// Tonokip RepRap firmware rewrite based off of Hydra-mmm firmware. // Licence: GPL #include "Tonokip_Firmware.h" #include "configuration.h" #include "pins.h" #ifdef SDSUPPORT #include "SdFat.h" #endif // look here for descriptions of gcodes: http://linuxcnc.org/handbook/gcode/g-code.html // http://objects.reprap.org/wiki/Mendel_User_Manual:_RepRapGCodes //Implemented Codes //------------------- // G0 -> G1 // G1 - Coordinated Movement X Y Z E // G4 - Dwell S or P // G28 - Home all Axis // G90 - Use Absolute Coordinates // G91 - Use Relative Coordinates // G92 - Set current position to cordinates given //RepRap M Codes // M104 - Set extruder target temp // M105 - Read current temp // M106 - Fan on // M107 - Fan off // M109 - Wait for extruder current temp to reach target temp. // M114 - Display current position //Custom M Codes // M80 - Turn on Power Supply // M20 - List SD card // M21 - Init SD card // M22 - Release SD card // M23 - Select SD file (M23 filename.g) // M24 - Start/resume SD print // M25 - Pause SD print // M26 - Set SD position in bytes (M26 S12345) // M27 - Report SD print status // M28 - Start SD write (M28 filename.g) // M29 - Stop SD write // M81 - Turn off Power Supply // M82 - Set E codes absolute (default) // M83 - Set E codes relative while in Absolute Coordinates (G90) mode // M84 - Disable steppers until next move, // or use S to specify an inactivity timeout, after which the steppers will be disabled. S0 to disable the timeout. // M85 - Set inactivity shutdown timer with parameter S. To disable set zero (default) // M92 - Set axis_steps_per_unit - same syntax as G92 // M115 - Capabilities string // M140 - Set bed target temp // M190 - Wait for bed current temp to reach target temp. // M201 - Set max acceleration in units/s^2 for print moves (M201 X1000 Y1000) // M202 - Set max acceleration in units/s^2 for travel moves (M202 X1000 Y1000) //Stepper Movement Variables bool direction_x, direction_y, direction_z, direction_e; unsigned long previous_micros = 0, previous_micros_x = 0, previous_micros_y = 0, previous_micros_z = 0, previous_micros_e = 0, previous_millis_heater, previous_millis_bed_heater; unsigned long x_steps_to_take, y_steps_to_take, z_steps_to_take, e_steps_to_take; #ifdef RAMP_ACCELERATION unsigned long max_x_interval = 100000000.0 / (min_units_per_second * x_steps_per_unit); unsigned long max_y_interval = 100000000.0 / (min_units_per_second * y_steps_per_unit); unsigned long max_interval; unsigned long x_steps_per_sqr_second = max_acceleration_units_per_sq_second * x_steps_per_unit; unsigned long y_steps_per_sqr_second = max_acceleration_units_per_sq_second * y_steps_per_unit; unsigned long x_travel_steps_per_sqr_second = max_travel_acceleration_units_per_sq_second * x_steps_per_unit; unsigned long y_travel_steps_per_sqr_second = max_travel_acceleration_units_per_sq_second * y_steps_per_unit; unsigned long steps_per_sqr_second, plateau_steps; #endif #ifdef EXP_ACCELERATION unsigned long long_full_velocity_units = full_velocity_units * 100; unsigned long long_travel_move_full_velocity_units = travel_move_full_velocity_units * 100; unsigned long max_x_interval = 100000000.0 / (min_units_per_second * x_steps_per_unit); unsigned long max_y_interval = 100000000.0 / (min_units_per_second * y_steps_per_unit); unsigned long max_interval; unsigned long x_min_constant_speed_steps = min_constant_speed_units * x_steps_per_unit, y_min_constant_speed_steps = min_constant_speed_units * y_steps_per_unit, min_constant_speed_steps; #endif boolean acceleration_enabled = false, accelerating = false; unsigned long interval; float destination_x = 0.0, destination_y = 0.0, destination_z = 0.0, destination_e = 0.0; float current_x = 0.0, current_y = 0.0, current_z = 0.0, current_e = 0.0; long x_interval, y_interval, z_interval, e_interval; // for speed delay float feedrate = 1500, next_feedrate, z_feedrate, saved_feedrate; bool home_all_axis = true; float time_for_move; long gcode_N, gcode_LastN; bool relative_mode = false; //Determines Absolute or Relative Coordinates bool relative_mode_e = false; //Determines Absolute or Relative E Codes while in Absolute Coordinates mode. E is always relative in Relative Coordinates mode. long timediff = 0; #ifdef STEP_DELAY_RATIO long long_step_delay_ratio = STEP_DELAY_RATIO * 100; #endif // comm variables #define MAX_CMD_SIZE 96 #define BUFSIZE 8 char cmdbuffer[BUFSIZE][MAX_CMD_SIZE]; bool fromsd[BUFSIZE]; int bufindr = 0; int bufindw = 0; int buflen = 0; int i = 0; char serial_char; int serial_count = 0; boolean comment_mode = false; char *strchr_pointer; // just a pointer to find chars in the cmd string like X, Y, Z, E, etc // Manage heater variables. For a thermistor or AD595 thermocouple, raw values refer to the // reading from the analog pin. For a MAX6675 thermocouple, the raw value is the temperature in 0.25 // degree increments (i.e. 100=25 deg). int target_raw = 0; int current_raw = 0; int target_bed_raw = 0; int current_bed_raw = 0; float tt = 0, bt = 0; #ifdef PIDTEMP int temp_iState = 0; int temp_dState = 0; int pTerm; int iTerm; int dTerm; //int output; int error; int temp_iState_min = 100 * -PID_INTEGRAL_DRIVE_MAX / PID_IGAIN; int temp_iState_max = 100 * PID_INTEGRAL_DRIVE_MAX / PID_IGAIN; #endif #ifdef SMOOTHING uint32_t nma = SMOOTHFACTOR * analogRead(TEMP_0_PIN); #endif #ifdef WATCHPERIOD int watch_raw = -1000; unsigned long watchmillis = 0; #endif #ifdef MINTEMP int minttemp = temp2analog(MINTEMP); #endif #ifdef MAXTEMP int maxttemp = temp2analog(MAXTEMP); #endif //Inactivity shutdown variables unsigned long previous_millis_cmd = 0; unsigned long max_inactive_time = 0; unsigned long stepper_inactive_time = 0; #ifdef SDSUPPORT Sd2Card card; SdVolume volume; SdFile root; SdFile file; uint32_t filesize = 0; uint32_t sdpos = 0; bool sdmode = false; bool sdactive = false; bool savetosd = false; int16_t n; void initsd(){ sdactive = false; #if SDSS >- 1 if(root.isOpen()) root.close(); if (!card.init(SPI_FULL_SPEED,SDSS)){ //if (!card.init(SPI_HALF_SPEED,SDSS)) Serial.println("SD init fail"); } else if (!volume.init(&card)) Serial.println("volume.init failed"); else if (!root.openRoot(&volume)) Serial.println("openRoot failed"); else sdactive = true; #endif } inline void write_command(char *buf){ char* begin = buf; char* npos = 0; char* end = buf + strlen(buf) - 1; file.writeError = false; if((npos = strchr(buf, 'N')) != NULL){ begin = strchr(npos, ' ') + 1; end = strchr(npos, '*') - 1; } end[1] = '\r'; end[2] = '\n'; end[3] = '\0'; //Serial.println(begin); file.write(begin); if (file.writeError){ Serial.println("error writing to file"); } } #endif void setup() { Serial.begin(BAUDRATE); Serial.println("start"); for(int i = 0; i < BUFSIZE; i++){ fromsd[i] = false; } //Initialize Step Pins if(X_STEP_PIN > -1) pinMode(X_STEP_PIN,OUTPUT); if(Y_STEP_PIN > -1) pinMode(Y_STEP_PIN,OUTPUT); if(Z_STEP_PIN > -1) pinMode(Z_STEP_PIN,OUTPUT); if(E_STEP_PIN > -1) pinMode(E_STEP_PIN,OUTPUT); //Initialize Dir Pins if(X_DIR_PIN > -1) pinMode(X_DIR_PIN,OUTPUT); if(Y_DIR_PIN > -1) pinMode(Y_DIR_PIN,OUTPUT); if(Z_DIR_PIN > -1) pinMode(Z_DIR_PIN,OUTPUT); if(E_DIR_PIN > -1) pinMode(E_DIR_PIN,OUTPUT); //Steppers default to disabled. if(X_ENABLE_PIN > -1) if(!X_ENABLE_ON) digitalWrite(X_ENABLE_PIN,HIGH); if(Y_ENABLE_PIN > -1) if(!Y_ENABLE_ON) digitalWrite(Y_ENABLE_PIN,HIGH); if(Z_ENABLE_PIN > -1) if(!Z_ENABLE_ON) digitalWrite(Z_ENABLE_PIN,HIGH); if(E_ENABLE_PIN > -1) if(!E_ENABLE_ON) digitalWrite(E_ENABLE_PIN,HIGH); //endstop pullups #ifdef ENDSTOPPULLUPS if(X_MIN_PIN > -1) { pinMode(X_MIN_PIN,INPUT); digitalWrite(X_MIN_PIN,HIGH);} if(Y_MIN_PIN > -1) { pinMode(Y_MIN_PIN,INPUT); digitalWrite(Y_MIN_PIN,HIGH);} if(Z_MIN_PIN > -1) { pinMode(Z_MIN_PIN,INPUT); digitalWrite(Z_MIN_PIN,HIGH);} if(X_MAX_PIN > -1) { pinMode(X_MAX_PIN,INPUT); digitalWrite(X_MAX_PIN,HIGH);} if(Y_MAX_PIN > -1) { pinMode(Y_MAX_PIN,INPUT); digitalWrite(Y_MAX_PIN,HIGH);} if(Z_MAX_PIN > -1) { pinMode(Z_MAX_PIN,INPUT); digitalWrite(Z_MAX_PIN,HIGH);} #endif //Initialize Enable Pins if(X_ENABLE_PIN > -1) pinMode(X_ENABLE_PIN,OUTPUT); if(Y_ENABLE_PIN > -1) pinMode(Y_ENABLE_PIN,OUTPUT); if(Z_ENABLE_PIN > -1) pinMode(Z_ENABLE_PIN,OUTPUT); if(E_ENABLE_PIN > -1) pinMode(E_ENABLE_PIN,OUTPUT); if(HEATER_0_PIN > -1) pinMode(HEATER_0_PIN,OUTPUT); if(HEATER_1_PIN > -1) pinMode(HEATER_1_PIN,OUTPUT); #ifdef HEATER_USES_MAX6675 digitalWrite(SCK_PIN,0); pinMode(SCK_PIN,OUTPUT); digitalWrite(MOSI_PIN,1); pinMode(MOSI_PIN,OUTPUT); digitalWrite(MISO_PIN,1); pinMode(MISO_PIN,INPUT); digitalWrite(MAX6675_SS,1); pinMode(MAX6675_SS,OUTPUT); #endif #ifdef SDSUPPORT //power to SD reader #if SDPOWER > -1 pinMode(SDPOWER,OUTPUT); digitalWrite(SDPOWER,HIGH); #endif initsd(); #endif } void loop() { if(buflen<3) get_command(); if(buflen){ #ifdef SDSUPPORT if(savetosd){ if(strstr(cmdbuffer[bufindr],"M29") == NULL){ write_command(cmdbuffer[bufindr]); Serial.println("ok"); }else{ file.sync(); file.close(); savetosd = false; Serial.println("Done saving file."); } }else{ process_commands(); } #else process_commands(); #endif buflen = (buflen-1); bufindr = (bufindr + 1)%BUFSIZE; } //check heater every n milliseconds manage_heater(); manage_inactivity(1); } inline void get_command() { while( Serial.available() > 0 && buflen < BUFSIZE) { serial_char = Serial.read(); if(serial_char == '\n' || serial_char == '\r' || serial_char == ':' || serial_count >= (MAX_CMD_SIZE - 1) ) { if(!serial_count) return; //if empty line cmdbuffer[bufindw][serial_count] = 0; //terminate string if(!comment_mode){ fromsd[bufindw] = false; if(strstr(cmdbuffer[bufindw], "N") != NULL) { strchr_pointer = strchr(cmdbuffer[bufindw], 'N'); gcode_N = (strtol(&cmdbuffer[bufindw][strchr_pointer - cmdbuffer[bufindw] + 1], NULL, 10)); if(gcode_N != gcode_LastN+1 && (strstr(cmdbuffer[bufindw], "M110") == NULL) ) { Serial.print("Serial Error: Line Number is not Last Line Number+1, Last Line:"); Serial.println(gcode_LastN); //Serial.println(gcode_N); FlushSerialRequestResend(); serial_count = 0; return; } if(strstr(cmdbuffer[bufindw], "*") != NULL) { byte checksum = 0; byte count = 0; while(cmdbuffer[bufindw][count] != '*') checksum = checksum^cmdbuffer[bufindw][count++]; strchr_pointer = strchr(cmdbuffer[bufindw], '*'); if( (int)(strtod(&cmdbuffer[bufindw][strchr_pointer - cmdbuffer[bufindw] + 1], NULL)) != checksum) { Serial.print("Error: checksum mismatch, Last Line:"); Serial.println(gcode_LastN); FlushSerialRequestResend(); serial_count = 0; return; } //if no errors, continue parsing } else { Serial.print("Error: No Checksum with line number, Last Line:"); Serial.println(gcode_LastN); FlushSerialRequestResend(); serial_count = 0; return; } gcode_LastN = gcode_N; //if no errors, continue parsing } else // if we don't receive 'N' but still see '*' { if((strstr(cmdbuffer[bufindw], "*") != NULL)) { Serial.print("Error: No Line Number with checksum, Last Line:"); Serial.println(gcode_LastN); serial_count = 0; return; } } if((strstr(cmdbuffer[bufindw], "G") != NULL)){ strchr_pointer = strchr(cmdbuffer[bufindw], 'G'); switch((int)((strtod(&cmdbuffer[bufindw][strchr_pointer - cmdbuffer[bufindw] + 1], NULL)))){ case 0: case 1: #ifdef SDSUPPORT if(savetosd) break; #endif Serial.println("ok"); break; default: break; } } bufindw = (bufindw + 1)%BUFSIZE; buflen += 1; } comment_mode = false; //for new command serial_count = 0; //clear buffer } else { if(serial_char == ';') comment_mode = true; if(!comment_mode) cmdbuffer[bufindw][serial_count++] = serial_char; } } #ifdef SDSUPPORT if(!sdmode || serial_count!=0){ return; } while( filesize > sdpos && buflen < BUFSIZE) { n = file.read(); serial_char = (char)n; if(serial_char == '\n' || serial_char == '\r' || serial_char == ':' || serial_count >= (MAX_CMD_SIZE - 1) || n == -1) { sdpos = file.curPosition(); if(sdpos >= filesize){ sdmode = false; Serial.println("Done printing file"); } if(!serial_count) return; //if empty line cmdbuffer[bufindw][serial_count] = 0; //terminate string if(!comment_mode){ fromsd[bufindw] = true; buflen += 1; bufindw = (bufindw + 1)%BUFSIZE; } comment_mode = false; //for new command serial_count = 0; //clear buffer } else { if(serial_char == ';') comment_mode = true; if(!comment_mode) cmdbuffer[bufindw][serial_count++] = serial_char; } } #endif } inline float code_value() { return (strtod(&cmdbuffer[bufindr][strchr_pointer - cmdbuffer[bufindr] + 1], NULL)); } inline long code_value_long() { return (strtol(&cmdbuffer[bufindr][strchr_pointer - cmdbuffer[bufindr] + 1], NULL, 10)); } inline bool code_seen(char code_string[]) { return (strstr(cmdbuffer[bufindr], code_string) != NULL); } //Return True if the string was found inline bool code_seen(char code) { strchr_pointer = strchr(cmdbuffer[bufindr], code); return (strchr_pointer != NULL); //Return True if a character was found } //experimental feedrate calc float d = 0; float xdiff = 0, ydiff = 0, zdiff = 0, ediff = 0; inline void process_commands() { unsigned long codenum; //throw away variable char *starpos = NULL; if(code_seen('G')) { switch((int)code_value()) { case 0: // G0 -> G1 case 1: // G1 get_coordinates(); // For X Y Z E F prepare_move(); previous_millis_cmd = millis(); //ClearToSend(); return; //break; case 4: // G4 dwell codenum = 0; if(code_seen('P')) codenum = code_value(); // milliseconds to wait if(code_seen('S')) codenum = code_value() * 1000; // seconds to wait codenum += millis(); // keep track of when we started waiting while(millis() < codenum ){ manage_heater(); } break; case 28: //G28 Home all Axis one at a time saved_feedrate = feedrate; destination_x = 0; current_x = 0; destination_y = 0; current_y = 0; destination_z = 0; current_z = 0; destination_e = 0; current_e = 0; feedrate = 0; home_all_axis = !((code_seen('X')) || (code_seen('Y')) || (code_seen('Z'))); if((home_all_axis) || (code_seen('X'))) { if((X_MIN_PIN > -1 && X_HOME_DIR==-1) || (X_MAX_PIN > -1 && X_HOME_DIR==1)) { current_x = 0; destination_x = 1.5 * X_MAX_LENGTH * X_HOME_DIR; feedrate = min_units_per_second * 60; prepare_move(); current_x = 0; destination_x = -1 * X_HOME_DIR; prepare_move(); destination_x = 10 * X_HOME_DIR; prepare_move(); current_x = 0; destination_x = 0; feedrate = 0; } } if((home_all_axis) || (code_seen('Y'))) { if((Y_MIN_PIN > -1 && Y_HOME_DIR==-1) || (Y_MAX_PIN > -1 && Y_HOME_DIR==1)) { current_y = 0; destination_y = 1.5 * Y_MAX_LENGTH * Y_HOME_DIR; feedrate = min_units_per_second * 60; prepare_move(); current_y = 0; destination_y = -1 * Y_HOME_DIR; prepare_move(); destination_y = 10 * Y_HOME_DIR; prepare_move(); current_y = 0; destination_y = 0; feedrate = 0; } } if((home_all_axis) || (code_seen('Z'))) { if((Z_MIN_PIN > -1 && Z_HOME_DIR==-1) || (Z_MAX_PIN > -1 && Z_HOME_DIR==1)) { current_z = 0; destination_z = 1.5 * Z_MAX_LENGTH * Z_HOME_DIR; feedrate = max_z_feedrate/2; prepare_move(); current_z = 0; destination_z = -1 * Z_HOME_DIR; prepare_move(); destination_z = 10 * Z_HOME_DIR; prepare_move(); current_z = 0; destination_z = 0; feedrate = 0; } } feedrate = saved_feedrate; previous_millis_cmd = millis(); break; case 90: // G90 relative_mode = false; break; case 91: // G91 relative_mode = true; break; case 92: // G92 if(code_seen('X')) current_x = code_value(); if(code_seen('Y')) current_y = code_value(); if(code_seen('Z')) current_z = code_value(); if(code_seen('E')) current_e = code_value(); break; } } else if(code_seen('M')) { switch( (int)code_value() ) { #ifdef SDSUPPORT case 20: // M20 - list SD card Serial.println("Begin file list"); root.ls(); Serial.println("End file list"); break; case 21: // M21 - init SD card sdmode = false; initsd(); break; case 22: //M22 - release SD card sdmode = false; sdactive = false; break; case 23: //M23 - Select file if(sdactive){ sdmode = false; file.close(); starpos = (strchr(strchr_pointer + 4,'*')); if(starpos!=NULL) *(starpos-1)='\0'; if (file.open(&root, strchr_pointer + 4, O_READ)) { Serial.print("File opened:"); Serial.print(strchr_pointer + 4); Serial.print(" Size:"); Serial.println(file.fileSize()); sdpos = 0; filesize = file.fileSize(); Serial.println("File selected"); } else{ Serial.println("file.open failed"); } } break; case 24: //M24 - Start SD print if(sdactive){ sdmode = true; } break; case 25: //M25 - Pause SD print if(sdmode){ sdmode = false; } break; case 26: //M26 - Set SD index if(sdactive && code_seen('S')){ sdpos = code_value_long(); file.seekSet(sdpos); } break; case 27: //M27 - Get SD status if(sdactive){ Serial.print("SD printing byte "); Serial.print(sdpos); Serial.print("/"); Serial.println(filesize); }else{ Serial.println("Not SD printing"); } break; case 28: //M28 - Start SD write if(sdactive){ char* npos = 0; file.close(); sdmode = false; starpos = (strchr(strchr_pointer + 4,'*')); if(starpos != NULL){ npos = strchr(cmdbuffer[bufindr], 'N'); strchr_pointer = strchr(npos,' ') + 1; *(starpos-1) = '\0'; } if (!file.open(&root, strchr_pointer+4, O_CREAT | O_APPEND | O_WRITE | O_TRUNC)) { Serial.print("open failed, File: "); Serial.print(strchr_pointer + 4); Serial.print("."); }else{ savetosd = true; Serial.print("Writing to file: "); Serial.println(strchr_pointer + 4); } } break; case 29: //M29 - Stop SD write //processed in write to file routine above //savetosd = false; break; #endif case 104: // M104 if (code_seen('S')) target_raw = temp2analog(code_value()); #ifdef WATCHPERIOD if(target_raw > current_raw){ watchmillis = max(1,millis()); watch_raw = current_raw; }else{ watchmillis = 0; } #endif break; case 140: // M140 set bed temp if (code_seen('S')) target_bed_raw = temp2analogBed(code_value()); break; case 105: // M105 #if (TEMP_0_PIN > -1) || defined (HEATER_USES_MAX6675) tt = analog2temp(current_raw); #endif #if TEMP_1_PIN > -1 bt = analog2tempBed(current_bed_raw); #endif #if (TEMP_0_PIN > -1) || defined (HEATER_USES_MAX6675) Serial.print("ok T:"); Serial.print(tt); #if TEMP_1_PIN > -1 Serial.print(" B:"); Serial.println(bt); #else Serial.println(); #endif #else Serial.println("No thermistors - no temp"); #endif return; //break; case 109: // M109 - Wait for extruder heater to reach target. if (code_seen('S')) target_raw = temp2analog(code_value()); #ifdef WATCHPERIOD if(target_raw>current_raw){ watchmillis = max(1,millis()); watch_raw = current_raw; }else{ watchmillis = 0; } #endif codenum = millis(); while(current_raw < target_raw) { if( (millis() - codenum) > 1000 ) //Print Temp Reading every 1 second while heating up. { Serial.print("T:"); Serial.println( analog2temp(current_raw) ); codenum = millis(); } manage_heater(); } break; case 190: // M190 - Wait bed for heater to reach target. #if TEMP_1_PIN > -1 if (code_seen('S')) target_bed_raw = temp2analog(code_value()); codenum = millis(); while(current_bed_raw < target_bed_raw) { if( (millis()-codenum) > 1000 ) //Print Temp Reading every 1 second while heating up. { tt=analog2temp(current_raw); Serial.print("T:"); Serial.println( tt ); Serial.print("ok T:"); Serial.print( tt ); Serial.print(" B:"); Serial.println( analog2temp(current_bed_raw) ); codenum = millis(); } manage_heater(); } #endif break; case 106: //M106 Fan On if (code_seen('S')){ digitalWrite(FAN_PIN, HIGH); analogWrite(FAN_PIN, constrain(code_value(),0,255) ); } else digitalWrite(FAN_PIN, HIGH); break; case 107: //M107 Fan Off analogWrite(FAN_PIN, 0); digitalWrite(FAN_PIN, LOW); break; case 80: // M81 - ATX Power On if(PS_ON_PIN > -1) pinMode(PS_ON_PIN,OUTPUT); //GND break; case 81: // M81 - ATX Power Off if(PS_ON_PIN > -1) pinMode(PS_ON_PIN,INPUT); //Floating break; case 82: relative_mode_e = false; break; case 83: relative_mode_e = true; break; case 84: if(code_seen('S')){ stepper_inactive_time = code_value() * 1000; } else{ disable_x(); disable_y(); disable_z(); disable_e(); } break; case 85: // M85 code_seen('S'); max_inactive_time = code_value() * 1000; break; case 92: // M92 if(code_seen('X')) x_steps_per_unit = code_value(); if(code_seen('Y')) y_steps_per_unit = code_value(); if(code_seen('Z')) z_steps_per_unit = code_value(); if(code_seen('E')) e_steps_per_unit = code_value(); break; case 115: // M115 Serial.println("FIRMWARE_NAME:Sprinter FIRMWARE_URL:http%%3A/github.com/kliment/Sprinter/ PROTOCOL_VERSION:1.0 MACHINE_TYPE:Mendel EXTRUDER_COUNT:1"); break; case 114: // M114 Serial.print("X:"); Serial.print(current_x); Serial.print("Y:"); Serial.print(current_y); Serial.print("Z:"); Serial.print(current_z); Serial.print("E:"); Serial.println(current_e); break; case 119: // M119 #if (X_MIN_PIN > -1) Serial.print("x_min:"); Serial.println(digitalRead(X_MIN_PIN)?"H":"L"); #endif #if (X_MAX_PIN > -1) Serial.print("x_max:"); Serial.println(digitalRead(X_MAX_PIN)?"H":"L"); #endif #if (Y_MIN_PIN > -1) Serial.print("y_min:"); Serial.println(digitalRead(Y_MIN_PIN)?"H":"L"); #endif #if (Y_MAX_PIN > -1) Serial.print("y_max:"); Serial.println(digitalRead(Y_MAX_PIN)?"H":"L"); #endif #if (Z_MIN_PIN > -1) Serial.print("z_min:"); Serial.println(digitalRead(Z_MIN_PIN)?"H":"L"); #endif #if (Z_MAX_PIN > -1) Serial.print("z_max:"); Serial.println(digitalRead(Z_MAX_PIN)?"H":"L"); #endif break; #ifdef RAMP_ACCELERATION case 201: // M201 if(code_seen('X')) x_steps_per_sqr_second = code_value() * x_steps_per_unit; if(code_seen('Y')) y_steps_per_sqr_second = code_value() * y_steps_per_unit; break; case 202: // M202 if(code_seen('X')) x_travel_steps_per_sqr_second = code_value() * x_steps_per_unit; if(code_seen('Y')) y_travel_steps_per_sqr_second = code_value() * y_steps_per_unit; break; #endif } } else{ Serial.println("Unknown command:"); Serial.println(cmdbuffer[bufindr]); } ClearToSend(); } inline void FlushSerialRequestResend() { //char cmdbuffer[bufindr][100]="Resend:"; Serial.flush(); Serial.print("Resend:"); Serial.println(gcode_LastN + 1); ClearToSend(); } inline void ClearToSend() { previous_millis_cmd = millis(); #ifdef SDSUPPORT if(fromsd[bufindr]) return; #endif Serial.println("ok"); } inline void get_coordinates() { if(code_seen('X')) destination_x = (float)code_value() + relative_mode*current_x; else destination_x = current_x; //Are these else lines really needed? if(code_seen('Y')) destination_y = (float)code_value() + relative_mode*current_y; else destination_y = current_y; if(code_seen('Z')) destination_z = (float)code_value() + relative_mode*current_z; else destination_z = current_z; if(code_seen('E')) destination_e = (float)code_value() + (relative_mode_e || relative_mode)*current_e; else destination_e = current_e; if(code_seen('F')) { next_feedrate = code_value(); if(next_feedrate > 0.0) feedrate = next_feedrate; } } inline void prepare_move() { //Find direction if(destination_x >= current_x) direction_x = 1; else direction_x = 0; if(destination_y >= current_y) direction_y = 1; else direction_y = 0; if(destination_z >= current_z) direction_z = 1; else direction_z = 0; if(destination_e >= current_e) direction_e = 1; else direction_e = 0; if (min_software_endstops) { if (destination_x < 0) destination_x = 0.0; if (destination_y < 0) destination_y = 0.0; if (destination_z < 0) destination_z = 0.0; } if (max_software_endstops) { if (destination_x > X_MAX_LENGTH) destination_x = X_MAX_LENGTH; if (destination_y > Y_MAX_LENGTH) destination_y = Y_MAX_LENGTH; if (destination_z > Z_MAX_LENGTH) destination_z = Z_MAX_LENGTH; } if(feedrate > max_feedrate) feedrate = max_feedrate; if(feedrate > max_z_feedrate) z_feedrate = max_z_feedrate; else z_feedrate = feedrate; xdiff = (destination_x - current_x); ydiff = (destination_y - current_y); zdiff = (destination_z - current_z); ediff = (destination_e - current_e); x_steps_to_take = abs(xdiff) * x_steps_per_unit; y_steps_to_take = abs(ydiff) * y_steps_per_unit; z_steps_to_take = abs(zdiff) * z_steps_per_unit; e_steps_to_take = abs(ediff) * e_steps_per_unit; if(feedrate < 10) feedrate = 10; /* //experimental feedrate calc if(abs(xdiff) > 0.1 && abs(ydiff) > 0.1) d = sqrt(xdiff * xdiff + ydiff * ydiff); else if(abs(xdiff) > 0.1) d = abs(xdiff); else if(abs(ydiff) > 0.1) d = abs(ydiff); else if(abs(zdiff) > 0.05) d = abs(zdiff); else if(abs(ediff) > 0.1) d = abs(ediff); else d = 1; //extremely slow move, should be okay for moves under 0.1mm time_for_move = (xdiff / (feedrate / 60000000) ); //time = 60000000 * dist / feedrate //int feedz = (60000000 * zdiff) / time_for_move; //if(feedz > maxfeed) */ #define X_TIME_FOR_MOVE ((float)x_steps_to_take / (x_steps_per_unit*feedrate/60000000)) #define Y_TIME_FOR_MOVE ((float)y_steps_to_take / (y_steps_per_unit*feedrate/60000000)) #define Z_TIME_FOR_MOVE ((float)z_steps_to_take / (z_steps_per_unit*z_feedrate/60000000)) #define E_TIME_FOR_MOVE ((float)e_steps_to_take / (e_steps_per_unit*feedrate/60000000)) time_for_move = max(X_TIME_FOR_MOVE, Y_TIME_FOR_MOVE); time_for_move = max(time_for_move, Z_TIME_FOR_MOVE); if(time_for_move <= 0) time_for_move = max(time_for_move, E_TIME_FOR_MOVE); if(x_steps_to_take) x_interval = time_for_move / x_steps_to_take * 100; if(y_steps_to_take) y_interval = time_for_move / y_steps_to_take * 100; if(z_steps_to_take) z_interval = time_for_move / z_steps_to_take * 100; if(e_steps_to_take && (x_steps_to_take + y_steps_to_take <= 0) ) e_interval = time_for_move / e_steps_to_take * 100; //#define DEBUGGING false #if 0 if(0) { Serial.print("destination_x: "); Serial.println(destination_x); Serial.print("current_x: "); Serial.println(current_x); Serial.print("x_steps_to_take: "); Serial.println(x_steps_to_take); Serial.print("X_TIME_FOR_MVE: "); Serial.println(X_TIME_FOR_MOVE); Serial.print("x_interval: "); Serial.println(x_interval); Serial.println(""); Serial.print("destination_y: "); Serial.println(destination_y); Serial.print("current_y: "); Serial.println(current_y); Serial.print("y_steps_to_take: "); Serial.println(y_steps_to_take); Serial.print("Y_TIME_FOR_MVE: "); Serial.println(Y_TIME_FOR_MOVE); Serial.print("y_interval: "); Serial.println(y_interval); Serial.println(""); Serial.print("destination_z: "); Serial.println(destination_z); Serial.print("current_z: "); Serial.println(current_z); Serial.print("z_steps_to_take: "); Serial.println(z_steps_to_take); Serial.print("Z_TIME_FOR_MVE: "); Serial.println(Z_TIME_FOR_MOVE); Serial.print("z_interval: "); Serial.println(z_interval); Serial.println(""); Serial.print("destination_e: "); Serial.println(destination_e); Serial.print("current_e: "); Serial.println(current_e); Serial.print("e_steps_to_take: "); Serial.println(e_steps_to_take); Serial.print("E_TIME_FOR_MVE: "); Serial.println(E_TIME_FOR_MOVE); Serial.print("e_interval: "); Serial.println(e_interval); Serial.println(""); } #endif linear_move(x_steps_to_take, y_steps_to_take, z_steps_to_take, e_steps_to_take); // make the move } void linear_move(unsigned long x_steps_remaining, unsigned long y_steps_remaining, unsigned long z_steps_remaining, unsigned long e_steps_remaining) // make linear move with preset speeds and destinations, see G0 and G1 { //Determine direction of movement if (destination_x > current_x) digitalWrite(X_DIR_PIN,!INVERT_X_DIR); else digitalWrite(X_DIR_PIN,INVERT_X_DIR); if (destination_y > current_y) digitalWrite(Y_DIR_PIN,!INVERT_Y_DIR); else digitalWrite(Y_DIR_PIN,INVERT_Y_DIR); if (destination_z > current_z) digitalWrite(Z_DIR_PIN,!INVERT_Z_DIR); else digitalWrite(Z_DIR_PIN,INVERT_Z_DIR); if (destination_e > current_e) digitalWrite(E_DIR_PIN,!INVERT_E_DIR); else digitalWrite(E_DIR_PIN,INVERT_E_DIR); if(X_MIN_PIN > -1) if(!direction_x) if(digitalRead(X_MIN_PIN) != ENDSTOPS_INVERTING) x_steps_remaining=0; if(Y_MIN_PIN > -1) if(!direction_y) if(digitalRead(Y_MIN_PIN) != ENDSTOPS_INVERTING) y_steps_remaining=0; if(Z_MIN_PIN > -1) if(!direction_z) if(digitalRead(Z_MIN_PIN) != ENDSTOPS_INVERTING) z_steps_remaining=0; if(X_MAX_PIN > -1) if(direction_x) if(digitalRead(X_MAX_PIN) != ENDSTOPS_INVERTING) x_steps_remaining=0; if(Y_MAX_PIN > -1) if(direction_y) if(digitalRead(Y_MAX_PIN) != ENDSTOPS_INVERTING) y_steps_remaining=0; if(Z_MAX_PIN > -1) if(direction_z) if(digitalRead(Z_MAX_PIN) != ENDSTOPS_INVERTING) z_steps_remaining=0; //Only enable axis that are moving. If the axis doesn't need to move then it can stay disabled depending on configuration. if(x_steps_remaining) enable_x(); if(y_steps_remaining) enable_y(); if(z_steps_remaining) { enable_z(); do_z_step(); z_steps_remaining--; } if(e_steps_remaining) { enable_e(); do_e_step(); e_steps_remaining--; } //Define variables that are needed for the Bresenham algorithm. Please note that Z is not currently included in the Bresenham algorithm. unsigned int delta_x = x_steps_remaining; unsigned long x_interval_nanos; unsigned int delta_y = y_steps_remaining; unsigned long y_interval_nanos; unsigned int delta_z = z_steps_remaining; unsigned long z_interval_nanos; boolean steep_y = delta_y > delta_x;// && delta_y > delta_e && delta_y > delta_z; boolean steep_x = delta_x >= delta_y;// && delta_x > delta_e && delta_x > delta_z; //boolean steep_z = delta_z > delta_x && delta_z > delta_y && delta_z > delta_e; int error_x; int error_y; int error_z; #ifdef RAMP_ACCELERATION long max_speed_steps_per_second; long min_speed_steps_per_second; #endif #ifdef EXP_ACCELERATION unsigned long virtual_full_velocity_steps; unsigned long full_velocity_steps; #endif unsigned long steps_remaining; unsigned long steps_to_take; //Do some Bresenham calculations depending on which axis will lead it. if(steep_y) { error_x = delta_y / 2; interval = y_interval; #ifdef RAMP_ACCELERATION max_interval = max_y_interval; if(e_steps_to_take > 0) steps_per_sqr_second = y_steps_per_sqr_second; else steps_per_sqr_second = y_travel_steps_per_sqr_second; max_speed_steps_per_second = 100000000 / interval; min_speed_steps_per_second = 100000000 / max_interval; float plateau_time = (max_speed_steps_per_second - min_speed_steps_per_second) / (float) steps_per_sqr_second; plateau_steps = (long) ((steps_per_sqr_second / 2.0 * plateau_time + min_speed_steps_per_second) * plateau_time); #endif #ifdef EXP_ACCELERATION if(e_steps_to_take > 0) virtual_full_velocity_steps = long_full_velocity_units * y_steps_per_unit /100; else virtual_full_velocity_steps = long_travel_move_full_velocity_units * y_steps_per_unit /100; full_velocity_steps = min(virtual_full_velocity_steps, (delta_y - y_min_constant_speed_steps) / 2); max_interval = max_y_interval; min_constant_speed_steps = y_min_constant_speed_steps; #endif steps_remaining = delta_y; steps_to_take = delta_y; } else if (steep_x) { error_y = delta_x / 2; interval = x_interval; #ifdef RAMP_ACCELERATION max_interval = max_x_interval; if(e_steps_to_take > 0) steps_per_sqr_second = x_steps_per_sqr_second; else steps_per_sqr_second = x_travel_steps_per_sqr_second; max_speed_steps_per_second = 100000000 / interval; min_speed_steps_per_second = 100000000 / max_interval; float plateau_time = (max_speed_steps_per_second - min_speed_steps_per_second) / (float) steps_per_sqr_second; plateau_steps = (long) ((steps_per_sqr_second / 2.0 * plateau_time + min_speed_steps_per_second) * plateau_time); #endif #ifdef EXP_ACCELERATION if(e_steps_to_take > 0) virtual_full_velocity_steps = long_full_velocity_units * x_steps_per_unit /100; else virtual_full_velocity_steps = long_travel_move_full_velocity_units * x_steps_per_unit /100; full_velocity_steps = min(virtual_full_velocity_steps, (delta_x - x_min_constant_speed_steps) / 2); max_interval = max_x_interval; min_constant_speed_steps = x_min_constant_speed_steps; #endif steps_remaining = delta_x; steps_to_take = delta_x; } unsigned long steps_done = 0; #ifdef RAMP_ACCELERATION plateau_steps *= 1.01; // This is to compensate we use discrete intervals acceleration_enabled = true; long full_interval = interval; if(interval > max_interval) acceleration_enabled = false; boolean decelerating = false; #endif #ifdef EXP_ACCELERATION acceleration_enabled = true; if(full_velocity_steps == 0) full_velocity_steps++; if(interval > max_interval) acceleration_enabled = false; unsigned long full_interval = interval; if(min_constant_speed_steps >= steps_to_take) { acceleration_enabled = false; full_interval = max(max_interval, interval); // choose the min speed between feedrate and acceleration start speed } if(full_velocity_steps < virtual_full_velocity_steps && acceleration_enabled) full_interval = max(interval, max_interval - ((max_interval - full_interval) * full_velocity_steps / virtual_full_velocity_steps)); // choose the min speed between feedrate and speed at full steps unsigned int steps_acceleration_check = 1; accelerating = acceleration_enabled; #endif unsigned long start_move_micros = micros(); previous_micros_x = start_move_micros*100; previous_micros_y = previous_micros_x; previous_micros_z = previous_micros_x; previous_micros_e = previous_micros_x; //move until no more steps remain while(x_steps_remaining + y_steps_remaining + z_steps_remaining + e_steps_remaining > 0) { //If more that HEATER_CHECK_INTERVAL ms have passed since previous heating check, adjust temp manage_heater(); manage_inactivity(2); #ifdef RAMP_ACCELERATION //If acceleration is enabled on this move and we are in the acceleration segment, calculate the current interval if (acceleration_enabled && steps_done == 0) { interval = max_interval; } else if (acceleration_enabled && steps_done <= plateau_steps) { long current_speed = (long) ((((long) steps_per_sqr_second) / 10000) * ((micros() - start_move_micros) / 100) + (long) min_speed_steps_per_second); interval = 100000000 / current_speed; if (interval < full_interval) { accelerating = false; interval = full_interval; } if (steps_done >= steps_to_take / 2) { plateau_steps = steps_done; max_speed_steps_per_second = 100000000 / interval; accelerating = false; } } else if (acceleration_enabled && steps_remaining <= plateau_steps) { //(interval > minInterval * 100) { if (!accelerating) { start_move_micros = micros(); accelerating = true; decelerating = true; } long current_speed = (long) ((long) max_speed_steps_per_second - ((((long) steps_per_sqr_second) / 10000) * ((micros() - start_move_micros) / 100))); interval = 100000000 / current_speed; if (interval > max_interval) interval = max_interval; } else { //Else, we are just use the full speed interval as current interval interval = full_interval; accelerating = false; } #endif #ifdef EXP_ACCELERATION //If acceleration is enabled on this move and we are in the acceleration segment, calculate the current interval if (acceleration_enabled && steps_done < full_velocity_steps && steps_done / full_velocity_steps < 1 && (steps_done % steps_acceleration_check == 0)) { if(steps_done == 0) { interval = max_interval; } else { interval = max_interval - ((max_interval - full_interval) * steps_done / virtual_full_velocity_steps); } } else if (acceleration_enabled && steps_remaining < full_velocity_steps) { //Else, if acceleration is enabled on this move and we are in the deceleration segment, calculate the current interval if(steps_remaining == 0) { interval = max_interval; } else { interval = max_interval - ((max_interval - full_interval) * steps_remaining / virtual_full_velocity_steps); } accelerating = true; } else if (steps_done - full_velocity_steps >= 1 || !acceleration_enabled){ //Else, we are just use the full speed interval as current interval interval = full_interval; accelerating = false; } #endif //If there are x or y steps remaining, perform Bresenham algorithm if(x_steps_remaining || y_steps_remaining) { if(X_MIN_PIN > -1) if(!direction_x) if(digitalRead(X_MIN_PIN) != ENDSTOPS_INVERTING) break; if(Y_MIN_PIN > -1) if(!direction_y) if(digitalRead(Y_MIN_PIN) != ENDSTOPS_INVERTING) break; if(X_MAX_PIN > -1) if(direction_x) if(digitalRead(X_MAX_PIN) != ENDSTOPS_INVERTING) break; if(Y_MAX_PIN > -1) if(direction_y) if(digitalRead(Y_MAX_PIN) != ENDSTOPS_INVERTING) break; if(steep_y) { timediff = micros() * 100 - previous_micros_y; while(timediff >= interval && y_steps_remaining > 0) { steps_done++; steps_remaining--; y_steps_remaining--; timediff -= interval; error_x = error_x - delta_x; do_y_step(); if(error_x < 0) { do_x_step(); x_steps_remaining--; error_x = error_x + delta_y; } #ifdef RAMP_ACCELERATION if (steps_remaining == plateau_steps || (steps_done >= steps_to_take / 2 && accelerating && !decelerating)) break; #endif #ifdef STEP_DELAY_RATIO if(timediff >= interval) delayMicroseconds(long_step_delay_ratio * interval / 10000); #endif #ifdef STEP_DELAY_MICROS if(timediff >= interval) delayMicroseconds(STEP_DELAY_MICROS); #endif } } else if (steep_x) { timediff=micros() * 100 - previous_micros_x; while(timediff >= interval && x_steps_remaining>0) { steps_done++; steps_remaining--; x_steps_remaining--; timediff -= interval; error_y = error_y - delta_y; do_x_step(); if(error_y < 0) { do_y_step(); y_steps_remaining--; error_y = error_y + delta_x; } #ifdef RAMP_ACCELERATION if (steps_remaining == plateau_steps || (steps_done >= steps_to_take / 2 && accelerating && !decelerating)) break; #endif #ifdef STEP_DELAY_RATIO if(timediff >= interval) delayMicroseconds(long_step_delay_ratio * interval / 10000); #endif #ifdef STEP_DELAY_MICROS if(timediff >= interval) delayMicroseconds(STEP_DELAY_MICROS); #endif } } } #ifdef RAMP_ACCELERATION if((x_steps_remaining>0 || y_steps_remaining>0) && steps_to_take > 0 && (steps_remaining == plateau_steps || (steps_done >= steps_to_take / 2 && accelerating && !decelerating))) continue; #endif //If there are z steps remaining, check if z steps must be taken if(z_steps_remaining) { if(Z_MIN_PIN > -1) if(!direction_z) if(digitalRead(Z_MIN_PIN) != ENDSTOPS_INVERTING) break; if(Z_MAX_PIN > -1) if(direction_z) if(digitalRead(Z_MAX_PIN) != ENDSTOPS_INVERTING) break; timediff = micros() * 100-previous_micros_z; while(timediff >= z_interval && z_steps_remaining) { do_z_step(); z_steps_remaining--; timediff -= z_interval; #ifdef STEP_DELAY_RATIO if(timediff >= z_interval) delayMicroseconds(long_step_delay_ratio * z_interval / 10000); #endif #ifdef STEP_DELAY_MICROS if(timediff >= z_interval) delayMicroseconds(STEP_DELAY_MICROS); #endif } } //If there are e steps remaining, check if e steps must be taken if(e_steps_remaining){ if (x_steps_to_take + y_steps_to_take <= 0) timediff = micros()*100 - previous_micros_e; unsigned int final_e_steps_remaining = 0; if (steep_x && x_steps_to_take > 0) final_e_steps_remaining = e_steps_to_take * x_steps_remaining / x_steps_to_take; else if (steep_y && y_steps_to_take > 0) final_e_steps_remaining = e_steps_to_take * y_steps_remaining / y_steps_to_take; //If this move has X or Y steps, let E follow the Bresenham pace if (final_e_steps_remaining > 0) while(e_steps_remaining > final_e_steps_remaining) { do_e_step(); e_steps_remaining--;} else if (x_steps_to_take + y_steps_to_take > 0) while(e_steps_remaining) { do_e_step(); e_steps_remaining--;} //Else, normally check if e steps must be taken else while (timediff >= e_interval && e_steps_remaining) { do_e_step(); e_steps_remaining--; timediff -= e_interval; #ifdef STEP_DELAY_RATIO if(timediff >= e_interval) delayMicroseconds(long_step_delay_ratio * e_interval / 10000); #endif #ifdef STEP_DELAY_MICROS if(timediff >= e_interval) delayMicroseconds(STEP_DELAY_MICROS); #endif } } } if(DISABLE_X) disable_x(); if(DISABLE_Y) disable_y(); if(DISABLE_Z) disable_z(); if(DISABLE_E) disable_e(); // Update current position partly based on direction, we probably can combine this with the direction code above... if (destination_x > current_x) current_x = current_x + x_steps_to_take / x_steps_per_unit; else current_x = current_x - x_steps_to_take / x_steps_per_unit; if (destination_y > current_y) current_y = current_y + y_steps_to_take / y_steps_per_unit; else current_y = current_y - y_steps_to_take / y_steps_per_unit; if (destination_z > current_z) current_z = current_z + z_steps_to_take / z_steps_per_unit; else current_z = current_z - z_steps_to_take / z_steps_per_unit; if (destination_e > current_e) current_e = current_e + e_steps_to_take / e_steps_per_unit; else current_e = current_e - e_steps_to_take / e_steps_per_unit; } inline void do_x_step() { digitalWrite(X_STEP_PIN, HIGH); previous_micros_x += interval; //delayMicroseconds(3); digitalWrite(X_STEP_PIN, LOW); } inline void do_y_step() { digitalWrite(Y_STEP_PIN, HIGH); previous_micros_y += interval; //delayMicroseconds(3); digitalWrite(Y_STEP_PIN, LOW); } inline void do_z_step() { digitalWrite(Z_STEP_PIN, HIGH); previous_micros_z += z_interval; //delayMicroseconds(3); digitalWrite(Z_STEP_PIN, LOW); } inline void do_e_step() { digitalWrite(E_STEP_PIN, HIGH); previous_micros_e += e_interval; //delayMicroseconds(3); digitalWrite(E_STEP_PIN, LOW); } inline void disable_x() { if(X_ENABLE_PIN > -1) digitalWrite(X_ENABLE_PIN,!X_ENABLE_ON); } inline void disable_y() { if(Y_ENABLE_PIN > -1) digitalWrite(Y_ENABLE_PIN,!Y_ENABLE_ON); } inline void disable_z() { if(Z_ENABLE_PIN > -1) digitalWrite(Z_ENABLE_PIN,!Z_ENABLE_ON); } inline void disable_e() { if(E_ENABLE_PIN > -1) digitalWrite(E_ENABLE_PIN,!E_ENABLE_ON); } inline void enable_x() { if(X_ENABLE_PIN > -1) digitalWrite(X_ENABLE_PIN, X_ENABLE_ON); } inline void enable_y() { if(Y_ENABLE_PIN > -1) digitalWrite(Y_ENABLE_PIN, Y_ENABLE_ON); } inline void enable_z() { if(Z_ENABLE_PIN > -1) digitalWrite(Z_ENABLE_PIN, Z_ENABLE_ON); } inline void enable_e() { if(E_ENABLE_PIN > -1) digitalWrite(E_ENABLE_PIN, E_ENABLE_ON); } #define HEAT_INTERVAL 250 #ifdef HEATER_USES_MAX6675 unsigned long max6675_previous_millis = 0; int max6675_temp = 2000; inline int read_max6675() { if (millis() - max6675_previous_millis < HEAT_INTERVAL) return max6675_temp; max6675_previous_millis = millis(); max6675_temp = 0; #ifdef PRR PRR &= ~(1<> 3; } return max6675_temp; } #endif inline void manage_heater() { if((millis() - previous_millis_heater) < HEATER_CHECK_INTERVAL ) return; previous_millis_heater = millis(); #ifdef HEATER_USES_THERMISTOR current_raw = analogRead(TEMP_0_PIN); // When using thermistor, when the heater is colder than targer temp, we get a higher analog reading than target, // this switches it up so that the reading appears lower than target for the control logic. current_raw = 1023 - current_raw; #elif defined HEATER_USES_AD595 current_raw = analogRead(TEMP_0_PIN); #elif defined HEATER_USES_MAX6675 current_raw = read_max6675(); #endif #ifdef SMOOTHING nma = (nma + current_raw) - (nma / SMOOTHFACTOR); current_raw = nma / SMOOTHFACTOR; #endif #ifdef WATCHPERIOD if(watchmillis && millis() - watchmillis > WATCHPERIOD){ if(watch_raw + 1 >= current_raw){ target_raw = 0; digitalWrite(HEATER_0_PIN,LOW); digitalWrite(LED_PIN,LOW); }else{ watchmillis = 0; } } #endif #ifdef MINTEMP if(current_raw <= minttemp) target_raw = 0; #endif #ifdef MAXTEMP if(current_raw >= maxttemp) { target_raw = 0; } #endif #if (TEMP_0_PIN > -1) || defined (HEATER_USES_MAX66675) #ifdef PIDTEMP error = target_raw - current_raw; pTerm = (PID_PGAIN * error) / 100; temp_iState += error; temp_iState = constrain(temp_iState, temp_iState_min, temp_iState_max); iTerm = (PID_IGAIN * temp_iState) / 100; dTerm = (PID_DGAIN * (current_raw - temp_dState)) / 100; temp_dState = current_raw; analogWrite(HEATER_0_PIN, constrain(pTerm + iTerm - dTerm, 0, PID_MAX)); #else if(current_raw >= target_raw) { digitalWrite(HEATER_0_PIN,LOW); digitalWrite(LED_PIN,LOW); } else { digitalWrite(HEATER_0_PIN,HIGH); digitalWrite(LED_PIN,HIGH); } #endif #endif if(millis() - previous_millis_bed_heater < BED_CHECK_INTERVAL) return; previous_millis_bed_heater = millis(); #ifdef BED_USES_THERMISTOR current_bed_raw = analogRead(TEMP_1_PIN); // If using thermistor, when the heater is colder than targer temp, we get a higher analog reading than target, // this switches it up so that the reading appears lower than target for the control logic. current_bed_raw = 1023 - current_bed_raw; #elif defined BED_USES_AD595 current_bed_raw = analogRead(TEMP_1_PIN); #endif #if TEMP_1_PIN > -1 if(current_bed_raw >= target_bed_raw) { digitalWrite(HEATER_1_PIN,LOW); } else { digitalWrite(HEATER_1_PIN,HIGH); } #endif } // Takes hot end temperature value as input and returns corresponding raw value. // For a thermistor, it uses the RepRap thermistor temp table. // This is needed because PID in hydra firmware hovers around a given analog value, not a temp value. // This function is derived from inversing the logic from a portion of getTemperature() in FiveD RepRap firmware. float temp2analog(int celsius) { #ifdef HEATER_USES_THERMISTOR int raw = 0; byte i; for (i=1; i raw) { celsius = temptable[i-1][1] + (raw - temptable[i-1][0]) * (temptable[i][1] - temptable[i-1][1]) / (temptable[i][0] - temptable[i-1][0]); break; } } // Overflow: Set to last value in the table if (i == NUMTEMPS) celsius = temptable[i-1][1]; return celsius; #elif defined HEATER_USES_AD595 return raw * ((5.0 * 100.0) / 1024.0); #elif defined HEATER_USES_MAX6675 return raw * 0.25; #endif } // Derived from RepRap FiveD extruder::getTemperature() // For bed temperature measurement. float analog2tempBed(int raw) { #ifdef BED_USES_THERMISTOR int celsius = 0; byte i; raw = 1023 - raw; for (i=1; i raw) { celsius = bedtemptable[i-1][1] + (raw - bedtemptable[i-1][0]) * (bedtemptable[i][1] - bedtemptable[i-1][1]) / (bedtemptable[i][0] - bedtemptable[i-1][0]); break; } } // Overflow: Set to last value in the table if (i == NUMTEMPS) celsius = bedtemptable[i-1][1]; return celsius; #elif defined BED_USES_AD595 return raw * ((5.0 * 100.0) / 1024.0); #endif } inline void kill() { #if TEMP_0_PIN > -1 target_raw=0; digitalWrite(HEATER_0_PIN,LOW); #endif #if TEMP_1_PIN > -1 target_bed_raw=0; if(HEATER_1_PIN > -1) digitalWrite(HEATER_1_PIN,LOW); #endif disable_x(); disable_y(); disable_z(); disable_e(); if(PS_ON_PIN > -1) pinMode(PS_ON_PIN,INPUT); } inline void manage_inactivity(byte debug) { if( (millis()-previous_millis_cmd) > max_inactive_time ) if(max_inactive_time) kill(); if( (millis()-previous_millis_cmd) > stepper_inactive_time ) if(stepper_inactive_time) { disable_x(); disable_y(); disable_z(); disable_e(); } }