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|
#include "WProgram.h"
void init_extruder();
void wait_for_heater();
void valve_set(bool open, int millis);
void extruder_set_direction(bool direction);
void extruder_set_speed(byte speed);
void extruder_set_cooler(byte speed);
void extruder_set_temperature(int temp);
int extruder_get_temperature();
int extruder_read_thermistor();
int extruder_read_thermocouple();
int extruder_sample_temperature(byte pin);
void extruder_manage_temperature();
void extruder_heater_test();
void extruder_drive_test();
void extruder_valve_test();
void extruder_fan_test();
void init_process_string();
int parse_string(struct GcodeParser * gc, char instruction[], int size);
void process_string(char instruction[], int size);
int scan_float(char *str, float *valp, unsigned int *seen, unsigned int flag);
int scan_int(char *str, int *valp, unsigned int *seen, unsigned int flag);
void comms_test();
void init_steppers();
void dda_move(long micro_delay);
bool can_step(byte min_pin, byte max_pin, long current, long target, byte direction);
void do_step(byte step_pin);
bool read_switch(byte pin);
long to_steps(float steps_per_unit, float units);
void set_target(float x, float y, float z);
void set_position(float x, float y, float z);
void calculate_deltas();
long calculate_feedrate_delay(float feedrate);
long getMaxSpeed();
void enable_steppers();
void disable_steppers();
void delayMicrosecondsInterruptible(unsigned int us);
void X_motor_test();
void Y_motor_test();
void Z_motor_test();
#include "ctype.h"
#include "HardwareSerial.h"
#include "parameters.h"
#include "pins.h"
#include "ThermistorTable.h"
// Yep, this is actually -*- c++ -*-
// Sanguino G-code Interpreter
// Arduino v1.0 by Mike Ellery - initial software (mellery@gmail.com)
// v1.1 by Zach Hoeken - cleaned up and did lots of tweaks (hoeken@gmail.com)
// v1.2 by Chris Meighan - cleanup / G2&G3 support (cmeighan@gmail.com)
// v1.3 by Zach Hoeken - added thermocouple support and multi-sample temp readings. (hoeken@gmail.com)
// Sanguino v1.4 by Adrian Bowyer - switch to the Sanguino; extensive mods... (a.bowyer@bath.ac.uk)
// Uncomment the next line to run stand-alone tests on the machine (also see the
// ends of this, the process_string, the extruder, and the stepper_control tabs).
//#define TEST_MACHINE
//our command string
#define COMMAND_SIZE 128
char word[COMMAND_SIZE];
char c = '?';
byte serial_count = 0;
boolean comment = false;
void setup()
{
//Do startup stuff here
Serial.begin(19200);
Serial.println("start");
//other initialization.
init_process_string();
init_steppers();
init_extruder();
}
void loop()
{
#ifndef TEST_MACHINE
//keep it hot!
extruder_manage_temperature();
//read in characters if we got them.
if (Serial.available())
{
c = Serial.read();
if(c == '\r')
c = '\n';
// Throw away control chars except \n
if(c >= ' ' || c == '\n')
{
//newlines are ends of commands.
if (c != '\n')
{
// Start of comment - ignore any bytes received from now on
if (c == ';')
comment = true;
// If we're not in comment mode, add it to our array.
if (!comment)
word[serial_count++] = c;
}
}
}
// Data runaway?
if(serial_count >= COMMAND_SIZE)
init_process_string();
//if we've got a real command, do it
if (serial_count && c == '\n')
{
// Terminate string
word[serial_count] = 0;
//process our command!
process_string(word, serial_count);
//clear command.
init_process_string();
// Say we're ready for the next one
Serial.println("ok");
}
#else
// Run the parts of the machine as a test
// Do the comms test first. It should echo
// what you type in a terminal window connected
// to the Sanguino.
// If that works, comment out the next line to test the rest:
#define COMMS_TEST
#ifdef COMMS_TEST
comms_test();
#else
if (Serial.available() > 0)
{
c = Serial.read();
Serial.println(c);
}
switch(c)
{
case 0:
break;
case 'x':
X_motor_test();
break;
case 'y':
Y_motor_test();
break;
case 'z':
Z_motor_test();
break;
case 'h':
extruder_heater_test();
break;
case 'e':
extruder_drive_test();
break;
case 'v':
extruder_valve_test();
break;
case 'f':
extruder_fan_test();
break;
default:
Serial.println("Commands:\n");
Serial.println(" x - X motor test");
Serial.println(" y - Y motor test");
Serial.println(" z - Z motor test");
Serial.println(" h - extruder heater test");
Serial.println(" e - extruder drive test");
Serial.println(" v - extruder valve test");
Serial.println(" f - extruder fan test");
Serial.println(" s - stop current test at the end of its cycle then print this list\n\n");
Serial.print("Command: ");
c = 0;
}
#endif
#endif
}
// Yep, this is actually -*- c++ -*-
#define EXTRUDER_0_FORWARD true
#define EXTRUDER_0_REVERSE false
//these our the default values for the extruder.
int extruder_speed = 128;
int extruder_target_celsius = 0;
int extruder_max_celsius = 0;
byte extruder_heater_low = 64;
byte extruder_heater_high = 255;
byte extruder_heater_current = 0;
//this is for doing encoder based extruder control
int extruder_rpm = 0;
long extruder_delay = 0;
int extruder_error = 0;
int last_extruder_error = 0;
int extruder_error_delta = 0;
bool extruder_direction = EXTRUDER_0_FORWARD;
bool valve_open = false;
void init_extruder()
{
//default to cool...
extruder_set_temperature(-273);
//setup our pins
pinMode(EXTRUDER_0_MOTOR_DIR_PIN, OUTPUT);
pinMode(EXTRUDER_0_MOTOR_SPEED_PIN, OUTPUT);
pinMode(EXTRUDER_0_HEATER_PIN, OUTPUT);
pinMode(EXTRUDER_0_FAN_PIN, OUTPUT);
pinMode(EXTRUDER_0_VALVE_DIR_PIN, OUTPUT);
pinMode(EXTRUDER_0_VALVE_ENABLE_PIN, OUTPUT);
//initialize values
digitalWrite(EXTRUDER_0_MOTOR_DIR_PIN, EXTRUDER_0_FORWARD);
analogWrite(EXTRUDER_0_FAN_PIN, 0);
analogWrite(EXTRUDER_0_HEATER_PIN, 0);
analogWrite(EXTRUDER_0_MOTOR_SPEED_PIN, 0);
digitalWrite(EXTRUDER_0_VALVE_DIR_PIN, false);
digitalWrite(EXTRUDER_0_VALVE_ENABLE_PIN, 0);
}
void wait_for_heater()
{
//warmup if we're too cold.
while (extruder_get_temperature() < (extruder_target_celsius - 5))
{
extruder_manage_temperature();
//Serial.print("T: ");
//Serial.println(extruder_get_temperature());
delay(1000);
}
}
void valve_set(bool open, int millis)
{
wait_for_heater();
valve_open = open;
digitalWrite(EXTRUDER_0_VALVE_DIR_PIN, open);
digitalWrite(EXTRUDER_0_VALVE_ENABLE_PIN, 1);
delay(millis);
digitalWrite(EXTRUDER_0_VALVE_ENABLE_PIN, 0);
digitalWrite(EXTRUDER_0_VALVE_DIR_PIN, 0);
}
void extruder_set_direction(bool direction)
{
extruder_direction = direction;
digitalWrite(EXTRUDER_0_MOTOR_DIR_PIN, direction);
}
void extruder_set_speed(byte speed)
{
if(speed > 0)
wait_for_heater();
analogWrite(EXTRUDER_0_MOTOR_SPEED_PIN, speed);
}
void extruder_set_cooler(byte speed)
{
analogWrite(EXTRUDER_0_FAN_PIN, speed);
}
void extruder_set_temperature(int temp)
{
extruder_target_celsius = temp;
extruder_max_celsius = (int)((float)temp * 1.1);
}
/**
* Samples the temperature and converts it to degrees celsius.
* Returns degrees celsius.
*/
int extruder_get_temperature()
{
if (EXTRUDER_0_THERMISTOR_PIN > -1)
return extruder_read_thermistor();
else if (EXTRUDER_0_THERMOCOUPLE_PIN > -1)
return extruder_read_thermocouple();
}
/*
* This function gives us the temperature from the thermistor in Celsius
*/
int extruder_read_thermistor()
{
int raw = extruder_sample_temperature(EXTRUDER_0_THERMISTOR_PIN);
int celsius = 0;
byte i;
for (i=1; i<NUMTEMPS; i++)
{
if (temptable[i][0] > 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];
// Clamp to byte
if (celsius > 255) celsius = 255;
else if (celsius < 0) celsius = 0;
return celsius;
}
/*
* This function gives us the temperature from the thermocouple in Celsius
*/
int extruder_read_thermocouple()
{
return ( 5.0 * extruder_sample_temperature(EXTRUDER_0_THERMOCOUPLE_PIN) * 100.0) / 1024.0;
}
/*
* This function gives us an averaged sample of the analog temperature pin.
*/
int extruder_sample_temperature(byte pin)
{
int raw = 0;
//read in a certain number of samples
for (byte i=0; i<TEMPERATURE_SAMPLES; i++)
raw += analogRead(pin);
//average the samples
raw = raw/TEMPERATURE_SAMPLES;
//send it back.
return raw;
}
/*!
Manages motor and heater based on measured temperature:
o If temp is too low, don't start the motor
o Adjust the heater power to keep the temperature at the target
*/
void extruder_manage_temperature()
{
//make sure we know what our temp is.
int current_celsius = extruder_get_temperature();
byte newheat = 0;
//put the heater into high mode if we're not at our target.
if (current_celsius < extruder_target_celsius)
newheat = extruder_heater_high;
//put the heater on low if we're at our target.
else if (current_celsius < extruder_max_celsius)
newheat = extruder_heater_low;
// Only update heat if it changed
if (extruder_heater_current != newheat) {
extruder_heater_current = newheat;
analogWrite(EXTRUDER_0_HEATER_PIN, extruder_heater_current);
}
}
#ifdef TEST_MACHINE
bool heat_on;
void extruder_heater_test()
{
int t = extruder_get_temperature();
if(t < 50 && !heat_on)
{
Serial.println("\n *** Turning heater on.\n");
heat_on = true;
analogWrite(EXTRUDER_0_HEATER_PIN, extruder_heater_high);
}
if(t > 100 && heat_on)
{
Serial.println("\n *** Turning heater off.\n");
heat_on = false;
analogWrite(EXTRUDER_0_HEATER_PIN, 0);
}
Serial.print("Temperature: ");
Serial.print(t);
Serial.print(" deg C. The heater is ");
if(heat_on)
Serial.println("on.");
else
Serial.println("off.");
delay(2000);
}
void extruder_drive_test()
{
Serial.println("Turning the extruder motor on forwards for 5 seconds.");
extruder_set_direction(true);
extruder_set_speed(200);
delay(5000);
extruder_set_speed(0);
Serial.println("Pausing for 2 seconds.");
delay(2000);
Serial.println("Turning the extruder motor on backwards for 5 seconds.");
extruder_set_direction(false);
extruder_set_speed(200);
delay(5000);
extruder_set_speed(0);
Serial.println("Pausing for 2 seconds.");
delay(2000);
}
void extruder_valve_test()
{
Serial.println("Opening the valve.");
valve_set(true, 500);
Serial.println("Pausing for 2 seconds.");
delay(2000);
Serial.println("Closing the valve.");
valve_set(false, 500);
Serial.println("Pausing for 2 seconds.");
delay(2000);
}
void extruder_fan_test()
{
Serial.println("Fan on.");
extruder_set_cooler(255);
Serial.println("Pausing for 2 seconds.");
delay(2000);
Serial.println("Fan off.");
extruder_set_cooler(0);
Serial.println("Pausing for 2 seconds.");
delay(2000);
}
#endif
// Yep, this is actually -*- c++ -*-
// our point structure to make things nice.
struct LongPoint
{
long x;
long y;
long z;
};
struct FloatPoint
{
float x;
float y;
float z;
};
/* gcode line parse results */
struct GcodeParser
{
unsigned int seen;
int G;
int M;
float P;
float X;
float Y;
float Z;
float I;
float J;
float F;
float S;
float R;
float Q;
};
FloatPoint current_units;
FloatPoint target_units;
FloatPoint delta_units;
FloatPoint current_steps;
FloatPoint target_steps;
FloatPoint delta_steps;
boolean abs_mode = true; //0 = incremental; 1 = absolute
//default to mm for units
float x_units = X_STEPS_PER_MM;
float y_units = Y_STEPS_PER_MM;
float z_units = Z_STEPS_PER_MM;
float curve_section = CURVE_SECTION_MM;
//our direction vars
byte x_direction = 1;
byte y_direction = 1;
byte z_direction = 1;
int scan_int(char *str, int *valp);
int scan_float(char *str, float *valp);
//init our string processing
void init_process_string()
{
//init our command
//for (byte i=0; i<COMMAND_SIZE; i++)
// word[i] = 0;
serial_count = 0;
comment = false;
}
//our feedrate variables.
float feedrate = 0.0;
long feedrate_micros = 0;
/* keep track of the last G code - this is the command mode to use
* if there is no command in the current string
*/
int last_gcode_g = -1;
/* bit-flags for commands and parameters */
#define GCODE_G (1<<0)
#define GCODE_M (1<<1)
#define GCODE_P (1<<2)
#define GCODE_X (1<<3)
#define GCODE_Y (1<<4)
#define GCODE_Z (1<<5)
#define GCODE_I (1<<6)
#define GCODE_J (1<<7)
#define GCODE_K (1<<8)
#define GCODE_F (1<<9)
#define GCODE_S (1<<10)
#define GCODE_Q (1<<11)
#define GCODE_R (1<<12)
#define TYPE_INT 1
#define TYPE_FLOAT 2
#define PARSE_INT(ch, str, len, val, seen, flag) \
case ch: \
len = scan_int(str, &val, &seen, flag); \
break;
#define PARSE_FLOAT(ch, str, len, val, seen, flag) \
case ch: \
len = scan_float(str, &val, &seen, flag); \
break;
int parse_string(struct GcodeParser * gc, char instruction[], int size)
{
int ind;
int len; /* length of parameter argument */
gc->seen = 0;
len=0;
/* scan the string for commands and parameters, recording the arguments for each,
* and setting the seen flag for each that is seen
*/
for (ind=0; ind<size; ind += (1+len))
{
len = 0;
switch (instruction[ind])
{
PARSE_INT('G', &instruction[ind+1], len, gc->G, gc->seen, GCODE_G);
PARSE_INT('M', &instruction[ind+1], len, gc->M, gc->seen, GCODE_M);
PARSE_FLOAT('S', &instruction[ind+1], len, gc->S, gc->seen, GCODE_S);
PARSE_FLOAT('P', &instruction[ind+1], len, gc->P, gc->seen, GCODE_P);
PARSE_FLOAT('X', &instruction[ind+1], len, gc->X, gc->seen, GCODE_X);
PARSE_FLOAT('Y', &instruction[ind+1], len, gc->Y, gc->seen, GCODE_Y);
PARSE_FLOAT('Z', &instruction[ind+1], len, gc->Z, gc->seen, GCODE_Z);
PARSE_FLOAT('I', &instruction[ind+1], len, gc->I, gc->seen, GCODE_I);
PARSE_FLOAT('J', &instruction[ind+1], len, gc->J, gc->seen, GCODE_J);
PARSE_FLOAT('F', &instruction[ind+1], len, gc->F, gc->seen, GCODE_F);
PARSE_FLOAT('R', &instruction[ind+1], len, gc->R, gc->seen, GCODE_R);
PARSE_FLOAT('Q', &instruction[ind+1], len, gc->Q, gc->seen, GCODE_Q);
default:
break;
}
}
}
//Read the string and execute instructions
void process_string(char instruction[], int size)
{
GcodeParser gc; /* string parse result */
//the character / means delete block... used for comments and stuff.
if (instruction[0] == '/')
return;
//init baby!
FloatPoint fp;
fp.x = 0.0;
fp.y = 0.0;
fp.z = 0.0;
//get all our parameters!
parse_string(&gc, instruction, size);
/* if no command was seen, but parameters were, then use the last G code as
* the current command
*/
if ((!(gc.seen & (GCODE_G | GCODE_M))) &&
((gc.seen != 0) &&
(last_gcode_g >= 0))
)
{
/* yes - so use the previous command with the new parameters */
gc.G = last_gcode_g;
gc.seen |= GCODE_G;
}
//did we get a gcode?
if (gc.seen & GCODE_G)
{
last_gcode_g = gc.G; /* remember this for future instructions */
fp = current_units;
if (abs_mode)
{
if (gc.seen & GCODE_X)
fp.x = gc.X;
if (gc.seen & GCODE_Y)
fp.y = gc.Y;
if (gc.seen & GCODE_Z)
fp.z = gc.Z;
}
else
{
if (gc.seen & GCODE_X)
fp.x += gc.X;
if (gc.seen & GCODE_Y)
fp.y += gc.Y;
if (gc.seen & GCODE_Z)
fp.z += gc.Z;
}
// Get feedrate if supplied
if ( gc.seen & GCODE_F )
feedrate = gc.F;
//do something!
switch (gc.G)
{
//Rapid Positioning
//Linear Interpolation
//these are basically the same thing.
case 0:
case 1:
//set our target.
set_target(fp.x, fp.y, fp.z);
// Use currently set feedrate if doing a G1
if (gc.G == 1)
feedrate_micros = calculate_feedrate_delay(feedrate);
// Use our max for G0
else
feedrate_micros = getMaxSpeed();
//finally move.
dda_move(feedrate_micros);
break;
#ifdef SANGUINO
// No room for this in the Arduino
//Clockwise arc
case 2:
//Counterclockwise arc
case 3:
{
FloatPoint cent;
// Centre coordinates are always relative
if (gc.seen & GCODE_I) cent.x = current_units.x + gc.I;
else cent.x = current_units.x;
if (gc.seen & GCODE_J) cent.y = current_units.y + gc.J;
float angleA, angleB, angle, radius, length, aX, aY, bX, bY;
aX = (current_units.x - cent.x);
aY = (current_units.y - cent.y);
bX = (fp.x - cent.x);
bY = (fp.y - cent.y);
// Clockwise
if (gc.G == 2)
{
angleA = atan2(bY, bX);
angleB = atan2(aY, aX);
}
// Counterclockwise
else
{
angleA = atan2(aY, aX);
angleB = atan2(bY, bX);
}
// Make sure angleB is always greater than angleA
// and if not add 2PI so that it is (this also takes
// care of the special case of angleA == angleB,
// ie we want a complete circle)
if (angleB <= angleA)
angleB += 2 * M_PI;
angle = angleB - angleA;
radius = sqrt(aX * aX + aY * aY);
length = radius * angle;
int steps, s, step;
// Maximum of either 2.4 times the angle in radians or the length of the curve divided by the constant specified in _init.pde
steps = (int) ceil(max(angle * 2.4, length / curve_section));
FloatPoint newPoint;
float arc_start_z = current_units.z;
for (s = 1; s <= steps; s++)
{
step = (gc.G == 3) ? s : steps - s; // Work backwards for CW
newPoint.x = cent.x + radius * cos(angleA + angle
* ((float) step / steps));
newPoint.y = cent.y + radius * sin(angleA + angle
* ((float) step / steps));
set_target(newPoint.x, newPoint.y, arc_start_z + (fp.z
- arc_start_z) * s / steps);
// Need to calculate rate for each section of curve
if (feedrate > 0)
feedrate_micros = calculate_feedrate_delay(feedrate);
else
feedrate_micros = getMaxSpeed();
// Make step
dda_move(feedrate_micros);
}
}
break;
#endif
case 4: //Dwell
delay((int)(gc.P + 0.5)); // Changed by AB from 1000*gc.P
break;
//Inches for Units
case 20:
x_units = X_STEPS_PER_INCH;
y_units = Y_STEPS_PER_INCH;
z_units = Z_STEPS_PER_INCH;
curve_section = CURVE_SECTION_INCHES;
calculate_deltas();
break;
//mm for Units
case 21:
x_units = X_STEPS_PER_MM;
y_units = Y_STEPS_PER_MM;
z_units = Z_STEPS_PER_MM;
curve_section = CURVE_SECTION_MM;
calculate_deltas();
break;
//go home.
case 28:
set_target(0.0, 0.0, 0.0);
dda_move(getMaxSpeed());
break;
//go home via an intermediate point.
case 30:
//set our target.
set_target(fp.x, fp.y, fp.z);
//go there.
dda_move(getMaxSpeed());
//go home.
set_target(0.0, 0.0, 0.0);
dda_move(getMaxSpeed());
break;
// Drilling canned cycles
case 81: // Without dwell
case 82: // With dwell
case 83: // Peck drilling
{
float retract = gc.R;
if (!abs_mode)
retract += current_units.z;
// Retract to R position if Z is currently below this
if (current_units.z < retract)
{
set_target(current_units.x, current_units.y, retract);
dda_move(getMaxSpeed());
}
// Move to start XY
set_target(fp.x, fp.y, current_units.z);
dda_move(getMaxSpeed());
// Do the actual drilling
float target_z = retract;
float delta_z;
// For G83 move in increments specified by Q code, otherwise do in one pass
if (gc.G == 83)
delta_z = gc.Q;
else
delta_z = retract - fp.z;
do {
// Move rapidly to bottom of hole drilled so far (target Z if starting hole)
set_target(fp.x, fp.y, target_z);
dda_move(getMaxSpeed());
// Move with controlled feed rate by delta z (or to bottom of hole if less)
target_z -= delta_z;
if (target_z < fp.z)
target_z = fp.z;
set_target(fp.x, fp.y, target_z);
if (feedrate > 0)
feedrate_micros = calculate_feedrate_delay(feedrate);
else
feedrate_micros = getMaxSpeed();
dda_move(feedrate_micros);
// Dwell if doing a G82
if (gc.G == 82)
delay((int)(gc.P * 1000));
// Retract
set_target(fp.x, fp.y, retract);
dda_move(getMaxSpeed());
} while (target_z > fp.z);
}
break;
case 90: //Absolute Positioning
abs_mode = true;
break;
case 91: //Incremental Positioning
abs_mode = false;
break;
case 92: //Set position as fp
set_position(fp.x, fp.y, fp.z);
break;
/*
//Inverse Time Feed Mode
case 93:
break; //TODO: add this
//Feed per Minute Mode
case 94:
break; //TODO: add this
*/
default:
Serial.print("huh? G");
Serial.println(gc.G, DEC);
}
}
//find us an m code.
if (gc.seen & GCODE_M)
{
switch (gc.M)
{
//TODO: this is a bug because search_string returns 0. gotta fix that.
case 0:
true;
break;
/*
case 0:
//todo: stop program
break;
case 1:
//todo: optional stop
break;
case 2:
//todo: program end
break;
*/
//turn extruder on, forward
case 101:
extruder_set_direction(1);
extruder_set_speed(extruder_speed);
break;
//turn extruder on, reverse
case 102:
extruder_set_direction(0);
extruder_set_speed(extruder_speed);
break;
//turn extruder off
case 103:
extruder_set_speed(0);
break;
//custom code for temperature control
case 104:
if (gc.seen & GCODE_S)
{
extruder_set_temperature((int)gc.S);
// //warmup if we're too cold.
// while (extruder_get_temperature() < extruder_target_celsius)
// {
// extruder_manage_temperature();
// Serial.print("T: ");
// Serial.println(extruder_get_temperature());
// delay(1000);
// }
}
break;
//custom code for temperature reading
case 105:
Serial.print("T:");
Serial.println(extruder_get_temperature());
break;
//turn fan on
case 106:
extruder_set_cooler(255);
break;
//turn fan off
case 107:
extruder_set_cooler(0);
break;
//set max extruder speed, 0-255 PWM
case 108:
if (gc.seen & GCODE_S)
extruder_speed = (int)gc.S;
break;
// Open the valve
case 126:
valve_set(true, (int)(gc.P + 0.5));
break;
// Close the valve
case 127:
valve_set(false, (int)(gc.P + 0.5));
break;
default:
Serial.print("Huh? M");
Serial.println(gc.M, DEC);
}
}
}
int scan_float(char *str, float *valp, unsigned int *seen, unsigned int flag)
{
float res;
int len;
char *end;
res = (float)strtod(str, &end);
len = end - str;
if (len > 0)
{
*valp = res;
*seen |= flag;
}
else
*valp = 0;
return len; /* length of number */
}
int scan_int(char *str, int *valp, unsigned int *seen, unsigned int flag)
{
int res;
int len;
char *end;
res = (int)strtol(str, &end, 10);
len = end - str;
if (len > 0)
{
*valp = res;
*seen |= flag;
}
else
*valp = 0;
return len; /* length of number */
}
#ifdef TEST_MACHINE
// Read and echo bytes.
void comms_test()
{
if (Serial.available() > 0)
Serial.print((char)Serial.read());
}
#endif
// Yep, this is actually -*- c++ -*-
//init our variables
long max_delta;
long x_counter;
long y_counter;
long z_counter;
bool x_can_step;
bool y_can_step;
bool z_can_step;
int milli_delay;
#if INVERT_ENABLE_PINS == 1
#define ENABLE_ON LOW
#else
#define ENABLE_ON HIGH
#endif
#define ENDSTOPS_MIN_ENABLED 1
void init_steppers()
{
//turn them off to start.
#ifdef SANGUINO
disable_steppers();
#endif
//init our points.
current_units.x = 0.0;
current_units.y = 0.0;
current_units.z = 0.0;
target_units.x = 0.0;
target_units.y = 0.0;
target_units.z = 0.0;
pinMode(X_STEP_PIN, OUTPUT);
pinMode(X_DIR_PIN, OUTPUT);
pinMode(Y_STEP_PIN, OUTPUT);
pinMode(Y_DIR_PIN, OUTPUT);
pinMode(Z_STEP_PIN, OUTPUT);
pinMode(Z_DIR_PIN, OUTPUT);
#ifdef SANGUINO
pinMode(X_ENABLE_PIN, OUTPUT);
pinMode(Y_ENABLE_PIN, OUTPUT);
pinMode(Z_ENABLE_PIN, OUTPUT);
#endif
#if ENDSTOPS_MIN_ENABLED == 1
pinMode(X_MIN_PIN, INPUT);
pinMode(Y_MIN_PIN, INPUT);
pinMode(Z_MIN_PIN, INPUT);
#endif
#if ENDSTOPS_MAX_ENABLED == 1
pinMode(X_MAX_PIN, INPUT);
pinMode(Y_MAX_PIN, INPUT);
pinMode(Z_MAX_PIN, INPUT);
#endif
//figure our stuff.
calculate_deltas();
}
void dda_move(long micro_delay)
{
//turn on steppers to start moving =)
#ifdef SANGUINO
enable_steppers();
#endif
//figure out our deltas
max_delta = max(delta_steps.x, delta_steps.y);
max_delta = max(delta_steps.z, max_delta);
//init stuff.
long x_counter = -max_delta/2;
long y_counter = -max_delta/2;
long z_counter = -max_delta/2;
//our step flags
bool x_can_step = 0;
bool y_can_step = 0;
bool z_can_step = 0;
//how long do we delay for?
if (micro_delay >= 16383)
milli_delay = micro_delay / 1000;
else
milli_delay = 0;
//do our DDA line!
do
{
x_can_step = can_step(X_MIN_PIN, X_MAX_PIN, current_steps.x, target_steps.x, x_direction);
y_can_step = can_step(Y_MIN_PIN, Y_MAX_PIN, current_steps.y, target_steps.y, y_direction);
z_can_step = can_step(Z_MIN_PIN, Z_MAX_PIN, current_steps.z, target_steps.z, z_direction);
if (x_can_step)
{
x_counter += delta_steps.x;
if (x_counter > 0)
{
do_step(X_STEP_PIN);
x_counter -= max_delta;
if (x_direction)
current_steps.x++;
else
current_steps.x--;
}
}
if (y_can_step)
{
y_counter += delta_steps.y;
if (y_counter > 0)
{
do_step(Y_STEP_PIN);
y_counter -= max_delta;
if (y_direction)
current_steps.y++;
else
current_steps.y--;
}
}
if (z_can_step)
{
z_counter += delta_steps.z;
if (z_counter > 0)
{
do_step(Z_STEP_PIN);
z_counter -= max_delta;
if (z_direction)
current_steps.z++;
else
current_steps.z--;
}
}
//keep it hot =)
extruder_manage_temperature();
//wait for next step.
if (milli_delay > 0)
delay(milli_delay);
else
delayMicrosecondsInterruptible(micro_delay);
}
while (x_can_step || y_can_step || z_can_step);
//set our points to be the same
current_units.x = target_units.x;
current_units.y = target_units.y;
current_units.z = target_units.z;
calculate_deltas();
}
bool can_step(byte min_pin, byte max_pin, long current, long target, byte direction)
{
//stop us if we're on target
if (target == current)
return false;
#if ENDSTOPS_MIN_ENABLED == 1
//stop us if we're at home and still going
else if (read_switch(min_pin) && !direction)
return false;
#endif
#if ENDSTOPS_MAX_ENABLED == 1
//stop us if we're at max and still going
else if (read_switch(max_pin) && direction)
return false;
#endif
//default to being able to step
return true;
}
void do_step(byte step_pin)
{
digitalWrite(step_pin, HIGH);
delayMicroseconds(5);
digitalWrite(step_pin, LOW);
}
bool read_switch(byte pin)
{
//dual read as crude debounce
#if ENDSTOPS_INVERTING == 1
return !digitalRead(pin) && !digitalRead(pin);
#else
return digitalRead(pin) && digitalRead(pin);
#endif
}
long to_steps(float steps_per_unit, float units)
{
return steps_per_unit * units;
}
void set_target(float x, float y, float z)
{
target_units.x = x;
target_units.y = y;
target_units.z = z;
calculate_deltas();
}
void set_position(float x, float y, float z)
{
current_units.x = x;
current_units.y = y;
current_units.z = z;
calculate_deltas();
}
void calculate_deltas()
{
//figure our deltas.
delta_units.x = abs(target_units.x - current_units.x);
delta_units.y = abs(target_units.y - current_units.y);
delta_units.z = abs(target_units.z - current_units.z);
//set our steps current, target, and delta
current_steps.x = to_steps(x_units, current_units.x);
current_steps.y = to_steps(y_units, current_units.y);
current_steps.z = to_steps(z_units, current_units.z);
target_steps.x = to_steps(x_units, target_units.x);
target_steps.y = to_steps(y_units, target_units.y);
target_steps.z = to_steps(z_units, target_units.z);
delta_steps.x = abs(target_steps.x - current_steps.x);
delta_steps.y = abs(target_steps.y - current_steps.y);
delta_steps.z = abs(target_steps.z - current_steps.z);
//what is our direction
x_direction = (target_units.x >= current_units.x);
y_direction = (target_units.y >= current_units.y);
z_direction = (target_units.z >= current_units.z);
//set our direction pins as well
#if INVERT_X_DIR == 1
digitalWrite(X_DIR_PIN, !x_direction);
#else
digitalWrite(X_DIR_PIN, x_direction);
#endif
#if INVERT_Y_DIR == 1
digitalWrite(Y_DIR_PIN, !y_direction);
#else
digitalWrite(Y_DIR_PIN, y_direction);
#endif
#if INVERT_Z_DIR == 1
digitalWrite(Z_DIR_PIN, !z_direction);
#else
digitalWrite(Z_DIR_PIN, z_direction);
#endif
}
long calculate_feedrate_delay(float feedrate)
{
//how long is our line length?
float distance = sqrt(delta_units.x*delta_units.x +
delta_units.y*delta_units.y +
delta_units.z*delta_units.z);
long master_steps = 0;
//find the dominant axis.
if (delta_steps.x > delta_steps.y)
{
if (delta_steps.z > delta_steps.x)
master_steps = delta_steps.z;
else
master_steps = delta_steps.x;
}
else
{
if (delta_steps.z > delta_steps.y)
master_steps = delta_steps.z;
else
master_steps = delta_steps.y;
}
//calculate delay between steps in microseconds. this is sort of tricky, but not too bad.
//the formula has been condensed to save space. here it is in english:
// (feedrate is in mm/minute)
// distance / feedrate * 60000000.0 = move duration in microseconds
// move duration / master_steps = time between steps for master axis.
return ((distance * 60000000.0) / feedrate) / master_steps;
}
long getMaxSpeed()
{
if (delta_steps.z > 0)
return calculate_feedrate_delay(FAST_Z_FEEDRATE);
else
return calculate_feedrate_delay(FAST_XY_FEEDRATE);
}
#ifdef SANGUINO
void enable_steppers()
{
// Enable steppers only for axes which are moving
// taking account of the fact that some or all axes
// may share an enable line (check using macros at
// compile time to avoid needless code)
if ( target_units.x == current_units.x
#if X_ENABLE_PIN == Y_ENABLE_PIN
&& target_units.y == current_units.y
#endif
#if X_ENABLE_PIN == Z_ENABLE_PIN
&& target_units.z == current_units.z
#endif
)
digitalWrite(X_ENABLE_PIN, !ENABLE_ON);
else
digitalWrite(X_ENABLE_PIN, ENABLE_ON);
if ( target_units.y == current_units.y
#if Y_ENABLE_PIN == X_ENABLE_PIN
&& target_units.x == current_units.x
#endif
#if Y_ENABLE_PIN == Z_ENABLE_PIN
&& target_units.z == current_units.z
#endif
)
digitalWrite(Y_ENABLE_PIN, !ENABLE_ON);
else
digitalWrite(Y_ENABLE_PIN, ENABLE_ON);
if ( target_units.z == current_units.z
#if Z_ENABLE_PIN == X_ENABLE_PIN
&& target_units.x == current_units.x
#endif
#if Z_ENABLE_PIN == Y_ENABLE_PIN
&& target_units.y == current_units.y
#endif
)
digitalWrite(Z_ENABLE_PIN, !ENABLE_ON);
else
digitalWrite(Z_ENABLE_PIN, ENABLE_ON);
}
void disable_steppers()
{
//disable our steppers
digitalWrite(X_ENABLE_PIN, !ENABLE_ON);
digitalWrite(Y_ENABLE_PIN, !ENABLE_ON);
digitalWrite(Z_ENABLE_PIN, !ENABLE_ON);
}
#endif
void delayMicrosecondsInterruptible(unsigned int us)
{
#if F_CPU >= 16000000L
// for the 16 MHz clock on most Arduino boards
// for a one-microsecond delay, simply return. the overhead
// of the function call yields a delay of approximately 1 1/8 us.
if (--us == 0)
return;
// the following loop takes a quarter of a microsecond (4 cycles)
// per iteration, so execute it four times for each microsecond of
// delay requested.
us <<= 2;
// account for the time taken in the preceeding commands.
us -= 2;
#else
// for the 8 MHz internal clock on the ATmega168
// for a one- or two-microsecond delay, simply return. the overhead of
// the function calls takes more than two microseconds. can't just
// subtract two, since us is unsigned; we'd overflow.
if (--us == 0)
return;
if (--us == 0)
return;
// the following loop takes half of a microsecond (4 cycles)
// per iteration, so execute it twice for each microsecond of
// delay requested.
us <<= 1;
// partially compensate for the time taken by the preceeding commands.
// we can't subtract any more than this or we'd overflow w/ small delays.
us--;
#endif
// busy wait
__asm__ __volatile__ (
"1: sbiw %0,1" "\n\t" // 2 cycles
"brne 1b" : "=w" (us) : "0" (us) // 2 cycles
);
}
#ifdef TEST_MACHINE
void X_motor_test()
{
Serial.println("Moving X forward by 100 mm at half maximum speed.");
set_target(100, 0, 0);
enable_steppers();
dda_move(calculate_feedrate_delay(FAST_XY_FEEDRATE/2));
Serial.println("Pause for 2 seconds.");
delay(2000);
Serial.println("Moving X back to the start.");
set_target(0, 0, 0);
enable_steppers();
dda_move(calculate_feedrate_delay(FAST_XY_FEEDRATE/2));
Serial.println("Pause for 2 seconds.");
delay(2000);
}
void Y_motor_test()
{
Serial.println("Moving Y forward by 100 mm at half maximum speed.");
set_target(0, 100, 0);
enable_steppers();
dda_move(calculate_feedrate_delay(FAST_XY_FEEDRATE/2));
Serial.println("Pause for 2 seconds.");
delay(2000);
Serial.println("Moving Y back to the start.");
set_target(0, 0, 0);
enable_steppers();
dda_move(calculate_feedrate_delay(FAST_XY_FEEDRATE/2));
Serial.println("Pause for 2 seconds.");
delay(2000);
}
void Z_motor_test()
{
Serial.println("Moving Z down by 5 mm at half maximum speed.");
set_target(0, 0, 5);
enable_steppers();
dda_move(calculate_feedrate_delay(FAST_Z_FEEDRATE/2));
Serial.println("Pause for 2 seconds.");
delay(2000);
Serial.println("Moving Z back to the start.");
set_target(0, 0, 0);
enable_steppers();
dda_move(calculate_feedrate_delay(FAST_Z_FEEDRATE/2));
Serial.println("Pause for 2 seconds.");
delay(2000);
}
#endif
int main(void)
{
init();
setup();
for (;;)
loop();
return 0;
}
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