) u8g.drawBitmapP(STATUS_COOLER_X, coolery, STATUS_COOLER_BYTEWIDTH, coolerh, blink && cooler.enabled ? status_cooler_bmp2 : status_cooler_bmp1); #endif // Laser Cooler Flow Meter #if DO_DRAW_FLOWMETER const uint8_t flowmetery = STATUS_FLOWMETER_Y(status_flowmeter_bmp1), flowmeterh = STATUS_FLOWMETER_HEIGHT(status_flowmeter_bmp1); if (PAGE_CONTAINS(flowmetery, flowmetery + flowmeterh - 1)) u8g.drawBitmapP(STATUS_FLOWMETER_X, flowmetery, STATUS_FLOWMETER_BYTEWIDTH, flowmeterh, blink && cooler.flowpulses ? status_flowmeter_bmp2 : status_flowmeter_bmp1); #endif // Heated Bed TERN_(DO_DRAW_BED, _draw_bed_status(blink)); // Heated Chamber TERN_(DO_DRAW_CHAMBER, _draw_chamber_status()); // Cooler TERN_(DO_DRAW_COOLER, _draw_cooler_status()); // Flowmeter TERN_(DO_DRAW_FLOWMETER, _draw_flowmeter_status()); // Fan, if a bitmap was provided #if DO_DRAW_FAN if (PAGE_CONTAINS(STATUS_FAN_TEXT_Y - INFO_FONT_ASCENT, STATUS_FAN_TEXT_Y - 1)) { char c = '%'; uint16_t spd = thermalManager.fan_speed[0]; if (spd) { #if ENABLED(ADAPTIVE_FAN_SLOWING) if (!blink && thermalManager.fan_speed_scaler[0] < 128) { spd = thermalManager.scaledFanSpeed(0, spd); c = '*'; } #endif lcd_put_u8str(STATUS_FAN_TEXT_X, STATUS_FAN_TEXT_Y, i16tostr3rj(thermalManager.pwmToPercent(spd))); lcd_put_wchar(c); } } #endif } #if ENABLED(SDSUPPORT) // // SD Card Symbol // if (card.isFileOpen() && PAGE_CONTAINS(42, 51)) { // Upper box u8g.drawBox(42, 42, 8, 7); // 42-48 (or 41-47) // Right edge u8g.drawBox(50, 44, 2, 5); // 44-48 (or 43-47) // Bottom hollow box u8g.drawFrame(42, 49, 10, 4); // 49-52 (or 48-51) // Corner pixel u8g.drawPixel(50, 43); // 43 (or 42) } #endif // SDSUPPORT #if HAS_PRINT_PROGRESS // // Progress bar frame // if (PAGE_CONTAINS(PROGRESS_BAR_Y, PROGRESS_BAR_Y + 3)) u8g.drawFrame(PROGRESS_BAR_X, PROGRESS_BAR_Y, PROGRESS_BAR_WIDTH, 4); // // Progress bar solid part // if (PAGE_CONTAINS(PROGRESS_BAR_Y + 1, PROGRESS_BAR_Y + 2)) u8g.drawBox(PROGRESS_BAR_X + 1, PROGRESS_BAR_Y + 1, progress_bar_solid_width, 2); if (PAGE_CONTAINS(EXTRAS_BASELINE - INFO_FONT_ASCENT, EXTRAS_BASELINE - 1)) { #if ALL(DOGM_SD_PERCENT, SHOW_REMAINING_TIME, ROTATE_PROGRESS_DISPLAY) if (prev_blink != blink) { prev_blink = blink; if (++progress_state >= 3) progress_state = 0; } if (progress_state == 0) { if (progress_string[0]) { lcd_put_u8str(progress_x_pos, EXTRAS_BASELINE, progress_string); lcd_put_wchar('%'); } } else if (progress_state == 2 && estimation_string[0]) { lcd_put_u8str_P(PROGRESS_BAR_X, EXTRAS_BASELINE, PSTR("R:")); lcd_put_u8str(estimation_x_pos, EXTRAS_BASELINE, estimation_string); } else if (elapsed_string[0]) { lcd_put_u8str_P(PROGRESS_BAR_X, EXTRAS_BASELINE, E_LBL); lcd_put_u8str(elapsed_x_pos, EXTRAS_BASELINE, elapsed_string); } #else // !DOGM_SD_PERCENT || !SHOW_REMAINING_TIME || !ROTATE_PROGRESS_DISPLAY // // SD Percent Complete // #if ENABLED(DOGM_SD_PERCENT) if (progress_string[0]) { lcd_put_u8str(55, EXTRAS_BASELINE, progress_string); // Percent complete lcd_put_wchar('%'); } #endif // // Elapsed Time // #if ENABLED(SHOW_REMAINING_TIME) if (blink && estimation_string[0]) { lcd_put_wchar(estimation_x_pos, EXTRAS_BASELINE, 'R'); lcd_put_u8str(estimation_string); } else #endif lcd_put_u8str(elapsed_x_pos, EXTRAS_BASELINE, elapsed_string); #endif // !DOGM_SD_PERCENT || !SHOW_REMAINING_TIME || !ROTATE_PROGRESS_DISPLAY } #endif // HAS_PRINT_PROGRESS // // XYZ Coordinates // #if EITHER(XYZ_NO_FRAME, XYZ_HOLLOW_FRAME) #define XYZ_FRAME_TOP 29 #define XYZ_FRAME_HEIGHT INFO_FONT_ASCENT + 3 #else #define XYZ_FRAME_TOP 30 #define XYZ_FRAME_HEIGHT INFO_FONT_ASCENT + 1 #endif if (PAGE_CONTAINS(XYZ_FRAME_TOP, XYZ_FRAME_TOP + XYZ_FRAME_HEIGHT - 1)) { #if DISABLED(XYZ_NO_FRAME) #if ENABLED(XYZ_HOLLOW_FRAME) u8g.drawFrame(0, XYZ_FRAME_TOP, LCD_PIXEL_WIDTH, XYZ_FRAME_HEIGHT); // 8: 29-40 7: 29-39 #else u8g.drawBox(0, XYZ_FRAME_TOP, LCD_PIXEL_WIDTH, XYZ_FRAME_HEIGHT); // 8: 30-39 7: 30-37 #endif #endif if (PAGE_CONTAINS(XYZ_BASELINE - (INFO_FONT_ASCENT - 1), XYZ_BASELINE)) { #if NONE(XYZ_NO_FRAME, XYZ_HOLLOW_FRAME) u8g.setColorIndex(0); // white on black #endif #if HAS_DUAL_MIXING // Two-component mix / gradient instead of XY char mixer_messages[15]; PGM_P mix_label; #if ENABLED(GRADIENT_MIX) if (mixer.gradient.enabled) { mixer.update_mix_from_gradient(); mix_label = PSTR("Gr"); } else #endif { mixer.update_mix_from_vtool(); mix_label = PSTR("Mx"); } #if GCC_VERSION <= 50000 #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wformat-overflow" #endif sprintf_P(mixer_messages, PSTR(S_FMT " %d;%d%% "), mix_label, int(mixer.mix[0]), int(mixer.mix[1])); lcd_put_u8str(X_LABEL_POS, XYZ_BASELINE, mixer_messages); #if GCC_VERSION <= 50000 #pragma GCC diagnostic pop #endif #else if (show_e_total) { _draw_axis_value(E_AXIS, xstring, true); lcd_put_u8str_P(PSTR(" ")); } else { _draw_axis_value(X_AXIS, xstring, blink); _draw_axis_value(Y_AXIS, ystring, blink); } #endif _draw_axis_value(Z_AXIS, zstring, blink); #if NONE(XYZ_NO_FRAME, XYZ_HOLLOW_FRAME) u8g.setColorIndex(1); // black on white #endif } } // // Feedrate // #define EXTRAS_2_BASELINE (EXTRAS_BASELINE + 3) if (PAGE_CONTAINS(EXTRAS_2_BASELINE - INFO_FONT_ASCENT, EXTRAS_2_BASELINE - 1)) { set_font(FONT_MENU); lcd_put_wchar(3, EXTRAS_2_BASELINE, LCD_STR_FEEDRATE[0]); set_font(FONT_STATUSMENU); lcd_put_u8str(12, EXTRAS_2_BASELINE, i16tostr3rj(feedrate_percentage)); lcd_put_wchar('%'); // // Filament sensor display if SD is disabled // #if ENABLED(FILAMENT_LCD_DISPLAY) && DISABLED(SDSUPPORT) lcd_put_u8str(56, EXTRAS_2_BASELINE, wstring); lcd_put_u8str(102, EXTRAS_2_BASELINE, mstring); lcd_put_wchar('%'); set_font(FONT_MENU); lcd_put_wchar(47, EXTRAS_2_BASELINE, LCD_STR_FILAM_DIA[0]); // lcd_put_u8str_P(PSTR(LCD_STR_FILAM_DIA)); lcd_put_wchar(93, EXTRAS_2_BASELINE, LCD_STR_FILAM_MUL[0]); #endif } // // Status line // if (PAGE_CONTAINS(STATUS_BASELINE - INFO_FONT_ASCENT, STATUS_BASELINE + INFO_FONT_DESCENT)) { lcd_moveto(0, STATUS_BASELINE); #if BOTH(FILAMENT_LCD_DISPLAY, SDSUPPORT) // Alternate Status message and Filament display if (ELAPSED(millis(), next_filament_display)) { lcd_put_u8str_P(PSTR(LCD_STR_FILAM_DIA)); lcd_put_wchar(':'); lcd_put_u8str(wstring); lcd_put_u8str_P(PSTR(" " LCD_STR_FILAM_MUL)); lcd_put_wchar(':'); lcd_put_u8str(mstring); lcd_put_wchar('%'); return; } #endif draw_status_message(blink); } } /** * Draw the Status Message area */ void MarlinUI::draw_status_message(const bool blink) { // Get the UTF8 character count of the string uint8_t lcd_width = LCD_WIDTH, pixel_width = LCD_PIXEL_WIDTH, slen = utf8_strlen(status_message); #if HAS_POWER_MONITOR if (power_monitor.display_enabled()) { // make room at the end of the status line for the power monitor reading lcd_width -= 6; pixel_width -= (MENU_FONT_WIDTH) * 6; } #endif #if ENABLED(STATUS_MESSAGE_SCROLLING) static bool last_blink = false; if (slen <= lcd_width) { // The string fits within the line. Print with no scrolling lcd_put_u8str(status_message); while (slen < lcd_width) { lcd_put_wchar(' '); ++slen; } } else { // String is longer than the available space if (blink != last_blink) { last_blink = blink; advance_status_scroll(); } // Get a pointer to the next valid UTF8 character // and the string remaining length uint8_t rlen; const char *stat = status_and_len(rlen); lcd_put_u8str_max(stat, pixel_width); // If the remaining string doesn't completely fill the screen if (rlen < lcd_width) { uint8_t chars = lcd_width - rlen; // Amount of space left in characters lcd_put_wchar(' '); // Always at 1+ spaces left, draw a space if (--chars) { // Draw a second space if there's room lcd_put_wchar(' '); if (--chars) { // Draw a third space if there's room lcd_put_wchar(' '); if (--chars) { // Print a second copy of the message lcd_put_u8str_max(status_message, pixel_width - (rlen + 2) * (MENU_FONT_WIDTH)); lcd_put_wchar(' '); } } } } } #else // !STATUS_MESSAGE_SCROLLING UNUSED(blink); // Just print the string to the LCD lcd_put_u8str_max(status_message, pixel_width); // Fill the rest with spaces for (; slen < lcd_width; ++slen) lcd_put_wchar(' '); #endif // !STATUS_MESSAGE_SCROLLING #if HAS_POWER_MONITOR display_power_monitor(pixel_width + MENU_FONT_WIDTH, STATUS_BASELINE); #endif } #endif // HAS_MARLINUI_U8GLIB && !LIGHTWEIGHT_UI