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# include "temperature.h"
# include "ultralcd.h"
# ifdef ULTRA_LCD
# include "Marlin.h"
# include "language.h"
# include "cardreader.h"
# include "temperature.h"
# include "stepper.h"
# include "ConfigurationStore.h"
# include <string.h>
# include "util.h"
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# include "mesh_bed_leveling.h"
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//#include "Configuration.h"
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# include "SdFatUtil.h"
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# include "pat9125.h"
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# ifdef HAVE_TMC2130_DRIVERS
# include "tmc2130.h"
# endif //HAVE_TMC2130_DRIVERS
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# define _STRINGIFY(s) #s
int8_t encoderDiff ; /* encoderDiff is updated from interrupt context and added to encoderPosition every LCD update */
extern int lcd_change_fil_state ;
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//Function pointer to menu functions.
typedef void ( * menuFunc_t ) ( ) ;
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static void lcd_sd_updir ( ) ;
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struct EditMenuParentState
{
//prevMenu and prevEncoderPosition are used to store the previous menu location when editing settings.
menuFunc_t prevMenu ;
uint16_t prevEncoderPosition ;
//Variables used when editing values.
const char * editLabel ;
void * editValue ;
int32_t minEditValue , maxEditValue ;
// menuFunc_t callbackFunc;
} ;
union MenuData
{
struct BabyStep
{
// 29B total
int8_t status ;
int babystepMem [ 3 ] ;
float babystepMemMM [ 3 ] ;
} babyStep ;
struct SupportMenu
{
// 6B+16B=22B total
int8_t status ;
bool is_flash_air ;
uint8_t ip [ 4 ] ;
char ip_str [ 3 * 4 + 3 + 1 ] ;
} supportMenu ;
struct AdjustBed
{
// 6+13+16=35B
// editMenuParentState is used when an edit menu is entered, so it knows
// the return menu and encoder state.
struct EditMenuParentState editMenuParentState ;
int8_t status ;
int8_t left ;
int8_t right ;
int8_t front ;
int8_t rear ;
int left2 ;
int right2 ;
int front2 ;
int rear2 ;
} adjustBed ;
// editMenuParentState is used when an edit menu is entered, so it knows
// the return menu and encoder state.
struct EditMenuParentState editMenuParentState ;
} ;
// State of the currently active menu.
// C Union manages sharing of the static memory by all the menus.
union MenuData menuData = { 0 } ;
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union Data
{
byte b [ 2 ] ;
int value ;
} ;
int8_t ReInitLCD = 0 ;
int8_t SDscrool = 0 ;
int8_t SilentModeMenu = 0 ;
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# ifdef SNMM
uint8_t snmm_extruder = 0 ;
# endif
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int lcd_commands_type = LCD_COMMAND_IDLE ;
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int lcd_commands_step = 0 ;
bool isPrintPaused = false ;
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uint8_t farm_mode = 0 ;
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int farm_no = 0 ;
int farm_timer = 30 ;
int farm_status = 0 ;
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unsigned long allert_timer = millis ( ) ;
bool printer_connected = true ;
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unsigned long display_time ; //just timer for showing pid finished message on lcd;
float pid_temp = DEFAULT_PID_TEMP ;
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bool long_press_active = false ;
long long_press_timer = millis ( ) ;
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long button_blanking_time = millis ( ) ;
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bool button_pressed = false ;
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bool menuExiting = false ;
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# ifdef FILAMENT_LCD_DISPLAY
unsigned long message_millis = 0 ;
# endif
# ifdef ULTIPANEL
static float manual_feedrate [ ] = MANUAL_FEEDRATE ;
# endif // ULTIPANEL
/* !Configuration settings */
uint8_t lcd_status_message_level ;
char lcd_status_message [ LCD_WIDTH + 1 ] = " " ; //////WELCOME!
unsigned char firstrun = 1 ;
# ifdef DOGLCD
# include "dogm_lcd_implementation.h"
# else
# include "ultralcd_implementation_hitachi_HD44780.h"
# endif
/** forward declarations **/
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// void copy_and_scalePID_i();
// void copy_and_scalePID_d();
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/* Different menus */
static void lcd_status_screen ( ) ;
# ifdef ULTIPANEL
extern bool powersupply ;
static void lcd_main_menu ( ) ;
static void lcd_tune_menu ( ) ;
static void lcd_prepare_menu ( ) ;
static void lcd_move_menu ( ) ;
static void lcd_settings_menu ( ) ;
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static void lcd_calibration_menu ( ) ;
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static void lcd_language_menu ( ) ;
static void lcd_control_temperature_menu ( ) ;
static void lcd_control_temperature_preheat_pla_settings_menu ( ) ;
static void lcd_control_temperature_preheat_abs_settings_menu ( ) ;
static void lcd_control_motion_menu ( ) ;
static void lcd_control_volumetric_menu ( ) ;
static void prusa_stat_printerstatus ( int _status ) ;
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static void prusa_stat_farm_number ( ) ;
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static void prusa_stat_temperatures ( ) ;
static void prusa_stat_printinfo ( ) ;
static void lcd_farm_no ( ) ;
# ifdef DOGLCD
static void lcd_set_contrast ( ) ;
# endif
static void lcd_control_retract_menu ( ) ;
static void lcd_sdcard_menu ( ) ;
# ifdef DELTA_CALIBRATION_MENU
static void lcd_delta_calibrate_menu ( ) ;
# endif // DELTA_CALIBRATION_MENU
static void lcd_quick_feedback ( ) ; //Cause an LCD refresh, and give the user visual or audible feedback that something has happened
/* Different types of actions that can be used in menu items. */
static void menu_action_back ( menuFunc_t data ) ;
# define menu_action_back_RAM menu_action_back
static void menu_action_submenu ( menuFunc_t data ) ;
static void menu_action_gcode ( const char * pgcode ) ;
static void menu_action_function ( menuFunc_t data ) ;
static void menu_action_setlang ( unsigned char lang ) ;
static void menu_action_sdfile ( const char * filename , char * longFilename ) ;
static void menu_action_sddirectory ( const char * filename , char * longFilename ) ;
static void menu_action_setting_edit_bool ( const char * pstr , bool * ptr ) ;
static void menu_action_setting_edit_int3 ( const char * pstr , int * ptr , int minValue , int maxValue ) ;
static void menu_action_setting_edit_float3 ( const char * pstr , float * ptr , float minValue , float maxValue ) ;
static void menu_action_setting_edit_float32 ( const char * pstr , float * ptr , float minValue , float maxValue ) ;
static void menu_action_setting_edit_float43 ( const char * pstr , float * ptr , float minValue , float maxValue ) ;
static void menu_action_setting_edit_float5 ( const char * pstr , float * ptr , float minValue , float maxValue ) ;
static void menu_action_setting_edit_float51 ( const char * pstr , float * ptr , float minValue , float maxValue ) ;
static void menu_action_setting_edit_float52 ( const char * pstr , float * ptr , float minValue , float maxValue ) ;
static void menu_action_setting_edit_long5 ( const char * pstr , unsigned long * ptr , unsigned long minValue , unsigned long maxValue ) ;
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/*
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static void menu_action_setting_edit_callback_bool ( const char * pstr , bool * ptr , menuFunc_t callbackFunc ) ;
static void menu_action_setting_edit_callback_int3 ( const char * pstr , int * ptr , int minValue , int maxValue , menuFunc_t callbackFunc ) ;
static void menu_action_setting_edit_callback_float3 ( const char * pstr , float * ptr , float minValue , float maxValue , menuFunc_t callbackFunc ) ;
static void menu_action_setting_edit_callback_float32 ( const char * pstr , float * ptr , float minValue , float maxValue , menuFunc_t callbackFunc ) ;
static void menu_action_setting_edit_callback_float43 ( const char * pstr , float * ptr , float minValue , float maxValue , menuFunc_t callbackFunc ) ;
static void menu_action_setting_edit_callback_float5 ( const char * pstr , float * ptr , float minValue , float maxValue , menuFunc_t callbackFunc ) ;
static void menu_action_setting_edit_callback_float51 ( const char * pstr , float * ptr , float minValue , float maxValue , menuFunc_t callbackFunc ) ;
static void menu_action_setting_edit_callback_float52 ( const char * pstr , float * ptr , float minValue , float maxValue , menuFunc_t callbackFunc ) ;
static void menu_action_setting_edit_callback_long5 ( const char * pstr , unsigned long * ptr , unsigned long minValue , unsigned long maxValue , menuFunc_t callbackFunc ) ;
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*/
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# define ENCODER_FEEDRATE_DEADZONE 10
# if !defined(LCD_I2C_VIKI)
# ifndef ENCODER_STEPS_PER_MENU_ITEM
# define ENCODER_STEPS_PER_MENU_ITEM 5
# endif
# ifndef ENCODER_PULSES_PER_STEP
# define ENCODER_PULSES_PER_STEP 1
# endif
# else
# ifndef ENCODER_STEPS_PER_MENU_ITEM
# define ENCODER_STEPS_PER_MENU_ITEM 2 // VIKI LCD rotary encoder uses a different number of steps per rotation
# endif
# ifndef ENCODER_PULSES_PER_STEP
# define ENCODER_PULSES_PER_STEP 1
# endif
# endif
/* Helper macros for menus */
# define START_MENU() do { \
if ( encoderPosition > 0x8000 ) encoderPosition = 0 ; \
if ( encoderPosition / ENCODER_STEPS_PER_MENU_ITEM < currentMenuViewOffset ) currentMenuViewOffset = encoderPosition / ENCODER_STEPS_PER_MENU_ITEM ; \
uint8_t _lineNr = currentMenuViewOffset , _menuItemNr ; \
bool wasClicked = LCD_CLICKED ; \
for ( uint8_t _drawLineNr = 0 ; _drawLineNr < LCD_HEIGHT ; _drawLineNr + + , _lineNr + + ) { \
_menuItemNr = 0 ;
# define MENU_ITEM(type, label, args...) do { \
if ( _menuItemNr = = _lineNr ) { \
if ( lcdDrawUpdate ) { \
const char * _label_pstr = ( label ) ; \
if ( ( encoderPosition / ENCODER_STEPS_PER_MENU_ITEM ) = = _menuItemNr ) { \
lcd_implementation_drawmenu_ # # type # # _selected ( _drawLineNr , _label_pstr , # # args ) ; \
} else { \
lcd_implementation_drawmenu_ # # type ( _drawLineNr , _label_pstr , # # args ) ; \
} \
} \
if ( wasClicked & & ( encoderPosition / ENCODER_STEPS_PER_MENU_ITEM ) = = _menuItemNr ) { \
lcd_quick_feedback ( ) ; \
menu_action_ # # type ( args ) ; \
return ; \
} \
} \
_menuItemNr + + ; \
} while ( 0 )
# define MENU_ITEM_DUMMY() do { _menuItemNr++; } while(0)
# define MENU_ITEM_EDIT(type, label, args...) MENU_ITEM(setting_edit_ ## type, label, (label) , ## args )
# define MENU_ITEM_EDIT_CALLBACK(type, label, args...) MENU_ITEM(setting_edit_callback_ ## type, label, (label) , ## args )
# define END_MENU() \
if ( encoderPosition / ENCODER_STEPS_PER_MENU_ITEM > = _menuItemNr ) encoderPosition = _menuItemNr * ENCODER_STEPS_PER_MENU_ITEM - 1 ; \
if ( ( uint8_t ) ( encoderPosition / ENCODER_STEPS_PER_MENU_ITEM ) > = currentMenuViewOffset + LCD_HEIGHT ) { currentMenuViewOffset = ( encoderPosition / ENCODER_STEPS_PER_MENU_ITEM ) - LCD_HEIGHT + 1 ; lcdDrawUpdate = 1 ; _lineNr = currentMenuViewOffset - 1 ; _drawLineNr = - 1 ; } \
} } while ( 0 )
/** Used variables to keep track of the menu */
# ifndef REPRAPWORLD_KEYPAD
volatile uint8_t buttons ; //Contains the bits of the currently pressed buttons.
# else
volatile uint8_t buttons_reprapworld_keypad ; // to store the reprapworld_keypad shift register values
# endif
# ifdef LCD_HAS_SLOW_BUTTONS
volatile uint8_t slow_buttons ; //Contains the bits of the currently pressed buttons.
# endif
uint8_t currentMenuViewOffset ; /* scroll offset in the current menu */
uint8_t lastEncoderBits ;
uint32_t encoderPosition ;
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uint32_t savedEncoderPosition ;
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# if (SDCARDDETECT > 0)
bool lcd_oldcardstatus ;
# endif
# endif //ULTIPANEL
menuFunc_t currentMenu = lcd_status_screen ; /* function pointer to the currently active menu */
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menuFunc_t savedMenu ;
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uint32_t lcd_next_update_millis ;
uint8_t lcd_status_update_delay ;
bool ignore_click = false ;
bool wait_for_unclick ;
uint8_t lcdDrawUpdate = 2 ; /* Set to none-zero when the LCD needs to draw, decreased after every draw. Set to 2 in LCD routines so the LCD gets at least 1 full redraw (first redraw is partial) */
// place-holders for Ki and Kd edits
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# ifdef PIDTEMP
// float raw_Ki, raw_Kd;
# endif
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static void lcd_goto_menu ( menuFunc_t menu , const uint32_t encoder = 0 , const bool feedback = true , bool reset_menu_state = true ) {
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if ( currentMenu ! = menu ) {
currentMenu = menu ;
encoderPosition = encoder ;
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if ( reset_menu_state ) {
// Resets the global shared C union.
// This ensures, that the menu entered will find out, that it shall initialize itself.
memset ( & menuData , 0 , sizeof ( menuData ) ) ;
}
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if ( feedback ) lcd_quick_feedback ( ) ;
// For LCD_PROGRESS_BAR re-initialize the custom characters
# if defined(LCD_PROGRESS_BAR) && defined(SDSUPPORT)
lcd_set_custom_characters ( menu = = lcd_status_screen ) ;
# endif
}
}
/* Main status screen. It's up to the implementation specific part to show what is needed. As this is very display dependent */
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// Language selection dialog not active.
# define LANGSEL_OFF 0
// Language selection dialog modal, entered from the info screen. This is the case on firmware boot up,
// if the language index stored in the EEPROM is not valid.
# define LANGSEL_MODAL 1
// Language selection dialog entered from the Setup menu.
# define LANGSEL_ACTIVE 2
// Language selection dialog status
unsigned char langsel = LANGSEL_OFF ;
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void set_language_from_EEPROM ( ) {
unsigned char eep = eeprom_read_byte ( ( unsigned char * ) EEPROM_LANG ) ;
if ( eep < LANG_NUM )
{
lang_selected = eep ;
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// Language is valid, no need to enter the language selection screen.
langsel = LANGSEL_OFF ;
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}
else
{
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lang_selected = LANG_ID_DEFAULT ;
// Invalid language, enter the language selection screen in a modal mode.
langsel = LANGSEL_MODAL ;
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}
}
static void lcd_status_screen ( )
{
if ( firstrun = = 1 )
{
firstrun = 0 ;
set_language_from_EEPROM ( ) ;
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if ( lcd_status_message_level = = 0 ) {
strncpy_P ( lcd_status_message , WELCOME_MSG , LCD_WIDTH ) ;
}
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if ( eeprom_read_byte ( ( uint8_t * ) EEPROM_TOTALTIME ) = = 255 & & eeprom_read_byte ( ( uint8_t * ) EEPROM_TOTALTIME + 1 ) = = 255 & & eeprom_read_byte ( ( uint8_t * ) EEPROM_TOTALTIME + 2 ) = = 255 & & eeprom_read_byte ( ( uint8_t * ) EEPROM_TOTALTIME + 3 ) = = 255 )
{
eeprom_update_dword ( ( uint32_t * ) EEPROM_TOTALTIME , 0 ) ;
eeprom_update_dword ( ( uint32_t * ) EEPROM_FILAMENTUSED , 0 ) ;
}
if ( langsel ) {
//strncpy_P(lcd_status_message, PSTR(">>>>>>>>>>>> PRESS v"), LCD_WIDTH);
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// Entering the language selection screen in a modal mode.
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}
}
if ( lcd_status_update_delay )
lcd_status_update_delay - - ;
else
lcdDrawUpdate = 1 ;
if ( lcdDrawUpdate )
{
ReInitLCD + + ;
if ( ReInitLCD = = 30 ) {
lcd_implementation_init ( // to maybe revive the LCD if static electricity killed it.
# if defined(LCD_PROGRESS_BAR) && defined(SDSUPPORT)
currentMenu = = lcd_status_screen
# endif
) ;
ReInitLCD = 0 ;
} else {
if ( ( ReInitLCD % 10 ) = = 0 ) {
//lcd_implementation_nodisplay();
lcd_implementation_init_noclear ( // to maybe revive the LCD if static electricity killed it.
# if defined(LCD_PROGRESS_BAR) && defined(SDSUPPORT)
currentMenu = = lcd_status_screen
# endif
) ;
}
}
//lcd_implementation_display();
lcd_implementation_status_screen ( ) ;
//lcd_implementation_clear();
if ( farm_mode )
{
farm_timer - - ;
if ( farm_timer < 1 )
{
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farm_timer = 180 ;
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prusa_statistics ( 0 ) ;
}
switch ( farm_timer )
{
case 45 :
prusa_statistics ( 21 ) ;
break ;
case 10 :
if ( IS_SD_PRINTING )
{
prusa_statistics ( 20 ) ;
}
break ;
}
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} // end of farm_mode
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lcd_status_update_delay = 10 ; /* redraw the main screen every second. This is easier then trying keep track of all things that change on the screen */
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if ( lcd_commands_type ! = LCD_COMMAND_IDLE )
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{
lcd_commands ( ) ;
}
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} // end of lcdDrawUpdate
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# ifdef ULTIPANEL
bool current_click = LCD_CLICKED ;
if ( ignore_click ) {
if ( wait_for_unclick ) {
if ( ! current_click ) {
ignore_click = wait_for_unclick = false ;
}
else {
current_click = false ;
}
}
else if ( current_click ) {
lcd_quick_feedback ( ) ;
wait_for_unclick = true ;
current_click = false ;
}
}
//if (--langsel ==0) {langsel=1;current_click=true;}
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if ( current_click & & ( lcd_commands_type ! = LCD_COMMAND_STOP_PRINT ) ) //click is aborted unless stop print finishes
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{
lcd_goto_menu ( lcd_main_menu ) ;
lcd_implementation_init ( // to maybe revive the LCD if static electricity killed it.
# if defined(LCD_PROGRESS_BAR) && defined(SDSUPPORT)
currentMenu = = lcd_status_screen
# endif
) ;
# ifdef FILAMENT_LCD_DISPLAY
message_millis = millis ( ) ; // get status message to show up for a while
# endif
}
# ifdef ULTIPANEL_FEEDMULTIPLY
// Dead zone at 100% feedrate
if ( ( feedmultiply < 100 & & ( feedmultiply + int ( encoderPosition ) ) > 100 ) | |
( feedmultiply > 100 & & ( feedmultiply + int ( encoderPosition ) ) < 100 ) )
{
encoderPosition = 0 ;
feedmultiply = 100 ;
}
if ( feedmultiply = = 100 & & int ( encoderPosition ) > ENCODER_FEEDRATE_DEADZONE )
{
feedmultiply + = int ( encoderPosition ) - ENCODER_FEEDRATE_DEADZONE ;
encoderPosition = 0 ;
}
else if ( feedmultiply = = 100 & & int ( encoderPosition ) < - ENCODER_FEEDRATE_DEADZONE )
{
feedmultiply + = int ( encoderPosition ) + ENCODER_FEEDRATE_DEADZONE ;
encoderPosition = 0 ;
}
else if ( feedmultiply ! = 100 )
{
feedmultiply + = int ( encoderPosition ) ;
encoderPosition = 0 ;
}
# endif //ULTIPANEL_FEEDMULTIPLY
if ( feedmultiply < 10 )
feedmultiply = 10 ;
else if ( feedmultiply > 999 )
feedmultiply = 999 ;
# endif //ULTIPANEL
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if ( farm_mode & & ! printer_connected ) {
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_PRINTER_DISCONNECTED ) ;
}
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lcd . setCursor ( 0 , 3 ) ;
lcd_implementation_print ( pat9125_x ) ;
lcd . setCursor ( 10 , 3 ) ;
lcd_implementation_print ( pat9125_y ) ;
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}
# ifdef ULTIPANEL
void lcd_commands ( )
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{
char cmd1 [ 25 ] ;
if ( lcd_commands_type = = LCD_COMMAND_LONG_PAUSE )
{
if ( lcd_commands_step = = 0 ) {
card . pauseSDPrint ( ) ;
lcd_setstatuspgm ( MSG_FINISHING_MOVEMENTS ) ;
lcdDrawUpdate = 3 ;
lcd_commands_step = 1 ;
}
if ( lcd_commands_step = = 1 & & ! blocks_queued ( ) ) {
lcd_setstatuspgm ( MSG_PRINT_PAUSED ) ;
isPrintPaused = true ;
long_pause ( ) ;
lcd_commands_type = 0 ;
lcd_commands_step = 0 ;
}
}
if ( lcd_commands_type = = LCD_COMMAND_LONG_PAUSE_RESUME ) {
char cmd1 [ 30 ] ;
if ( lcd_commands_step = = 0 ) {
lcdDrawUpdate = 3 ;
lcd_commands_step = 4 ;
}
if ( lcd_commands_step = = 1 & & ! blocks_queued ( ) ) { //recover feedmultiply
sprintf_P ( cmd1 , PSTR ( " M220 S%d " ) , saved_feedmultiply ) ;
enquecommand ( cmd1 ) ;
isPrintPaused = false ;
pause_time + = ( millis ( ) - start_pause_print ) ; //accumulate time when print is paused for correct statistics calculation
card . startFileprint ( ) ;
lcd_commands_step = 0 ;
lcd_commands_type = 0 ;
}
if ( lcd_commands_step = = 2 & & ! blocks_queued ( ) ) { //turn on fan, move Z and unretract
sprintf_P ( cmd1 , PSTR ( " M106 S%d " ) , fanSpeedBckp ) ;
enquecommand ( cmd1 ) ;
strcpy ( cmd1 , " G1 Z " ) ;
strcat ( cmd1 , ftostr32 ( pause_lastpos [ Z_AXIS ] ) ) ;
enquecommand ( cmd1 ) ;
if ( axis_relative_modes [ 3 ] = = true ) enquecommand_P ( PSTR ( " M83 " ) ) ; // set extruder to relative mode.
else enquecommand_P ( PSTR ( " M82 " ) ) ; // set extruder to absolute mode
enquecommand_P ( PSTR ( " G1 E " STRINGIFY ( DEFAULT_RETRACTION ) ) ) ; //unretract
enquecommand_P ( PSTR ( " G90 " ) ) ; //absolute positioning
lcd_commands_step = 1 ;
}
if ( lcd_commands_step = = 3 & & ! blocks_queued ( ) ) { //wait for nozzle to reach target temp
strcpy ( cmd1 , " M109 S " ) ;
strcat ( cmd1 , ftostr3 ( HotendTempBckp ) ) ;
enquecommand ( cmd1 ) ;
lcd_commands_step = 2 ;
}
if ( lcd_commands_step = = 4 & & ! blocks_queued ( ) ) { //set temperature back and move xy
strcpy ( cmd1 , " M104 S " ) ;
strcat ( cmd1 , ftostr3 ( HotendTempBckp ) ) ;
enquecommand ( cmd1 ) ;
strcpy ( cmd1 , " G1 X " ) ;
strcat ( cmd1 , ftostr32 ( pause_lastpos [ X_AXIS ] ) ) ;
strcat ( cmd1 , " Y " ) ;
strcat ( cmd1 , ftostr32 ( pause_lastpos [ Y_AXIS ] ) ) ;
enquecommand ( cmd1 ) ;
lcd_setstatuspgm ( MSG_RESUMING_PRINT ) ;
lcd_commands_step = 3 ;
}
}
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if ( lcd_commands_type = = LCD_COMMAND_STOP_PRINT ) /// stop print
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{
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uint8_t stopped_extruder ;
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if ( lcd_commands_step = = 0 )
{
lcd_commands_step = 6 ;
custom_message = true ;
}
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if ( lcd_commands_step = = 1 & & ! blocks_queued ( ) )
{
lcd_commands_step = 0 ;
lcd_commands_type = 0 ;
lcd_setstatuspgm ( WELCOME_MSG ) ;
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custom_message_type = 0 ;
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custom_message = false ;
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isPrintPaused = false ;
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}
if ( lcd_commands_step = = 2 & & ! blocks_queued ( ) )
{
setTargetBed ( 0 ) ;
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enquecommand_P ( PSTR ( " M104 S0 " ) ) ; //set hotend temp to 0
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manage_heater ( ) ;
lcd_setstatuspgm ( WELCOME_MSG ) ;
cancel_heatup = false ;
lcd_commands_step = 1 ;
}
if ( lcd_commands_step = = 3 & & ! blocks_queued ( ) )
{
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// M84: Disable steppers.
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enquecommand_P ( PSTR ( " M84 " ) ) ;
autotempShutdown ( ) ;
lcd_commands_step = 2 ;
}
if ( lcd_commands_step = = 4 & & ! blocks_queued ( ) )
{
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lcd_setstatuspgm ( MSG_PLEASE_WAIT ) ;
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// G90: Absolute positioning.
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enquecommand_P ( PSTR ( " G90 " ) ) ;
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// M83: Set extruder to relative mode.
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enquecommand_P ( PSTR ( " M83 " ) ) ;
# ifdef X_CANCEL_POS
enquecommand_P ( PSTR ( " G1 X " STRINGIFY ( X_CANCEL_POS ) " Y " STRINGIFY ( Y_CANCEL_POS ) " E0 F7000 " ) ) ;
# else
enquecommand_P ( PSTR ( " G1 X50 Y " STRINGIFY ( Y_MAX_POS ) " E0 F7000 " ) ) ;
# endif
lcd_ignore_click ( false ) ;
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# ifdef SNMM
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lcd_commands_step = 8 ;
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# else
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lcd_commands_step = 3 ;
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# endif
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}
if ( lcd_commands_step = = 5 & & ! blocks_queued ( ) )
{
lcd_setstatuspgm ( MSG_PRINT_ABORTED ) ;
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// G91: Set to relative positioning.
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enquecommand_P ( PSTR ( " G91 " ) ) ;
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// Lift up.
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enquecommand_P ( PSTR ( " G1 Z15 F1500 " ) ) ;
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if ( axis_known_position [ X_AXIS ] & & axis_known_position [ Y_AXIS ] ) lcd_commands_step = 4 ;
else lcd_commands_step = 3 ;
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}
if ( lcd_commands_step = = 6 & & ! blocks_queued ( ) )
{
lcd_setstatuspgm ( MSG_PRINT_ABORTED ) ;
cancel_heatup = true ;
setTargetBed ( 0 ) ;
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# ifndef SNMM
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setTargetHotend ( 0 , 0 ) ; //heating when changing filament for multicolor
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setTargetHotend ( 0 , 1 ) ;
setTargetHotend ( 0 , 2 ) ;
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# endif
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manage_heater ( ) ;
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custom_message = true ;
custom_message_type = 2 ;
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lcd_commands_step = 5 ;
}
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if ( lcd_commands_step = = 7 & & ! blocks_queued ( ) ) {
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switch ( snmm_stop_print_menu ( ) ) {
case 0 : enquecommand_P ( PSTR ( " M702 " ) ) ; break ; //all
case 1 : enquecommand_P ( PSTR ( " M702 U " ) ) ; break ; //used
case 2 : enquecommand_P ( PSTR ( " M702 C " ) ) ; break ; //current
default : enquecommand_P ( PSTR ( " M702 " ) ) ; break ;
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}
lcd_commands_step = 3 ;
}
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if ( lcd_commands_step = = 8 & & ! blocks_queued ( ) ) { //step 8 is here for delay (going to next step after execution of all gcodes from step 4)
lcd_commands_step = 7 ;
}
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}
if ( lcd_commands_type = = 3 )
{
lcd_commands_type = 0 ;
}
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if ( lcd_commands_type = = LCD_COMMAND_FARM_MODE_CONFIRM ) /// farm mode confirm
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{
if ( lcd_commands_step = = 0 ) { lcd_commands_step = 6 ; custom_message = true ; }
if ( lcd_commands_step = = 1 & & ! blocks_queued ( ) )
{
lcd_confirm_print ( ) ;
lcd_commands_step = 0 ;
lcd_commands_type = 0 ;
}
if ( lcd_commands_step = = 2 & & ! blocks_queued ( ) )
{
lcd_commands_step = 1 ;
}
if ( lcd_commands_step = = 3 & & ! blocks_queued ( ) )
{
lcd_commands_step = 2 ;
}
if ( lcd_commands_step = = 4 & & ! blocks_queued ( ) )
{
enquecommand_P ( PSTR ( " G90 " ) ) ;
enquecommand_P ( PSTR ( " G1 X " STRINGIFY ( X_CANCEL_POS ) " Y " STRINGIFY ( Y_CANCEL_POS ) " E0 F7000 " ) ) ;
lcd_commands_step = 3 ;
}
if ( lcd_commands_step = = 5 & & ! blocks_queued ( ) )
{
lcd_commands_step = 4 ;
}
if ( lcd_commands_step = = 6 & & ! blocks_queued ( ) )
{
enquecommand_P ( PSTR ( " G91 " ) ) ;
enquecommand_P ( PSTR ( " G1 Z15 F1500 " ) ) ;
st_synchronize ( ) ;
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# ifdef SNMM
lcd_commands_step = 7 ;
# else
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lcd_commands_step = 5 ;
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# endif
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}
}
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if ( lcd_commands_type = = LCD_COMMAND_PID_EXTRUDER ) {
char cmd1 [ 30 ] ;
if ( lcd_commands_step = = 0 ) {
custom_message_type = 3 ;
custom_message_state = 1 ;
custom_message = true ;
lcdDrawUpdate = 3 ;
lcd_commands_step = 3 ;
}
if ( lcd_commands_step = = 3 & & ! blocks_queued ( ) ) { //PID calibration
strcpy ( cmd1 , " M303 E0 S " ) ;
strcat ( cmd1 , ftostr3 ( pid_temp ) ) ;
enquecommand ( cmd1 ) ;
lcd_setstatuspgm ( MSG_PID_RUNNING ) ;
lcd_commands_step = 2 ;
}
if ( lcd_commands_step = = 2 & & pid_tuning_finished ) { //saving to eeprom
pid_tuning_finished = false ;
custom_message_state = 0 ;
lcd_setstatuspgm ( MSG_PID_FINISHED ) ;
strcpy ( cmd1 , " M301 P " ) ;
strcat ( cmd1 , ftostr32 ( _Kp ) ) ;
strcat ( cmd1 , " I " ) ;
strcat ( cmd1 , ftostr32 ( _Ki ) ) ;
strcat ( cmd1 , " D " ) ;
strcat ( cmd1 , ftostr32 ( _Kd ) ) ;
enquecommand ( cmd1 ) ;
enquecommand_P ( PSTR ( " M500 " ) ) ;
display_time = millis ( ) ;
lcd_commands_step = 1 ;
}
if ( ( lcd_commands_step = = 1 ) & & ( ( millis ( ) - display_time ) > 2000 ) ) { //calibration finished message
lcd_setstatuspgm ( WELCOME_MSG ) ;
custom_message_type = 0 ;
custom_message = false ;
pid_temp = DEFAULT_PID_TEMP ;
lcd_commands_step = 0 ;
lcd_commands_type = 0 ;
}
}
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}
static void lcd_return_to_status ( ) {
lcd_implementation_init ( // to maybe revive the LCD if static electricity killed it.
# if defined(LCD_PROGRESS_BAR) && defined(SDSUPPORT)
currentMenu = = lcd_status_screen
# endif
) ;
lcd_goto_menu ( lcd_status_screen , 0 , false ) ;
}
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static void lcd_sdcard_pause ( ) {
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lcd_return_to_status ( ) ;
lcd_commands_type = LCD_COMMAND_LONG_PAUSE ;
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}
static void lcd_sdcard_resume ( ) {
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lcd_return_to_status ( ) ;
lcd_commands_type = LCD_COMMAND_LONG_PAUSE_RESUME ;
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}
float move_menu_scale ;
static void lcd_move_menu_axis ( ) ;
/* Menu implementation */
void lcd_preheat_pla ( )
{
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setTargetHotend0 ( PLA_PREHEAT_HOTEND_TEMP ) ;
setTargetBed ( PLA_PREHEAT_HPB_TEMP ) ;
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fanSpeed = 0 ;
lcd_return_to_status ( ) ;
setWatch ( ) ; // heater sanity check timer
}
void lcd_preheat_abs ( )
{
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setTargetHotend0 ( ABS_PREHEAT_HOTEND_TEMP ) ;
setTargetBed ( ABS_PREHEAT_HPB_TEMP ) ;
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fanSpeed = 0 ;
lcd_return_to_status ( ) ;
setWatch ( ) ; // heater sanity check timer
}
void lcd_preheat_pp ( )
{
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setTargetHotend0 ( PP_PREHEAT_HOTEND_TEMP ) ;
setTargetBed ( PP_PREHEAT_HPB_TEMP ) ;
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fanSpeed = 0 ;
lcd_return_to_status ( ) ;
setWatch ( ) ; // heater sanity check timer
}
void lcd_preheat_pet ( )
{
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setTargetHotend0 ( PET_PREHEAT_HOTEND_TEMP ) ;
setTargetBed ( PET_PREHEAT_HPB_TEMP ) ;
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fanSpeed = 0 ;
lcd_return_to_status ( ) ;
setWatch ( ) ; // heater sanity check timer
}
void lcd_preheat_hips ( )
{
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setTargetHotend0 ( HIPS_PREHEAT_HOTEND_TEMP ) ;
setTargetBed ( HIPS_PREHEAT_HPB_TEMP ) ;
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fanSpeed = 0 ;
lcd_return_to_status ( ) ;
setWatch ( ) ; // heater sanity check timer
}
void lcd_preheat_flex ( )
{
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setTargetHotend0 ( FLEX_PREHEAT_HOTEND_TEMP ) ;
setTargetBed ( FLEX_PREHEAT_HPB_TEMP ) ;
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fanSpeed = 0 ;
lcd_return_to_status ( ) ;
setWatch ( ) ; // heater sanity check timer
}
void lcd_cooldown ( )
{
setTargetHotend0 ( 0 ) ;
setTargetHotend1 ( 0 ) ;
setTargetHotend2 ( 0 ) ;
setTargetBed ( 0 ) ;
fanSpeed = 0 ;
lcd_return_to_status ( ) ;
}
static void lcd_preheat_menu ( )
{
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
MENU_ITEM ( function , PSTR ( " ABS - " STRINGIFY ( ABS_PREHEAT_HOTEND_TEMP ) " / " STRINGIFY ( ABS_PREHEAT_HPB_TEMP ) ) , lcd_preheat_abs ) ;
MENU_ITEM ( function , PSTR ( " PLA - " STRINGIFY ( PLA_PREHEAT_HOTEND_TEMP ) " / " STRINGIFY ( PLA_PREHEAT_HPB_TEMP ) ) , lcd_preheat_pla ) ;
MENU_ITEM ( function , PSTR ( " PET - " STRINGIFY ( PET_PREHEAT_HOTEND_TEMP ) " / " STRINGIFY ( PET_PREHEAT_HPB_TEMP ) ) , lcd_preheat_pet ) ;
MENU_ITEM ( function , PSTR ( " HIPS - " STRINGIFY ( HIPS_PREHEAT_HOTEND_TEMP ) " / " STRINGIFY ( HIPS_PREHEAT_HPB_TEMP ) ) , lcd_preheat_hips ) ;
MENU_ITEM ( function , PSTR ( " PP - " STRINGIFY ( PP_PREHEAT_HOTEND_TEMP ) " / " STRINGIFY ( PP_PREHEAT_HPB_TEMP ) ) , lcd_preheat_pp ) ;
MENU_ITEM ( function , PSTR ( " FLEX - " STRINGIFY ( FLEX_PREHEAT_HOTEND_TEMP ) " / " STRINGIFY ( FLEX_PREHEAT_HPB_TEMP ) ) , lcd_preheat_flex ) ;
MENU_ITEM ( function , MSG_COOLDOWN , lcd_cooldown ) ;
END_MENU ( ) ;
}
static void lcd_support_menu ( )
{
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if ( menuData . supportMenu . status = = 0 | | lcdDrawUpdate = = 2 ) {
// Menu was entered or SD card status has changed (plugged in or removed).
// Initialize its status.
menuData . supportMenu . status = 1 ;
menuData . supportMenu . is_flash_air = card . ToshibaFlashAir_isEnabled ( ) & & card . ToshibaFlashAir_GetIP ( menuData . supportMenu . ip ) ;
if ( menuData . supportMenu . is_flash_air )
sprintf_P ( menuData . supportMenu . ip_str , PSTR ( " %d.%d.%d.%d " ) ,
menuData . supportMenu . ip [ 0 ] , menuData . supportMenu . ip [ 1 ] ,
menuData . supportMenu . ip [ 2 ] , menuData . supportMenu . ip [ 3 ] ) ;
} else if ( menuData . supportMenu . is_flash_air & &
menuData . supportMenu . ip [ 0 ] = = 0 & & menuData . supportMenu . ip [ 1 ] = = 0 & &
menuData . supportMenu . ip [ 2 ] = = 0 & & menuData . supportMenu . ip [ 3 ] = = 0 & &
+ + menuData . supportMenu . status = = 16 ) {
// Waiting for the FlashAir card to get an IP address from a router. Force an update.
menuData . supportMenu . status = 0 ;
}
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START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
// Ideally this block would be optimized out by the compiler.
const uint8_t fw_string_len = strlen_P ( FW_VERSION_STR_P ( ) ) ;
if ( fw_string_len < 6 ) {
MENU_ITEM ( back , PSTR ( MSG_FW_VERSION " - " FW_version ) , lcd_main_menu ) ;
} else {
MENU_ITEM ( back , PSTR ( " FW - " FW_version ) , lcd_main_menu ) ;
}
MENU_ITEM ( back , MSG_PRUSA3D , lcd_main_menu ) ;
MENU_ITEM ( back , MSG_PRUSA3D_FORUM , lcd_main_menu ) ;
MENU_ITEM ( back , MSG_PRUSA3D_HOWTO , lcd_main_menu ) ;
MENU_ITEM ( back , PSTR ( " ------------ " ) , lcd_main_menu ) ;
MENU_ITEM ( back , PSTR ( FILAMENT_SIZE ) , lcd_main_menu ) ;
MENU_ITEM ( back , PSTR ( ELECTRONICS ) , lcd_main_menu ) ;
MENU_ITEM ( back , PSTR ( NOZZLE_TYPE ) , lcd_main_menu ) ;
MENU_ITEM ( back , PSTR ( " ------------ " ) , lcd_main_menu ) ;
MENU_ITEM ( back , PSTR ( " Date: " ) , lcd_main_menu ) ;
MENU_ITEM ( back , PSTR ( __DATE__ ) , lcd_main_menu ) ;
// Show the FlashAir IP address, if the card is available.
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if ( menuData . supportMenu . is_flash_air ) {
MENU_ITEM ( back , PSTR ( " ------------ " ) , lcd_main_menu ) ;
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MENU_ITEM ( back , PSTR ( " FlashAir IP Addr: " ) , lcd_main_menu ) ;
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MENU_ITEM ( back_RAM , menuData . supportMenu . ip_str , lcd_main_menu ) ;
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}
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# ifndef MK1BP
MENU_ITEM ( back , PSTR ( " ------------ " ) , lcd_main_menu ) ;
MENU_ITEM ( function , PSTR ( " XYZ cal. details " ) , lcd_service_mode_show_result ) ;
# endif //MK1BP
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END_MENU ( ) ;
}
void lcd_unLoadFilament ( )
{
if ( degHotend0 ( ) > EXTRUDE_MINTEMP ) {
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enquecommand_P ( PSTR ( " M702 " ) ) ; //unload filament
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} else {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ERROR ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PREHEAT_NOZZLE ) ;
delay ( 2000 ) ;
lcd_implementation_clear ( ) ;
}
lcd_return_to_status ( ) ;
}
void lcd_change_filament ( ) {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 1 ) ;
lcd_printPGM ( MSG_CHANGING_FILAMENT ) ;
}
void lcd_wait_interact ( ) {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 1 ) ;
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# ifdef SNMM
lcd_printPGM ( MSG_PREPARE_FILAMENT ) ;
# else
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lcd_printPGM ( MSG_INSERT_FILAMENT ) ;
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# endif
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lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PRESS ) ;
}
void lcd_change_success ( ) {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_CHANGE_SUCCESS ) ;
}
void lcd_loading_color ( ) {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_LOADING_COLOR ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PLEASE_WAIT ) ;
for ( int i = 0 ; i < 20 ; i + + ) {
lcd . setCursor ( i , 3 ) ;
lcd . print ( " . " ) ;
for ( int j = 0 ; j < 10 ; j + + ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
delay ( 85 ) ;
}
}
}
void lcd_loading_filament ( ) {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_LOADING_FILAMENT ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PLEASE_WAIT ) ;
for ( int i = 0 ; i < 20 ; i + + ) {
lcd . setCursor ( i , 3 ) ;
lcd . print ( " . " ) ;
for ( int j = 0 ; j < 10 ; j + + ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
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# ifdef SNMM
delay ( 153 ) ;
# else
delay ( 137 ) ;
# endif
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}
}
}
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void lcd_alright ( ) {
int enc_dif = 0 ;
int cursor_pos = 1 ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_CORRECTLY ) ;
lcd . setCursor ( 1 , 1 ) ;
lcd_printPGM ( MSG_YES ) ;
lcd . setCursor ( 1 , 2 ) ;
lcd_printPGM ( MSG_NOT_LOADED ) ;
lcd . setCursor ( 1 , 3 ) ;
lcd_printPGM ( MSG_NOT_COLOR ) ;
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
while ( lcd_change_fil_state = = 0 ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 4 ) {
if ( ( abs ( enc_dif - encoderDiff ) ) > 1 ) {
if ( enc_dif > encoderDiff ) {
cursor_pos - - ;
}
if ( enc_dif < encoderDiff ) {
cursor_pos + + ;
}
if ( cursor_pos > 3 ) {
cursor_pos = 3 ;
}
if ( cursor_pos < 1 ) {
cursor_pos = 1 ;
}
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , cursor_pos ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
delay ( 100 ) ;
}
}
if ( lcd_clicked ( ) ) {
lcd_change_fil_state = cursor_pos ;
delay ( 500 ) ;
}
} ;
lcd_implementation_clear ( ) ;
lcd_return_to_status ( ) ;
}
void lcd_LoadFilament ( )
{
if ( degHotend0 ( ) > EXTRUDE_MINTEMP )
{
custom_message = true ;
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loading_flag = true ;
enquecommand_P ( PSTR ( " M701 " ) ) ; //load filament
SERIAL_ECHOLN ( " Loading filament " ) ;
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}
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else
{
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ERROR ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PREHEAT_NOZZLE ) ;
delay ( 2000 ) ;
lcd_implementation_clear ( ) ;
}
lcd_return_to_status ( ) ;
}
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void lcd_menu_statistics ( )
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{
if ( IS_SD_PRINTING )
{
int _met = total_filament_used / 100000 ;
int _cm = ( total_filament_used - ( _met * 100000 ) ) / 10 ;
int _t = ( millis ( ) - starttime ) / 1000 ;
int _h = _t / 3600 ;
int _m = ( _t - ( _h * 3600 ) ) / 60 ;
int _s = _t - ( ( _h * 3600 ) + ( _m * 60 ) ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_STATS_FILAMENTUSED ) ;
lcd . setCursor ( 6 , 1 ) ;
lcd . print ( itostr3 ( _met ) ) ;
lcd . print ( " m " ) ;
lcd . print ( ftostr32ns ( _cm ) ) ;
lcd . print ( " cm " ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_STATS_PRINTTIME ) ;
lcd . setCursor ( 8 , 3 ) ;
lcd . print ( itostr2 ( _h ) ) ;
lcd . print ( " h " ) ;
lcd . print ( itostr2 ( _m ) ) ;
lcd . print ( " m " ) ;
lcd . print ( itostr2 ( _s ) ) ;
lcd . print ( " s " ) ;
if ( lcd_clicked ( ) )
{
lcd_quick_feedback ( ) ;
lcd_return_to_status ( ) ;
}
}
else
{
unsigned long _filament = eeprom_read_dword ( ( uint32_t * ) EEPROM_FILAMENTUSED ) ;
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unsigned long _time = eeprom_read_dword ( ( uint32_t * ) EEPROM_TOTALTIME ) ; //in minutes
uint8_t _hours , _minutes ;
uint32_t _days ;
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float _filament_m = ( float ) _filament ;
int _filament_km = ( _filament > = 100000 ) ? _filament / 100000 : 0 ;
if ( _filament_km > 0 ) _filament_m = _filament - ( _filament_km * 100000 ) ;
_days = _time / 1440 ;
_hours = ( _time - ( _days * 1440 ) ) / 60 ;
_minutes = _time - ( ( _days * 1440 ) + ( _hours * 60 ) ) ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_STATS_TOTALFILAMENT ) ;
lcd . setCursor ( 17 - strlen ( ftostr32ns ( _filament_m ) ) , 1 ) ;
lcd . print ( ftostr32ns ( _filament_m ) ) ;
if ( _filament_km > 0 )
{
lcd . setCursor ( 17 - strlen ( ftostr32ns ( _filament_m ) ) - 3 , 1 ) ;
lcd . print ( " km " ) ;
lcd . setCursor ( 17 - strlen ( ftostr32ns ( _filament_m ) ) - 8 , 1 ) ;
lcd . print ( itostr4 ( _filament_km ) ) ;
}
lcd . setCursor ( 18 , 1 ) ;
lcd . print ( " m " ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_STATS_TOTALPRINTTIME ) ; ;
lcd . setCursor ( 18 , 3 ) ;
lcd . print ( " m " ) ;
lcd . setCursor ( 14 , 3 ) ;
lcd . print ( itostr3 ( _minutes ) ) ;
lcd . setCursor ( 14 , 3 ) ;
lcd . print ( " : " ) ;
lcd . setCursor ( 12 , 3 ) ;
lcd . print ( " h " ) ;
lcd . setCursor ( 9 , 3 ) ;
lcd . print ( itostr3 ( _hours ) ) ;
lcd . setCursor ( 9 , 3 ) ;
lcd . print ( " : " ) ;
lcd . setCursor ( 7 , 3 ) ;
lcd . print ( " d " ) ;
lcd . setCursor ( 4 , 3 ) ;
lcd . print ( itostr3 ( _days ) ) ;
while ( ! lcd_clicked ( ) )
{
manage_heater ( ) ;
manage_inactivity ( true ) ;
delay ( 100 ) ;
}
lcd_quick_feedback ( ) ;
lcd_return_to_status ( ) ;
}
}
static void _lcd_move ( const char * name , int axis , int min , int max ) {
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if ( encoderPosition ! = 0 ) {
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refresh_cmd_timeout ( ) ;
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if ( ! planner_queue_full ( ) ) {
current_position [ axis ] + = float ( ( int ) encoderPosition ) * move_menu_scale ;
if ( min_software_endstops & & current_position [ axis ] < min ) current_position [ axis ] = min ;
if ( max_software_endstops & & current_position [ axis ] > max ) current_position [ axis ] = max ;
encoderPosition = 0 ;
world2machine_clamp ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] ) ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , manual_feedrate [ axis ] / 60 , active_extruder ) ;
lcdDrawUpdate = 1 ;
}
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}
if ( lcdDrawUpdate ) lcd_implementation_drawedit ( name , ftostr31 ( current_position [ axis ] ) ) ;
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if ( LCD_CLICKED ) lcd_goto_menu ( lcd_move_menu_axis ) ; {
}
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}
static void lcd_move_e ( )
{
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if ( degHotend0 ( ) > EXTRUDE_MINTEMP ) {
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if ( encoderPosition ! = 0 )
{
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refresh_cmd_timeout ( ) ;
if ( ! planner_queue_full ( ) ) {
current_position [ E_AXIS ] + = float ( ( int ) encoderPosition ) * move_menu_scale ;
encoderPosition = 0 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , manual_feedrate [ E_AXIS ] / 60 , active_extruder ) ;
lcdDrawUpdate = 1 ;
}
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}
if ( lcdDrawUpdate )
{
lcd_implementation_drawedit ( PSTR ( " Extruder " ) , ftostr31 ( current_position [ E_AXIS ] ) ) ;
}
if ( LCD_CLICKED ) lcd_goto_menu ( lcd_move_menu_axis ) ;
}
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else {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ERROR ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PREHEAT_NOZZLE ) ;
delay ( 2000 ) ;
lcd_return_to_status ( ) ;
}
}
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void lcd_service_mode_show_result ( ) {
lcd_set_custom_characters_degree ( ) ;
count_xyz_details ( ) ;
lcd_update_enable ( false ) ;
lcd_implementation_clear ( ) ;
lcd_printPGM ( PSTR ( " Y distance from min: " ) ) ;
lcd_print_at_PGM ( 0 , 1 , PSTR ( " Left: " ) ) ;
lcd_print_at_PGM ( 0 , 2 , PSTR ( " Center: " ) ) ;
lcd_print_at_PGM ( 0 , 3 , PSTR ( " Right: " ) ) ;
for ( int i = 0 ; i < 3 ; i + + ) {
if ( distance_from_min [ i ] < 200 ) {
lcd_print_at_PGM ( 8 , i + 1 , PSTR ( " " ) ) ;
lcd . print ( distance_from_min [ i ] ) ;
lcd_print_at_PGM ( ( distance_from_min [ i ] < 0 ) ? 14 : 13 , i + 1 , PSTR ( " mm " ) ) ;
} else lcd_print_at_PGM ( 8 , i + 1 , PSTR ( " N/A " ) ) ;
}
delay_keep_alive ( 500 ) ;
while ( ! lcd_clicked ( ) ) {
delay_keep_alive ( 100 ) ;
}
delay_keep_alive ( 500 ) ;
lcd_implementation_clear ( ) ;
lcd_printPGM ( PSTR ( " Measured skew: " ) ) ;
if ( angleDiff < 100 ) {
lcd . print ( angleDiff * 180 / M_PI ) ;
lcd . print ( LCD_STR_DEGREE ) ;
} else lcd_print_at_PGM ( 15 , 0 , PSTR ( " N/A " ) ) ;
lcd_print_at_PGM ( 0 , 1 , PSTR ( " -------------------- " ) ) ;
lcd_print_at_PGM ( 0 , 2 , PSTR ( " Slight skew: " ) ) ;
lcd_print_at_PGM ( 15 , 2 , PSTR ( " " ) ) ;
lcd . print ( bed_skew_angle_mild * 180 / M_PI ) ;
lcd . print ( LCD_STR_DEGREE ) ;
lcd_print_at_PGM ( 0 , 3 , PSTR ( " Severe skew: " ) ) ;
lcd_print_at_PGM ( 15 , 3 , PSTR ( " " ) ) ;
lcd . print ( bed_skew_angle_extreme * 180 / M_PI ) ;
lcd . print ( LCD_STR_DEGREE ) ;
delay_keep_alive ( 500 ) ;
while ( ! lcd_clicked ( ) ) {
delay_keep_alive ( 100 ) ;
}
delay_keep_alive ( 500 ) ;
lcd_set_custom_characters_arrows ( ) ;
lcd_return_to_status ( ) ;
lcd_update_enable ( true ) ;
lcd_update ( 2 ) ;
}
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// Save a single axis babystep value.
void EEPROM_save_B ( int pos , int * value )
{
union Data data ;
data . value = * value ;
eeprom_update_byte ( ( unsigned char * ) pos , data . b [ 0 ] ) ;
eeprom_update_byte ( ( unsigned char * ) pos + 1 , data . b [ 1 ] ) ;
}
// Read a single axis babystep value.
void EEPROM_read_B ( int pos , int * value )
{
union Data data ;
data . b [ 0 ] = eeprom_read_byte ( ( unsigned char * ) pos ) ;
data . b [ 1 ] = eeprom_read_byte ( ( unsigned char * ) pos + 1 ) ;
* value = data . value ;
}
static void lcd_move_x ( ) {
_lcd_move ( PSTR ( " X " ) , X_AXIS , X_MIN_POS , X_MAX_POS ) ;
}
static void lcd_move_y ( ) {
_lcd_move ( PSTR ( " Y " ) , Y_AXIS , Y_MIN_POS , Y_MAX_POS ) ;
}
static void lcd_move_z ( ) {
_lcd_move ( PSTR ( " Z " ) , Z_AXIS , Z_MIN_POS , Z_MAX_POS ) ;
}
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static void _lcd_babystep ( int axis , const char * msg )
{
if ( menuData . babyStep . status = = 0 ) {
// Menu was entered.
// Initialize its status.
menuData . babyStep . status = 1 ;
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check_babystep ( ) ;
EEPROM_read_B ( EEPROM_BABYSTEP_X , & menuData . babyStep . babystepMem [ 0 ] ) ;
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EEPROM_read_B ( EEPROM_BABYSTEP_Y , & menuData . babyStep . babystepMem [ 1 ] ) ;
EEPROM_read_B ( EEPROM_BABYSTEP_Z , & menuData . babyStep . babystepMem [ 2 ] ) ;
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menuData . babyStep . babystepMemMM [ 0 ] = menuData . babyStep . babystepMem [ 0 ] / axis_steps_per_unit [ X_AXIS ] ;
menuData . babyStep . babystepMemMM [ 1 ] = menuData . babyStep . babystepMem [ 1 ] / axis_steps_per_unit [ Y_AXIS ] ;
menuData . babyStep . babystepMemMM [ 2 ] = menuData . babyStep . babystepMem [ 2 ] / axis_steps_per_unit [ Z_AXIS ] ;
lcdDrawUpdate = 1 ;
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//SERIAL_ECHO("Z baby step: ");
//SERIAL_ECHO(menuData.babyStep.babystepMem[2]);
// Wait 90 seconds before closing the live adjust dialog.
lcd_timeoutToStatus = millis ( ) + 90000 ;
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}
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if ( encoderPosition ! = 0 )
{
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if ( homing_flag ) encoderPosition = 0 ;
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menuData . babyStep . babystepMem [ axis ] + = ( int ) encoderPosition ;
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if ( axis = = 2 ) {
if ( menuData . babyStep . babystepMem [ axis ] < Z_BABYSTEP_MIN ) menuData . babyStep . babystepMem [ axis ] = Z_BABYSTEP_MIN ; //-3999 -> -9.99 mm
else if ( menuData . babyStep . babystepMem [ axis ] > Z_BABYSTEP_MAX ) menuData . babyStep . babystepMem [ axis ] = Z_BABYSTEP_MAX ; //0
else {
CRITICAL_SECTION_START
babystepsTodo [ axis ] + = ( int ) encoderPosition ;
CRITICAL_SECTION_END
}
}
menuData . babyStep . babystepMemMM [ axis ] = menuData . babyStep . babystepMem [ axis ] / axis_steps_per_unit [ axis ] ;
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delay ( 50 ) ;
encoderPosition = 0 ;
lcdDrawUpdate = 1 ;
}
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if ( lcdDrawUpdate )
lcd_implementation_drawedit_2 ( msg , ftostr13ns ( menuData . babyStep . babystepMemMM [ axis ] ) ) ;
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if ( LCD_CLICKED | | menuExiting ) {
// Only update the EEPROM when leaving the menu.
EEPROM_save_B (
( axis = = 0 ) ? EEPROM_BABYSTEP_X : ( ( axis = = 1 ) ? EEPROM_BABYSTEP_Y : EEPROM_BABYSTEP_Z ) ,
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& menuData . babyStep . babystepMem [ axis ] ) ;
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}
if ( LCD_CLICKED ) lcd_goto_menu ( lcd_main_menu ) ;
}
static void lcd_babystep_x ( ) {
_lcd_babystep ( X_AXIS , ( MSG_BABYSTEPPING_X ) ) ;
}
static void lcd_babystep_y ( ) {
_lcd_babystep ( Y_AXIS , ( MSG_BABYSTEPPING_Y ) ) ;
}
static void lcd_babystep_z ( ) {
_lcd_babystep ( Z_AXIS , ( MSG_BABYSTEPPING_Z ) ) ;
}
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static void lcd_adjust_bed ( ) ;
static void lcd_adjust_bed_reset ( )
{
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_VALID , 1 ) ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_LEFT , 0 ) ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_RIGHT , 0 ) ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_FRONT , 0 ) ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_REAR , 0 ) ;
lcd_goto_menu ( lcd_adjust_bed , 0 , false ) ;
// Because we did not leave the menu, the menuData did not reset.
// Force refresh of the bed leveling data.
menuData . adjustBed . status = 0 ;
}
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void adjust_bed_reset ( ) {
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_VALID , 1 ) ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_LEFT , 0 ) ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_RIGHT , 0 ) ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_FRONT , 0 ) ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_REAR , 0 ) ;
menuData . adjustBed . left = menuData . adjustBed . left2 = 0 ;
menuData . adjustBed . right = menuData . adjustBed . right2 = 0 ;
menuData . adjustBed . front = menuData . adjustBed . front2 = 0 ;
menuData . adjustBed . rear = menuData . adjustBed . rear2 = 0 ;
}
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# define BED_ADJUSTMENT_UM_MAX 50
static void lcd_adjust_bed ( )
{
if ( menuData . adjustBed . status = = 0 ) {
// Menu was entered.
// Initialize its status.
menuData . adjustBed . status = 1 ;
bool valid = false ;
menuData . adjustBed . left = menuData . adjustBed . left2 = eeprom_read_int8 ( ( unsigned char * ) EEPROM_BED_CORRECTION_LEFT ) ;
menuData . adjustBed . right = menuData . adjustBed . right2 = eeprom_read_int8 ( ( unsigned char * ) EEPROM_BED_CORRECTION_RIGHT ) ;
menuData . adjustBed . front = menuData . adjustBed . front2 = eeprom_read_int8 ( ( unsigned char * ) EEPROM_BED_CORRECTION_FRONT ) ;
menuData . adjustBed . rear = menuData . adjustBed . rear2 = eeprom_read_int8 ( ( unsigned char * ) EEPROM_BED_CORRECTION_REAR ) ;
if ( eeprom_read_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_VALID ) = = 1 & &
menuData . adjustBed . left > = - BED_ADJUSTMENT_UM_MAX & & menuData . adjustBed . left < = BED_ADJUSTMENT_UM_MAX & &
menuData . adjustBed . right > = - BED_ADJUSTMENT_UM_MAX & & menuData . adjustBed . right < = BED_ADJUSTMENT_UM_MAX & &
menuData . adjustBed . front > = - BED_ADJUSTMENT_UM_MAX & & menuData . adjustBed . front < = BED_ADJUSTMENT_UM_MAX & &
menuData . adjustBed . rear > = - BED_ADJUSTMENT_UM_MAX & & menuData . adjustBed . rear < = BED_ADJUSTMENT_UM_MAX )
valid = true ;
if ( ! valid ) {
// Reset the values: simulate an edit.
menuData . adjustBed . left2 = 0 ;
menuData . adjustBed . right2 = 0 ;
menuData . adjustBed . front2 = 0 ;
menuData . adjustBed . rear2 = 0 ;
}
lcdDrawUpdate = 1 ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_BED_CORRECTION_VALID , 1 ) ;
}
if ( menuData . adjustBed . left ! = menuData . adjustBed . left2 )
eeprom_update_int8 ( ( unsigned char * ) EEPROM_BED_CORRECTION_LEFT , menuData . adjustBed . left = menuData . adjustBed . left2 ) ;
if ( menuData . adjustBed . right ! = menuData . adjustBed . right2 )
eeprom_update_int8 ( ( unsigned char * ) EEPROM_BED_CORRECTION_RIGHT , menuData . adjustBed . right = menuData . adjustBed . right2 ) ;
if ( menuData . adjustBed . front ! = menuData . adjustBed . front2 )
eeprom_update_int8 ( ( unsigned char * ) EEPROM_BED_CORRECTION_FRONT , menuData . adjustBed . front = menuData . adjustBed . front2 ) ;
if ( menuData . adjustBed . rear ! = menuData . adjustBed . rear2 )
eeprom_update_int8 ( ( unsigned char * ) EEPROM_BED_CORRECTION_REAR , menuData . adjustBed . rear = menuData . adjustBed . rear2 ) ;
START_MENU ( ) ;
MENU_ITEM ( back , MSG_SETTINGS , lcd_calibration_menu ) ;
MENU_ITEM_EDIT ( int3 , MSG_BED_CORRECTION_LEFT , & menuData . adjustBed . left2 , - BED_ADJUSTMENT_UM_MAX , BED_ADJUSTMENT_UM_MAX ) ;
MENU_ITEM_EDIT ( int3 , MSG_BED_CORRECTION_RIGHT , & menuData . adjustBed . right2 , - BED_ADJUSTMENT_UM_MAX , BED_ADJUSTMENT_UM_MAX ) ;
MENU_ITEM_EDIT ( int3 , MSG_BED_CORRECTION_FRONT , & menuData . adjustBed . front2 , - BED_ADJUSTMENT_UM_MAX , BED_ADJUSTMENT_UM_MAX ) ;
MENU_ITEM_EDIT ( int3 , MSG_BED_CORRECTION_REAR , & menuData . adjustBed . rear2 , - BED_ADJUSTMENT_UM_MAX , BED_ADJUSTMENT_UM_MAX ) ;
MENU_ITEM ( function , MSG_BED_CORRECTION_RESET , lcd_adjust_bed_reset ) ;
END_MENU ( ) ;
}
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void pid_extruder ( ) {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 1 , 0 ) ;
lcd_printPGM ( MSG_SET_TEMPERATURE ) ;
pid_temp + = int ( encoderPosition ) ;
if ( pid_temp > HEATER_0_MAXTEMP ) pid_temp = HEATER_0_MAXTEMP ;
if ( pid_temp < HEATER_0_MINTEMP ) pid_temp = HEATER_0_MINTEMP ;
encoderPosition = 0 ;
lcd . setCursor ( 1 , 2 ) ;
lcd . print ( ftostr3 ( pid_temp ) ) ;
if ( lcd_clicked ( ) ) {
lcd_commands_type = LCD_COMMAND_PID_EXTRUDER ;
lcd_return_to_status ( ) ;
lcd_update ( 2 ) ;
}
}
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void lcd_adjust_z ( ) {
int enc_dif = 0 ;
int cursor_pos = 1 ;
int fsm = 0 ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ADJUSTZ ) ;
lcd . setCursor ( 1 , 1 ) ;
lcd_printPGM ( MSG_YES ) ;
lcd . setCursor ( 1 , 2 ) ;
lcd_printPGM ( MSG_NO ) ;
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
while ( fsm = = 0 ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 4 ) {
if ( ( abs ( enc_dif - encoderDiff ) ) > 1 ) {
if ( enc_dif > encoderDiff ) {
cursor_pos - - ;
}
if ( enc_dif < encoderDiff ) {
cursor_pos + + ;
}
if ( cursor_pos > 2 ) {
cursor_pos = 2 ;
}
if ( cursor_pos < 1 ) {
cursor_pos = 1 ;
}
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , cursor_pos ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
delay ( 100 ) ;
}
}
if ( lcd_clicked ( ) ) {
fsm = cursor_pos ;
if ( fsm = = 1 ) {
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int babystepLoadZ = 0 ;
EEPROM_read_B ( EEPROM_BABYSTEP_Z , & babystepLoadZ ) ;
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CRITICAL_SECTION_START
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babystepsTodo [ Z_AXIS ] = babystepLoadZ ;
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CRITICAL_SECTION_END
} else {
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int zero = 0 ;
EEPROM_save_B ( EEPROM_BABYSTEP_X , & zero ) ;
EEPROM_save_B ( EEPROM_BABYSTEP_Y , & zero ) ;
EEPROM_save_B ( EEPROM_BABYSTEP_Z , & zero ) ;
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}
delay ( 500 ) ;
}
} ;
lcd_implementation_clear ( ) ;
lcd_return_to_status ( ) ;
}
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void lcd_wait_for_cool_down ( ) {
lcd_set_custom_characters_degree ( ) ;
while ( ( degHotend ( 0 ) > MAX_HOTEND_TEMP_CALIBRATION ) | | ( degBed ( ) > MAX_BED_TEMP_CALIBRATION ) ) {
lcd_display_message_fullscreen_P ( MSG_WAITING_TEMP ) ;
lcd . setCursor ( 0 , 4 ) ;
lcd . print ( LCD_STR_THERMOMETER [ 0 ] ) ;
lcd . print ( ftostr3 ( degHotend ( 0 ) ) ) ;
lcd . print ( " /0 " ) ;
lcd . print ( LCD_STR_DEGREE ) ;
lcd . setCursor ( 9 , 4 ) ;
lcd . print ( LCD_STR_BEDTEMP [ 0 ] ) ;
lcd . print ( ftostr3 ( degBed ( ) ) ) ;
lcd . print ( " /0 " ) ;
lcd . print ( LCD_STR_DEGREE ) ;
lcd_set_custom_characters ( ) ;
delay_keep_alive ( 1000 ) ;
}
lcd_set_custom_characters_arrows ( ) ;
}
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// Lets the user move the Z carriage up to the end stoppers.
// When done, it sets the current Z to Z_MAX_POS and returns true.
// Otherwise the Z calibration is not changed and false is returned.
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bool lcd_calibrate_z_end_stop_manual ( bool only_z )
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{
bool clean_nozzle_asked = false ;
// Don't know where we are. Let's claim we are Z=0, so the soft end stops will not be triggered when moving up.
current_position [ Z_AXIS ] = 0 ;
plan_set_position ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] ) ;
// Until confirmed by the confirmation dialog.
for ( ; ; ) {
unsigned long previous_millis_cmd = millis ( ) ;
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const char * msg = only_z ? MSG_MOVE_CARRIAGE_TO_THE_TOP_Z : MSG_MOVE_CARRIAGE_TO_THE_TOP ;
const char * msg_next = lcd_display_message_fullscreen_P ( msg ) ;
const bool multi_screen = msg_next ! = NULL ;
unsigned long previous_millis_msg = millis ( ) ;
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// Until the user finishes the z up movement.
encoderDiff = 0 ;
encoderPosition = 0 ;
for ( ; ; ) {
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// if (millis() - previous_millis_cmd > LCD_TIMEOUT_TO_STATUS)
// goto canceled;
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manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( encoderDiff ) > = ENCODER_PULSES_PER_STEP ) {
delay ( 50 ) ;
previous_millis_cmd = millis ( ) ;
encoderPosition + = abs ( encoderDiff / ENCODER_PULSES_PER_STEP ) ;
encoderDiff = 0 ;
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if ( ! planner_queue_full ( ) ) {
// Only move up, whatever direction the user rotates the encoder.
current_position [ Z_AXIS ] + = fabs ( encoderPosition ) ;
encoderPosition = 0 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , manual_feedrate [ Z_AXIS ] / 60 , active_extruder ) ;
}
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}
if ( lcd_clicked ( ) ) {
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// Abort a move if in progress.
planner_abort_hard ( ) ;
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while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
break ;
}
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if ( multi_screen & & millis ( ) - previous_millis_msg > 5000 ) {
if ( msg_next = = NULL )
msg_next = msg ;
msg_next = lcd_display_message_fullscreen_P ( msg_next ) ;
previous_millis_msg = millis ( ) ;
}
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}
if ( ! clean_nozzle_asked ) {
lcd_show_fullscreen_message_and_wait_P ( MSG_CONFIRM_NOZZLE_CLEAN ) ;
clean_nozzle_asked = true ;
}
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// Let the user confirm, that the Z carriage is at the top end stoppers.
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int8_t result = lcd_show_fullscreen_message_yes_no_and_wait_P ( MSG_CONFIRM_CARRIAGE_AT_THE_TOP , false ) ;
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if ( result = = - 1 )
goto canceled ;
else if ( result = = 1 )
goto calibrated ;
// otherwise perform another round of the Z up dialog.
}
calibrated :
// Let the machine think the Z axis is a bit higher than it is, so it will not home into the bed
// during the search for the induction points.
current_position [ Z_AXIS ] = Z_MAX_POS - 3.f ;
plan_set_position ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] ) ;
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if ( only_z ) {
lcd_display_message_fullscreen_P ( MSG_MEASURE_BED_REFERENCE_HEIGHT_LINE1 ) ;
lcd_implementation_print_at ( 0 , 3 , 1 ) ;
lcd_printPGM ( MSG_MEASURE_BED_REFERENCE_HEIGHT_LINE2 ) ;
} else {
lcd_show_fullscreen_message_and_wait_P ( MSG_PAPER ) ;
lcd_display_message_fullscreen_P ( MSG_FIND_BED_OFFSET_AND_SKEW_LINE1 ) ;
lcd_implementation_print_at ( 0 , 2 , 1 ) ;
lcd_printPGM ( MSG_FIND_BED_OFFSET_AND_SKEW_LINE2 ) ;
}
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return true ;
canceled :
return false ;
}
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static inline bool pgm_is_whitespace ( const char * c_addr )
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{
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const char c = pgm_read_byte ( c_addr ) ;
return c = = ' ' | | c = = ' \t ' | | c = = ' \r ' | | c = = ' \n ' ;
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}
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static inline bool pgm_is_interpunction ( const char * c_addr )
{
const char c = pgm_read_byte ( c_addr ) ;
return c = = ' . ' | | c = = ' , ' | | c = = ' : ' | | c = = ' ; ' | | c = = ' ? ' | | c = = ' ! ' | | c = = ' / ' ;
}
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const char * lcd_display_message_fullscreen_P ( const char * msg , uint8_t & nlines )
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{
// Disable update of the screen by the usual lcd_update() routine.
lcd_update_enable ( false ) ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
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const char * msgend = msg ;
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uint8_t row = 0 ;
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bool multi_screen = false ;
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for ( ; row < 4 ; + + row ) {
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while ( pgm_is_whitespace ( msg ) )
+ + msg ;
if ( pgm_read_byte ( msg ) = = 0 )
// End of the message.
break ;
lcd . setCursor ( 0 , row ) ;
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uint8_t linelen = min ( strlen_P ( msg ) , 20 ) ;
const char * msgend2 = msg + linelen ;
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msgend = msgend2 ;
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if ( row = = 3 & & linelen = = 20 ) {
// Last line of the display, full line shall be displayed.
// Find out, whether this message will be split into multiple screens.
while ( pgm_is_whitespace ( msgend ) )
+ + msgend ;
multi_screen = pgm_read_byte ( msgend ) ! = 0 ;
if ( multi_screen )
msgend = ( msgend2 - = 2 ) ;
}
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if ( pgm_read_byte ( msgend ) ! = 0 & & ! pgm_is_whitespace ( msgend ) & & ! pgm_is_interpunction ( msgend ) ) {
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// Splitting a word. Find the start of the current word.
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while ( msgend > msg & & ! pgm_is_whitespace ( msgend - 1 ) )
- - msgend ;
if ( msgend = = msg )
// Found a single long word, which cannot be split. Just cut it.
msgend = msgend2 ;
}
for ( ; msg < msgend ; + + msg ) {
char c = char ( pgm_read_byte ( msg ) ) ;
if ( c = = ' ~ ' )
c = ' ' ;
lcd . print ( c ) ;
}
}
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if ( multi_screen ) {
// Display the "next screen" indicator character.
// lcd_set_custom_characters_arrows();
lcd_set_custom_characters_nextpage ( ) ;
lcd . setCursor ( 19 , 3 ) ;
// Display the down arrow.
lcd . print ( char ( 1 ) ) ;
}
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nlines = row ;
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return multi_screen ? msgend : NULL ;
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}
void lcd_show_fullscreen_message_and_wait_P ( const char * msg )
{
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const char * msg_next = lcd_display_message_fullscreen_P ( msg ) ;
bool multi_screen = msg_next ! = NULL ;
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// Until confirmed by a button click.
for ( ; ; ) {
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// Wait for 5 seconds before displaying the next text.
for ( uint8_t i = 0 ; i < 100 ; + + i ) {
delay_keep_alive ( 50 ) ;
if ( lcd_clicked ( ) ) {
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
return ;
}
}
if ( multi_screen ) {
if ( msg_next = = NULL )
msg_next = msg ;
msg_next = lcd_display_message_fullscreen_P ( msg_next ) ;
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}
}
}
void lcd_wait_for_click ( )
{
for ( ; ; ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( lcd_clicked ( ) ) {
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
return ;
}
}
}
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int8_t lcd_show_fullscreen_message_yes_no_and_wait_P ( const char * msg , bool allow_timeouting , bool default_yes )
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{
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lcd_display_message_fullscreen_P ( msg ) ;
if ( default_yes ) {
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( PSTR ( " > " ) ) ;
lcd_printPGM ( MSG_YES ) ;
lcd . setCursor ( 1 , 3 ) ;
lcd_printPGM ( MSG_NO ) ;
}
else {
lcd . setCursor ( 1 , 2 ) ;
lcd_printPGM ( MSG_YES ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( PSTR ( " > " ) ) ;
lcd_printPGM ( MSG_NO ) ;
}
bool yes = default_yes ? true : false ;
// Wait for user confirmation or a timeout.
unsigned long previous_millis_cmd = millis ( ) ;
int8_t enc_dif = encoderDiff ;
for ( ; ; ) {
if ( allow_timeouting & & millis ( ) - previous_millis_cmd > LCD_TIMEOUT_TO_STATUS )
return - 1 ;
manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( enc_dif - encoderDiff ) > 4 ) {
lcd . setCursor ( 0 , 2 ) ;
if ( enc_dif < encoderDiff & & yes ) {
lcd_printPGM ( ( PSTR ( " " ) ) ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( ( PSTR ( " > " ) ) ) ;
yes = false ;
}
else if ( enc_dif > encoderDiff & & ! yes ) {
lcd_printPGM ( ( PSTR ( " > " ) ) ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( ( PSTR ( " " ) ) ) ;
yes = true ;
}
enc_dif = encoderDiff ;
}
if ( lcd_clicked ( ) ) {
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
return yes ;
}
}
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}
void lcd_bed_calibration_show_result ( BedSkewOffsetDetectionResultType result , uint8_t point_too_far_mask )
{
const char * msg = NULL ;
if ( result = = BED_SKEW_OFFSET_DETECTION_POINT_NOT_FOUND ) {
lcd_show_fullscreen_message_and_wait_P ( MSG_BED_SKEW_OFFSET_DETECTION_POINT_NOT_FOUND ) ;
} else if ( result = = BED_SKEW_OFFSET_DETECTION_FITTING_FAILED ) {
if ( point_too_far_mask = = 0 )
msg = MSG_BED_SKEW_OFFSET_DETECTION_FITTING_FAILED ;
else if ( point_too_far_mask = = 2 | | point_too_far_mask = = 7 )
// Only the center point or all the three front points.
msg = MSG_BED_SKEW_OFFSET_DETECTION_FAILED_FRONT_BOTH_FAR ;
else if ( point_too_far_mask & 1 = = 0 )
// The right and maybe the center point out of reach.
msg = MSG_BED_SKEW_OFFSET_DETECTION_FAILED_FRONT_RIGHT_FAR ;
else
// The left and maybe the center point out of reach.
msg = MSG_BED_SKEW_OFFSET_DETECTION_FAILED_FRONT_LEFT_FAR ;
lcd_show_fullscreen_message_and_wait_P ( msg ) ;
} else {
if ( point_too_far_mask ! = 0 ) {
if ( point_too_far_mask = = 2 | | point_too_far_mask = = 7 )
// Only the center point or all the three front points.
msg = MSG_BED_SKEW_OFFSET_DETECTION_WARNING_FRONT_BOTH_FAR ;
else if ( point_too_far_mask & 1 = = 0 )
// The right and maybe the center point out of reach.
msg = MSG_BED_SKEW_OFFSET_DETECTION_WARNING_FRONT_RIGHT_FAR ;
else
// The left and maybe the center point out of reach.
msg = MSG_BED_SKEW_OFFSET_DETECTION_WARNING_FRONT_LEFT_FAR ;
lcd_show_fullscreen_message_and_wait_P ( msg ) ;
}
if ( point_too_far_mask = = 0 | | result > 0 ) {
switch ( result ) {
default :
// should not happen
msg = MSG_BED_SKEW_OFFSET_DETECTION_FITTING_FAILED ;
break ;
case BED_SKEW_OFFSET_DETECTION_PERFECT :
msg = MSG_BED_SKEW_OFFSET_DETECTION_PERFECT ;
break ;
case BED_SKEW_OFFSET_DETECTION_SKEW_MILD :
msg = MSG_BED_SKEW_OFFSET_DETECTION_SKEW_MILD ;
break ;
case BED_SKEW_OFFSET_DETECTION_SKEW_EXTREME :
msg = MSG_BED_SKEW_OFFSET_DETECTION_SKEW_EXTREME ;
break ;
}
lcd_show_fullscreen_message_and_wait_P ( msg ) ;
}
}
}
static void lcd_show_end_stops ( ) {
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( ( PSTR ( " End stops diag " ) ) ) ;
lcd . setCursor ( 0 , 1 ) ;
lcd_printPGM ( ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 ) ? ( PSTR ( " X1 " ) ) : ( PSTR ( " X0 " ) ) ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( ( READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 ) ? ( PSTR ( " Y1 " ) ) : ( PSTR ( " Y0 " ) ) ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( ( READ ( Z_MIN_PIN ) ^ Z_MIN_ENDSTOP_INVERTING = = 1 ) ? ( PSTR ( " Z1 " ) ) : ( PSTR ( " Z0 " ) ) ) ;
}
static void menu_show_end_stops ( ) {
lcd_show_end_stops ( ) ;
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if ( LCD_CLICKED ) lcd_goto_menu ( lcd_calibration_menu ) ;
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}
// Lets the user move the Z carriage up to the end stoppers.
// When done, it sets the current Z to Z_MAX_POS and returns true.
// Otherwise the Z calibration is not changed and false is returned.
void lcd_diag_show_end_stops ( )
{
int enc_dif = encoderDiff ;
lcd_implementation_clear ( ) ;
for ( ; ; ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
lcd_show_end_stops ( ) ;
if ( lcd_clicked ( ) ) {
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
break ;
}
}
lcd_implementation_clear ( ) ;
lcd_return_to_status ( ) ;
}
void prusa_statistics ( int _message ) {
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2016-07-22 13:28:01 +00:00
switch ( _message )
{
case 0 : // default message
if ( IS_SD_PRINTING )
{
SERIAL_ECHO ( " { " ) ;
prusa_stat_printerstatus ( 4 ) ;
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prusa_stat_farm_number ( ) ;
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prusa_stat_printinfo ( ) ;
SERIAL_ECHOLN ( " } " ) ;
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status_number = 4 ;
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}
else
{
SERIAL_ECHO ( " { " ) ;
prusa_stat_printerstatus ( 1 ) ;
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prusa_stat_farm_number ( ) ;
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SERIAL_ECHOLN ( " } " ) ;
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status_number = 1 ;
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}
break ;
case 1 : // 1 heating
farm_status = 2 ;
SERIAL_ECHO ( " { " ) ;
prusa_stat_printerstatus ( 2 ) ;
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prusa_stat_farm_number ( ) ;
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SERIAL_ECHOLN ( " } " ) ;
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status_number = 2 ;
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farm_timer = 1 ;
break ;
case 2 : // heating done
farm_status = 3 ;
SERIAL_ECHO ( " { " ) ;
prusa_stat_printerstatus ( 3 ) ;
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prusa_stat_farm_number ( ) ;
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SERIAL_ECHOLN ( " } " ) ;
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status_number = 3 ;
2016-07-22 13:28:01 +00:00
farm_timer = 1 ;
if ( IS_SD_PRINTING )
{
farm_status = 4 ;
SERIAL_ECHO ( " { " ) ;
prusa_stat_printerstatus ( 4 ) ;
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prusa_stat_farm_number ( ) ;
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SERIAL_ECHOLN ( " } " ) ;
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status_number = 4 ;
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}
else
{
SERIAL_ECHO ( " { " ) ;
prusa_stat_printerstatus ( 3 ) ;
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prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
status_number = 3 ;
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}
farm_timer = 1 ;
break ;
case 3 : // filament change
break ;
case 4 : // print succesfull
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SERIAL_ECHOLN ( " {[RES:1] " ) ;
prusa_stat_printerstatus ( status_number ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
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farm_timer = 2 ;
break ;
case 5 : // print not succesfull
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SERIAL_ECHOLN ( " {[RES:0] " ) ;
prusa_stat_printerstatus ( status_number ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
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farm_timer = 2 ;
break ;
case 6 : // print done
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SERIAL_ECHOLN ( " {[PRN:8] " ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
status_number = 8 ;
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farm_timer = 2 ;
break ;
case 7 : // print done - stopped
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SERIAL_ECHOLN ( " {[PRN:9] " ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
status_number = 9 ;
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farm_timer = 2 ;
break ;
case 8 : // printer started
SERIAL_ECHO ( " {[PRN:0][PFN: " ) ;
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status_number = 0 ;
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SERIAL_ECHO ( farm_no ) ;
SERIAL_ECHOLN ( " ]} " ) ;
farm_timer = 2 ;
break ;
case 20 : // echo farm no
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SERIAL_ECHOLN ( " { " ) ;
prusa_stat_printerstatus ( status_number ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
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farm_timer = 5 ;
break ;
case 21 : // temperatures
SERIAL_ECHO ( " { " ) ;
prusa_stat_temperatures ( ) ;
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prusa_stat_farm_number ( ) ;
prusa_stat_printerstatus ( status_number ) ;
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SERIAL_ECHOLN ( " } " ) ;
break ;
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case 22 : // waiting for filament change
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SERIAL_ECHOLN ( " {[PRN:5] " ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
status_number = 5 ;
2016-08-31 15:12:05 +00:00
break ;
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case 90 : // Error - Thermal Runaway
SERIAL_ECHOLN ( " {[ERR:1] " ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
break ;
case 91 : // Error - Thermal Runaway Preheat
SERIAL_ECHOLN ( " {[ERR:2] " ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
break ;
case 92 : // Error - Min temp
SERIAL_ECHOLN ( " {[ERR:3] " ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
break ;
case 93 : // Error - Max temp
SERIAL_ECHOLN ( " {[ERR:4] " ) ;
prusa_stat_farm_number ( ) ;
SERIAL_ECHOLN ( " } " ) ;
break ;
2016-08-31 15:12:05 +00:00
case 99 : // heartbeat
SERIAL_ECHO ( " {[PRN:99] " ) ;
prusa_stat_temperatures ( ) ;
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SERIAL_ECHO ( " [PFN: " ) ;
SERIAL_ECHO ( farm_no ) ;
SERIAL_ECHO ( " ] " ) ;
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SERIAL_ECHOLN ( " } " ) ;
break ;
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}
}
static void prusa_stat_printerstatus ( int _status )
{
SERIAL_ECHO ( " [PRN: " ) ;
SERIAL_ECHO ( _status ) ;
SERIAL_ECHO ( " ] " ) ;
}
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static void prusa_stat_farm_number ( ) {
SERIAL_ECHO ( " [PFN: " ) ;
SERIAL_ECHO ( farm_no ) ;
SERIAL_ECHO ( " ] " ) ;
}
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static void prusa_stat_temperatures ( )
{
SERIAL_ECHO ( " [ST0: " ) ;
SERIAL_ECHO ( target_temperature [ 0 ] ) ;
SERIAL_ECHO ( " ][STB: " ) ;
SERIAL_ECHO ( target_temperature_bed ) ;
SERIAL_ECHO ( " ][AT0: " ) ;
SERIAL_ECHO ( current_temperature [ 0 ] ) ;
SERIAL_ECHO ( " ][ATB: " ) ;
SERIAL_ECHO ( current_temperature_bed ) ;
SERIAL_ECHO ( " ] " ) ;
}
static void prusa_stat_printinfo ( )
{
SERIAL_ECHO ( " [TFU: " ) ;
SERIAL_ECHO ( total_filament_used ) ;
SERIAL_ECHO ( " ][PCD: " ) ;
SERIAL_ECHO ( itostr3 ( card . percentDone ( ) ) ) ;
SERIAL_ECHO ( " ][FEM: " ) ;
SERIAL_ECHO ( itostr3 ( feedmultiply ) ) ;
SERIAL_ECHO ( " ][FNM: " ) ;
SERIAL_ECHO ( longFilenameOLD ) ;
SERIAL_ECHO ( " ][TIM: " ) ;
if ( starttime ! = 0 )
{
SERIAL_ECHO ( millis ( ) / 1000 - starttime / 1000 ) ;
}
else
{
SERIAL_ECHO ( 0 ) ;
}
SERIAL_ECHO ( " ][FWR: " ) ;
SERIAL_ECHO ( FW_version ) ;
SERIAL_ECHO ( " ] " ) ;
}
void lcd_pick_babystep ( ) {
int enc_dif = 0 ;
int cursor_pos = 1 ;
int fsm = 0 ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_PICK_Z ) ;
lcd . setCursor ( 3 , 2 ) ;
lcd . print ( " 1 " ) ;
lcd . setCursor ( 3 , 3 ) ;
lcd . print ( " 2 " ) ;
lcd . setCursor ( 12 , 2 ) ;
lcd . print ( " 3 " ) ;
lcd . setCursor ( 12 , 3 ) ;
lcd . print ( " 4 " ) ;
lcd . setCursor ( 1 , 2 ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
while ( fsm = = 0 ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 4 ) {
if ( ( abs ( enc_dif - encoderDiff ) ) > 1 ) {
if ( enc_dif > encoderDiff ) {
cursor_pos - - ;
}
if ( enc_dif < encoderDiff ) {
cursor_pos + + ;
}
if ( cursor_pos > 4 ) {
cursor_pos = 4 ;
}
if ( cursor_pos < 1 ) {
cursor_pos = 1 ;
}
lcd . setCursor ( 1 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 1 , 3 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 10 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 10 , 3 ) ;
lcd . print ( " " ) ;
if ( cursor_pos < 3 ) {
lcd . setCursor ( 1 , cursor_pos + 1 ) ;
lcd . print ( " > " ) ;
} else {
lcd . setCursor ( 10 , cursor_pos - 1 ) ;
lcd . print ( " > " ) ;
}
enc_dif = encoderDiff ;
delay ( 100 ) ;
}
}
if ( lcd_clicked ( ) ) {
fsm = cursor_pos ;
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int babyStepZ ;
EEPROM_read_B ( EEPROM_BABYSTEP_Z0 + ( ( fsm - 1 ) * 2 ) , & babyStepZ ) ;
EEPROM_save_B ( EEPROM_BABYSTEP_Z , & babyStepZ ) ;
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calibration_status_store ( CALIBRATION_STATUS_CALIBRATED ) ;
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delay ( 500 ) ;
}
} ;
lcd_implementation_clear ( ) ;
lcd_return_to_status ( ) ;
}
void lcd_move_menu_axis ( )
{
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START_MENU ( ) ;
MENU_ITEM ( back , MSG_SETTINGS , lcd_settings_menu ) ;
MENU_ITEM ( submenu , MSG_MOVE_X , lcd_move_x ) ;
MENU_ITEM ( submenu , MSG_MOVE_Y , lcd_move_y ) ;
MENU_ITEM ( submenu , MSG_MOVE_Z , lcd_move_z ) ;
MENU_ITEM ( submenu , MSG_MOVE_E , lcd_move_e ) ;
END_MENU ( ) ;
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}
static void lcd_move_menu_1mm ( )
{
move_menu_scale = 1.0 ;
lcd_move_menu_axis ( ) ;
}
void EEPROM_save ( int pos , uint8_t * value , uint8_t size )
{
do
{
eeprom_write_byte ( ( unsigned char * ) pos , * value ) ;
pos + + ;
value + + ;
} while ( - - size ) ;
}
void EEPROM_read ( int pos , uint8_t * value , uint8_t size )
{
do
{
* value = eeprom_read_byte ( ( unsigned char * ) pos ) ;
pos + + ;
value + + ;
} while ( - - size ) ;
}
static void lcd_silent_mode_set ( ) {
SilentModeMenu = ! SilentModeMenu ;
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eeprom_update_byte ( ( unsigned char * ) EEPROM_SILENT , SilentModeMenu ) ;
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# ifdef HAVE_TMC2130_DRIVERS
tmc2130_mode = SilentModeMenu ? TMC2130_MODE_SILENT : TMC2130_MODE_NORMAL ;
tmc2130_init ( ) ;
# endif //HAVE_TMC2130_DRIVERS
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digipot_init ( ) ;
lcd_goto_menu ( lcd_settings_menu , 7 ) ;
}
static void lcd_set_lang ( unsigned char lang ) {
lang_selected = lang ;
firstrun = 1 ;
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eeprom_update_byte ( ( unsigned char * ) EEPROM_LANG , lang ) ;
/*langsel=0;*/
if ( langsel = = LANGSEL_MODAL )
// From modal mode to an active mode? This forces the menu to return to the setup menu.
langsel = LANGSEL_ACTIVE ;
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}
void lcd_force_language_selection ( ) {
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eeprom_update_byte ( ( unsigned char * ) EEPROM_LANG , LANG_ID_FORCE_SELECTION ) ;
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}
static void lcd_language_menu ( )
{
START_MENU ( ) ;
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if ( langsel = = LANGSEL_OFF ) {
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MENU_ITEM ( back , MSG_SETTINGS , lcd_settings_menu ) ;
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} else if ( langsel = = LANGSEL_ACTIVE ) {
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MENU_ITEM ( back , MSG_WATCH , lcd_status_screen ) ;
}
for ( int i = 0 ; i < LANG_NUM ; i + + ) {
MENU_ITEM ( setlang , MSG_LANGUAGE_NAME_EXPLICIT ( i ) , i ) ;
}
END_MENU ( ) ;
}
void lcd_mesh_bedleveling ( )
{
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mesh_bed_run_from_menu = true ;
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enquecommand_P ( PSTR ( " G80 " ) ) ;
lcd_return_to_status ( ) ;
}
void lcd_mesh_calibration ( )
{
enquecommand_P ( PSTR ( " M45 " ) ) ;
lcd_return_to_status ( ) ;
}
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void lcd_mesh_calibration_z ( )
{
enquecommand_P ( PSTR ( " M45 Z " ) ) ;
lcd_return_to_status ( ) ;
}
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void lcd_pinda_calibration_menu ( )
{
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MENU_CALIBRATION , lcd_calibration_menu ) ;
MENU_ITEM ( submenu , MSG_CALIBRATE_PINDA , lcd_calibrate_pinda ) ;
if ( temp_cal_active = = false ) {
MENU_ITEM ( function , MSG_TEMP_CALIBRATION_OFF , lcd_temp_calibration_set ) ;
}
else {
MENU_ITEM ( function , MSG_TEMP_CALIBRATION_ON , lcd_temp_calibration_set ) ;
}
END_MENU ( ) ;
}
void lcd_temp_calibration_set ( ) {
temp_cal_active = ! temp_cal_active ;
eeprom_update_byte ( ( unsigned char * ) EEPROM_TEMP_CAL_ACTIVE , temp_cal_active ) ;
digipot_init ( ) ;
lcd_goto_menu ( lcd_pinda_calibration_menu , 2 ) ;
}
void lcd_calibrate_pinda ( ) {
enquecommand_P ( PSTR ( " G76 " ) ) ;
lcd_return_to_status ( ) ;
}
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# ifndef SNMM
/*void lcd_calibrate_extruder() {
if ( degHotend0 ( ) > EXTRUDE_MINTEMP )
{
current_position [ E_AXIS ] = 0 ; //set initial position to zero
plan_set_e_position ( current_position [ E_AXIS ] ) ;
//long steps_start = st_get_position(E_AXIS);
long steps_final ;
float e_steps_per_unit ;
float feedrate = ( 180 / axis_steps_per_unit [ E_AXIS ] ) * 1 ; //3 //initial automatic extrusion feedrate (depends on current value of axis_steps_per_unit to avoid too fast extrusion)
float e_shift_calibration = ( axis_steps_per_unit [ E_AXIS ] > 180 ) ? ( ( 180 / axis_steps_per_unit [ E_AXIS ] ) * 70 ) : 70 ; //length of initial automatic extrusion sequence
const char * msg_e_cal_knob = MSG_E_CAL_KNOB ;
const char * msg_next_e_cal_knob = lcd_display_message_fullscreen_P ( msg_e_cal_knob ) ;
const bool multi_screen = msg_next_e_cal_knob ! = NULL ;
unsigned long msg_millis ;
lcd_show_fullscreen_message_and_wait_P ( MSG_MARK_FIL ) ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 1 ) ; lcd_printPGM ( MSG_PLEASE_WAIT ) ;
current_position [ E_AXIS ] + = e_shift_calibration ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , feedrate , active_extruder ) ;
st_synchronize ( ) ;
lcd_display_message_fullscreen_P ( msg_e_cal_knob ) ;
msg_millis = millis ( ) ;
while ( ! LCD_CLICKED ) {
if ( multi_screen & & millis ( ) - msg_millis > 5000 ) {
if ( msg_next_e_cal_knob = = NULL )
msg_next_e_cal_knob = msg_e_cal_knob ;
msg_next_e_cal_knob = lcd_display_message_fullscreen_P ( msg_next_e_cal_knob ) ;
msg_millis = millis ( ) ;
}
//manage_inactivity(true);
manage_heater ( ) ;
if ( abs ( encoderDiff ) > = ENCODER_PULSES_PER_STEP ) { //adjusting mark by knob rotation
delay_keep_alive ( 50 ) ;
//previous_millis_cmd = millis();
encoderPosition + = ( encoderDiff / ENCODER_PULSES_PER_STEP ) ;
encoderDiff = 0 ;
if ( ! planner_queue_full ( ) ) {
current_position [ E_AXIS ] + = float ( abs ( ( int ) encoderPosition ) ) * 0.01 ; //0.05
encoderPosition = 0 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , feedrate , active_extruder ) ;
}
}
}
steps_final = current_position [ E_AXIS ] * axis_steps_per_unit [ E_AXIS ] ;
//steps_final = st_get_position(E_AXIS);
lcdDrawUpdate = 1 ;
e_steps_per_unit = ( ( float ) ( steps_final ) ) / 100.0f ;
if ( e_steps_per_unit < MIN_E_STEPS_PER_UNIT ) e_steps_per_unit = MIN_E_STEPS_PER_UNIT ;
if ( e_steps_per_unit > MAX_E_STEPS_PER_UNIT ) e_steps_per_unit = MAX_E_STEPS_PER_UNIT ;
lcd_implementation_clear ( ) ;
axis_steps_per_unit [ E_AXIS ] = e_steps_per_unit ;
enquecommand_P ( PSTR ( " M500 " ) ) ; //store settings to eeprom
//lcd_implementation_drawedit(PSTR("Result"), ftostr31(axis_steps_per_unit[E_AXIS]));
//delay_keep_alive(2000);
delay_keep_alive ( 500 ) ;
lcd_show_fullscreen_message_and_wait_P ( MSG_CLEAN_NOZZLE_E ) ;
lcd_update_enable ( true ) ;
lcdDrawUpdate = 2 ;
}
else
{
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ERROR ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PREHEAT_NOZZLE ) ;
delay ( 2000 ) ;
lcd_implementation_clear ( ) ;
}
lcd_return_to_status ( ) ;
}
void lcd_extr_cal_reset ( ) {
float tmp1 [ ] = DEFAULT_AXIS_STEPS_PER_UNIT ;
axis_steps_per_unit [ E_AXIS ] = tmp1 [ 3 ] ;
//extrudemultiply = 100;
enquecommand_P ( PSTR ( " M500 " ) ) ;
} */
# endif
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void lcd_toshiba_flash_air_compatibility_toggle ( )
{
card . ToshibaFlashAir_enable ( ! card . ToshibaFlashAir_isEnabled ( ) ) ;
eeprom_update_byte ( ( uint8_t * ) EEPROM_TOSHIBA_FLASH_AIR_COMPATIBLITY , card . ToshibaFlashAir_isEnabled ( ) ) ;
}
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static void lcd_settings_menu ( )
{
EEPROM_read ( EEPROM_SILENT , ( uint8_t * ) & SilentModeMenu , sizeof ( SilentModeMenu ) ) ;
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
MENU_ITEM ( submenu , MSG_TEMPERATURE , lcd_control_temperature_menu ) ;
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if ( ! homing_flag )
{
MENU_ITEM ( submenu , MSG_MOVE_AXIS , lcd_move_menu_1mm ) ;
}
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if ( ! isPrintPaused )
{
MENU_ITEM ( gcode , MSG_DISABLE_STEPPERS , PSTR ( " M84 " ) ) ;
}
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if ( ( SilentModeMenu = = 0 ) | | ( farm_mode ) ) {
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MENU_ITEM ( function , MSG_SILENT_MODE_OFF , lcd_silent_mode_set ) ;
} else {
MENU_ITEM ( function , MSG_SILENT_MODE_ON , lcd_silent_mode_set ) ;
}
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if ( ! isPrintPaused & & ! homing_flag )
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{
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MENU_ITEM ( submenu , MSG_BABYSTEP_Z , lcd_babystep_z ) ;
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}
MENU_ITEM ( submenu , MSG_LANGUAGE_SELECT , lcd_language_menu ) ;
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if ( card . ToshibaFlashAir_isEnabled ( ) ) {
MENU_ITEM ( function , MSG_TOSHIBA_FLASH_AIR_COMPATIBILITY_ON , lcd_toshiba_flash_air_compatibility_toggle ) ;
} else {
MENU_ITEM ( function , MSG_TOSHIBA_FLASH_AIR_COMPATIBILITY_OFF , lcd_toshiba_flash_air_compatibility_toggle ) ;
}
if ( farm_mode )
{
MENU_ITEM ( submenu , PSTR ( " Farm number " ) , lcd_farm_no ) ;
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MENU_ITEM ( function , PSTR ( " Disable farm mode " ) , lcd_disable_farm_mode ) ;
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}
END_MENU ( ) ;
}
static void lcd_calibration_menu ( )
{
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
if ( ! isPrintPaused )
{
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MENU_ITEM ( function , MSG_SELFTEST , lcd_selftest ) ;
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# ifdef MK1BP
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// MK1
// "Calibrate Z"
MENU_ITEM ( gcode , MSG_HOMEYZ , PSTR ( " G28 Z " ) ) ;
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# else //MK1BP
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// MK2
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MENU_ITEM ( function , MSG_CALIBRATE_BED , lcd_mesh_calibration ) ;
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// "Calibrate Z" with storing the reference values to EEPROM.
MENU_ITEM ( submenu , MSG_HOMEYZ , lcd_mesh_calibration_z ) ;
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# ifndef SNMM
//MENU_ITEM(function, MSG_CALIBRATE_E, lcd_calibrate_extruder);
# endif
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// "Mesh Bed Leveling"
MENU_ITEM ( submenu , MSG_MESH_BED_LEVELING , lcd_mesh_bedleveling ) ;
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# endif //MK1BP
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MENU_ITEM ( gcode , MSG_AUTO_HOME , PSTR ( " G28 W " ) ) ;
MENU_ITEM ( submenu , MSG_BED_CORRECTION_MENU , lcd_adjust_bed ) ;
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# ifndef MK1BP
MENU_ITEM ( submenu , MSG_CALIBRATION_PINDA_MENU , lcd_pinda_calibration_menu ) ;
# endif //MK1BP
MENU_ITEM ( submenu , MSG_PID_EXTRUDER , pid_extruder ) ;
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MENU_ITEM ( submenu , MSG_SHOW_END_STOPS , menu_show_end_stops ) ;
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# ifndef MK1BP
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MENU_ITEM ( gcode , MSG_CALIBRATE_BED_RESET , PSTR ( " M44 " ) ) ;
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# endif //MK1BP
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# ifndef SNMM
//MENU_ITEM(function, MSG_RESET_CALIBRATE_E, lcd_extr_cal_reset);
# endif
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}
END_MENU ( ) ;
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}
/*
void lcd_mylang_top ( int hlaska ) {
lcd . setCursor ( 0 , 0 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ALL [ hlaska - 1 ] [ LANGUAGE_SELECT ] ) ;
}
void lcd_mylang_drawmenu ( int cursor ) {
int first = 0 ;
if ( cursor > 2 ) first = cursor - 2 ;
if ( cursor = = LANG_NUM ) first = LANG_NUM - 3 ;
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 1 , 1 ) ;
lcd_printPGM ( MSG_ALL [ first ] [ LANGUAGE_NAME ] ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 1 , 2 ) ;
lcd_printPGM ( MSG_ALL [ first + 1 ] [ LANGUAGE_NAME ] ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 1 , 3 ) ;
lcd_printPGM ( MSG_ALL [ first + 2 ] [ LANGUAGE_NAME ] ) ;
if ( cursor = = 1 ) lcd . setCursor ( 0 , 1 ) ;
if ( cursor > 1 & & cursor < LANG_NUM ) lcd . setCursor ( 0 , 2 ) ;
if ( cursor = = LANG_NUM ) lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " > " ) ;
if ( cursor < LANG_NUM - 1 ) {
lcd . setCursor ( 19 , 3 ) ;
lcd . print ( " \x01 " ) ;
}
if ( cursor > 2 ) {
lcd . setCursor ( 19 , 1 ) ;
lcd . print ( " ^ " ) ;
}
}
*/
void lcd_mylang_drawmenu ( int cursor ) {
int first = 0 ;
if ( cursor > 3 ) first = cursor - 3 ;
if ( cursor = = LANG_NUM & & LANG_NUM > 4 ) first = LANG_NUM - 4 ;
if ( cursor = = LANG_NUM & & LANG_NUM = = 4 ) first = LANG_NUM - 4 ;
lcd . setCursor ( 0 , 0 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 1 , 0 ) ;
lcd_printPGM ( MSG_LANGUAGE_NAME_EXPLICIT ( first + 0 ) ) ;
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 1 , 1 ) ;
lcd_printPGM ( MSG_LANGUAGE_NAME_EXPLICIT ( first + 1 ) ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd . print ( " " ) ;
if ( LANG_NUM > 2 ) {
lcd . setCursor ( 1 , 2 ) ;
lcd_printPGM ( MSG_LANGUAGE_NAME_EXPLICIT ( first + 2 ) ) ;
}
lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " " ) ;
if ( LANG_NUM > 3 ) {
lcd . setCursor ( 1 , 3 ) ;
lcd_printPGM ( MSG_LANGUAGE_NAME_EXPLICIT ( first + 3 ) ) ;
}
if ( cursor = = 1 ) lcd . setCursor ( 0 , 0 ) ;
if ( cursor = = 2 ) lcd . setCursor ( 0 , 1 ) ;
if ( cursor > 2 ) lcd . setCursor ( 0 , 2 ) ;
if ( cursor = = LANG_NUM & & LANG_NUM > 3 ) lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " > " ) ;
if ( cursor < LANG_NUM - 1 & & LANG_NUM > 4 ) {
lcd . setCursor ( 19 , 3 ) ;
lcd . print ( " \x01 " ) ;
}
if ( cursor > 3 & & LANG_NUM > 4 ) {
lcd . setCursor ( 19 , 0 ) ;
lcd . print ( " ^ " ) ;
}
}
void lcd_mylang_drawcursor ( int cursor ) {
if ( cursor = = 1 ) lcd . setCursor ( 0 , 1 ) ;
if ( cursor > 1 & & cursor < LANG_NUM ) lcd . setCursor ( 0 , 2 ) ;
if ( cursor = = LANG_NUM ) lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " > " ) ;
}
void lcd_mylang ( ) {
int enc_dif = 0 ;
int cursor_pos = 1 ;
lang_selected = 255 ;
int hlaska = 1 ;
int counter = 0 ;
lcd_set_custom_characters_arrows ( ) ;
lcd_implementation_clear ( ) ;
//lcd_mylang_top(hlaska);
lcd_mylang_drawmenu ( cursor_pos ) ;
enc_dif = encoderDiff ;
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while ( ( lang_selected = = 255 ) ) {
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manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 4 ) {
//if ( (abs(enc_dif - encoderDiff)) > 1 ) {
if ( enc_dif > encoderDiff ) {
cursor_pos - - ;
}
if ( enc_dif < encoderDiff ) {
cursor_pos + + ;
}
if ( cursor_pos > LANG_NUM ) {
cursor_pos = LANG_NUM ;
}
if ( cursor_pos < 1 ) {
cursor_pos = 1 ;
}
lcd_mylang_drawmenu ( cursor_pos ) ;
enc_dif = encoderDiff ;
delay ( 100 ) ;
//}
} else delay ( 20 ) ;
if ( lcd_clicked ( ) ) {
lcd_set_lang ( cursor_pos - 1 ) ;
delay ( 500 ) ;
}
/*
if ( + + counter = = 80 ) {
hlaska + + ;
if ( hlaska > LANG_NUM ) hlaska = 1 ;
lcd_mylang_top ( hlaska ) ;
lcd_mylang_drawcursor ( cursor_pos ) ;
counter = 0 ;
}
*/
} ;
if ( MYSERIAL . available ( ) > 1 ) {
lang_selected = 0 ;
firstrun = 0 ;
}
lcd_set_custom_characters_degree ( ) ;
lcd_implementation_clear ( ) ;
lcd_return_to_status ( ) ;
}
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void bowden_menu ( ) {
int enc_dif = encoderDiff ;
int cursor_pos = 0 ;
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lcd_implementation_clear ( ) ;
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lcd . setCursor ( 0 , 0 ) ;
lcd . print ( " > " ) ;
for ( int i = 0 ; i < 4 ; i + + ) {
lcd . setCursor ( 1 , i ) ;
lcd . print ( " Extruder " ) ;
lcd . print ( i ) ;
lcd . print ( " : " ) ;
EEPROM_read_B ( EEPROM_BOWDEN_LENGTH + i * 2 , & bowden_length [ i ] ) ;
lcd . print ( bowden_length [ i ] - 48 ) ;
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}
enc_dif = encoderDiff ;
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while ( 1 ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 2 ) {
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if ( enc_dif > encoderDiff ) {
cursor_pos - - ;
}
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if ( enc_dif < encoderDiff ) {
cursor_pos + + ;
}
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if ( cursor_pos > 3 ) {
cursor_pos = 3 ;
}
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if ( cursor_pos < 0 ) {
cursor_pos = 0 ;
}
lcd . setCursor ( 0 , 0 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , cursor_pos ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
delay ( 100 ) ;
}
if ( lcd_clicked ( ) ) {
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
lcd_implementation_clear ( ) ;
while ( 1 ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
lcd . setCursor ( 1 , 1 ) ;
lcd . print ( " Extruder " ) ;
lcd . print ( cursor_pos ) ;
lcd . print ( " : " ) ;
lcd . setCursor ( 13 , 1 ) ;
lcd . print ( bowden_length [ cursor_pos ] - 48 ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 2 ) {
if ( enc_dif > encoderDiff ) {
bowden_length [ cursor_pos ] - - ;
lcd . setCursor ( 13 , 1 ) ;
lcd . print ( bowden_length [ cursor_pos ] - 48 ) ;
enc_dif = encoderDiff ;
}
if ( enc_dif < encoderDiff ) {
bowden_length [ cursor_pos ] + + ;
lcd . setCursor ( 13 , 1 ) ;
lcd . print ( bowden_length [ cursor_pos ] - 48 ) ;
enc_dif = encoderDiff ;
}
}
delay ( 100 ) ;
if ( lcd_clicked ( ) ) {
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
EEPROM_save_B ( EEPROM_BOWDEN_LENGTH + cursor_pos * 2 , & bowden_length [ cursor_pos ] ) ;
if ( lcd_show_fullscreen_message_yes_no_and_wait_P ( PSTR ( " Continue with another bowden? " ) ) ) {
lcd_update_enable ( true ) ;
lcd_implementation_clear ( ) ;
enc_dif = encoderDiff ;
lcd . setCursor ( 0 , cursor_pos ) ;
lcd . print ( " > " ) ;
for ( int i = 0 ; i < 4 ; i + + ) {
lcd . setCursor ( 1 , i ) ;
lcd . print ( " Extruder " ) ;
lcd . print ( i ) ;
lcd . print ( " : " ) ;
EEPROM_read_B ( EEPROM_BOWDEN_LENGTH + i * 2 , & bowden_length [ i ] ) ;
lcd . print ( bowden_length [ i ] - 48 ) ;
}
break ;
}
else return ;
}
}
}
}
}
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static char snmm_stop_print_menu ( ) { //menu for choosing which filaments will be unloaded in stop print
lcd_implementation_clear ( ) ;
lcd_print_at_PGM ( 0 , 0 , MSG_UNLOAD_FILAMENT ) ; lcd . print ( " : " ) ;
lcd . setCursor ( 0 , 1 ) ; lcd . print ( " > " ) ;
lcd_print_at_PGM ( 1 , 1 , MSG_ALL ) ;
lcd_print_at_PGM ( 1 , 2 , MSG_USED ) ;
lcd_print_at_PGM ( 1 , 3 , MSG_CURRENT ) ;
char cursor_pos = 1 ;
int enc_dif = 0 ;
while ( 1 ) {
manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 4 ) {
if ( ( abs ( enc_dif - encoderDiff ) ) > 1 ) {
if ( enc_dif > encoderDiff ) cursor_pos - - ;
if ( enc_dif < encoderDiff ) cursor_pos + + ;
if ( cursor_pos > 3 ) cursor_pos = 3 ;
if ( cursor_pos < 1 ) cursor_pos = 1 ;
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , cursor_pos ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
delay ( 100 ) ;
}
}
if ( lcd_clicked ( ) ) {
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
return ( cursor_pos - 1 ) ;
}
}
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}
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char choose_extruder_menu ( ) {
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int items_no = 4 ;
int first = 0 ;
int enc_dif = 0 ;
char cursor_pos = 1 ;
enc_dif = encoderDiff ;
lcd_implementation_clear ( ) ;
lcd_printPGM ( MSG_CHOOSE_EXTRUDER ) ;
lcd . setCursor ( 0 , 1 ) ;
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lcd . print ( " > " ) ;
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for ( int i = 0 ; i < 3 ; i + + ) {
lcd_print_at_PGM ( 1 , i + 1 , MSG_EXTRUDER ) ;
}
while ( 1 ) {
for ( int i = 0 ; i < 3 ; i + + ) {
lcd . setCursor ( 2 + strlen_P ( MSG_EXTRUDER ) , i + 1 ) ;
lcd . print ( first + i + 1 ) ;
}
manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 4 ) {
if ( ( abs ( enc_dif - encoderDiff ) ) > 1 ) {
if ( enc_dif > encoderDiff ) {
cursor_pos - - ;
}
if ( enc_dif < encoderDiff ) {
cursor_pos + + ;
}
if ( cursor_pos > 3 ) {
cursor_pos = 3 ;
if ( first < items_no - 3 ) {
first + + ;
lcd_implementation_clear ( ) ;
lcd_printPGM ( MSG_CHOOSE_EXTRUDER ) ;
for ( int i = 0 ; i < 3 ; i + + ) {
lcd_print_at_PGM ( 1 , i + 1 , MSG_EXTRUDER ) ;
}
}
}
if ( cursor_pos < 1 ) {
cursor_pos = 1 ;
if ( first > 0 ) {
first - - ;
lcd_implementation_clear ( ) ;
lcd_printPGM ( MSG_CHOOSE_EXTRUDER ) ;
for ( int i = 0 ; i < 3 ; i + + ) {
lcd_print_at_PGM ( 1 , i + 1 , MSG_EXTRUDER ) ;
}
}
}
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , cursor_pos ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
delay ( 100 ) ;
}
}
if ( lcd_clicked ( ) ) {
lcd_update ( 2 ) ;
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
return ( cursor_pos + first - 1 ) ;
}
}
}
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char reset_menu ( ) {
# ifdef SNMM
int items_no = 5 ;
# else
int items_no = 4 ;
# endif
static int first = 0 ;
int enc_dif = 0 ;
char cursor_pos = 0 ;
const char * item [ items_no ] ;
item [ 0 ] = " Language " ;
item [ 1 ] = " Statistics " ;
item [ 2 ] = " Shipping prep " ;
item [ 3 ] = " All Data " ;
# ifdef SNMM
item [ 4 ] = " Bowden length " ;
# endif // SNMM
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enc_dif = encoderDiff ;
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lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd . print ( " > " ) ;
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while ( 1 ) {
for ( int i = 0 ; i < 4 ; i + + ) {
lcd . setCursor ( 1 , i ) ;
lcd . print ( item [ first + i ] ) ;
}
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manage_heater ( ) ;
manage_inactivity ( true ) ;
if ( abs ( ( enc_dif - encoderDiff ) ) > 4 ) {
if ( ( abs ( enc_dif - encoderDiff ) ) > 1 ) {
if ( enc_dif > encoderDiff ) {
cursor_pos - - ;
}
if ( enc_dif < encoderDiff ) {
cursor_pos + + ;
}
if ( cursor_pos > 3 ) {
cursor_pos = 3 ;
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if ( first < items_no - 4 ) {
first + + ;
lcd_implementation_clear ( ) ;
}
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}
if ( cursor_pos < 0 ) {
cursor_pos = 0 ;
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if ( first > 0 ) {
first - - ;
lcd_implementation_clear ( ) ;
}
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}
lcd . setCursor ( 0 , 0 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , cursor_pos ) ;
lcd . print ( " > " ) ;
enc_dif = encoderDiff ;
delay ( 100 ) ;
}
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}
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if ( lcd_clicked ( ) ) {
while ( lcd_clicked ( ) ) ;
delay ( 10 ) ;
while ( lcd_clicked ( ) ) ;
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return ( cursor_pos + first ) ;
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}
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}
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}
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static void lcd_disable_farm_mode ( ) {
int8_t disable = lcd_show_fullscreen_message_yes_no_and_wait_P ( PSTR ( " Disable farm mode? " ) , true , false ) ; //allow timeouting, default no
if ( disable ) {
enquecommand_P ( PSTR ( " G99 " ) ) ;
lcd_return_to_status ( ) ;
}
else {
lcd_goto_menu ( lcd_settings_menu ) ;
}
lcd_update_enable ( true ) ;
lcdDrawUpdate = 2 ;
}
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static void lcd_ping_allert ( ) {
if ( ( abs ( millis ( ) - allert_timer ) * 0.001 ) > PING_ALLERT_PERIOD ) {
allert_timer = millis ( ) ;
SET_OUTPUT ( BEEPER ) ;
for ( int i = 0 ; i < 2 ; i + + ) {
WRITE ( BEEPER , HIGH ) ;
delay ( 50 ) ;
WRITE ( BEEPER , LOW ) ;
delay ( 100 ) ;
}
}
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} ;
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# ifdef SNMM
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static void extr_mov ( float shift , float feed_rate ) { //move extruder no matter what the current heater temperature is
set_extrude_min_temp ( .0 ) ;
current_position [ E_AXIS ] + = shift ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , feed_rate , active_extruder ) ;
set_extrude_min_temp ( EXTRUDE_MINTEMP ) ;
}
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void change_extr ( int extr ) { //switches multiplexer for extruders
st_synchronize ( ) ;
delay ( 100 ) ;
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disable_e0 ( ) ;
disable_e1 ( ) ;
disable_e2 ( ) ;
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# ifdef SNMM
snmm_extruder = extr ;
# endif
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pinMode ( E_MUX0_PIN , OUTPUT ) ;
pinMode ( E_MUX1_PIN , OUTPUT ) ;
pinMode ( E_MUX2_PIN , OUTPUT ) ;
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switch ( extr ) {
case 1 :
WRITE ( E_MUX0_PIN , HIGH ) ;
WRITE ( E_MUX1_PIN , LOW ) ;
WRITE ( E_MUX2_PIN , LOW ) ;
break ;
case 2 :
WRITE ( E_MUX0_PIN , LOW ) ;
WRITE ( E_MUX1_PIN , HIGH ) ;
WRITE ( E_MUX2_PIN , LOW ) ;
break ;
case 3 :
WRITE ( E_MUX0_PIN , HIGH ) ;
WRITE ( E_MUX1_PIN , HIGH ) ;
WRITE ( E_MUX2_PIN , LOW ) ;
break ;
default :
WRITE ( E_MUX0_PIN , LOW ) ;
WRITE ( E_MUX1_PIN , LOW ) ;
WRITE ( E_MUX2_PIN , LOW ) ;
break ;
}
delay ( 100 ) ;
}
static int get_ext_nr ( ) { //reads multiplexer input pins and return current extruder number (counted from 0)
return ( 4 * READ ( E_MUX2_PIN ) + 2 * READ ( E_MUX1_PIN ) + READ ( E_MUX0_PIN ) ) ;
}
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void display_loading ( ) {
switch ( snmm_extruder ) {
case 1 : lcd_display_message_fullscreen_P ( MSG_FILAMENT_LOADING_T1 ) ; break ;
case 2 : lcd_display_message_fullscreen_P ( MSG_FILAMENT_LOADING_T2 ) ; break ;
case 3 : lcd_display_message_fullscreen_P ( MSG_FILAMENT_LOADING_T3 ) ; break ;
default : lcd_display_message_fullscreen_P ( MSG_FILAMENT_LOADING_T0 ) ; break ;
}
}
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static void extr_adj ( int extruder ) //loading filament for SNMM
{
bool correct ;
max_feedrate [ E_AXIS ] = 80 ;
//max_feedrate[E_AXIS] = 50;
START :
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
switch ( extruder ) {
case 1 : lcd_display_message_fullscreen_P ( MSG_FILAMENT_LOADING_T1 ) ; break ;
case 2 : lcd_display_message_fullscreen_P ( MSG_FILAMENT_LOADING_T2 ) ; break ;
case 3 : lcd_display_message_fullscreen_P ( MSG_FILAMENT_LOADING_T3 ) ; break ;
default : lcd_display_message_fullscreen_P ( MSG_FILAMENT_LOADING_T0 ) ; break ;
}
do {
extr_mov ( 0.001 , 1000 ) ;
delay_keep_alive ( 2 ) ;
} while ( ! lcd_clicked ( ) ) ;
//delay_keep_alive(500);
st_synchronize ( ) ;
//correct = lcd_show_fullscreen_message_yes_no_and_wait_P(MSG_FIL_LOADED_CHECK, false);
//if (!correct) goto START;
//extr_mov(BOWDEN_LENGTH/2.f, 500); //dividing by 2 is there because of max. extrusion length limitation (x_max + y_max)
//extr_mov(BOWDEN_LENGTH/2.f, 500);
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extr_mov ( bowden_length [ extruder ] , 500 ) ;
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lcd_implementation_clear ( ) ;
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lcd . setCursor ( 0 , 0 ) ; lcd_printPGM ( MSG_LOADING_FILAMENT ) ;
if ( strlen ( MSG_LOADING_FILAMENT ) > 18 ) lcd . setCursor ( 0 , 1 ) ;
else lcd . print ( " " ) ;
lcd . print ( snmm_extruder + 1 ) ;
lcd . setCursor ( 0 , 2 ) ; lcd_printPGM ( MSG_PLEASE_WAIT ) ;
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st_synchronize ( ) ;
max_feedrate [ E_AXIS ] = 50 ;
lcd_update_enable ( true ) ;
lcd_return_to_status ( ) ;
lcdDrawUpdate = 2 ;
}
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void extr_unload ( ) { //unloads filament
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float tmp_motor [ 3 ] = DEFAULT_PWM_MOTOR_CURRENT ;
float tmp_motor_loud [ 3 ] = DEFAULT_PWM_MOTOR_CURRENT_LOUD ;
int8_t SilentMode ;
if ( degHotend0 ( ) > EXTRUDE_MINTEMP ) {
lcd_implementation_clear ( ) ;
lcd_display_message_fullscreen_P ( PSTR ( " " ) ) ;
max_feedrate [ E_AXIS ] = 50 ;
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lcd . setCursor ( 0 , 0 ) ; lcd_printPGM ( MSG_UNLOADING_FILAMENT ) ;
lcd . print ( " " ) ;
lcd . print ( snmm_extruder + 1 ) ;
lcd . setCursor ( 0 , 2 ) ; lcd_printPGM ( MSG_PLEASE_WAIT ) ;
if ( current_position [ Z_AXIS ] < 15 ) {
current_position [ Z_AXIS ] + = 15 ; //lifting in Z direction to make space for extrusion
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 25 , active_extruder ) ;
}
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current_position [ E_AXIS ] + = 10 ; //extrusion
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 10 , active_extruder ) ;
digipot_current ( 2 , E_MOTOR_HIGH_CURRENT ) ;
if ( current_temperature [ 0 ] < 230 ) { //PLA & all other filaments
current_position [ E_AXIS ] + = 5.4 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 2800 / 60 , active_extruder ) ;
current_position [ E_AXIS ] + = 3.2 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 3000 / 60 , active_extruder ) ;
current_position [ E_AXIS ] + = 3 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 3400 / 60 , active_extruder ) ;
}
else { //ABS
current_position [ E_AXIS ] + = 3.1 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 2000 / 60 , active_extruder ) ;
current_position [ E_AXIS ] + = 3.1 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 2500 / 60 , active_extruder ) ;
current_position [ E_AXIS ] + = 4 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 3000 / 60 , active_extruder ) ;
/*current_position[X_AXIS] += 23; //delay
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 600 / 60 , active_extruder ) ; //delay
current_position [ X_AXIS ] - = 23 ; //delay
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 600 / 60 , active_extruder ) ; //delay*/
delay_keep_alive ( 4700 ) ;
}
max_feedrate [ E_AXIS ] = 80 ;
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current_position [ E_AXIS ] - = ( bowden_length [ snmm_extruder ] + 60 + FIL_LOAD_LENGTH ) / 2 ;
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plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 500 , active_extruder ) ;
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current_position [ E_AXIS ] - = ( bowden_length [ snmm_extruder ] + 60 + FIL_LOAD_LENGTH ) / 2 ;
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plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , 500 , active_extruder ) ;
st_synchronize ( ) ;
//digipot_init();
if ( SilentMode = = 1 ) digipot_current ( 2 , tmp_motor [ 2 ] ) ; //set back to normal operation currents
else digipot_current ( 2 , tmp_motor_loud [ 2 ] ) ;
lcd_update_enable ( true ) ;
lcd_return_to_status ( ) ;
max_feedrate [ E_AXIS ] = 50 ;
}
else {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ERROR ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PREHEAT_NOZZLE ) ;
delay ( 2000 ) ;
lcd_implementation_clear ( ) ;
}
lcd_return_to_status ( ) ;
}
//wrapper functions for loading filament
static void extr_adj_0 ( ) {
change_extr ( 0 ) ;
extr_adj ( 0 ) ;
}
static void extr_adj_1 ( ) {
change_extr ( 1 ) ;
extr_adj ( 1 ) ;
}
static void extr_adj_2 ( ) {
change_extr ( 2 ) ;
extr_adj ( 2 ) ;
}
static void extr_adj_3 ( ) {
change_extr ( 3 ) ;
extr_adj ( 3 ) ;
}
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static void load_all ( ) {
for ( int i = 0 ; i < 4 ; i + + ) {
change_extr ( i ) ;
extr_adj ( i ) ;
}
}
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//wrapper functions for changing extruders
static void extr_change_0 ( ) {
change_extr ( 0 ) ;
lcd_return_to_status ( ) ;
}
static void extr_change_1 ( ) {
change_extr ( 1 ) ;
lcd_return_to_status ( ) ;
}
static void extr_change_2 ( ) {
change_extr ( 2 ) ;
lcd_return_to_status ( ) ;
}
static void extr_change_3 ( ) {
change_extr ( 3 ) ;
lcd_return_to_status ( ) ;
}
//wrapper functions for unloading filament
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void extr_unload_all ( ) {
if ( degHotend0 ( ) > EXTRUDE_MINTEMP ) {
for ( int i = 0 ; i < 4 ; i + + ) {
change_extr ( i ) ;
extr_unload ( ) ;
}
}
else {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ERROR ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PREHEAT_NOZZLE ) ;
delay ( 2000 ) ;
lcd_implementation_clear ( ) ;
lcd_return_to_status ( ) ;
}
}
//unloading just used filament (for snmm)
void extr_unload_used ( ) {
if ( degHotend0 ( ) > EXTRUDE_MINTEMP ) {
for ( int i = 0 ; i < 4 ; i + + ) {
if ( snmm_filaments_used & ( 1 < < i ) ) {
change_extr ( i ) ;
extr_unload ( ) ;
}
}
snmm_filaments_used = 0 ;
}
else {
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_ERROR ) ;
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_PREHEAT_NOZZLE ) ;
delay ( 2000 ) ;
lcd_implementation_clear ( ) ;
lcd_return_to_status ( ) ;
}
}
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static void extr_unload_0 ( ) {
change_extr ( 0 ) ;
extr_unload ( ) ;
}
static void extr_unload_1 ( ) {
change_extr ( 1 ) ;
extr_unload ( ) ;
}
static void extr_unload_2 ( ) {
change_extr ( 2 ) ;
extr_unload ( ) ;
}
static void extr_unload_3 ( ) {
change_extr ( 3 ) ;
extr_unload ( ) ;
}
static void fil_load_menu ( )
{
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
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MENU_ITEM ( function , MSG_LOAD_ALL , load_all ) ;
MENU_ITEM ( function , MSG_LOAD_FILAMENT_1 , extr_adj_0 ) ;
MENU_ITEM ( function , MSG_LOAD_FILAMENT_2 , extr_adj_1 ) ;
MENU_ITEM ( function , MSG_LOAD_FILAMENT_3 , extr_adj_2 ) ;
MENU_ITEM ( function , MSG_LOAD_FILAMENT_4 , extr_adj_3 ) ;
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END_MENU ( ) ;
}
static void fil_unload_menu ( )
{
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
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MENU_ITEM ( function , MSG_UNLOAD_ALL , extr_unload_all ) ;
MENU_ITEM ( function , MSG_UNLOAD_FILAMENT_1 , extr_unload_0 ) ;
MENU_ITEM ( function , MSG_UNLOAD_FILAMENT_2 , extr_unload_1 ) ;
MENU_ITEM ( function , MSG_UNLOAD_FILAMENT_3 , extr_unload_2 ) ;
MENU_ITEM ( function , MSG_UNLOAD_FILAMENT_4 , extr_unload_3 ) ;
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END_MENU ( ) ;
}
static void change_extr_menu ( ) {
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
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MENU_ITEM ( function , MSG_EXTRUDER_1 , extr_change_0 ) ;
MENU_ITEM ( function , MSG_EXTRUDER_2 , extr_change_1 ) ;
MENU_ITEM ( function , MSG_EXTRUDER_3 , extr_change_2 ) ;
MENU_ITEM ( function , MSG_EXTRUDER_4 , extr_change_3 ) ;
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END_MENU ( ) ;
}
# endif
static void lcd_farm_no ( )
{
char step = 0 ;
int enc_dif = 0 ;
int _farmno = farm_no ;
int _ret = 0 ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd . print ( " Farm no " ) ;
do
{
if ( abs ( ( enc_dif - encoderDiff ) ) > 2 ) {
if ( enc_dif > encoderDiff ) {
switch ( step ) {
case ( 0 ) : if ( _farmno > = 100 ) _farmno - = 100 ; break ;
case ( 1 ) : if ( _farmno % 100 > = 10 ) _farmno - = 10 ; break ;
case ( 2 ) : if ( _farmno % 10 > = 1 ) _farmno - - ; break ;
default : break ;
}
}
if ( enc_dif < encoderDiff ) {
switch ( step ) {
case ( 0 ) : if ( _farmno < 900 ) _farmno + = 100 ; break ;
case ( 1 ) : if ( _farmno % 100 < 90 ) _farmno + = 10 ; break ;
case ( 2 ) : if ( _farmno % 10 < = 8 ) _farmno + + ; break ;
default : break ;
}
}
enc_dif = 0 ;
encoderDiff = 0 ;
}
lcd . setCursor ( 0 , 2 ) ;
if ( _farmno < 100 ) lcd . print ( " 0 " ) ;
if ( _farmno < 10 ) lcd . print ( " 0 " ) ;
lcd . print ( _farmno ) ;
lcd . print ( " " ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd . print ( " " ) ;
lcd . setCursor ( step , 3 ) ;
lcd . print ( " ^ " ) ;
delay ( 100 ) ;
if ( lcd_clicked ( ) )
{
delay ( 200 ) ;
step + + ;
if ( step = = 3 ) {
_ret = 1 ;
farm_no = _farmno ;
EEPROM_save_B ( EEPROM_FARM_NUMBER , & farm_no ) ;
prusa_statistics ( 20 ) ;
lcd_return_to_status ( ) ;
}
}
manage_heater ( ) ;
} while ( _ret = = 0 ) ;
}
void lcd_confirm_print ( )
{
int enc_dif = 0 ;
int cursor_pos = 1 ;
int _ret = 0 ;
int _t = 0 ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd . print ( " Print ok ? " ) ;
do
{
if ( abs ( ( enc_dif - encoderDiff ) ) > 2 ) {
if ( enc_dif > encoderDiff ) {
cursor_pos - - ;
}
if ( enc_dif < encoderDiff ) {
cursor_pos + + ;
}
}
if ( cursor_pos > 2 ) { cursor_pos = 2 ; }
if ( cursor_pos < 1 ) { cursor_pos = 1 ; }
lcd . setCursor ( 0 , 2 ) ; lcd . print ( " " ) ;
lcd . setCursor ( 0 , 3 ) ; lcd . print ( " " ) ;
lcd . setCursor ( 2 , 2 ) ;
lcd_printPGM ( MSG_YES ) ;
lcd . setCursor ( 2 , 3 ) ;
lcd_printPGM ( MSG_NO ) ;
lcd . setCursor ( 0 , 1 + cursor_pos ) ;
lcd . print ( " > " ) ;
delay ( 100 ) ;
_t = _t + 1 ;
if ( _t > 100 )
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{
prusa_statistics ( 99 ) ;
_t = 0 ;
}
if ( lcd_clicked ( ) )
{
if ( cursor_pos = = 1 )
{
_ret = 1 ;
prusa_statistics ( 20 ) ;
prusa_statistics ( 4 ) ;
}
if ( cursor_pos = = 2 )
{
_ret = 2 ;
prusa_statistics ( 20 ) ;
prusa_statistics ( 5 ) ;
}
}
manage_heater ( ) ;
manage_inactivity ( ) ;
} while ( _ret = = 0 ) ;
}
static void lcd_main_menu ( )
{
SDscrool = 0 ;
START_MENU ( ) ;
// Majkl superawesome menu
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MENU_ITEM ( back , MSG_WATCH , lcd_status_screen ) ;
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MENU_ITEM ( function , PSTR ( " recover print " ) , recover_print ) ;
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/* if (farm_mode && !IS_SD_PRINTING )
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{
int tempScrool = 0 ;
if ( lcdDrawUpdate = = 0 & & LCD_CLICKED = = 0 )
//delay(100);
return ; // nothing to do (so don't thrash the SD card)
uint16_t fileCnt = card . getnrfilenames ( ) ;
card . getWorkDirName ( ) ;
if ( card . filename [ 0 ] = = ' / ' )
{
# if SDCARDDETECT == -1
MENU_ITEM ( function , MSG_REFRESH , lcd_sd_refresh ) ;
# endif
} else {
MENU_ITEM ( function , PSTR ( LCD_STR_FOLDER " .. " ) , lcd_sd_updir ) ;
}
for ( uint16_t i = 0 ; i < fileCnt ; i + + )
{
if ( _menuItemNr = = _lineNr )
{
# ifndef SDCARD_RATHERRECENTFIRST
card . getfilename ( i ) ;
# else
card . getfilename ( fileCnt - 1 - i ) ;
# endif
if ( card . filenameIsDir )
{
MENU_ITEM ( sddirectory , MSG_CARD_MENU , card . filename , card . longFilename ) ;
} else {
MENU_ITEM ( sdfile , MSG_CARD_MENU , card . filename , card . longFilename ) ;
}
} else {
MENU_ITEM_DUMMY ( ) ;
}
}
MENU_ITEM ( back , PSTR ( " - - - - - - - - - " ) , lcd_status_screen ) ;
} */
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if ( ( IS_SD_PRINTING | | is_usb_printing ) & & ( current_position [ Z_AXIS ] < Z_HEIGHT_HIDE_LIVE_ADJUST_MENU ) & & ! homing_flag & & ! mesh_bed_leveling_flag )
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{
MENU_ITEM ( submenu , MSG_BABYSTEP_Z , lcd_babystep_z ) ; //8
}
if ( moves_planned ( ) | | IS_SD_PRINTING | | is_usb_printing )
{
MENU_ITEM ( submenu , MSG_TUNE , lcd_tune_menu ) ;
} else
{
MENU_ITEM ( submenu , MSG_PREHEAT , lcd_preheat_menu ) ;
}
# ifdef SDSUPPORT
if ( card . cardOK )
{
if ( card . isFileOpen ( ) )
{
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if ( mesh_bed_leveling_flag = = false & & homing_flag = = false ) {
if ( card . sdprinting )
{
MENU_ITEM ( function , MSG_PAUSE_PRINT , lcd_sdcard_pause ) ;
}
else
{
MENU_ITEM ( function , MSG_RESUME_PRINT , lcd_sdcard_resume ) ;
}
MENU_ITEM ( submenu , MSG_STOP_PRINT , lcd_sdcard_stop ) ;
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}
}
else
{
if ( ! is_usb_printing )
{
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//if (farm_mode) MENU_ITEM(submenu, MSG_FARM_CARD_MENU, lcd_farm_sdcard_menu);
/*else*/ MENU_ITEM ( submenu , MSG_CARD_MENU , lcd_sdcard_menu ) ;
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}
# if SDCARDDETECT < 1
MENU_ITEM ( gcode , MSG_CNG_SDCARD , PSTR ( " M21 " ) ) ; // SD-card changed by user
# endif
}
} else
{
MENU_ITEM ( submenu , MSG_NO_CARD , lcd_sdcard_menu ) ;
# if SDCARDDETECT < 1
MENU_ITEM ( gcode , MSG_INIT_SDCARD , PSTR ( " M21 " ) ) ; // Manually initialize the SD-card via user interface
# endif
}
# endif
if ( IS_SD_PRINTING | | is_usb_printing )
{
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if ( farm_mode )
{
MENU_ITEM ( submenu , PSTR ( " Farm number " ) , lcd_farm_no ) ;
}
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}
else
{
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# ifndef SNMM
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MENU_ITEM ( function , MSG_LOAD_FILAMENT , lcd_LoadFilament ) ;
MENU_ITEM ( function , MSG_UNLOAD_FILAMENT , lcd_unLoadFilament ) ;
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# endif
# ifdef SNMM
MENU_ITEM ( submenu , MSG_LOAD_FILAMENT , fil_load_menu ) ;
MENU_ITEM ( submenu , MSG_UNLOAD_FILAMENT , fil_unload_menu ) ;
MENU_ITEM ( submenu , MSG_CHANGE_EXTR , change_extr_menu ) ;
# endif
MENU_ITEM ( submenu , MSG_SETTINGS , lcd_settings_menu ) ;
if ( ! isPrintPaused ) MENU_ITEM ( submenu , MSG_MENU_CALIBRATION , lcd_calibration_menu ) ;
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}
if ( ! is_usb_printing )
{
MENU_ITEM ( submenu , MSG_STATISTICS , lcd_menu_statistics ) ;
}
MENU_ITEM ( submenu , MSG_SUPPORT , lcd_support_menu ) ;
END_MENU ( ) ;
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}
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void stack_error ( ) {
SET_OUTPUT ( BEEPER ) ;
WRITE ( BEEPER , HIGH ) ;
delay ( 1000 ) ;
WRITE ( BEEPER , LOW ) ;
lcd_display_message_fullscreen_P ( MSG_STACK_ERROR ) ;
//err_triggered = 1;
while ( 1 ) delay_keep_alive ( 1000 ) ;
}
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# ifdef SDSUPPORT
static void lcd_autostart_sd ( )
{
card . lastnr = 0 ;
card . setroot ( ) ;
card . checkautostart ( true ) ;
}
# endif
static void lcd_silent_mode_set_tune ( ) {
SilentModeMenu = ! SilentModeMenu ;
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eeprom_update_byte ( ( unsigned char * ) EEPROM_SILENT , SilentModeMenu ) ;
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# ifdef HAVE_TMC2130_DRIVERS
tmc2130_mode = SilentModeMenu ? TMC2130_MODE_SILENT : TMC2130_MODE_NORMAL ;
tmc2130_init ( ) ;
# endif //HAVE_TMC2130_DRIVERS
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digipot_init ( ) ;
lcd_goto_menu ( lcd_tune_menu , 9 ) ;
}
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static void lcd_colorprint_change ( ) {
enquecommand_P ( PSTR ( " M600 " ) ) ;
custom_message = true ;
custom_message_type = 2 ; //just print status message
lcd_setstatuspgm ( MSG_FINISHING_MOVEMENTS ) ;
lcd_return_to_status ( ) ;
lcdDrawUpdate = 3 ;
}
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static void lcd_tune_menu ( )
{
EEPROM_read ( EEPROM_SILENT , ( uint8_t * ) & SilentModeMenu , sizeof ( SilentModeMenu ) ) ;
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ; //1
MENU_ITEM_EDIT ( int3 , MSG_SPEED , & feedmultiply , 10 , 999 ) ; //2
MENU_ITEM_EDIT ( int3 , MSG_NOZZLE , & target_temperature [ 0 ] , 0 , HEATER_0_MAXTEMP - 10 ) ; //3
MENU_ITEM_EDIT ( int3 , MSG_BED , & target_temperature_bed , 0 , BED_MAXTEMP - 10 ) ; //4
MENU_ITEM_EDIT ( int3 , MSG_FAN_SPEED , & fanSpeed , 0 , 255 ) ; //5
MENU_ITEM_EDIT ( int3 , MSG_FLOW , & extrudemultiply , 10 , 999 ) ; //6
# ifdef FILAMENTCHANGEENABLE
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MENU_ITEM ( function , MSG_FILAMENTCHANGE , lcd_colorprint_change ) ; //7
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# endif
if ( SilentModeMenu = = 0 ) {
MENU_ITEM ( function , MSG_SILENT_MODE_OFF , lcd_silent_mode_set_tune ) ;
} else {
MENU_ITEM ( function , MSG_SILENT_MODE_ON , lcd_silent_mode_set_tune ) ;
}
END_MENU ( ) ;
}
static void lcd_move_menu_01mm ( )
{
move_menu_scale = 0.1 ;
lcd_move_menu_axis ( ) ;
}
static void lcd_control_temperature_menu ( )
{
# ifdef PIDTEMP
// set up temp variables - undo the default scaling
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// raw_Ki = unscalePID_i(Ki);
// raw_Kd = unscalePID_d(Kd);
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# endif
START_MENU ( ) ;
MENU_ITEM ( back , MSG_SETTINGS , lcd_settings_menu ) ;
# if TEMP_SENSOR_0 != 0
MENU_ITEM_EDIT ( int3 , MSG_NOZZLE , & target_temperature [ 0 ] , 0 , HEATER_0_MAXTEMP - 10 ) ;
# endif
# if TEMP_SENSOR_1 != 0
MENU_ITEM_EDIT ( int3 , MSG_NOZZLE1 , & target_temperature [ 1 ] , 0 , HEATER_1_MAXTEMP - 10 ) ;
# endif
# if TEMP_SENSOR_2 != 0
MENU_ITEM_EDIT ( int3 , MSG_NOZZLE2 , & target_temperature [ 2 ] , 0 , HEATER_2_MAXTEMP - 10 ) ;
# endif
# if TEMP_SENSOR_BED != 0
MENU_ITEM_EDIT ( int3 , MSG_BED , & target_temperature_bed , 0 , BED_MAXTEMP - 3 ) ;
# endif
MENU_ITEM_EDIT ( int3 , MSG_FAN_SPEED , & fanSpeed , 0 , 255 ) ;
# if defined AUTOTEMP && (TEMP_SENSOR_0 != 0)
MENU_ITEM_EDIT ( bool , MSG_AUTOTEMP , & autotemp_enabled ) ;
MENU_ITEM_EDIT ( float3 , MSG_MIN , & autotemp_min , 0 , HEATER_0_MAXTEMP - 10 ) ;
MENU_ITEM_EDIT ( float3 , MSG_MAX , & autotemp_max , 0 , HEATER_0_MAXTEMP - 10 ) ;
MENU_ITEM_EDIT ( float32 , MSG_FACTOR , & autotemp_factor , 0.0 , 1.0 ) ;
# endif
END_MENU ( ) ;
}
# if SDCARDDETECT == -1
static void lcd_sd_refresh ( )
{
card . initsd ( ) ;
currentMenuViewOffset = 0 ;
}
# endif
static void lcd_sd_updir ( )
{
SDscrool = 0 ;
card . updir ( ) ;
currentMenuViewOffset = 0 ;
}
void lcd_sdcard_stop ( )
{
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_STOP_PRINT ) ;
lcd . setCursor ( 2 , 2 ) ;
lcd_printPGM ( MSG_NO ) ;
lcd . setCursor ( 2 , 3 ) ;
lcd_printPGM ( MSG_YES ) ;
lcd . setCursor ( 0 , 2 ) ; lcd . print ( " " ) ;
lcd . setCursor ( 0 , 3 ) ; lcd . print ( " " ) ;
if ( ( int32_t ) encoderPosition > 2 ) { encoderPosition = 2 ; }
if ( ( int32_t ) encoderPosition < 1 ) { encoderPosition = 1 ; }
lcd . setCursor ( 0 , 1 + encoderPosition ) ;
lcd . print ( " > " ) ;
if ( lcd_clicked ( ) )
{
if ( ( int32_t ) encoderPosition = = 1 )
{
lcd_return_to_status ( ) ;
}
if ( ( int32_t ) encoderPosition = = 2 )
{
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cancel_heatup = true ;
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# ifdef MESH_BED_LEVELING
mbl . active = false ;
# endif
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// Stop the stoppers, update the position from the stoppers.
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if ( mesh_bed_leveling_flag = = false & & homing_flag = = false ) {
planner_abort_hard ( ) ;
// Because the planner_abort_hard() initialized current_position[Z] from the stepper,
// Z baystep is no more applied. Reset it.
babystep_reset ( ) ;
}
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// Clean the input command queue.
cmdqueue_reset ( ) ;
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lcd_setstatuspgm ( MSG_PRINT_ABORTED ) ;
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lcd_update ( 2 ) ;
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card . sdprinting = false ;
card . closefile ( ) ;
stoptime = millis ( ) ;
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unsigned long t = ( stoptime - starttime - pause_time ) / 1000 ; //time in s
pause_time = 0 ;
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save_statistics ( total_filament_used , t ) ;
lcd_return_to_status ( ) ;
lcd_ignore_click ( true ) ;
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lcd_commands_type = LCD_COMMAND_STOP_PRINT ;
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// Turn off the print fan
SET_OUTPUT ( FAN_PIN ) ;
WRITE ( FAN_PIN , 0 ) ;
fanSpeed = 0 ;
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}
}
}
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/*
void getFileDescription ( char * name , char * description ) {
// get file description, ie the REAL filenam, ie the second line
card . openFile ( name , true ) ;
int i = 0 ;
// skip the first line (which is the version line)
while ( true ) {
uint16_t readByte = card . get ( ) ;
if ( readByte = = ' \n ' ) {
break ;
}
}
// read the second line (which is the description line)
while ( true ) {
uint16_t readByte = card . get ( ) ;
if ( i = = 0 ) {
// skip the first '^'
readByte = card . get ( ) ;
}
description [ i ] = readByte ;
i + + ;
if ( readByte = = ' \n ' ) {
break ;
}
}
card . closefile ( ) ;
description [ i - 1 ] = 0 ;
}
*/
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void lcd_sdcard_menu ( )
{
int tempScrool = 0 ;
if ( lcdDrawUpdate = = 0 & & LCD_CLICKED = = 0 )
//delay(100);
return ; // nothing to do (so don't thrash the SD card)
uint16_t fileCnt = card . getnrfilenames ( ) ;
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
card . getWorkDirName ( ) ;
if ( card . filename [ 0 ] = = ' / ' )
{
# if SDCARDDETECT == -1
MENU_ITEM ( function , MSG_REFRESH , lcd_sd_refresh ) ;
# endif
} else {
MENU_ITEM ( function , PSTR ( LCD_STR_FOLDER " .. " ) , lcd_sd_updir ) ;
}
for ( uint16_t i = 0 ; i < fileCnt ; i + + )
{
if ( _menuItemNr = = _lineNr )
{
# ifndef SDCARD_RATHERRECENTFIRST
card . getfilename ( i ) ;
# else
card . getfilename ( fileCnt - 1 - i ) ;
# endif
if ( card . filenameIsDir )
{
MENU_ITEM ( sddirectory , MSG_CARD_MENU , card . filename , card . longFilename ) ;
} else {
MENU_ITEM ( sdfile , MSG_CARD_MENU , card . filename , card . longFilename ) ;
}
} else {
MENU_ITEM_DUMMY ( ) ;
}
}
END_MENU ( ) ;
}
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//char description [10] [31];
/*void get_description() {
uint16_t fileCnt = card . getnrfilenames ( ) ;
for ( uint16_t i = 0 ; i < fileCnt ; i + + )
{
card . getfilename ( fileCnt - 1 - i ) ;
getFileDescription ( card . filename , description [ i ] ) ;
}
} */
/*void lcd_farm_sdcard_menu()
{
static int i = 0 ;
if ( i = = 0 ) {
get_description ( ) ;
i + + ;
}
//int j;
//char description[31];
int tempScrool = 0 ;
if ( lcdDrawUpdate = = 0 & & LCD_CLICKED = = 0 )
//delay(100);
return ; // nothing to do (so don't thrash the SD card)
uint16_t fileCnt = card . getnrfilenames ( ) ;
START_MENU ( ) ;
MENU_ITEM ( back , MSG_MAIN , lcd_main_menu ) ;
card . getWorkDirName ( ) ;
if ( card . filename [ 0 ] = = ' / ' )
{
# if SDCARDDETECT == -1
MENU_ITEM ( function , MSG_REFRESH , lcd_sd_refresh ) ;
# endif
}
else {
MENU_ITEM ( function , PSTR ( LCD_STR_FOLDER " .. " ) , lcd_sd_updir ) ;
}
for ( uint16_t i = 0 ; i < fileCnt ; i + + )
{
if ( _menuItemNr = = _lineNr )
{
# ifndef SDCARD_RATHERRECENTFIRST
card . getfilename ( i ) ;
# else
card . getfilename ( fileCnt - 1 - i ) ;
# endif
if ( card . filenameIsDir )
{
MENU_ITEM ( sddirectory , MSG_CARD_MENU , card . filename , card . longFilename ) ;
}
else {
MENU_ITEM ( sdfile , MSG_CARD_MENU , card . filename , description [ i ] ) ;
}
}
else {
MENU_ITEM_DUMMY ( ) ;
}
}
END_MENU ( ) ;
} */
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# define menu_edit_type(_type, _name, _strFunc, scale) \
void menu_edit_ # # _name ( ) \
{ \
if ( ( int32_t ) encoderPosition < 0 ) encoderPosition = 0 ; \
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if ( ( int32_t ) encoderPosition > menuData . editMenuParentState . maxEditValue ) encoderPosition = menuData . editMenuParentState . maxEditValue ; \
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if ( lcdDrawUpdate ) \
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lcd_implementation_drawedit ( menuData . editMenuParentState . editLabel , _strFunc ( ( ( _type ) ( ( int32_t ) encoderPosition + menuData . editMenuParentState . minEditValue ) ) / scale ) ) ; \
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if ( LCD_CLICKED ) \
{ \
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* ( ( _type * ) menuData . editMenuParentState . editValue ) = ( ( _type ) ( ( int32_t ) encoderPosition + menuData . editMenuParentState . minEditValue ) ) / scale ; \
lcd_goto_menu ( menuData . editMenuParentState . prevMenu , menuData . editMenuParentState . prevEncoderPosition , true , false ) ; \
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} \
} \
static void menu_action_setting_edit_ # # _name ( const char * pstr , _type * ptr , _type minValue , _type maxValue ) \
{ \
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menuData . editMenuParentState . prevMenu = currentMenu ; \
menuData . editMenuParentState . prevEncoderPosition = encoderPosition ; \
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\
lcdDrawUpdate = 2 ; \
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menuData . editMenuParentState . editLabel = pstr ; \
menuData . editMenuParentState . editValue = ptr ; \
menuData . editMenuParentState . minEditValue = minValue * scale ; \
menuData . editMenuParentState . maxEditValue = maxValue * scale - menuData . editMenuParentState . minEditValue ; \
lcd_goto_menu ( menu_edit_ # # _name , ( * ptr ) * scale - menuData . editMenuParentState . minEditValue , true , false ) ; \
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\
} \
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/*
void menu_edit_callback_ # # _name ( ) { \
menu_edit_ # # _name ( ) ; \
if ( LCD_CLICKED ) ( * callbackFunc ) ( ) ; \
} \
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static void menu_action_setting_edit_callback_ # # _name ( const char * pstr , _type * ptr , _type minValue , _type maxValue , menuFunc_t callback ) \
{ \
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menuData . editMenuParentState . prevMenu = currentMenu ; \
menuData . editMenuParentState . prevEncoderPosition = encoderPosition ; \
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\
lcdDrawUpdate = 2 ; \
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lcd_goto_menu ( menu_edit_callback_ # # _name , ( * ptr ) * scale - menuData . editMenuParentState . minEditValue , true , false ) ; \
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\
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menuData . editMenuParentState . editLabel = pstr ; \
menuData . editMenuParentState . editValue = ptr ; \
menuData . editMenuParentState . minEditValue = minValue * scale ; \
menuData . editMenuParentState . maxEditValue = maxValue * scale - menuData . editMenuParentState . minEditValue ; \
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callbackFunc = callback ; \
}
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*/
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menu_edit_type ( int , int3 , itostr3 , 1 )
menu_edit_type ( float , float3 , ftostr3 , 1 )
menu_edit_type ( float , float32 , ftostr32 , 100 )
menu_edit_type ( float , float43 , ftostr43 , 1000 )
menu_edit_type ( float , float5 , ftostr5 , 0.01 )
menu_edit_type ( float , float51 , ftostr51 , 10 )
menu_edit_type ( float , float52 , ftostr52 , 100 )
menu_edit_type ( unsigned long , long5 , ftostr5 , 0.01 )
static void lcd_selftest ( )
{
int _progress = 0 ;
bool _result = false ;
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lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ; lcd_printPGM ( MSG_SELFTEST_START ) ;
delay ( 2000 ) ;
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_progress = lcd_selftest_screen ( - 1 , _progress , 3 , true , 2000 ) ;
_result = lcd_selftest_fan_dialog ( 0 ) ;
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if ( _result )
{
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_progress = lcd_selftest_screen ( 0 , _progress , 3 , true , 2000 ) ;
_result = lcd_selftest_fan_dialog ( 1 ) ;
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}
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if ( _result )
{
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_progress = lcd_selftest_screen ( 1 , _progress , 3 , true , 2000 ) ;
//_progress = lcd_selftest_screen(2, _progress, 3, true, 2000);
_result = true ; // lcd_selfcheck_endstops();
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}
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if ( _result )
{
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_progress = lcd_selftest_screen ( 3 , _progress , 3 , true , 1000 ) ;
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//_result = lcd_selfcheck_check_heater(false);
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}
if ( _result )
{
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//current_position[Z_AXIS] += 15; //move Z axis higher to avoid false triggering of Z end stop in case that we are very low - just above heatbed
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_progress = lcd_selftest_screen ( 4 , _progress , 3 , true , 2000 ) ;
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//_result = lcd_selfcheck_axis(X_AXIS, X_MAX_POS);
homeaxis ( X_AXIS ) ;
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}
if ( _result )
{
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_progress = lcd_selftest_screen ( 4 , _progress , 3 , true , 0 ) ;
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_result = lcd_selfcheck_pulleys ( X_AXIS ) ;
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}
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if ( _result )
{
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_progress = lcd_selftest_screen ( 5 , _progress , 3 , true , 1500 ) ;
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//_result = lcd_selfcheck_axis(Y_AXIS, Y_MAX_POS);
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}
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if ( _result )
{
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_progress = lcd_selftest_screen ( 5 , _progress , 3 , true , 0 ) ;
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//_result = lcd_selfcheck_pulleys(Y_AXIS);
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}
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if ( _result )
{
current_position [ X_AXIS ] = current_position [ X_AXIS ] - 3 ;
current_position [ Y_AXIS ] = current_position [ Y_AXIS ] - 14 ;
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_progress = lcd_selftest_screen ( 6 , _progress , 3 , true , 1500 ) ;
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//_result = lcd_selfcheck_axis(2, Z_MAX_POS);
//enquecommand_P(PSTR("G28 W"));
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}
if ( _result )
{
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_progress = lcd_selftest_screen ( 7 , _progress , 3 , true , 2000 ) ;
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//_result = lcd_selfcheck_check_heater(true);
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}
if ( _result )
{
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_progress = lcd_selftest_screen ( 8 , _progress , 3 , true , 5000 ) ;
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}
else
{
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_progress = lcd_selftest_screen ( 9 , _progress , 3 , true , 5000 ) ;
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}
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lcd_reset_alert_level ( ) ;
enquecommand_P ( PSTR ( " M84 " ) ) ;
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lcd_implementation_clear ( ) ;
lcd_next_update_millis = millis ( ) + LCD_UPDATE_INTERVAL ;
if ( _result )
{
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LCD_ALERTMESSAGERPGM ( MSG_SELFTEST_OK ) ;
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}
else
{
LCD_ALERTMESSAGERPGM ( MSG_SELFTEST_FAILED ) ;
}
}
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static bool lcd_selfcheck_axis ( int _axis , int _travel )
{
bool _stepdone = false ;
bool _stepresult = false ;
int _progress = 0 ;
int _travel_done = 0 ;
int _err_endstop = 0 ;
int _lcd_refresh = 0 ;
_travel = _travel + ( _travel / 10 ) ;
do {
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current_position [ _axis ] = current_position [ _axis ] - 1 ;
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plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ 3 ] , manual_feedrate [ 0 ] / 60 , active_extruder ) ;
st_synchronize ( ) ;
if ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 | | READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 | | READ ( Z_MIN_PIN ) ^ Z_MIN_ENDSTOP_INVERTING = = 1 )
{
if ( _axis = = 0 )
{
_stepresult = ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 ) ? true : false ;
_err_endstop = ( READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 ) ? 1 : 2 ;
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}
if ( _axis = = 1 )
{
_stepresult = ( READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 ) ? true : false ;
_err_endstop = ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 ) ? 0 : 2 ;
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}
if ( _axis = = 2 )
{
_stepresult = ( READ ( Z_MIN_PIN ) ^ Z_MIN_ENDSTOP_INVERTING = = 1 ) ? true : false ;
_err_endstop = ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 ) ? 0 : 1 ;
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/*disable_x();
disable_y ( ) ;
disable_z ( ) ; */
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}
_stepdone = true ;
}
if ( _lcd_refresh < 6 )
{
_lcd_refresh + + ;
}
else
{
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_progress = lcd_selftest_screen ( 4 + _axis , _progress , 3 , false , 0 ) ;
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_lcd_refresh = 0 ;
}
manage_heater ( ) ;
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manage_inactivity ( true ) ;
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//delay(100);
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( _travel_done < = _travel ) ? _travel_done + + : _stepdone = true ;
} while ( ! _stepdone ) ;
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//current_position[_axis] = current_position[_axis] + 15;
//plan_buffer_line(current_position[X_AXIS], current_position[Y_AXIS], current_position[Z_AXIS], current_position[3], manual_feedrate[0] / 60, active_extruder);
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if ( ! _stepresult )
{
const char * _error_1 ;
const char * _error_2 ;
if ( _axis = = X_AXIS ) _error_1 = " X " ;
if ( _axis = = Y_AXIS ) _error_1 = " Y " ;
if ( _axis = = Z_AXIS ) _error_1 = " Z " ;
if ( _err_endstop = = 0 ) _error_2 = " X " ;
if ( _err_endstop = = 1 ) _error_2 = " Y " ;
if ( _err_endstop = = 2 ) _error_2 = " Z " ;
if ( _travel_done > = _travel )
{
lcd_selftest_error ( 5 , _error_1 , _error_2 ) ;
}
else
{
lcd_selftest_error ( 4 , _error_1 , _error_2 ) ;
}
}
return _stepresult ;
}
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static bool lcd_selfcheck_pulleys ( int axis )
{
float tmp_motor_loud [ 3 ] = DEFAULT_PWM_MOTOR_CURRENT_LOUD ;
float tmp_motor [ 3 ] = DEFAULT_PWM_MOTOR_CURRENT ;
float current_position_init ;
float move ;
bool endstop_triggered = false ;
bool result = true ;
int i ;
unsigned long timeout_counter ;
refresh_cmd_timeout ( ) ;
manage_inactivity ( true ) ;
if ( axis = = 0 ) move = 50 ; //X_AXIS
else move = 50 ; //Y_AXIS
current_position_init = current_position [ axis ] ;
current_position [ axis ] + = 2 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ 3 ] , manual_feedrate [ 0 ] / 60 , active_extruder ) ;
for ( i = 0 ; i < 5 ; i + + ) {
refresh_cmd_timeout ( ) ;
current_position [ axis ] = current_position [ axis ] + move ;
digipot_current ( 0 , 850 ) ; //set motor current higher
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ 3 ] , 200 , active_extruder ) ;
st_synchronize ( ) ;
if ( SilentModeMenu = = 1 ) digipot_current ( 0 , tmp_motor [ 0 ] ) ; //set back to normal operation currents
else digipot_current ( 0 , tmp_motor_loud [ 0 ] ) ; //set motor current back
current_position [ axis ] = current_position [ axis ] - move ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ 3 ] , 50 , active_extruder ) ;
st_synchronize ( ) ;
if ( ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 ) | | ( READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 ) ) {
lcd_selftest_error ( 8 , ( axis = = 0 ) ? " X " : " Y " , " " ) ;
return ( false ) ;
}
}
timeout_counter = millis ( ) + 2500 ;
endstop_triggered = false ;
manage_inactivity ( true ) ;
while ( ! endstop_triggered ) {
if ( ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 ) | | ( READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 ) ) {
endstop_triggered = true ;
if ( current_position_init - 1 < = current_position [ axis ] & & current_position_init + 1 > = current_position [ axis ] ) {
current_position [ axis ] + = 15 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ 3 ] , manual_feedrate [ 0 ] / 60 , active_extruder ) ;
st_synchronize ( ) ;
return ( true ) ;
}
else {
lcd_selftest_error ( 8 , ( axis = = 0 ) ? " X " : " Y " , " " ) ;
return ( false ) ;
}
}
else {
current_position [ axis ] - = 1 ;
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ 3 ] , manual_feedrate [ 0 ] / 60 , active_extruder ) ;
st_synchronize ( ) ;
if ( millis ( ) > timeout_counter ) {
lcd_selftest_error ( 8 , ( axis = = 0 ) ? " X " : " Y " , " " ) ;
return ( false ) ;
}
}
}
}
static bool lcd_selfcheck_endstops ( )
{
bool _result = true ;
if ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 | | READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 | | READ ( Z_MIN_PIN ) ^ Z_MIN_ENDSTOP_INVERTING = = 1 )
{
current_position [ 0 ] = ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 ) ? current_position [ 0 ] = current_position [ 0 ] + 10 : current_position [ 0 ] ;
current_position [ 1 ] = ( READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 ) ? current_position [ 1 ] = current_position [ 1 ] + 10 : current_position [ 1 ] ;
current_position [ 2 ] = ( READ ( Z_MIN_PIN ) ^ Z_MIN_ENDSTOP_INVERTING = = 1 ) ? current_position [ 2 ] = current_position [ 2 ] + 10 : current_position [ 2 ] ;
}
plan_buffer_line ( current_position [ X_AXIS ] , current_position [ Y_AXIS ] , current_position [ Z_AXIS ] , current_position [ E_AXIS ] , manual_feedrate [ 0 ] / 60 , active_extruder ) ;
delay ( 500 ) ;
if ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 | | READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 | | READ ( Z_MIN_PIN ) ^ Z_MIN_ENDSTOP_INVERTING = = 1 )
{
_result = false ;
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char _error [ 4 ] = " " ;
if ( READ ( X_MIN_PIN ) ^ X_MIN_ENDSTOP_INVERTING = = 1 ) strcat ( _error , " X " ) ;
if ( READ ( Y_MIN_PIN ) ^ Y_MIN_ENDSTOP_INVERTING = = 1 ) strcat ( _error , " Y " ) ;
if ( READ ( Z_MIN_PIN ) ^ Z_MIN_ENDSTOP_INVERTING = = 1 ) strcat ( _error , " Z " ) ;
lcd_selftest_error ( 3 , _error , " " ) ;
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}
manage_heater ( ) ;
manage_inactivity ( true ) ;
return _result ;
}
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static bool lcd_selfcheck_check_heater ( bool _isbed )
{
int _counter = 0 ;
int _progress = 0 ;
bool _stepresult = false ;
bool _docycle = true ;
int _checked_snapshot = ( _isbed ) ? degBed ( ) : degHotend ( 0 ) ;
int _opposite_snapshot = ( _isbed ) ? degHotend ( 0 ) : degBed ( ) ;
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int _cycles = ( _isbed ) ? 180 : 60 ; //~ 90s / 30s
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target_temperature [ 0 ] = ( _isbed ) ? 0 : 200 ;
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target_temperature_bed = ( _isbed ) ? 100 : 0 ;
manage_heater ( ) ;
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manage_inactivity ( true ) ;
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do {
_counter + + ;
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_docycle = ( _counter < _cycles ) ? true : false ;
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manage_heater ( ) ;
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manage_inactivity ( true ) ;
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_progress = ( _isbed ) ? lcd_selftest_screen ( 7 , _progress , 2 , false , 400 ) : lcd_selftest_screen ( 3 , _progress , 2 , false , 400 ) ;
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/*if (_isbed) {
MYSERIAL . print ( " Bed temp: " ) ;
MYSERIAL . println ( degBed ( ) ) ;
}
else {
MYSERIAL . print ( " Hotend temp: " ) ;
MYSERIAL . println ( degHotend ( 0 ) ) ;
} */
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} while ( _docycle ) ;
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target_temperature [ 0 ] = 0 ;
target_temperature_bed = 0 ;
manage_heater ( ) ;
int _checked_result = ( _isbed ) ? degBed ( ) - _checked_snapshot : degHotend ( 0 ) - _checked_snapshot ;
int _opposite_result = ( _isbed ) ? degHotend ( 0 ) - _opposite_snapshot : degBed ( ) - _opposite_snapshot ;
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/*
MYSERIAL . println ( " " ) ;
MYSERIAL . print ( " Checked result: " ) ;
MYSERIAL . println ( _checked_result ) ;
MYSERIAL . print ( " Opposite result: " ) ;
MYSERIAL . println ( _opposite_result ) ;
*/
if ( _opposite_result < ( ( _isbed ) ? 10 : 3 ) )
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{
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if ( _checked_result > = ( ( _isbed ) ? 3 : 10 ) )
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{
_stepresult = true ;
}
else
{
lcd_selftest_error ( 1 , " " , " " ) ;
}
}
else
{
lcd_selftest_error ( 2 , " " , " " ) ;
}
manage_heater ( ) ;
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manage_inactivity ( true ) ;
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return _stepresult ;
}
static void lcd_selftest_error ( int _error_no , const char * _error_1 , const char * _error_2 )
{
lcd_implementation_quick_feedback ( ) ;
target_temperature [ 0 ] = 0 ;
target_temperature_bed = 0 ;
manage_heater ( ) ;
manage_inactivity ( ) ;
lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
lcd_printPGM ( MSG_SELFTEST_ERROR ) ;
lcd . setCursor ( 0 , 1 ) ;
lcd_printPGM ( MSG_SELFTEST_PLEASECHECK ) ;
switch ( _error_no )
{
case 1 :
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_SELFTEST_HEATERTHERMISTOR ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_SELFTEST_NOTCONNECTED ) ;
break ;
case 2 :
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_SELFTEST_BEDHEATER ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_SELFTEST_WIRINGERROR ) ;
break ;
case 3 :
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_SELFTEST_ENDSTOPS ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_SELFTEST_WIRINGERROR ) ;
lcd . setCursor ( 17 , 3 ) ;
lcd . print ( _error_1 ) ;
break ;
case 4 :
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_SELFTEST_MOTOR ) ;
lcd . setCursor ( 18 , 2 ) ;
lcd . print ( _error_1 ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_SELFTEST_ENDSTOP ) ;
lcd . setCursor ( 18 , 3 ) ;
lcd . print ( _error_2 ) ;
break ;
case 5 :
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_SELFTEST_ENDSTOP_NOTHIT ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_SELFTEST_MOTOR ) ;
lcd . setCursor ( 18 , 3 ) ;
lcd . print ( _error_1 ) ;
break ;
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case 6 :
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_SELFTEST_COOLING_FAN ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_SELFTEST_WIRINGERROR ) ;
lcd . setCursor ( 18 , 3 ) ;
lcd . print ( _error_1 ) ;
break ;
case 7 :
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_SELFTEST_EXTRUDER_FAN ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_SELFTEST_WIRINGERROR ) ;
lcd . setCursor ( 18 , 3 ) ;
lcd . print ( _error_1 ) ;
break ;
case 8 :
lcd . setCursor ( 0 , 2 ) ;
lcd_printPGM ( MSG_LOOSE_PULLEY ) ;
lcd . setCursor ( 0 , 3 ) ;
lcd_printPGM ( MSG_SELFTEST_MOTOR ) ;
lcd . setCursor ( 18 , 3 ) ;
lcd . print ( _error_1 ) ;
break ;
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}
delay ( 1000 ) ;
lcd_implementation_quick_feedback ( ) ;
do {
delay ( 100 ) ;
manage_heater ( ) ;
manage_inactivity ( ) ;
} while ( ! lcd_clicked ( ) ) ;
LCD_ALERTMESSAGERPGM ( MSG_SELFTEST_FAILED ) ;
lcd_return_to_status ( ) ;
}
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static bool lcd_selftest_fan_dialog ( int _fan )
{
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bool _result = true ;
int _errno = 6 ;
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switch ( _fan ) {
case 0 :
fanSpeed = 0 ;
manage_heater ( ) ; //turn off fan
setExtruderAutoFanState ( EXTRUDER_0_AUTO_FAN_PIN , 1 ) ; //extruder fan
delay ( 2000 ) ; //delay_keep_alive would turn off extruder fan, because temerature is too low
manage_heater ( ) ; //count average fan speed from 2s delay and turn off fans
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if ( ! fan_speed [ 0 ] ) _result = false ;
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/*SERIAL_ECHOPGM("Extruder fan speed: ");
MYSERIAL . println ( fan_speed [ 0 ] ) ;
SERIAL_ECHOPGM ( " Print fan speed: " ) ;
MYSERIAL . print ( fan_speed [ 1 ] ) ; */
break ;
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case 1 :
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//will it work with Thotend > 50 C ?
fanSpeed = 255 ; //print fan
delay_keep_alive ( 2000 ) ;
fanSpeed = 0 ;
manage_heater ( ) ; //turn off fan
manage_inactivity ( true ) ; //to turn off print fan
if ( ! fan_speed [ 1 ] ) {
_result = false ; _errno = 7 ;
}
/*SERIAL_ECHOPGM("Extruder fan speed: ");
MYSERIAL . println ( fan_speed [ 0 ] ) ;
SERIAL_ECHOPGM ( " Print fan speed: " ) ;
MYSERIAL . print ( fan_speed [ 1 ] ) ; */
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break ;
}
if ( ! _result )
{
const char * _err ;
lcd_selftest_error ( _errno , _err , _err ) ;
}
return _result ;
}
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static int lcd_selftest_screen ( int _step , int _progress , int _progress_scale , bool _clear , int _delay )
{
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//SERIAL_ECHOPGM("Step:");
//MYSERIAL.println(_step);
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lcd_next_update_millis = millis ( ) + ( LCD_UPDATE_INTERVAL * 10000 ) ;
int _step_block = 0 ;
const char * _indicator = ( _progress > _progress_scale ) ? " - " : " | " ;
if ( _clear ) lcd_implementation_clear ( ) ;
lcd . setCursor ( 0 , 0 ) ;
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if ( _step = = - 1 ) lcd_printPGM ( MSG_SELFTEST_FAN ) ;
if ( _step = = 0 ) lcd_printPGM ( MSG_SELFTEST_FAN ) ;
if ( _step = = 1 ) lcd_printPGM ( MSG_SELFTEST_FAN ) ;
if ( _step = = 2 ) lcd_printPGM ( MSG_SELFTEST_CHECK_ENDSTOPS ) ;
if ( _step = = 3 ) lcd_printPGM ( MSG_SELFTEST_CHECK_HOTEND ) ;
if ( _step = = 4 ) lcd_printPGM ( MSG_SELFTEST_CHECK_X ) ;
if ( _step = = 5 ) lcd_printPGM ( MSG_SELFTEST_CHECK_Y ) ;
if ( _step = = 6 ) lcd_printPGM ( MSG_SELFTEST_CHECK_Z ) ;
if ( _step = = 7 ) lcd_printPGM ( MSG_SELFTEST_CHECK_BED ) ;
if ( _step = = 8 ) lcd_printPGM ( MSG_SELFTEST_CHECK_ALLCORRECT ) ;
if ( _step = = 9 ) lcd_printPGM ( MSG_SELFTEST_FAILED ) ;
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lcd . setCursor ( 0 , 1 ) ;
lcd . print ( " -------------------- " ) ;
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if ( ( _step > = - 1 ) & & ( _step < = 1 ) )
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{
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//SERIAL_ECHOLNPGM("Fan test");
lcd_print_at_PGM ( 0 , 2 , PSTR ( " Extruder fan: " ) ) ;
lcd . setCursor ( 14 , 2 ) ;
( _step < 0 ) ? lcd . print ( _indicator ) : lcd . print ( " OK " ) ;
lcd_print_at_PGM ( 0 , 3 , PSTR ( " Print fan: " ) ) ;
lcd . setCursor ( 14 , 3 ) ;
( _step < 1 ) ? lcd . print ( _indicator ) : lcd . print ( " OK " ) ;
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}
else if ( _step ! = 9 )
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{
//SERIAL_ECHOLNPGM("Other tests");
_step_block = 3 ;
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lcd_selftest_screen_step ( 3 , 9 , ( ( _step = = _step_block ) ? 1 : ( _step < _step_block ) ? 0 : 2 ) , " Hotend " , _indicator ) ;
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_step_block = 4 ;
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lcd_selftest_screen_step ( 2 , 2 , ( ( _step = = _step_block ) ? 1 : ( _step < _step_block ) ? 0 : 2 ) , " X " , _indicator ) ;
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_step_block = 5 ;
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lcd_selftest_screen_step ( 2 , 8 , ( ( _step = = _step_block ) ? 1 : ( _step < _step_block ) ? 0 : 2 ) , " Y " , _indicator ) ;
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_step_block = 6 ;
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lcd_selftest_screen_step ( 2 , 14 , ( ( _step = = _step_block ) ? 1 : ( _step < _step_block ) ? 0 : 2 ) , " Z " , _indicator ) ;
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_step_block = 7 ;
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lcd_selftest_screen_step ( 3 , 0 , ( ( _step = = _step_block ) ? 1 : ( _step < _step_block ) ? 0 : 2 ) , " Bed " , _indicator ) ;
}
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if ( _delay > 0 ) delay ( _delay ) ;
_progress + + ;
return ( _progress > _progress_scale * 2 ) ? 0 : _progress ;
}
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static void lcd_selftest_screen_step ( int _row , int _col , int _state , const char * _name , const char * _indicator )
{
lcd . setCursor ( _col , _row ) ;
switch ( _state )
{
case 1 :
lcd . print ( _name ) ;
lcd . setCursor ( _col + strlen ( _name ) , _row ) ;
lcd . print ( " : " ) ;
lcd . setCursor ( _col + strlen ( _name ) + 1 , _row ) ;
lcd . print ( _indicator ) ;
break ;
case 2 :
lcd . print ( _name ) ;
lcd . setCursor ( _col + strlen ( _name ) , _row ) ;
lcd . print ( " : " ) ;
lcd . setCursor ( _col + strlen ( _name ) + 1 , _row ) ;
lcd . print ( " OK " ) ;
break ;
default :
lcd . print ( _name ) ;
}
}
/** End of menus **/
static void lcd_quick_feedback ( )
{
lcdDrawUpdate = 2 ;
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button_pressed = false ;
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lcd_implementation_quick_feedback ( ) ;
}
/** Menu action functions **/
static void menu_action_back ( menuFunc_t data ) {
lcd_goto_menu ( data ) ;
}
static void menu_action_submenu ( menuFunc_t data ) {
lcd_goto_menu ( data ) ;
}
static void menu_action_gcode ( const char * pgcode ) {
enquecommand_P ( pgcode ) ;
}
static void menu_action_setlang ( unsigned char lang ) {
lcd_set_lang ( lang ) ;
}
static void menu_action_function ( menuFunc_t data ) {
( * data ) ( ) ;
}
static void menu_action_sdfile ( const char * filename , char * longFilename )
{
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loading_flag = false ;
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char cmd [ 30 ] ;
char * c ;
sprintf_P ( cmd , PSTR ( " M23 %s " ) , filename ) ;
for ( c = & cmd [ 4 ] ; * c ; c + + )
* c = tolower ( * c ) ;
enquecommand ( cmd ) ;
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for ( int i = 0 ; i < 8 ; i + + ) {
eeprom_write_byte ( ( uint8_t * ) EEPROM_FILENAME + i , filename [ i ] ) ;
}
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enquecommand_P ( PSTR ( " M24 " ) ) ;
lcd_return_to_status ( ) ;
}
static void menu_action_sddirectory ( const char * filename , char * longFilename )
{
card . chdir ( filename ) ;
encoderPosition = 0 ;
}
static void menu_action_setting_edit_bool ( const char * pstr , bool * ptr )
{
* ptr = ! ( * ptr ) ;
}
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/*
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static void menu_action_setting_edit_callback_bool ( const char * pstr , bool * ptr , menuFunc_t callback )
{
menu_action_setting_edit_bool ( pstr , ptr ) ;
( * callback ) ( ) ;
}
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*/
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# endif //ULTIPANEL
/** LCD API **/
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void lcd_init ( )
{
lcd_implementation_init ( ) ;
# ifdef NEWPANEL
SET_INPUT ( BTN_EN1 ) ;
SET_INPUT ( BTN_EN2 ) ;
WRITE ( BTN_EN1 , HIGH ) ;
WRITE ( BTN_EN2 , HIGH ) ;
# if BTN_ENC > 0
SET_INPUT ( BTN_ENC ) ;
WRITE ( BTN_ENC , HIGH ) ;
# endif
# ifdef REPRAPWORLD_KEYPAD
pinMode ( SHIFT_CLK , OUTPUT ) ;
pinMode ( SHIFT_LD , OUTPUT ) ;
pinMode ( SHIFT_OUT , INPUT ) ;
WRITE ( SHIFT_OUT , HIGH ) ;
WRITE ( SHIFT_LD , HIGH ) ;
# endif
# else // Not NEWPANEL
# ifdef SR_LCD_2W_NL // Non latching 2 wire shift register
pinMode ( SR_DATA_PIN , OUTPUT ) ;
pinMode ( SR_CLK_PIN , OUTPUT ) ;
# elif defined(SHIFT_CLK)
pinMode ( SHIFT_CLK , OUTPUT ) ;
pinMode ( SHIFT_LD , OUTPUT ) ;
pinMode ( SHIFT_EN , OUTPUT ) ;
pinMode ( SHIFT_OUT , INPUT ) ;
WRITE ( SHIFT_OUT , HIGH ) ;
WRITE ( SHIFT_LD , HIGH ) ;
WRITE ( SHIFT_EN , LOW ) ;
# else
# ifdef ULTIPANEL
# error ULTIPANEL requires an encoder
# endif
# endif // SR_LCD_2W_NL
# endif //!NEWPANEL
# if defined (SDSUPPORT) && defined(SDCARDDETECT) && (SDCARDDETECT > 0)
pinMode ( SDCARDDETECT , INPUT ) ;
WRITE ( SDCARDDETECT , HIGH ) ;
lcd_oldcardstatus = IS_SD_INSERTED ;
# endif //(SDCARDDETECT > 0)
# ifdef LCD_HAS_SLOW_BUTTONS
slow_buttons = 0 ;
# endif
lcd_buttons_update ( ) ;
# ifdef ULTIPANEL
encoderDiff = 0 ;
# endif
}
//#include <avr/pgmspace.h>
static volatile bool lcd_update_enabled = true ;
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unsigned long lcd_timeoutToStatus = 0 ;
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void lcd_update_enable ( bool enabled )
{
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if ( lcd_update_enabled ! = enabled ) {
lcd_update_enabled = enabled ;
if ( enabled ) {
// Reset encoder position. This is equivalent to re-entering a menu.
encoderPosition = 0 ;
encoderDiff = 0 ;
// Enabling the normal LCD update procedure.
// Reset the timeout interval.
lcd_timeoutToStatus = millis ( ) + LCD_TIMEOUT_TO_STATUS ;
// Force the keypad update now.
lcd_next_update_millis = millis ( ) - 1 ;
// Full update.
lcd_implementation_clear ( ) ;
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# if defined(LCD_PROGRESS_BAR) && defined(SDSUPPORT)
lcd_set_custom_characters ( currentMenu = = lcd_status_screen ) ;
# else
if ( currentMenu = = lcd_status_screen )
lcd_set_custom_characters_degree ( ) ;
else
lcd_set_custom_characters_arrows ( ) ;
# endif
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lcd_update ( 2 ) ;
} else {
// Clear the LCD always, or let it to the caller?
}
}
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}
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void lcd_update ( uint8_t lcdDrawUpdateOverride )
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{
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if ( lcdDrawUpdate < lcdDrawUpdateOverride )
lcdDrawUpdate = lcdDrawUpdateOverride ;
if ( ! lcd_update_enabled )
return ;
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# ifdef LCD_HAS_SLOW_BUTTONS
slow_buttons = lcd_implementation_read_slow_buttons ( ) ; // buttons which take too long to read in interrupt context
# endif
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lcd_buttons_update ( ) ;
# if (SDCARDDETECT > 0)
if ( ( IS_SD_INSERTED ! = lcd_oldcardstatus & & lcd_detected ( ) ) )
{
lcdDrawUpdate = 2 ;
lcd_oldcardstatus = IS_SD_INSERTED ;
lcd_implementation_init ( // to maybe revive the LCD if static electricity killed it.
# if defined(LCD_PROGRESS_BAR) && defined(SDSUPPORT)
currentMenu = = lcd_status_screen
# endif
) ;
if ( lcd_oldcardstatus )
{
card . initsd ( ) ;
LCD_MESSAGERPGM ( MSG_SD_INSERTED ) ;
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//get_description();
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}
else
{
card . release ( ) ;
LCD_MESSAGERPGM ( MSG_SD_REMOVED ) ;
}
}
# endif //CARDINSERTED
if ( lcd_next_update_millis < millis ( ) )
{
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# ifdef DEBUG_BLINK_ACTIVE
static bool active_led = false ;
active_led = ! active_led ;
pinMode ( LED_PIN , OUTPUT ) ;
digitalWrite ( LED_PIN , active_led ? HIGH : LOW ) ;
# endif //DEBUG_BLINK_ACTIVE
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# ifdef ULTIPANEL
# ifdef REPRAPWORLD_KEYPAD
if ( REPRAPWORLD_KEYPAD_MOVE_Z_UP ) {
reprapworld_keypad_move_z_up ( ) ;
}
if ( REPRAPWORLD_KEYPAD_MOVE_Z_DOWN ) {
reprapworld_keypad_move_z_down ( ) ;
}
if ( REPRAPWORLD_KEYPAD_MOVE_X_LEFT ) {
reprapworld_keypad_move_x_left ( ) ;
}
if ( REPRAPWORLD_KEYPAD_MOVE_X_RIGHT ) {
reprapworld_keypad_move_x_right ( ) ;
}
if ( REPRAPWORLD_KEYPAD_MOVE_Y_DOWN ) {
reprapworld_keypad_move_y_down ( ) ;
}
if ( REPRAPWORLD_KEYPAD_MOVE_Y_UP ) {
reprapworld_keypad_move_y_up ( ) ;
}
if ( REPRAPWORLD_KEYPAD_MOVE_HOME ) {
reprapworld_keypad_move_home ( ) ;
}
# endif
if ( abs ( encoderDiff ) > = ENCODER_PULSES_PER_STEP )
{
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if ( lcdDrawUpdate = = 0 )
lcdDrawUpdate = 1 ;
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encoderPosition + = encoderDiff / ENCODER_PULSES_PER_STEP ;
encoderDiff = 0 ;
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lcd_timeoutToStatus = millis ( ) + LCD_TIMEOUT_TO_STATUS ;
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}
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if ( LCD_CLICKED ) lcd_timeoutToStatus = millis ( ) + LCD_TIMEOUT_TO_STATUS ;
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# endif //ULTIPANEL
# ifdef DOGLCD // Changes due to different driver architecture of the DOGM display
blink + + ; // Variable for fan animation and alive dot
u8g . firstPage ( ) ;
do
{
u8g . setFont ( u8g_font_6x10_marlin ) ;
u8g . setPrintPos ( 125 , 0 ) ;
if ( blink % 2 ) u8g . setColorIndex ( 1 ) ; else u8g . setColorIndex ( 0 ) ; // Set color for the alive dot
u8g . drawPixel ( 127 , 63 ) ; // draw alive dot
u8g . setColorIndex ( 1 ) ; // black on white
( * currentMenu ) ( ) ;
if ( ! lcdDrawUpdate ) break ; // Terminate display update, when nothing new to draw. This must be done before the last dogm.next()
} while ( u8g . nextPage ( ) ) ;
# else
( * currentMenu ) ( ) ;
# endif
# ifdef LCD_HAS_STATUS_INDICATORS
lcd_implementation_update_indicators ( ) ;
# endif
# ifdef ULTIPANEL
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if ( lcd_timeoutToStatus < millis ( ) & & currentMenu ! = lcd_status_screen )
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{
// Exiting a menu. Let's call the menu function the last time with menuExiting flag set to true
// to give it a chance to save its state.
// This is useful for example, when the babystep value has to be written into EEPROM.
if ( currentMenu ! = NULL ) {
menuExiting = true ;
( * currentMenu ) ( ) ;
menuExiting = false ;
}
lcd_return_to_status ( ) ;
lcdDrawUpdate = 2 ;
}
# endif //ULTIPANEL
if ( lcdDrawUpdate = = 2 ) lcd_implementation_clear ( ) ;
if ( lcdDrawUpdate ) lcdDrawUpdate - - ;
lcd_next_update_millis = millis ( ) + LCD_UPDATE_INTERVAL ;
}
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if ( ! SdFatUtil : : test_stack_integrity ( ) ) stack_error ( ) ;
lcd_ping ( ) ; //check that we have received ping command if we are in farm mode
}
void lcd_printer_connected ( ) {
printer_connected = true ;
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}
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void lcd_ping ( ) { //chceck if printer is connected to monitoring when in farm mode
if ( farm_mode ) {
bool empty = is_buffer_empty ( ) ;
if ( ( millis ( ) - PingTime ) * 0.001 > ( empty ? PING_TIME : PING_TIME_LONG ) ) { //if commands buffer is empty use shorter time period
//if there are comamnds in buffer, some long gcodes can delay execution of ping command
//therefore longer period is used
printer_connected = false ;
//lcd_ping_allert(); //acustic signals
}
else {
lcd_printer_connected ( ) ;
}
}
}
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void lcd_ignore_click ( bool b )
{
ignore_click = b ;
wait_for_unclick = false ;
}
void lcd_finishstatus ( ) {
int len = strlen ( lcd_status_message ) ;
if ( len > 0 ) {
while ( len < LCD_WIDTH ) {
lcd_status_message [ len + + ] = ' ' ;
}
}
lcd_status_message [ LCD_WIDTH ] = ' \0 ' ;
# if defined(LCD_PROGRESS_BAR) && defined(SDSUPPORT)
# if PROGRESS_MSG_EXPIRE > 0
messageTick =
# endif
progressBarTick = millis ( ) ;
# endif
lcdDrawUpdate = 2 ;
# ifdef FILAMENT_LCD_DISPLAY
message_millis = millis ( ) ; //get status message to show up for a while
# endif
}
void lcd_setstatus ( const char * message )
{
if ( lcd_status_message_level > 0 )
return ;
strncpy ( lcd_status_message , message , LCD_WIDTH ) ;
lcd_finishstatus ( ) ;
}
void lcd_setstatuspgm ( const char * message )
{
if ( lcd_status_message_level > 0 )
return ;
strncpy_P ( lcd_status_message , message , LCD_WIDTH ) ;
lcd_finishstatus ( ) ;
}
void lcd_setalertstatuspgm ( const char * message )
{
lcd_setstatuspgm ( message ) ;
lcd_status_message_level = 1 ;
# ifdef ULTIPANEL
lcd_return_to_status ( ) ;
# endif //ULTIPANEL
}
void lcd_reset_alert_level ( )
{
lcd_status_message_level = 0 ;
}
# ifdef DOGLCD
void lcd_setcontrast ( uint8_t value )
{
lcd_contrast = value & 63 ;
u8g . setContrast ( lcd_contrast ) ;
}
# endif
# ifdef ULTIPANEL
/* Warning: This function is called from interrupt context */
void lcd_buttons_update ( )
{
# ifdef NEWPANEL
uint8_t newbutton = 0 ;
if ( READ ( BTN_EN1 ) = = 0 ) newbutton | = EN_A ;
if ( READ ( BTN_EN2 ) = = 0 ) newbutton | = EN_B ;
# if BTN_ENC > 0
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if ( lcd_update_enabled = = true ) { //if we are in non-modal mode, long press can be used and short press triggers with button release
if ( READ ( BTN_ENC ) = = 0 ) { //button is pressed
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lcd_timeoutToStatus = millis ( ) + LCD_TIMEOUT_TO_STATUS ;
if ( millis ( ) > button_blanking_time ) {
button_blanking_time = millis ( ) + BUTTON_BLANKING_TIME ;
if ( button_pressed = = false & & long_press_active = = false ) {
if ( currentMenu ! = lcd_move_z ) {
savedMenu = currentMenu ;
savedEncoderPosition = encoderPosition ;
}
long_press_timer = millis ( ) ;
button_pressed = true ;
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}
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else {
if ( millis ( ) - long_press_timer > LONG_PRESS_TIME ) { //long press activated
long_press_active = true ;
move_menu_scale = 1.0 ;
lcd_goto_menu ( lcd_move_z ) ;
}
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}
}
}
else { //button not pressed
if ( button_pressed ) { //button was released
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button_blanking_time = millis ( ) + BUTTON_BLANKING_TIME ;
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if ( long_press_active = = false ) { //button released before long press gets activated
if ( currentMenu = = lcd_move_z ) {
//return to previously active menu and previous encoder position
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lcd_goto_menu ( savedMenu , savedEncoderPosition ) ;
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}
else {
newbutton | = EN_C ;
}
}
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else if ( currentMenu = = lcd_move_z ) lcd_quick_feedback ( ) ;
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//button_pressed is set back to false via lcd_quick_feedback function
}
else {
long_press_active = false ;
}
}
}
else { //we are in modal mode
if ( READ ( BTN_ENC ) = = 0 )
newbutton | = EN_C ;
}
# endif
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buttons = newbutton ;
# ifdef LCD_HAS_SLOW_BUTTONS
buttons | = slow_buttons ;
# endif
# ifdef REPRAPWORLD_KEYPAD
// for the reprapworld_keypad
uint8_t newbutton_reprapworld_keypad = 0 ;
WRITE ( SHIFT_LD , LOW ) ;
WRITE ( SHIFT_LD , HIGH ) ;
for ( int8_t i = 0 ; i < 8 ; i + + ) {
newbutton_reprapworld_keypad = newbutton_reprapworld_keypad > > 1 ;
if ( READ ( SHIFT_OUT ) )
newbutton_reprapworld_keypad | = ( 1 < < 7 ) ;
WRITE ( SHIFT_CLK , HIGH ) ;
WRITE ( SHIFT_CLK , LOW ) ;
}
buttons_reprapworld_keypad = ~ newbutton_reprapworld_keypad ; //invert it, because a pressed switch produces a logical 0
# endif
# else //read it from the shift register
uint8_t newbutton = 0 ;
WRITE ( SHIFT_LD , LOW ) ;
WRITE ( SHIFT_LD , HIGH ) ;
unsigned char tmp_buttons = 0 ;
for ( int8_t i = 0 ; i < 8 ; i + + )
{
newbutton = newbutton > > 1 ;
if ( READ ( SHIFT_OUT ) )
newbutton | = ( 1 < < 7 ) ;
WRITE ( SHIFT_CLK , HIGH ) ;
WRITE ( SHIFT_CLK , LOW ) ;
}
buttons = ~ newbutton ; //invert it, because a pressed switch produces a logical 0
# endif //!NEWPANEL
//manage encoder rotation
uint8_t enc = 0 ;
if ( buttons & EN_A ) enc | = B01 ;
if ( buttons & EN_B ) enc | = B10 ;
if ( enc ! = lastEncoderBits )
{
switch ( enc )
{
case encrot0 :
if ( lastEncoderBits = = encrot3 )
encoderDiff + + ;
else if ( lastEncoderBits = = encrot1 )
encoderDiff - - ;
break ;
case encrot1 :
if ( lastEncoderBits = = encrot0 )
encoderDiff + + ;
else if ( lastEncoderBits = = encrot2 )
encoderDiff - - ;
break ;
case encrot2 :
if ( lastEncoderBits = = encrot1 )
encoderDiff + + ;
else if ( lastEncoderBits = = encrot3 )
encoderDiff - - ;
break ;
case encrot3 :
if ( lastEncoderBits = = encrot2 )
encoderDiff + + ;
else if ( lastEncoderBits = = encrot0 )
encoderDiff - - ;
break ;
}
}
lastEncoderBits = enc ;
}
bool lcd_detected ( void )
{
# if (defined(LCD_I2C_TYPE_MCP23017) || defined(LCD_I2C_TYPE_MCP23008)) && defined(DETECT_DEVICE)
return lcd . LcdDetected ( ) = = 1 ;
# else
return true ;
# endif
}
void lcd_buzz ( long duration , uint16_t freq )
{
# ifdef LCD_USE_I2C_BUZZER
lcd . buzz ( duration , freq ) ;
# endif
}
bool lcd_clicked ( )
{
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bool clicked = LCD_CLICKED ;
if ( clicked ) button_pressed = false ;
return clicked ;
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}
# endif //ULTIPANEL
/********************************/
/** Float conversion utilities **/
/********************************/
// convert float to string with +123.4 format
char conv [ 8 ] ;
char * ftostr3 ( const float & x )
{
return itostr3 ( ( int ) x ) ;
}
char * itostr2 ( const uint8_t & x )
{
//sprintf(conv,"%5.1f",x);
int xx = x ;
conv [ 0 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 1 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 2 ] = 0 ;
return conv ;
}
// Convert float to string with 123.4 format, dropping sign
char * ftostr31 ( const float & x )
{
int xx = x * 10 ;
conv [ 0 ] = ( xx > = 0 ) ? ' + ' : ' - ' ;
xx = abs ( xx ) ;
conv [ 1 ] = ( xx / 1000 ) % 10 + ' 0 ' ;
conv [ 2 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 3 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 4 ] = ' . ' ;
conv [ 5 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 6 ] = 0 ;
return conv ;
}
// Convert float to string with 123.4 format
char * ftostr31ns ( const float & x )
{
int xx = x * 10 ;
//conv[0]=(xx>=0)?'+':'-';
xx = abs ( xx ) ;
conv [ 0 ] = ( xx / 1000 ) % 10 + ' 0 ' ;
conv [ 1 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 2 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 3 ] = ' . ' ;
conv [ 4 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 5 ] = 0 ;
return conv ;
}
char * ftostr32 ( const float & x )
{
long xx = x * 100 ;
if ( xx > = 0 )
conv [ 0 ] = ( xx / 10000 ) % 10 + ' 0 ' ;
else
conv [ 0 ] = ' - ' ;
xx = abs ( xx ) ;
conv [ 1 ] = ( xx / 1000 ) % 10 + ' 0 ' ;
conv [ 2 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 3 ] = ' . ' ;
conv [ 4 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 5 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 6 ] = 0 ;
return conv ;
}
//// Convert float to rj string with 123.45 format
char * ftostr32ns ( const float & x ) {
long xx = abs ( x ) ;
conv [ 0 ] = xx > = 10000 ? ( xx / 10000 ) % 10 + ' 0 ' : ' ' ;
conv [ 1 ] = xx > = 1000 ? ( xx / 1000 ) % 10 + ' 0 ' : ' ' ;
conv [ 2 ] = xx > = 100 ? ( xx / 100 ) % 10 + ' 0 ' : ' 0 ' ;
conv [ 3 ] = ' . ' ;
conv [ 4 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 5 ] = xx % 10 + ' 0 ' ;
return conv ;
}
// Convert float to string with 1.234 format
char * ftostr43 ( const float & x )
{
long xx = x * 1000 ;
if ( xx > = 0 )
conv [ 0 ] = ( xx / 1000 ) % 10 + ' 0 ' ;
else
conv [ 0 ] = ' - ' ;
xx = abs ( xx ) ;
conv [ 1 ] = ' . ' ;
conv [ 2 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 3 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 4 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 5 ] = 0 ;
return conv ;
}
//Float to string with 1.23 format
char * ftostr12ns ( const float & x )
{
long xx = x * 100 ;
xx = abs ( xx ) ;
conv [ 0 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 1 ] = ' . ' ;
conv [ 2 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 3 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 4 ] = 0 ;
return conv ;
}
//Float to string with 1.234 format
char * ftostr13ns ( const float & x )
{
long xx = x * 1000 ;
if ( xx > = 0 )
conv [ 0 ] = ' ' ;
else
conv [ 0 ] = ' - ' ;
xx = abs ( xx ) ;
conv [ 1 ] = ( xx / 1000 ) % 10 + ' 0 ' ;
conv [ 2 ] = ' . ' ;
conv [ 3 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 4 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 5 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 6 ] = 0 ;
return conv ;
}
// convert float to space-padded string with -_23.4_ format
char * ftostr32sp ( const float & x ) {
long xx = abs ( x * 100 ) ;
uint8_t dig ;
if ( x < 0 ) { // negative val = -_0
conv [ 0 ] = ' - ' ;
dig = ( xx / 1000 ) % 10 ;
conv [ 1 ] = dig ? ' 0 ' + dig : ' ' ;
}
else { // positive val = __0
dig = ( xx / 10000 ) % 10 ;
if ( dig ) {
conv [ 0 ] = ' 0 ' + dig ;
conv [ 1 ] = ' 0 ' + ( xx / 1000 ) % 10 ;
}
else {
conv [ 0 ] = ' ' ;
dig = ( xx / 1000 ) % 10 ;
conv [ 1 ] = dig ? ' 0 ' + dig : ' ' ;
}
}
conv [ 2 ] = ' 0 ' + ( xx / 100 ) % 10 ; // lsd always
dig = xx % 10 ;
if ( dig ) { // 2 decimal places
conv [ 5 ] = ' 0 ' + dig ;
conv [ 4 ] = ' 0 ' + ( xx / 10 ) % 10 ;
conv [ 3 ] = ' . ' ;
}
else { // 1 or 0 decimal place
dig = ( xx / 10 ) % 10 ;
if ( dig ) {
conv [ 4 ] = ' 0 ' + dig ;
conv [ 3 ] = ' . ' ;
}
else {
conv [ 3 ] = conv [ 4 ] = ' ' ;
}
conv [ 5 ] = ' ' ;
}
conv [ 6 ] = ' \0 ' ;
return conv ;
}
char * itostr31 ( const int & xx )
{
conv [ 0 ] = ( xx > = 0 ) ? ' + ' : ' - ' ;
conv [ 1 ] = ( xx / 1000 ) % 10 + ' 0 ' ;
conv [ 2 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 3 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 4 ] = ' . ' ;
conv [ 5 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 6 ] = 0 ;
return conv ;
}
// Convert int to rj string with 123 or -12 format
char * itostr3 ( const int & x )
{
int xx = x ;
if ( xx < 0 ) {
conv [ 0 ] = ' - ' ;
xx = - xx ;
} else if ( xx > = 100 )
conv [ 0 ] = ( xx / 100 ) % 10 + ' 0 ' ;
else
conv [ 0 ] = ' ' ;
if ( xx > = 10 )
conv [ 1 ] = ( xx / 10 ) % 10 + ' 0 ' ;
else
conv [ 1 ] = ' ' ;
conv [ 2 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 3 ] = 0 ;
return conv ;
}
// Convert int to lj string with 123 format
char * itostr3left ( const int & xx )
{
if ( xx > = 100 )
{
conv [ 0 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 1 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 2 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 3 ] = 0 ;
}
else if ( xx > = 10 )
{
conv [ 0 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 1 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 2 ] = 0 ;
}
else
{
conv [ 0 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 1 ] = 0 ;
}
return conv ;
}
// Convert int to rj string with 1234 format
char * itostr4 ( const int & xx ) {
conv [ 0 ] = xx > = 1000 ? ( xx / 1000 ) % 10 + ' 0 ' : ' ' ;
conv [ 1 ] = xx > = 100 ? ( xx / 100 ) % 10 + ' 0 ' : ' ' ;
conv [ 2 ] = xx > = 10 ? ( xx / 10 ) % 10 + ' 0 ' : ' ' ;
conv [ 3 ] = xx % 10 + ' 0 ' ;
conv [ 4 ] = 0 ;
return conv ;
}
// Convert float to rj string with 12345 format
char * ftostr5 ( const float & x ) {
long xx = abs ( x ) ;
conv [ 0 ] = xx > = 10000 ? ( xx / 10000 ) % 10 + ' 0 ' : ' ' ;
conv [ 1 ] = xx > = 1000 ? ( xx / 1000 ) % 10 + ' 0 ' : ' ' ;
conv [ 2 ] = xx > = 100 ? ( xx / 100 ) % 10 + ' 0 ' : ' ' ;
conv [ 3 ] = xx > = 10 ? ( xx / 10 ) % 10 + ' 0 ' : ' ' ;
conv [ 4 ] = xx % 10 + ' 0 ' ;
conv [ 5 ] = 0 ;
return conv ;
}
// Convert float to string with +1234.5 format
char * ftostr51 ( const float & x )
{
long xx = x * 10 ;
conv [ 0 ] = ( xx > = 0 ) ? ' + ' : ' - ' ;
xx = abs ( xx ) ;
conv [ 1 ] = ( xx / 10000 ) % 10 + ' 0 ' ;
conv [ 2 ] = ( xx / 1000 ) % 10 + ' 0 ' ;
conv [ 3 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 4 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 5 ] = ' . ' ;
conv [ 6 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 7 ] = 0 ;
return conv ;
}
// Convert float to string with +123.45 format
char * ftostr52 ( const float & x )
{
long xx = x * 100 ;
conv [ 0 ] = ( xx > = 0 ) ? ' + ' : ' - ' ;
xx = abs ( xx ) ;
conv [ 1 ] = ( xx / 10000 ) % 10 + ' 0 ' ;
conv [ 2 ] = ( xx / 1000 ) % 10 + ' 0 ' ;
conv [ 3 ] = ( xx / 100 ) % 10 + ' 0 ' ;
conv [ 4 ] = ' . ' ;
conv [ 5 ] = ( xx / 10 ) % 10 + ' 0 ' ;
conv [ 6 ] = ( xx ) % 10 + ' 0 ' ;
conv [ 7 ] = 0 ;
return conv ;
}
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/*
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// Callback for after editing PID i value
// grab the PID i value out of the temp variable; scale it; then update the PID driver
void copy_and_scalePID_i ( )
{
# ifdef PIDTEMP
Ki = scalePID_i ( raw_Ki ) ;
updatePID ( ) ;
# endif
}
// Callback for after editing PID d value
// grab the PID d value out of the temp variable; scale it; then update the PID driver
void copy_and_scalePID_d ( )
{
# ifdef PIDTEMP
Kd = scalePID_d ( raw_Kd ) ;
updatePID ( ) ;
# endif
}
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*/
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# endif //ULTRA_LCD