Merge branch 'deltabot' of https://github.com/jcrocholl/Marlin into deltabot
Conflicts: Marlin/Configuration.h Marlin/Marlin_main.cpp Marlin/pins.h
This commit is contained in:
commit
373f3ecab3
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@ -63,6 +63,43 @@
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#define POWER_SUPPLY 1
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#define POWER_SUPPLY 1
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//===========================================================================
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//============================== Delta Settings =============================
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//===========================================================================
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// Enable DELTA kinematics
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#define DELTA
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// Make delta curves from many straight lines (linear interpolation).
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// This is a trade-off between visible corners (not enough segments)
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// and processor overload (too many expensive sqrt calls).
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#define DELTA_SEGMENTS_PER_SECOND 200
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// Center-to-center distance of the holes in the diagonal push rods.
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#define DELTA_DIAGONAL_ROD 250.0 // mm
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// Horizontal offset from middle of printer to smooth rod center.
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#define DELTA_SMOOTH_ROD_OFFSET 175.0 // mm
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// Horizontal offset of the universal joints on the end effector.
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#define DELTA_EFFECTOR_OFFSET 33.0 // mm
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// Horizontal offset of the universal joints on the carriages.
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#define DELTA_CARRIAGE_OFFSET 18.0 // mm
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// Effective horizontal distance bridged by diagonal push rods.
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#define DELTA_RADIUS (DELTA_SMOOTH_ROD_OFFSET-DELTA_EFFECTOR_OFFSET-DELTA_CARRIAGE_OFFSET)
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// Effective X/Y positions of the three vertical towers.
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#define SIN_60 0.8660254037844386
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#define COS_60 0.5
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#define DELTA_TOWER1_X -SIN_60*DELTA_RADIUS // front left tower
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#define DELTA_TOWER1_Y -COS_60*DELTA_RADIUS
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#define DELTA_TOWER2_X SIN_60*DELTA_RADIUS // front right tower
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#define DELTA_TOWER2_Y -COS_60*DELTA_RADIUS
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#define DELTA_TOWER3_X 0.0 // back middle tower
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#define DELTA_TOWER3_Y DELTA_RADIUS
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//===========================================================================
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//===========================================================================
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//=============================Thermal Settings ============================
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//=============================Thermal Settings ============================
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//===========================================================================
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//===========================================================================
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@ -128,8 +165,8 @@
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// PID settings:
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// PID settings:
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// Comment the following line to disable PID and enable bang-bang.
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// Comment the following line to disable PID and enable bang-bang.
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#define PIDTEMP
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#define PIDTEMP
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#define BANG_MAX 256 // limits current to nozzle while in bang-bang mode; 256=full current
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#define BANG_MAX 255 // limits current to nozzle while in bang-bang mode; 255=full current
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#define PID_MAX 256 // limits current to nozzle while PID is active (see PID_FUNCTIONAL_RANGE below); 256=full current
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#define PID_MAX 255 // limits current to nozzle while PID is active (see PID_FUNCTIONAL_RANGE below); 255=full current
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#ifdef PIDTEMP
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#ifdef PIDTEMP
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//#define PID_DEBUG // Sends debug data to the serial port.
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//#define PID_DEBUG // Sends debug data to the serial port.
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//#define PID_OPENLOOP 1 // Puts PID in open loop. M104/M140 sets the output power from 0 to PID_MAX
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//#define PID_OPENLOOP 1 // Puts PID in open loop. M104/M140 sets the output power from 0 to PID_MAX
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@ -172,9 +209,9 @@
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// This sets the max power delived to the bed, and replaces the HEATER_BED_DUTY_CYCLE_DIVIDER option.
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// This sets the max power delived to the bed, and replaces the HEATER_BED_DUTY_CYCLE_DIVIDER option.
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// all forms of bed control obey this (PID, bang-bang, bang-bang with hysteresis)
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// all forms of bed control obey this (PID, bang-bang, bang-bang with hysteresis)
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// setting this to anything other than 256 enables a form of PWM to the bed just like HEATER_BED_DUTY_CYCLE_DIVIDER did,
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// setting this to anything other than 255 enables a form of PWM to the bed just like HEATER_BED_DUTY_CYCLE_DIVIDER did,
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// so you shouldn't use it unless you are OK with PWM on your bed. (see the comment on enabling PIDTEMPBED)
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// so you shouldn't use it unless you are OK with PWM on your bed. (see the comment on enabling PIDTEMPBED)
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#define MAX_BED_POWER 256 // limits duty cycle to bed; 256=full current
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#define MAX_BED_POWER 255 // limits duty cycle to bed; 255=full current
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#ifdef PIDTEMPBED
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#ifdef PIDTEMPBED
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//120v 250W silicone heater into 4mm borosilicate (MendelMax 1.5+)
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//120v 250W silicone heater into 4mm borosilicate (MendelMax 1.5+)
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@ -282,9 +319,11 @@ const bool Z_ENDSTOPS_INVERTING = true; // set to true to invert the logic of th
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//#define BED_CENTER_AT_0_0 // If defined, the center of the bed is at (X=0, Y=0)
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//#define BED_CENTER_AT_0_0 // If defined, the center of the bed is at (X=0, Y=0)
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//Manual homing switch locations:
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//Manual homing switch locations:
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// For deltabots this means top and center of the cartesian print volume.
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#define MANUAL_X_HOME_POS 0
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#define MANUAL_X_HOME_POS 0
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#define MANUAL_Y_HOME_POS 0
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#define MANUAL_Y_HOME_POS 0
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#define MANUAL_Z_HOME_POS 0
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#define MANUAL_Z_HOME_POS 0
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//#define MANUAL_Z_HOME_POS 402 // For delta: Distance between nozzle and print surface after homing.
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//// MOVEMENT SETTINGS
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//// MOVEMENT SETTINGS
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#define NUM_AXIS 4 // The axis order in all axis related arrays is X, Y, Z, E
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#define NUM_AXIS 4 // The axis order in all axis related arrays is X, Y, Z, E
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@ -157,6 +157,9 @@ void FlushSerialRequestResend();
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void ClearToSend();
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void ClearToSend();
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void get_coordinates();
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void get_coordinates();
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#ifdef DELTA
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void calculate_delta(float cartesian[3]);
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#endif
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void prepare_move();
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void prepare_move();
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void kill();
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void kill();
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void Stop();
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void Stop();
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@ -198,6 +198,9 @@ int EtoPPressure=0;
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//===========================================================================
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//===========================================================================
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const char axis_codes[NUM_AXIS] = {'X', 'Y', 'Z', 'E'};
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const char axis_codes[NUM_AXIS] = {'X', 'Y', 'Z', 'E'};
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static float destination[NUM_AXIS] = { 0.0, 0.0, 0.0, 0.0};
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static float destination[NUM_AXIS] = { 0.0, 0.0, 0.0, 0.0};
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#ifdef DELTA
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static float delta[3] = {0.0, 0.0, 0.0};
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#endif
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static float offset[3] = {0.0, 0.0, 0.0};
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static float offset[3] = {0.0, 0.0, 0.0};
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static bool home_all_axis = true;
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static bool home_all_axis = true;
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static float feedrate = 1500.0, next_feedrate, saved_feedrate;
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static float feedrate = 1500.0, next_feedrate, saved_feedrate;
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@ -836,6 +839,10 @@ void process_commands()
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feedrate = 0.0;
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feedrate = 0.0;
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st_synchronize();
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st_synchronize();
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endstops_hit_on_purpose();
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endstops_hit_on_purpose();
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current_position[X_AXIS] = destination[X_AXIS];
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current_position[Y_AXIS] = destination[Y_AXIS];
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current_position[Z_AXIS] = destination[Z_AXIS];
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}
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}
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#endif
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#endif
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@ -847,14 +854,14 @@ void process_commands()
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if((home_all_axis) || (code_seen(axis_codes[Y_AXIS]))) {
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if((home_all_axis) || (code_seen(axis_codes[Y_AXIS]))) {
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HOMEAXIS(Y);
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HOMEAXIS(Y);
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}
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}
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#if Z_HOME_DIR < 0 // If homing towards BED do Z last
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#if Z_HOME_DIR < 0 // If homing towards BED do Z last
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if((home_all_axis) || (code_seen(axis_codes[Z_AXIS]))) {
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if((home_all_axis) || (code_seen(axis_codes[Z_AXIS]))) {
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HOMEAXIS(Z);
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HOMEAXIS(Z);
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}
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}
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#endif
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#endif
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if(code_seen(axis_codes[X_AXIS]))
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if(code_seen(axis_codes[X_AXIS]))
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{
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{
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if(code_value_long() != 0) {
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if(code_value_long() != 0) {
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current_position[X_AXIS]=code_value()+add_homeing[0];
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current_position[X_AXIS]=code_value()+add_homeing[0];
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current_position[Z_AXIS]=code_value()+add_homeing[2];
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current_position[Z_AXIS]=code_value()+add_homeing[2];
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}
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}
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}
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}
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plan_set_position(current_position[X_AXIS], current_position[Y_AXIS], current_position[Z_AXIS], current_position[E_AXIS]);
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#ifdef DELTA
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calculate_delta(current_position);
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plan_set_position(delta[X_AXIS], delta[Y_AXIS], delta[Z_AXIS], current_position[E_AXIS]);
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#else
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plan_set_position(current_position[X_AXIS], current_position[Y_AXIS], current_position[Z_AXIS], current_position[E_AXIS]);
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#endif
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#ifdef ENDSTOPS_ONLY_FOR_HOMING
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#ifdef ENDSTOPS_ONLY_FOR_HOMING
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enable_endstops(false);
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enable_endstops(false);
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#endif
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#endif
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}
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}
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}
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}
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#ifdef DELTA
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void calculate_delta(float cartesian[3])
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{
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delta[X_AXIS] = sqrt(sq(DELTA_DIAGONAL_ROD)
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- sq(DELTA_TOWER1_X-cartesian[X_AXIS])
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- sq(DELTA_TOWER1_Y-cartesian[Y_AXIS])
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) + cartesian[Z_AXIS];
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delta[Y_AXIS] = sqrt(sq(DELTA_DIAGONAL_ROD)
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- sq(DELTA_TOWER2_X-cartesian[X_AXIS])
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- sq(DELTA_TOWER2_Y-cartesian[Y_AXIS])
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) + cartesian[Z_AXIS];
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delta[Z_AXIS] = sqrt(sq(DELTA_DIAGONAL_ROD)
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- sq(DELTA_TOWER3_X-cartesian[X_AXIS])
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- sq(DELTA_TOWER3_Y-cartesian[Y_AXIS])
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) + cartesian[Z_AXIS];
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/*
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SERIAL_ECHOPGM("cartesian x="); SERIAL_ECHO(cartesian[X_AXIS]);
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SERIAL_ECHOPGM(" y="); SERIAL_ECHO(cartesian[Y_AXIS]);
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SERIAL_ECHOPGM(" z="); SERIAL_ECHOLN(cartesian[Z_AXIS]);
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SERIAL_ECHOPGM("delta x="); SERIAL_ECHO(delta[X_AXIS]);
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SERIAL_ECHOPGM(" y="); SERIAL_ECHO(delta[Y_AXIS]);
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SERIAL_ECHOPGM(" z="); SERIAL_ECHOLN(delta[Z_AXIS]);
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*/
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}
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#endif
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void prepare_move()
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void prepare_move()
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{
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{
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clamp_to_software_endstops(destination);
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clamp_to_software_endstops(destination);
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previous_millis_cmd = millis();
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previous_millis_cmd = millis();
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#ifdef DELTA
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float difference[NUM_AXIS];
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for (int8_t i=0; i < NUM_AXIS; i++) {
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difference[i] = destination[i] - current_position[i];
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}
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float cartesian_mm = sqrt(sq(difference[X_AXIS]) +
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sq(difference[Y_AXIS]) +
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sq(difference[Z_AXIS]));
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if (cartesian_mm < 0.000001) { cartesian_mm = abs(difference[E_AXIS]); }
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if (cartesian_mm < 0.000001) { return; }
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float seconds = 6000 * cartesian_mm / feedrate / feedmultiply;
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int steps = max(1, int(DELTA_SEGMENTS_PER_SECOND * seconds));
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// SERIAL_ECHOPGM("mm="); SERIAL_ECHO(cartesian_mm);
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// SERIAL_ECHOPGM(" seconds="); SERIAL_ECHO(seconds);
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// SERIAL_ECHOPGM(" steps="); SERIAL_ECHOLN(steps);
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for (int s = 1; s <= steps; s++) {
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float fraction = float(s) / float(steps);
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for(int8_t i=0; i < NUM_AXIS; i++) {
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destination[i] = current_position[i] + difference[i] * fraction;
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}
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calculate_delta(destination);
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plan_buffer_line(delta[X_AXIS], delta[Y_AXIS], delta[Z_AXIS],
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destination[E_AXIS], feedrate*feedmultiply/60/100.0,
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active_extruder);
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}
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#else
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// Do not use feedmultiply for E or Z only moves
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// Do not use feedmultiply for E or Z only moves
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if( (current_position[X_AXIS] == destination [X_AXIS]) && (current_position[Y_AXIS] == destination [Y_AXIS])) {
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if( (current_position[X_AXIS] == destination [X_AXIS]) && (current_position[Y_AXIS] == destination [Y_AXIS])) {
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plan_buffer_line(destination[X_AXIS], destination[Y_AXIS], destination[Z_AXIS], destination[E_AXIS], feedrate/60, active_extruder);
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plan_buffer_line(destination[X_AXIS], destination[Y_AXIS], destination[Z_AXIS], destination[E_AXIS], feedrate/60, active_extruder);
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@ -2063,6 +2127,7 @@ void prepare_move()
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else {
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else {
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plan_buffer_line(destination[X_AXIS], destination[Y_AXIS], destination[Z_AXIS], destination[E_AXIS], feedrate*feedmultiply/60/100.0, active_extruder);
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plan_buffer_line(destination[X_AXIS], destination[Y_AXIS], destination[Z_AXIS], destination[E_AXIS], feedrate*feedmultiply/60/100.0, active_extruder);
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}
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}
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#endif
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for(int8_t i=0; i < NUM_AXIS; i++) {
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for(int8_t i=0; i < NUM_AXIS; i++) {
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current_position[i] = destination[i];
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current_position[i] = destination[i];
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}
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}
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@ -2305,4 +2370,5 @@ bool setTargetedHotend(int code){
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}
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}
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}
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}
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return false;
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return false;
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}
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}
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