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/*
* This class controls the movement of the RepRap machine.
* It implements a DDA in four dimensions, so the length of extruded
* filament is treated as a variable, just like X, Y, and Z.
*
* Adrian Bowyer 9 May 2009
*/
#ifndef CARTESIAN_DDA_H
#define CARTESIAN_DDA_H
// Main class for moving the RepRap machine about
class cartesian_dda
{
private:
//extruder* ext; // The extruder I'm currently using - keep this up to date...
FloatPoint units; // Factors for converting either mm or inches to steps
FloatPoint target_position; // Where it's going
FloatPoint delta_position; // The difference between the two
float distance; // How long the path is
LongPoint current_steps; // Similar information as above in steps rather than units
LongPoint target_steps;
LongPoint delta_steps;
LongPoint dda_counter; // DDA error-accumulation variables
long t_scale; // When doing lots of t steps, scale them so the DDA doesn't spend for ever on them
byte x_direction; // Am I going in the + or - direction?
byte y_direction;
byte z_direction;
byte e_direction;
byte f_direction;
bool x_can_step; // Am I not at an endstop? Have I not reached the target? etc.
bool y_can_step;
bool z_can_step;
bool e_can_step;
bool f_can_step;
// Variables for acceleration calculations
long total_steps; // The number of steps to take along the longest movement axis
long timestep; // microseconds
bool nullmove; // this move is zero length
bool real_move; // Flag to know if we've changed something physical
volatile bool live; // Flag for when we're plotting a line
// Internal functions that need not concern the user
// Take a single step
void do_x_step();
void do_y_step();
void do_z_step();
void do_e_step();
// Can this axis step?
bool can_step(byte min_pin, byte max_pin, long current, long target, byte dir);
// Read a limit switch
bool read_switch(byte pin);
// Work out the number of microseconds between steps
long calculate_feedrate_delay(const float& feedrate);
// Switch the steppers on and off
void enable_steppers();
void disable_steppers();
// Custom short delay function (microseconds)
//void delayMicrosecondsInterruptible(unsigned int us);
public:
cartesian_dda();
// Set where I'm going
void set_target(const FloatPoint& p);
// Start the DDA
void dda_start();
// Do one step of the DDA
void dda_step();
// Are we running at the moment?
bool active();
// True for mm; false for inches
void set_units(bool using_mm);
// Record the selection of a new extruder
//void set_extruder(extruder* ex);
};
// Short functions inline to save memory; particularly useful in the Arduino
//inline void cartesian_dda::set_extruder(extruder* ex)
//{
// ext = ex;
//}
inline bool cartesian_dda::active()
{
return live;
}
inline void cartesian_dda::do_x_step()
{
digitalWrite(X_STEP_PIN, HIGH);
delayMicrosecondsInterruptible(5);
digitalWrite(X_STEP_PIN, LOW);
}
inline void cartesian_dda::do_y_step()
{
digitalWrite(Y_STEP_PIN, HIGH);
delayMicrosecondsInterruptible(5);
digitalWrite(Y_STEP_PIN, LOW);
}
inline void cartesian_dda::do_z_step()
{
digitalWrite(Z_STEP_PIN, HIGH);
delayMicrosecondsInterruptible(5);
digitalWrite(Z_STEP_PIN, LOW);
}
inline void cartesian_dda::do_e_step()
{
ex[extruder_in_use]->sStep();
}
inline long cartesian_dda::calculate_feedrate_delay(const float& feedrate)
{
// Calculate delay between steps in microseconds. Here it is in English:
// (feedrate is in mm/minute, distance is in mm)
// 60000000.0*distance/feedrate = move duration in microseconds
// move duration/total_steps = time between steps for master axis.
return round( (distance*60000000.0) / (feedrate*(float)total_steps) );
}
inline bool cartesian_dda::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
}
#endif
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