Support for up to 9 axes (#23112, #24036, #24231)

This commit is contained in:
Scott Lahteine 2022-04-29 15:21:15 -05:00
parent 369542db3b
commit fd13a928c1
103 changed files with 4553 additions and 799 deletions

View File

@ -176,6 +176,9 @@
//#define I_DRIVER_TYPE A4988
//#define J_DRIVER_TYPE A4988
//#define K_DRIVER_TYPE A4988
//#define U_DRIVER_TYPE A4988
//#define V_DRIVER_TYPE A4988
//#define W_DRIVER_TYPE A4988
#define E0_DRIVER_TYPE A4988
//#define E1_DRIVER_TYPE A4988
//#define E2_DRIVER_TYPE A4988
@ -186,20 +189,25 @@
//#define E7_DRIVER_TYPE A4988
/**
* Axis codes for additional axes:
* This defines the axis code that is used in G-code commands to
* reference a specific axis.
* 'A' for rotational axis parallel to X
* 'B' for rotational axis parallel to Y
* 'C' for rotational axis parallel to Z
* 'U' for secondary linear axis parallel to X
* 'V' for secondary linear axis parallel to Y
* 'W' for secondary linear axis parallel to Z
* Regardless of the settings, firmware-internal axis IDs are
* I (AXIS4), J (AXIS5), K (AXIS6).
* Additional Axis Settings
*
* Define AXISn_ROTATES for all axes that rotate or pivot.
* Rotational axis coordinates are expressed in degrees.
*
* AXISn_NAME defines the letter used to refer to the axis in (most) G-code commands.
* By convention the names and roles are typically:
* 'A' : Rotational axis parallel to X
* 'B' : Rotational axis parallel to Y
* 'C' : Rotational axis parallel to Z
* 'U' : Secondary linear axis parallel to X
* 'V' : Secondary linear axis parallel to Y
* 'W' : Secondary linear axis parallel to Z
*
* Regardless of these settings the axes are internally named I, J, K, U, V, W.
*/
#ifdef I_DRIVER_TYPE
#define AXIS4_NAME 'A' // :['A', 'B', 'C', 'U', 'V', 'W']
#define AXIS4_ROTATES
#endif
#ifdef J_DRIVER_TYPE
#define AXIS5_NAME 'B' // :['B', 'C', 'U', 'V', 'W']
@ -209,6 +217,18 @@
#define AXIS6_NAME 'C' // :['C', 'U', 'V', 'W']
#define AXIS6_ROTATES
#endif
#ifdef U_DRIVER_TYPE
#define AXIS7_NAME 'U' // :['U', 'V', 'W']
//#define AXIS7_ROTATES
#endif
#ifdef V_DRIVER_TYPE
#define AXIS8_NAME 'V' // :['V', 'W']
//#define AXIS8_ROTATES
#endif
#ifdef W_DRIVER_TYPE
#define AXIS9_NAME 'W' // :['W']
//#define AXIS9_ROTATES
#endif
// @section extruder
@ -860,12 +880,18 @@
//#define USE_IMIN_PLUG
//#define USE_JMIN_PLUG
//#define USE_KMIN_PLUG
//#define USE_UMIN_PLUG
//#define USE_VMIN_PLUG
//#define USE_WMIN_PLUG
//#define USE_XMAX_PLUG
//#define USE_YMAX_PLUG
//#define USE_ZMAX_PLUG
//#define USE_IMAX_PLUG
//#define USE_JMAX_PLUG
//#define USE_KMAX_PLUG
//#define USE_UMAX_PLUG
//#define USE_VMAX_PLUG
//#define USE_WMAX_PLUG
// Enable pullup for all endstops to prevent a floating state
#define ENDSTOPPULLUPS
@ -877,12 +903,18 @@
//#define ENDSTOPPULLUP_IMIN
//#define ENDSTOPPULLUP_JMIN
//#define ENDSTOPPULLUP_KMIN
//#define ENDSTOPPULLUP_UMIN
//#define ENDSTOPPULLUP_VMIN
//#define ENDSTOPPULLUP_WMIN
//#define ENDSTOPPULLUP_XMAX
//#define ENDSTOPPULLUP_YMAX
//#define ENDSTOPPULLUP_ZMAX
//#define ENDSTOPPULLUP_IMAX
//#define ENDSTOPPULLUP_JMAX
//#define ENDSTOPPULLUP_KMAX
//#define ENDSTOPPULLUP_UMAX
//#define ENDSTOPPULLUP_VMAX
//#define ENDSTOPPULLUP_WMAX
//#define ENDSTOPPULLUP_ZMIN_PROBE
#endif
@ -896,12 +928,18 @@
//#define ENDSTOPPULLDOWN_IMIN
//#define ENDSTOPPULLDOWN_JMIN
//#define ENDSTOPPULLDOWN_KMIN
//#define ENDSTOPPULLDOWN_UMIN
//#define ENDSTOPPULLDOWN_VMIN
//#define ENDSTOPPULLDOWN_WMIN
//#define ENDSTOPPULLDOWN_XMAX
//#define ENDSTOPPULLDOWN_YMAX
//#define ENDSTOPPULLDOWN_ZMAX
//#define ENDSTOPPULLDOWN_IMAX
//#define ENDSTOPPULLDOWN_JMAX
//#define ENDSTOPPULLDOWN_KMAX
//#define ENDSTOPPULLDOWN_UMAX
//#define ENDSTOPPULLDOWN_VMAX
//#define ENDSTOPPULLDOWN_WMAX
//#define ENDSTOPPULLDOWN_ZMIN_PROBE
#endif
@ -912,12 +950,18 @@
#define I_MIN_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define J_MIN_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define K_MIN_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define U_MIN_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define V_MIN_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define W_MIN_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define X_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define Y_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define Z_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define I_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define J_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define K_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define U_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define V_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define W_MAX_ENDSTOP_INVERTING false // Set to true to invert the logic of the endstop.
#define Z_MIN_PROBE_ENDSTOP_INVERTING false // Set to true to invert the logic of the probe.
// Enable this feature if all enabled endstop pins are interrupt-capable.
@ -962,16 +1006,16 @@
//#define DISTINCT_E_FACTORS
/**
* Default Axis Steps Per Unit (steps/mm)
* Default Axis Steps Per Unit (linear=steps/mm, rotational=steps/°)
* Override with M92
* X, Y, Z [, I [, J [, K]]], E0 [, E1[, E2...]]
* X, Y, Z [, I [, J [, K...]]], E0 [, E1[, E2...]]
*/
#define DEFAULT_AXIS_STEPS_PER_UNIT { 80, 80, 400, 500 }
/**
* Default Max Feed Rate (mm/s)
* Default Max Feed Rate (linear=mm/s, rotational=°/s)
* Override with M203
* X, Y, Z [, I [, J [, K]]], E0 [, E1[, E2...]]
* X, Y, Z [, I [, J [, K...]]], E0 [, E1[, E2...]]
*/
#define DEFAULT_MAX_FEEDRATE { 300, 300, 5, 25 }
@ -981,10 +1025,10 @@
#endif
/**
* Default Max Acceleration (change/s) change = mm/s
* Default Max Acceleration (speed change with time) (linear=mm/(s^2), rotational=°/(s^2))
* (Maximum start speed for accelerated moves)
* Override with M201
* X, Y, Z [, I [, J [, K]]], E0 [, E1[, E2...]]
* X, Y, Z [, I [, J [, K...]]], E0 [, E1[, E2...]]
*/
#define DEFAULT_MAX_ACCELERATION { 3000, 3000, 100, 10000 }
@ -994,7 +1038,7 @@
#endif
/**
* Default Acceleration (change/s) change = mm/s
* Default Acceleration (speed change with time) (linear=mm/(s^2), rotational=°/(s^2))
* Override with M204
*
* M204 P Acceleration
@ -1007,7 +1051,7 @@
/**
* Default Jerk limits (mm/s)
* Override with M205 X Y Z E
* Override with M205 X Y Z . . . E
*
* "Jerk" specifies the minimum speed change that requires acceleration.
* When changing speed and direction, if the difference is less than the
@ -1021,6 +1065,9 @@
//#define DEFAULT_IJERK 0.3
//#define DEFAULT_JJERK 0.3
//#define DEFAULT_KJERK 0.3
//#define DEFAULT_UJERK 0.3
//#define DEFAULT_VJERK 0.3
//#define DEFAULT_WJERK 0.3
//#define TRAVEL_EXTRA_XYJERK 0.0 // Additional jerk allowance for all travel moves
@ -1359,6 +1406,9 @@
//#define I_ENABLE_ON 0
//#define J_ENABLE_ON 0
//#define K_ENABLE_ON 0
//#define U_ENABLE_ON 0
//#define V_ENABLE_ON 0
//#define W_ENABLE_ON 0
// Disable axis steppers immediately when they're not being stepped.
// WARNING: When motors turn off there is a chance of losing position accuracy!
@ -1368,6 +1418,9 @@
//#define DISABLE_I false
//#define DISABLE_J false
//#define DISABLE_K false
//#define DISABLE_U false
//#define DISABLE_V false
//#define DISABLE_W false
// Turn off the display blinking that warns about possible accuracy reduction
//#define DISABLE_REDUCED_ACCURACY_WARNING
@ -1386,6 +1439,9 @@
//#define INVERT_I_DIR false
//#define INVERT_J_DIR false
//#define INVERT_K_DIR false
//#define INVERT_U_DIR false
//#define INVERT_V_DIR false
//#define INVERT_W_DIR false
// @section extruder
@ -1424,6 +1480,9 @@
//#define I_HOME_DIR -1
//#define J_HOME_DIR -1
//#define K_HOME_DIR -1
//#define U_HOME_DIR -1
//#define V_HOME_DIR -1
//#define W_HOME_DIR -1
// @section machine
@ -1431,7 +1490,7 @@
#define X_BED_SIZE 200
#define Y_BED_SIZE 200
// Travel limits (mm) after homing, corresponding to endstop positions.
// Travel limits (linear=mm, rotational=°) after homing, corresponding to endstop positions.
#define X_MIN_POS 0
#define Y_MIN_POS 0
#define Z_MIN_POS 0
@ -1444,6 +1503,12 @@
//#define J_MAX_POS 50
//#define K_MIN_POS 0
//#define K_MAX_POS 50
//#define U_MIN_POS 0
//#define U_MAX_POS 50
//#define V_MIN_POS 0
//#define V_MAX_POS 50
//#define W_MIN_POS 0
//#define W_MAX_POS 50
/**
* Software Endstops
@ -1463,6 +1528,9 @@
#define MIN_SOFTWARE_ENDSTOP_I
#define MIN_SOFTWARE_ENDSTOP_J
#define MIN_SOFTWARE_ENDSTOP_K
#define MIN_SOFTWARE_ENDSTOP_U
#define MIN_SOFTWARE_ENDSTOP_V
#define MIN_SOFTWARE_ENDSTOP_W
#endif
// Max software endstops constrain movement within maximum coordinate bounds
@ -1474,6 +1542,9 @@
#define MAX_SOFTWARE_ENDSTOP_I
#define MAX_SOFTWARE_ENDSTOP_J
#define MAX_SOFTWARE_ENDSTOP_K
#define MAX_SOFTWARE_ENDSTOP_U
#define MAX_SOFTWARE_ENDSTOP_V
#define MAX_SOFTWARE_ENDSTOP_W
#endif
#if EITHER(MIN_SOFTWARE_ENDSTOPS, MAX_SOFTWARE_ENDSTOPS)
@ -1788,6 +1859,9 @@
//#define MANUAL_I_HOME_POS 0
//#define MANUAL_J_HOME_POS 0
//#define MANUAL_K_HOME_POS 0
//#define MANUAL_U_HOME_POS 0
//#define MANUAL_V_HOME_POS 0
//#define MANUAL_W_HOME_POS 0
/**
* Use "Z Safe Homing" to avoid homing with a Z probe outside the bed area.
@ -1803,7 +1877,7 @@
#define Z_SAFE_HOMING_Y_POINT Y_CENTER // Y point for Z homing
#endif
// Homing speeds (mm/min)
// Homing speeds (linear=mm/min, rotational=°/min)
#define HOMING_FEEDRATE_MM_M { (50*60), (50*60), (4*60) }
// Validate that endstops are triggered on homing moves

View File

@ -832,12 +832,12 @@
* the position of the toolhead relative to the workspace.
*/
//#define SENSORLESS_BACKOFF_MM { 2, 2, 0 } // (mm) Backoff from endstops before sensorless homing
//#define SENSORLESS_BACKOFF_MM { 2, 2, 0 } // (linear=mm, rotational=°) Backoff from endstops before sensorless homing
#define HOMING_BUMP_MM { 5, 5, 2 } // (mm) Backoff from endstops after first bump
#define HOMING_BUMP_MM { 5, 5, 2 } // (linear=mm, rotational=°) Backoff from endstops after first bump
#define HOMING_BUMP_DIVISOR { 2, 2, 4 } // Re-Bump Speed Divisor (Divides the Homing Feedrate)
//#define HOMING_BACKOFF_POST_MM { 2, 2, 2 } // (mm) Backoff from endstops after homing
//#define HOMING_BACKOFF_POST_MM { 2, 2, 2 } // (linear=mm, rotational=°) Backoff from endstops after homing
//#define QUICK_HOME // If G28 contains XY do a diagonal move first
//#define HOME_Y_BEFORE_X // If G28 contains XY home Y before X
@ -1023,6 +1023,9 @@
#define INVERT_I_STEP_PIN false
#define INVERT_J_STEP_PIN false
#define INVERT_K_STEP_PIN false
#define INVERT_U_STEP_PIN false
#define INVERT_V_STEP_PIN false
#define INVERT_W_STEP_PIN false
#define INVERT_E_STEP_PIN false
/**
@ -1037,11 +1040,14 @@
#define DISABLE_INACTIVE_I true
#define DISABLE_INACTIVE_J true
#define DISABLE_INACTIVE_K true
#define DISABLE_INACTIVE_U true
#define DISABLE_INACTIVE_V true
#define DISABLE_INACTIVE_W true
#define DISABLE_INACTIVE_E true
// Default Minimum Feedrates for printing and travel moves
#define DEFAULT_MINIMUMFEEDRATE 0.0 // (mm/s) Minimum feedrate. Set with M205 S.
#define DEFAULT_MINTRAVELFEEDRATE 0.0 // (mm/s) Minimum travel feedrate. Set with M205 T.
#define DEFAULT_MINIMUMFEEDRATE 0.0 // (mm/s. °/s for rotational-only moves) Minimum feedrate. Set with M205 S.
#define DEFAULT_MINTRAVELFEEDRATE 0.0 // (mm/s. °/s for rotational-only moves) Minimum travel feedrate. Set with M205 T.
// Minimum time that a segment needs to take as the buffer gets emptied
#define DEFAULT_MINSEGMENTTIME 20000 // (µs) Set with M205 B.
@ -1077,7 +1083,7 @@
#if ENABLED(BACKLASH_COMPENSATION)
// Define values for backlash distance and correction.
// If BACKLASH_GCODE is enabled these values are the defaults.
#define BACKLASH_DISTANCE_MM { 0, 0, 0 } // (mm) One value for each linear axis
#define BACKLASH_DISTANCE_MM { 0, 0, 0 } // (linear=mm, rotational=°) One value for each linear axis
#define BACKLASH_CORRECTION 0.0 // 0.0 = no correction; 1.0 = full correction
// Add steps for motor direction changes on CORE kinematics
@ -1154,6 +1160,12 @@
//#define CALIBRATION_MEASURE_JMAX
//#define CALIBRATION_MEASURE_KMIN
//#define CALIBRATION_MEASURE_KMAX
//#define CALIBRATION_MEASURE_UMIN
//#define CALIBRATION_MEASURE_UMAX
//#define CALIBRATION_MEASURE_VMIN
//#define CALIBRATION_MEASURE_VMAX
//#define CALIBRATION_MEASURE_WMIN
//#define CALIBRATION_MEASURE_WMAX
// Probing at the exact top center only works if the center is flat. If
// probing on a screwhead or hollow washer, probe near the edges.
@ -2012,6 +2024,21 @@
// @section leveling
/**
* Use Safe Bed Leveling coordinates to move axes to a useful position before bed probing.
* For example, after homing a rotational axis the Z probe might not be perpendicular to the bed.
* Choose values the orient the bed horizontally and the Z-probe vertically.
*/
//#define SAFE_BED_LEVELING_START_X 0.0
//#define SAFE_BED_LEVELING_START_Y 0.0
//#define SAFE_BED_LEVELING_START_Z 0.0
//#define SAFE_BED_LEVELING_START_I 0.0
//#define SAFE_BED_LEVELING_START_J 0.0
//#define SAFE_BED_LEVELING_START_K 0.0
//#define SAFE_BED_LEVELING_START_U 0.0
//#define SAFE_BED_LEVELING_START_V 0.0
//#define SAFE_BED_LEVELING_START_W 0.0
/**
* Points to probe for all 3-point Leveling procedures.
* Override if the automatically selected points are inadequate.
@ -2630,6 +2657,24 @@
#define K_MICROSTEPS 16
#endif
#if AXIS_DRIVER_TYPE_U(TMC26X)
#define U_MAX_CURRENT 1000
#define U_SENSE_RESISTOR 91
#define U_MICROSTEPS 16
#endif
#if AXIS_DRIVER_TYPE_V(TMC26X)
#define V_MAX_CURRENT 1000
#define V_SENSE_RESISTOR 91
#define V_MICROSTEPS 16
#endif
#if AXIS_DRIVER_TYPE_W(TMC26X)
#define W_MAX_CURRENT 1000
#define W_SENSE_RESISTOR 91
#define W_MICROSTEPS 16
#endif
#if AXIS_DRIVER_TYPE_E0(TMC26X)
#define E0_MAX_CURRENT 1000
#define E0_SENSE_RESISTOR 91
@ -2818,6 +2863,36 @@
//#define K_HOLD_MULTIPLIER 0.5
#endif
#if AXIS_IS_TMC(U)
#define U_CURRENT 800
#define U_CURRENT_HOME U_CURRENT
#define U_MICROSTEPS 8
#define U_RSENSE 0.11
#define U_CHAIN_POS -1
//#define U_INTERPOLATE true
//#define U_HOLD_MULTIPLIER 0.5
#endif
#if AXIS_IS_TMC(V)
#define V_CURRENT 800
#define V_CURRENT_HOME V_CURRENT
#define V_MICROSTEPS 8
#define V_RSENSE 0.11
#define V_CHAIN_POS -1
//#define V_INTERPOLATE true
//#define V_HOLD_MULTIPLIER 0.5
#endif
#if AXIS_IS_TMC(W)
#define W_CURRENT 800
#define W_CURRENT_HOME W_CURRENT
#define W_MICROSTEPS 8
#define W_RSENSE 0.11
#define W_CHAIN_POS -1
//#define W_INTERPOLATE true
//#define W_HOLD_MULTIPLIER 0.5
#endif
#if AXIS_IS_TMC(E0)
#define E0_CURRENT 800
#define E0_MICROSTEPS 16
@ -2905,6 +2980,9 @@
//#define I_CS_PIN -1
//#define J_CS_PIN -1
//#define K_CS_PIN -1
//#define U_CS_PIN -1
//#define V_CS_PIN -1
//#define W_CS_PIN -1
//#define E0_CS_PIN -1
//#define E1_CS_PIN -1
//#define E2_CS_PIN -1
@ -2947,6 +3025,9 @@
//#define I_SLAVE_ADDRESS 0
//#define J_SLAVE_ADDRESS 0
//#define K_SLAVE_ADDRESS 0
//#define U_SLAVE_ADDRESS 0
//#define V_SLAVE_ADDRESS 0
//#define W_SLAVE_ADDRESS 0
//#define E0_SLAVE_ADDRESS 0
//#define E1_SLAVE_ADDRESS 0
//#define E2_SLAVE_ADDRESS 0
@ -2974,6 +3055,9 @@
#define STEALTHCHOP_I
#define STEALTHCHOP_J
#define STEALTHCHOP_K
#define STEALTHCHOP_U
#define STEALTHCHOP_V
#define STEALTHCHOP_W
#define STEALTHCHOP_E
/**
@ -3000,9 +3084,12 @@
//#define CHOPPER_TIMING_Z2 CHOPPER_TIMING_Z
//#define CHOPPER_TIMING_Z3 CHOPPER_TIMING_Z
//#define CHOPPER_TIMING_Z4 CHOPPER_TIMING_Z
//#define CHOPPER_TIMING_I CHOPPER_TIMING
//#define CHOPPER_TIMING_J CHOPPER_TIMING
//#define CHOPPER_TIMING_K CHOPPER_TIMING
//#define CHOPPER_TIMING_I CHOPPER_TIMING // For I Axis
//#define CHOPPER_TIMING_J CHOPPER_TIMING // For J Axis
//#define CHOPPER_TIMING_K CHOPPER_TIMING // For K Axis
//#define CHOPPER_TIMING_U CHOPPER_TIMING // For U Axis
//#define CHOPPER_TIMING_V CHOPPER_TIMING // For V Axis
//#define CHOPPER_TIMING_W CHOPPER_TIMING // For W Axis
//#define CHOPPER_TIMING_E CHOPPER_TIMING // For Extruders (override below)
//#define CHOPPER_TIMING_E1 CHOPPER_TIMING_E
//#define CHOPPER_TIMING_E2 CHOPPER_TIMING_E
@ -3048,9 +3135,12 @@
#define Z2_HYBRID_THRESHOLD 3
#define Z3_HYBRID_THRESHOLD 3
#define Z4_HYBRID_THRESHOLD 3
#define I_HYBRID_THRESHOLD 3
#define J_HYBRID_THRESHOLD 3
#define K_HYBRID_THRESHOLD 3
#define I_HYBRID_THRESHOLD 3 // [linear=mm/s, rotational=°/s]
#define J_HYBRID_THRESHOLD 3 // [linear=mm/s, rotational=°/s]
#define K_HYBRID_THRESHOLD 3 // [linear=mm/s, rotational=°/s]
#define U_HYBRID_THRESHOLD 3 // [mm/s]
#define V_HYBRID_THRESHOLD 3
#define W_HYBRID_THRESHOLD 3
#define E0_HYBRID_THRESHOLD 30
#define E1_HYBRID_THRESHOLD 30
#define E2_HYBRID_THRESHOLD 30
@ -3100,6 +3190,9 @@
//#define I_STALL_SENSITIVITY 8
//#define J_STALL_SENSITIVITY 8
//#define K_STALL_SENSITIVITY 8
//#define U_STALL_SENSITIVITY 8
//#define V_STALL_SENSITIVITY 8
//#define W_STALL_SENSITIVITY 8
//#define SPI_ENDSTOPS // TMC2130 only
//#define IMPROVE_HOMING_RELIABILITY
#endif
@ -3267,6 +3360,33 @@
#define K_SLEW_RATE 1
#endif
#if AXIS_IS_L64XX(U)
#define U_MICROSTEPS 128
#define U_OVERCURRENT 2000
#define U_STALLCURRENT 1500
#define U_MAX_VOLTAGE 127
#define U_CHAIN_POS -1
#define U_SLEW_RATE 1
#endif
#if AXIS_IS_L64XX(V)
#define V_MICROSTEPS 128
#define V_OVERCURRENT 2000
#define V_STALLCURRENT 1500
#define V_MAX_VOLTAGE 127
#define V_CHAIN_POS -1
#define V_SLEW_RATE 1
#endif
#if AXIS_IS_L64XX(W)
#define W_MICROSTEPS 128
#define W_OVERCURRENT 2000
#define W_STALLCURRENT 1500
#define W_MAX_VOLTAGE 127
#define W_CHAIN_POS -1
#define W_SLEW_RATE 1
#endif
#if AXIS_IS_L64XX(E0)
#define E0_MICROSTEPS 128
#define E0_OVERCURRENT 2000

View File

@ -213,6 +213,51 @@ void setup_endstop_interrupts() {
pciSetup(K_MIN_PIN);
#endif
#endif
#if HAS_U_MAX
#if (digitalPinToInterrupt(U_MAX_PIN) != NOT_AN_INTERRUPT)
_ATTACH(U_MAX_PIN);
#else
static_assert(digitalPinHasPCICR(U_MAX_PIN), "U_MAX_PIN is not interrupt-capable");
pciSetup(U_MAX_PIN);
#endif
#elif HAS_U_MIN
#if (digitalPinToInterrupt(U_MIN_PIN) != NOT_AN_INTERRUPT)
_ATTACH(U_MIN_PIN);
#else
static_assert(digitalPinHasPCICR(U_MIN_PIN), "U_MIN_PIN is not interrupt-capable");
pciSetup(U_MIN_PIN);
#endif
#endif
#if HAS_V_MAX
#if (digitalPinToInterrupt(V_MAX_PIN) != NOT_AN_INTERRUPT)
_ATTACH(V_MAX_PIN);
#else
static_assert(digitalPinHasPCICR(V_MAX_PIN), "V_MAX_PIN is not interrupt-capable");
pciSetup(V_MAX_PIN);
#endif
#elif HAS_V_MIN
#if (digitalPinToInterrupt(V_MIN_PIN) != NOT_AN_INTERRUPT)
_ATTACH(V_MIN_PIN);
#else
static_assert(digitalPinHasPCICR(V_MIN_PIN), "V_MIN_PIN is not interrupt-capable");
pciSetup(V_MIN_PIN);
#endif
#endif
#if HAS_W_MAX
#if (digitalPinToInterrupt(W_MAX_PIN) != NOT_AN_INTERRUPT)
_ATTACH(W_MAX_PIN);
#else
static_assert(digitalPinHasPCICR(W_MAX_PIN), "W_MAX_PIN is not interrupt-capable");
pciSetup(W_MAX_PIN);
#endif
#elif HAS_W_MIN
#if (digitalPinToInterrupt(W_MIN_PIN) != NOT_AN_INTERRUPT)
_ATTACH(W_MIN_PIN);
#else
static_assert(digitalPinHasPCICR(W_MIN_PIN), "W_MIN_PIN is not interrupt-capable");
pciSetup(W_MIN_PIN);
#endif
#endif
#if HAS_X2_MAX
#if (digitalPinToInterrupt(X2_MAX_PIN) != NOT_AN_INTERRUPT)
_ATTACH(X2_MAX_PIN);

View File

@ -70,4 +70,10 @@ void setup_endstop_interrupts() {
TERN_(HAS_J_MIN, _ATTACH(J_MIN_PIN));
TERN_(HAS_K_MAX, _ATTACH(K_MAX_PIN));
TERN_(HAS_K_MIN, _ATTACH(K_MIN_PIN));
TERN_(HAS_U_MAX, _ATTACH(U_MAX_PIN));
TERN_(HAS_U_MIN, _ATTACH(U_MIN_PIN));
TERN_(HAS_V_MAX, _ATTACH(V_MAX_PIN));
TERN_(HAS_V_MIN, _ATTACH(V_MIN_PIN));
TERN_(HAS_W_MAX, _ATTACH(W_MAX_PIN));
TERN_(HAS_W_MIN, _ATTACH(W_MIN_PIN));
}

View File

@ -65,4 +65,10 @@ void setup_endstop_interrupts() {
TERN_(HAS_J_MIN, _ATTACH(J_MIN_PIN));
TERN_(HAS_K_MAX, _ATTACH(K_MAX_PIN));
TERN_(HAS_K_MIN, _ATTACH(K_MIN_PIN));
TERN_(HAS_U_MAX, _ATTACH(U_MAX_PIN));
TERN_(HAS_U_MIN, _ATTACH(U_MIN_PIN));
TERN_(HAS_V_MAX, _ATTACH(V_MAX_PIN));
TERN_(HAS_V_MIN, _ATTACH(V_MIN_PIN));
TERN_(HAS_W_MAX, _ATTACH(W_MAX_PIN));
TERN_(HAS_W_MIN, _ATTACH(W_MIN_PIN));
}

View File

@ -155,4 +155,37 @@ void setup_endstop_interrupts() {
#endif
_ATTACH(K_MIN_PIN);
#endif
#if HAS_U_MAX
#if !LPC1768_PIN_INTERRUPT_M(U_MAX_PIN)
#error "U_MAX_PIN is not INTERRUPT-capable."
#endif
_ATTACH(U_MAX_PIN);
#elif HAS_U_MIN
#if !LPC1768_PIN_INTERRUPT_M(U_MIN_PIN)
#error "U_MIN_PIN is not INTERRUPT-capable."
#endif
_ATTACH(U_MIN_PIN);
#endif
#if HAS_V_MAX
#if !LPC1768_PIN_INTERRUPT_M(V_MAX_PIN)
#error "V_MAX_PIN is not INTERRUPT-capable."
#endif
_ATTACH(V_MAX_PIN);
#elif HAS_V_MIN
#if !LPC1768_PIN_INTERRUPT_M(V_MIN_PIN)
#error "V_MIN_PIN is not INTERRUPT-capable."
#endif
_ATTACH(V_MIN_PIN);
#endif
#if HAS_W_MAX
#if !LPC1768_PIN_INTERRUPT_M(W_MAX_PIN)
#error "W_MAX_PIN is not INTERRUPT-capable."
#endif
_ATTACH(W_MAX_PIN);
#elif HAS_W_MIN
#if !LPC1768_PIN_INTERRUPT_M(W_MIN_PIN)
#error "W_MIN_PIN is not INTERRUPT-capable."
#endif
_ATTACH(W_MIN_PIN);
#endif
}

View File

@ -60,6 +60,12 @@
#define MATCH_J_MIN_EILINE(P) TERN0(HAS_J_MIN, DEFER4(MATCH_EILINE)(P, J_MIN_PIN))
#define MATCH_K_MAX_EILINE(P) TERN0(HAS_K_MAX, DEFER4(MATCH_EILINE)(P, K_MAX_PIN))
#define MATCH_K_MIN_EILINE(P) TERN0(HAS_K_MIN, DEFER4(MATCH_EILINE)(P, K_MIN_PIN))
#define MATCH_U_MAX_EILINE(P) TERN0(HAS_U_MAX, DEFER4(MATCH_EILINE)(P, U_MAX_PIN))
#define MATCH_U_MIN_EILINE(P) TERN0(HAS_U_MIN, DEFER4(MATCH_EILINE)(P, U_MIN_PIN))
#define MATCH_V_MAX_EILINE(P) TERN0(HAS_V_MAX, DEFER4(MATCH_EILINE)(P, V_MAX_PIN))
#define MATCH_V_MIN_EILINE(P) TERN0(HAS_V_MIN, DEFER4(MATCH_EILINE)(P, V_MIN_PIN))
#define MATCH_W_MAX_EILINE(P) TERN0(HAS_W_MAX, DEFER4(MATCH_EILINE)(P, W_MAX_PIN))
#define MATCH_W_MIN_EILINE(P) TERN0(HAS_W_MIN, DEFER4(MATCH_EILINE)(P, W_MIN_PIN))
#define MATCH_Z2_MAX_EILINE(P) TERN0(HAS_Z2_MAX, DEFER4(MATCH_EILINE)(P, Z2_MAX_PIN))
#define MATCH_Z2_MIN_EILINE(P) TERN0(HAS_Z2_MIN, DEFER4(MATCH_EILINE)(P, Z2_MIN_PIN))
#define MATCH_Z3_MAX_EILINE(P) TERN0(HAS_Z3_MAX, DEFER4(MATCH_EILINE)(P, Z3_MAX_PIN))
@ -75,6 +81,9 @@
&& !MATCH_I_MAX_EILINE(P) && !MATCH_I_MIN_EILINE(P) \
&& !MATCH_J_MAX_EILINE(P) && !MATCH_J_MIN_EILINE(P) \
&& !MATCH_K_MAX_EILINE(P) && !MATCH_K_MIN_EILINE(P) \
&& !MATCH_U_MAX_EILINE(P) && !MATCH_U_MIN_EILINE(P) \
&& !MATCH_V_MAX_EILINE(P) && !MATCH_V_MIN_EILINE(P) \
&& !MATCH_W_MAX_EILINE(P) && !MATCH_W_MIN_EILINE(P) \
&& !MATCH_Z2_MAX_EILINE(P) && !MATCH_Z2_MIN_EILINE(P) \
&& !MATCH_Z3_MAX_EILINE(P) && !MATCH_Z3_MIN_EILINE(P) \
&& !MATCH_Z4_MAX_EILINE(P) && !MATCH_Z4_MIN_EILINE(P) \
@ -199,4 +208,40 @@ void setup_endstop_interrupts() {
#endif
attachInterrupt(K_MIN_PIN, endstop_ISR, CHANGE);
#endif
#if HAS_U_MAX
#if !AVAILABLE_EILINE(U_MAX_PIN)
#error "U_MAX_PIN has no EXTINT line available."
#endif
attachInterrupt(U_MAX_PIN, endstop_ISR, CHANGE);
#endif
#if HAS_U_MIN
#if !AVAILABLE_EILINE(U_MIN_PIN)
#error "U_MIN_PIN has no EXTINT line available."
#endif
attachInterrupt(U_MIN_PIN, endstop_ISR, CHANGE);
#endif
#if HAS_V_MAX
#if !AVAILABLE_EILINE(V_MAX_PIN)
#error "V_MAX_PIN has no EXTINT line available."
#endif
attachInterrupt(V_MAX_PIN, endstop_ISR, CHANGE);
#endif
#if HAS_V_MIN
#if !AVAILABLE_EILINE(V_MIN_PIN)
#error "V_MIN_PIN has no EXTINT line available."
#endif
attachInterrupt(V_MIN_PIN, endstop_ISR, CHANGE);
#endif
#if HAS_W_MAX
#if !AVAILABLE_EILINE(W_MAX_PIN)
#error "W_MAX_PIN has no EXTINT line available."
#endif
attachInterrupt(W_MAX_PIN, endstop_ISR, CHANGE);
#endif
#if HAS_W_MIN
#if !AVAILABLE_EILINE(W_MIN_PIN)
#error "W_MIN_PIN has no EXTINT line available."
#endif
attachInterrupt(W_MIN_PIN, endstop_ISR, CHANGE);
#endif
}

View File

@ -52,4 +52,10 @@ void setup_endstop_interrupts() {
TERN_(HAS_J_MIN, _ATTACH(J_MIN_PIN));
TERN_(HAS_K_MAX, _ATTACH(K_MAX_PIN));
TERN_(HAS_K_MIN, _ATTACH(K_MIN_PIN));
TERN_(HAS_U_MAX, _ATTACH(U_MAX_PIN));
TERN_(HAS_U_MIN, _ATTACH(U_MIN_PIN));
TERN_(HAS_V_MAX, _ATTACH(V_MAX_PIN));
TERN_(HAS_V_MIN, _ATTACH(V_MIN_PIN));
TERN_(HAS_W_MAX, _ATTACH(W_MAX_PIN));
TERN_(HAS_W_MIN, _ATTACH(W_MIN_PIN));
}

View File

@ -77,4 +77,10 @@ void setup_endstop_interrupts() {
TERN_(HAS_J_MIN, _ATTACH(J_MIN_PIN));
TERN_(HAS_K_MAX, _ATTACH(K_MAX_PIN));
TERN_(HAS_K_MIN, _ATTACH(K_MIN_PIN));
TERN_(HAS_U_MAX, _ATTACH(U_MAX_PIN));
TERN_(HAS_U_MIN, _ATTACH(U_MIN_PIN));
TERN_(HAS_V_MAX, _ATTACH(V_MAX_PIN));
TERN_(HAS_V_MIN, _ATTACH(V_MIN_PIN));
TERN_(HAS_W_MAX, _ATTACH(W_MAX_PIN));
TERN_(HAS_W_MIN, _ATTACH(W_MIN_PIN));
}

View File

@ -70,4 +70,10 @@ void setup_endstop_interrupts() {
TERN_(HAS_J_MIN, _ATTACH(J_MIN_PIN));
TERN_(HAS_K_MAX, _ATTACH(K_MAX_PIN));
TERN_(HAS_K_MIN, _ATTACH(K_MIN_PIN));
TERN_(HAS_U_MAX, _ATTACH(U_MAX_PIN));
TERN_(HAS_U_MIN, _ATTACH(U_MIN_PIN));
TERN_(HAS_V_MAX, _ATTACH(V_MAX_PIN));
TERN_(HAS_V_MIN, _ATTACH(V_MIN_PIN));
TERN_(HAS_W_MAX, _ATTACH(W_MAX_PIN));
TERN_(HAS_W_MIN, _ATTACH(W_MIN_PIN));
}

View File

@ -69,4 +69,10 @@ void setup_endstop_interrupts() {
TERN_(HAS_J_MIN, _ATTACH(J_MIN_PIN));
TERN_(HAS_K_MAX, _ATTACH(K_MAX_PIN));
TERN_(HAS_K_MIN, _ATTACH(K_MIN_PIN));
TERN_(HAS_U_MAX, _ATTACH(U_MAX_PIN));
TERN_(HAS_U_MIN, _ATTACH(U_MIN_PIN));
TERN_(HAS_V_MAX, _ATTACH(V_MAX_PIN));
TERN_(HAS_V_MIN, _ATTACH(V_MIN_PIN));
TERN_(HAS_W_MAX, _ATTACH(W_MAX_PIN));
TERN_(HAS_W_MIN, _ATTACH(W_MIN_PIN));
}

View File

@ -443,6 +443,9 @@ inline void manage_inactivity(const bool no_stepper_sleep=false) {
TERN_(DISABLE_INACTIVE_I, stepper.disable_axis(I_AXIS));
TERN_(DISABLE_INACTIVE_J, stepper.disable_axis(J_AXIS));
TERN_(DISABLE_INACTIVE_K, stepper.disable_axis(K_AXIS));
TERN_(DISABLE_INACTIVE_U, stepper.disable_axis(U_AXIS));
TERN_(DISABLE_INACTIVE_V, stepper.disable_axis(V_AXIS));
TERN_(DISABLE_INACTIVE_W, stepper.disable_axis(W_AXIS));
TERN_(DISABLE_INACTIVE_E, stepper.disable_e_steppers());
TERN_(AUTO_BED_LEVELING_UBL, bedlevel.steppers_were_disabled());
@ -1003,6 +1006,15 @@ inline void tmc_standby_setup() {
#if PIN_EXISTS(K_STDBY)
SET_INPUT_PULLDOWN(K_STDBY_PIN);
#endif
#if PIN_EXISTS(U_STDBY)
SET_INPUT_PULLDOWN(U_STDBY_PIN);
#endif
#if PIN_EXISTS(V_STDBY)
SET_INPUT_PULLDOWN(V_STDBY_PIN);
#endif
#if PIN_EXISTS(W_STDBY)
SET_INPUT_PULLDOWN(W_STDBY_PIN);
#endif
#if PIN_EXISTS(E0_STDBY)
SET_INPUT_PULLDOWN(E0_STDBY_PIN);
#endif

View File

@ -63,6 +63,9 @@
#define AXIS_DRIVER_TYPE_I(T) _AXIS_DRIVER_TYPE(I,T)
#define AXIS_DRIVER_TYPE_J(T) _AXIS_DRIVER_TYPE(J,T)
#define AXIS_DRIVER_TYPE_K(T) _AXIS_DRIVER_TYPE(K,T)
#define AXIS_DRIVER_TYPE_U(T) _AXIS_DRIVER_TYPE(U,T)
#define AXIS_DRIVER_TYPE_V(T) _AXIS_DRIVER_TYPE(V,T)
#define AXIS_DRIVER_TYPE_W(T) _AXIS_DRIVER_TYPE(W,T)
#define AXIS_DRIVER_TYPE_X2(T) (HAS_X2_STEPPER && _AXIS_DRIVER_TYPE(X2,T))
#define AXIS_DRIVER_TYPE_Y2(T) (HAS_DUAL_Y_STEPPERS && _AXIS_DRIVER_TYPE(Y2,T))
@ -87,6 +90,7 @@
#define HAS_DRIVER(T) ( AXIS_DRIVER_TYPE_X(T) || AXIS_DRIVER_TYPE_Y(T) || AXIS_DRIVER_TYPE_Z(T) \
|| AXIS_DRIVER_TYPE_I(T) || AXIS_DRIVER_TYPE_J(T) || AXIS_DRIVER_TYPE_K(T) \
|| AXIS_DRIVER_TYPE_U(T) || AXIS_DRIVER_TYPE_V(T) || AXIS_DRIVER_TYPE_W(T) \
|| AXIS_DRIVER_TYPE_X2(T) || AXIS_DRIVER_TYPE_Y2(T) || AXIS_DRIVER_TYPE_Z2(T) \
|| AXIS_DRIVER_TYPE_Z3(T) || AXIS_DRIVER_TYPE_Z4(T) || HAS_E_DRIVER(T) )
@ -161,6 +165,7 @@
|| AXIS_HAS_##T(Y) || AXIS_HAS_##T(Y2) \
|| AXIS_HAS_##T(Z) || AXIS_HAS_##T(Z2) || AXIS_HAS_##T(Z3) || AXIS_HAS_##T(Z4) \
|| AXIS_HAS_##T(I) || AXIS_HAS_##T(J) || AXIS_HAS_##T(K) \
|| AXIS_HAS_##T(U) || AXIS_HAS_##T(V) || AXIS_HAS_##T(W) \
|| E_AXIS_HAS(T) )
#if ANY_AXIS_HAS(STEALTHCHOP)

View File

@ -457,6 +457,54 @@
#define STR_K ""
#endif
#if HAS_U_AXIS
#if AXIS7_NAME == 'U'
#define STR_U "U"
#define STR_U_MIN "u_min"
#define STR_U_MAX "u_max"
#elif AXIS7_NAME == 'V'
#define STR_U "V"
#define STR_U_MIN "v_min"
#define STR_U_MAX "v_max"
#elif AXIS7_NAME == 'W'
#define STR_U "W"
#define STR_U_MIN "w_min"
#define STR_U_MAX "w_max"
#else
#error "AXIS7_NAME can only be one of 'U', 'V', or 'W'."
#endif
#else
#define STR_U ""
#endif
#if HAS_V_AXIS
#if AXIS8_NAME == 'V'
#define STR_V "V"
#define STR_V_MIN "v_min"
#define STR_V_MAX "v_max"
#elif AXIS8_NAME == 'W'
#define STR_V "W"
#define STR_V_MIN "w_min"
#define STR_V_MAX "w_max"
#else
#error "AXIS8_NAME can only be one of 'V', or 'W'."
#endif
#else
#define STR_V ""
#endif
#if HAS_W_AXIS
#if AXIS9_NAME == 'W'
#define STR_W "W"
#define STR_W_MIN "w_min"
#define STR_W_MAX "w_max"
#else
#error "AXIS9_NAME can only be 'W'."
#endif
#else
#define STR_W ""
#endif
#if EITHER(HAS_MARLINUI_HD44780, IS_TFTGLCD_PANEL)
// Custom characters defined in the first 8 characters of the LCD

View File

@ -39,24 +39,36 @@
#define _ISTOP_ 0x04
#define _JSTOP_ 0x05
#define _KSTOP_ 0x06
#define _USTOP_ 0x07
#define _VSTOP_ 0x08
#define _WSTOP_ 0x09
#define _XMIN_ 0x11
#define _YMIN_ 0x12
#define _ZMIN_ 0x13
#define _IMIN_ 0x14
#define _JMIN_ 0x15
#define _KMIN_ 0x16
#define _UMIN_ 0x17
#define _VMIN_ 0x18
#define _WMIN_ 0x19
#define _XMAX_ 0x21
#define _YMAX_ 0x22
#define _ZMAX_ 0x23
#define _IMAX_ 0x24
#define _JMAX_ 0x25
#define _KMAX_ 0x26
#define _UMAX_ 0x27
#define _VMAX_ 0x28
#define _WMAX_ 0x29
#define _XDIAG_ 0x31
#define _YDIAG_ 0x32
#define _ZDIAG_ 0x33
#define _IDIAG_ 0x34
#define _JDIAG_ 0x35
#define _KDIAG_ 0x36
#define _UDIAG_ 0x37
#define _VDIAG_ 0x38
#define _WDIAG_ 0x39
#define _E0DIAG_ 0xE0
#define _E1DIAG_ 0xE1
#define _E2DIAG_ 0xE2
@ -350,7 +362,7 @@
#define _LIST_N(N,V...) LIST_##N(V)
#define LIST_N(N,V...) _LIST_N(N,V)
#define LIST_N_1(N,K) _LIST_N(N,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K)
#define LIST_N_1(N,K) _LIST_N(N,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K)
#define ARRAY_N(N,V...) { _LIST_N(N,V) }
#define ARRAY_N_1(N,K) { LIST_N_1(N,K) }

View File

@ -32,14 +32,18 @@ uint8_t marlin_debug_flags = MARLIN_DEBUG_NONE;
// Commonly-used strings in serial output
PGMSTR(NUL_STR, ""); PGMSTR(SP_P_STR, " P"); PGMSTR(SP_T_STR, " T");
PGMSTR(X_STR, "X"); PGMSTR(Y_STR, "Y"); PGMSTR(Z_STR, "Z"); PGMSTR(E_STR, "E");
PGMSTR(U_STR, STR_U); PGMSTR(V_STR, STR_V); PGMSTR(W_STR, STR_W);
PGMSTR(X_LBL, "X:"); PGMSTR(Y_LBL, "Y:"); PGMSTR(Z_LBL, "Z:"); PGMSTR(E_LBL, "E:");
PGMSTR(U_LBL, STR_U ":"); PGMSTR(V_LBL, STR_V ":"); PGMSTR(W_LBL, STR_W ":");
PGMSTR(SP_A_STR, " A"); PGMSTR(SP_B_STR, " B"); PGMSTR(SP_C_STR, " C");
PGMSTR(SP_X_STR, " X"); PGMSTR(SP_Y_STR, " Y"); PGMSTR(SP_Z_STR, " Z"); PGMSTR(SP_E_STR, " E");
PGMSTR(SP_X_LBL, " X:"); PGMSTR(SP_Y_LBL, " Y:"); PGMSTR(SP_Z_LBL, " Z:"); PGMSTR(SP_E_LBL, " E:");
PGMSTR(I_STR, STR_I); PGMSTR(J_STR, STR_J); PGMSTR(K_STR, STR_K);
PGMSTR(I_LBL, STR_I ":"); PGMSTR(J_LBL, STR_J ":"); PGMSTR(K_LBL, STR_K ":");
PGMSTR(SP_I_STR, " " STR_I); PGMSTR(SP_J_STR, " " STR_J); PGMSTR(SP_K_STR, " " STR_K);
PGMSTR(SP_U_STR, " " STR_U); PGMSTR(SP_V_STR, " " STR_V); PGMSTR(SP_W_STR, " " STR_W);
PGMSTR(SP_I_LBL, " " STR_I ":"); PGMSTR(SP_J_LBL, " " STR_J ":"); PGMSTR(SP_K_LBL, " " STR_K ":");
PGMSTR(SP_U_LBL, " " STR_U ":"); PGMSTR(SP_V_LBL, " " STR_V ":"); PGMSTR(SP_W_LBL, " " STR_W ":");
// Hook Meatpack if it's enabled on the first leaf
#if ENABLED(MEATPACK_ON_SERIAL_PORT_1)
@ -102,10 +106,10 @@ void print_bin(uint16_t val) {
}
}
void print_pos(LINEAR_AXIS_ARGS(const_float_t), FSTR_P const prefix/*=nullptr*/, FSTR_P const suffix/*=nullptr*/) {
void print_pos(NUM_AXIS_ARGS(const_float_t), FSTR_P const prefix/*=nullptr*/, FSTR_P const suffix/*=nullptr*/) {
if (prefix) serial_print(prefix);
SERIAL_ECHOPGM_P(
LIST_N(DOUBLE(LINEAR_AXES), SP_X_STR, x, SP_Y_STR, y, SP_Z_STR, z, SP_I_STR, i, SP_J_STR, j, SP_K_STR, k)
LIST_N(DOUBLE(NUM_AXES), SP_X_STR, x, SP_Y_STR, y, SP_Z_STR, z, SP_I_STR, i, SP_J_STR, j, SP_K_STR, k, SP_U_STR, u, SP_V_STR, v, SP_W_STR, w)
);
if (suffix) serial_print(suffix); else SERIAL_EOL();
}

View File

@ -29,17 +29,12 @@
#endif
// Commonly-used strings in serial output
extern const char NUL_STR[],
SP_X_STR[], SP_Y_STR[], SP_Z_STR[],
SP_A_STR[], SP_B_STR[], SP_C_STR[], SP_E_STR[],
SP_X_LBL[], SP_Y_LBL[], SP_Z_LBL[], SP_E_LBL[],
SP_I_STR[], SP_J_STR[], SP_K_STR[],
SP_I_LBL[], SP_J_LBL[], SP_K_LBL[],
SP_P_STR[], SP_T_STR[],
X_STR[], Y_STR[], Z_STR[], E_STR[],
I_STR[], J_STR[], K_STR[],
X_LBL[], Y_LBL[], Z_LBL[], E_LBL[],
I_LBL[], J_LBL[], K_LBL[];
extern const char NUL_STR[], SP_P_STR[], SP_T_STR[],
SP_A_STR[], SP_B_STR[], SP_C_STR[],
SP_X_STR[], SP_Y_STR[], SP_Z_STR[], SP_I_STR[], SP_J_STR[], SP_K_STR[], SP_U_STR[], SP_V_STR[], SP_W_STR[], SP_E_STR[],
SP_X_LBL[], SP_Y_LBL[], SP_Z_LBL[], SP_I_LBL[], SP_J_LBL[], SP_K_LBL[], SP_U_LBL[], SP_V_LBL[], SP_W_LBL[], SP_E_LBL[],
X_STR[], Y_STR[], Z_STR[], I_STR[], J_STR[], K_STR[], U_STR[], V_STR[], W_STR[], E_STR[],
X_LBL[], Y_LBL[], Z_LBL[], I_LBL[], J_LBL[], K_LBL[], U_LBL[], V_LBL[], W_LBL[], E_LBL[];
//
// Debugging flags for use by M111
@ -348,10 +343,10 @@ void serial_spaces(uint8_t count);
void serial_offset(const_float_t v, const uint8_t sp=0); // For v==0 draw space (sp==1) or plus (sp==2)
void print_bin(const uint16_t val);
void print_pos(LINEAR_AXIS_ARGS(const_float_t), FSTR_P const prefix=nullptr, FSTR_P const suffix=nullptr);
void print_pos(NUM_AXIS_ARGS(const_float_t), FSTR_P const prefix=nullptr, FSTR_P const suffix=nullptr);
inline void print_pos(const xyz_pos_t &xyz, FSTR_P const prefix=nullptr, FSTR_P const suffix=nullptr) {
print_pos(LINEAR_AXIS_ELEM(xyz), prefix, suffix);
print_pos(NUM_AXIS_ELEM(xyz), prefix, suffix);
}
#define SERIAL_POS(SUFFIX,VAR) do { print_pos(VAR, F(" " STRINGIFY(VAR) "="), F(" : " SUFFIX "\n")); }while(0)

View File

@ -36,23 +36,33 @@ struct IF { typedef R type; };
template <class L, class R>
struct IF<true, L, R> { typedef L type; };
#define LINEAR_AXIS_GANG(V...) GANG_N(LINEAR_AXES, V)
#define LINEAR_AXIS_CODE(V...) CODE_N(LINEAR_AXES, V)
#define LINEAR_AXIS_LIST(V...) LIST_N(LINEAR_AXES, V)
#define LINEAR_AXIS_ARRAY(V...) { LINEAR_AXIS_LIST(V) }
#define LINEAR_AXIS_ARGS(T...) LINEAR_AXIS_LIST(T x, T y, T z, T i, T j, T k)
#define LINEAR_AXIS_ELEM(O) LINEAR_AXIS_LIST(O.x, O.y, O.z, O.i, O.j, O.k)
#define LINEAR_AXIS_DEFS(T,V) LINEAR_AXIS_LIST(T x=V, T y=V, T z=V, T i=V, T j=V, T k=V)
#define NUM_AXIS_GANG(V...) GANG_N(NUM_AXES, V)
#define NUM_AXIS_CODE(V...) CODE_N(NUM_AXES, V)
#define NUM_AXIS_LIST(V...) LIST_N(NUM_AXES, V)
#define NUM_AXIS_ARRAY(V...) { NUM_AXIS_LIST(V) }
#define NUM_AXIS_ARGS(T...) NUM_AXIS_LIST(T x, T y, T z, T i, T j, T k, T u, T v, T w)
#define NUM_AXIS_ELEM(O) NUM_AXIS_LIST(O.x, O.y, O.z, O.i, O.j, O.k, O.u, O.v, O.w)
#define NUM_AXIS_DEFS(T,V) NUM_AXIS_LIST(T x=V, T y=V, T z=V, T i=V, T j=V, T k=V, T u=V, T v=V, T w=V)
#define LOGICAL_AXIS_GANG(E,V...) LINEAR_AXIS_GANG(V) GANG_ITEM_E(E)
#define LOGICAL_AXIS_CODE(E,V...) LINEAR_AXIS_CODE(V) CODE_ITEM_E(E)
#define LOGICAL_AXIS_LIST(E,V...) LINEAR_AXIS_LIST(V) LIST_ITEM_E(E)
#define LOGICAL_AXIS_GANG(E,V...) NUM_AXIS_GANG(V) GANG_ITEM_E(E)
#define LOGICAL_AXIS_CODE(E,V...) NUM_AXIS_CODE(V) CODE_ITEM_E(E)
#define LOGICAL_AXIS_LIST(E,V...) NUM_AXIS_LIST(V) LIST_ITEM_E(E)
#define LOGICAL_AXIS_ARRAY(E,V...) { LOGICAL_AXIS_LIST(E,V) }
#define LOGICAL_AXIS_ARGS(T...) LOGICAL_AXIS_LIST(T e, T x, T y, T z, T i, T j, T k)
#define LOGICAL_AXIS_ELEM(O) LOGICAL_AXIS_LIST(O.e, O.x, O.y, O.z, O.i, O.j, O.k)
#define LOGICAL_AXIS_DECL(T,V) LOGICAL_AXIS_LIST(T e=V, T x=V, T y=V, T z=V, T i=V, T j=V, T k=V)
#define LOGICAL_AXIS_ARGS(T...) LOGICAL_AXIS_LIST(T e, T x, T y, T z, T i, T j, T k, T u, T v, T w)
#define LOGICAL_AXIS_ELEM(O) LOGICAL_AXIS_LIST(O.e, O.x, O.y, O.z, O.i, O.j, O.k, O.u, O.v, O.w)
#define LOGICAL_AXIS_DECL(T,V) LOGICAL_AXIS_LIST(T e=V, T x=V, T y=V, T z=V, T i=V, T j=V, T k=V, T u=V, T v=V, T w=V)
#define LOGICAL_AXES_STRING LOGICAL_AXIS_GANG("E", "X", "Y", "Z", STR_I, STR_J, STR_K)
#define LOGICAL_AXES_STRING LOGICAL_AXIS_GANG("E", "X", "Y", "Z", STR_I, STR_J, STR_K, STR_U, STR_V, STR_W)
#define XYZ_GANG(V...) GANG_N(PRIMARY_LINEAR_AXES, V)
#define XYZ_CODE(V...) CODE_N(PRIMARY_LINEAR_AXES, V)
#define SECONDARY_AXIS_GANG(V...) GANG_N(SECONDARY_AXES, V)
#define SECONDARY_AXIS_CODE(V...) CODE_N(SECONDARY_AXES, V)
#if HAS_ROTATIONAL_AXES
#define ROTATIONAL_AXIS_GANG(V...) GANG_N(ROTATIONAL_AXES, V)
#endif
#if HAS_EXTRUDERS
#define LIST_ITEM_E(N) , N
@ -64,7 +74,7 @@ struct IF<true, L, R> { typedef L type; };
#define GANG_ITEM_E(N)
#endif
#define AXIS_COLLISION(L) (AXIS4_NAME == L || AXIS5_NAME == L || AXIS6_NAME == L)
#define AXIS_COLLISION(L) (AXIS4_NAME == L || AXIS5_NAME == L || AXIS6_NAME == L || AXIS7_NAME == L || AXIS8_NAME == L || AXIS9_NAME == L)
// General Flags for some number of states
template<size_t N>
@ -129,7 +139,7 @@ typedef struct AxisFlags {
enum AxisEnum : uint8_t {
// Linear axes may be controlled directly or indirectly
LINEAR_AXIS_LIST(X_AXIS, Y_AXIS, Z_AXIS, I_AXIS, J_AXIS, K_AXIS)
NUM_AXIS_LIST(X_AXIS, Y_AXIS, Z_AXIS, I_AXIS, J_AXIS, K_AXIS, U_AXIS, V_AXIS, W_AXIS)
// Extruder axes may be considered distinctly
#define _EN_ITEM(N) , E##N##_AXIS
@ -163,12 +173,13 @@ enum AxisEnum : uint8_t {
};
typedef IF<(NUM_AXIS_ENUMS > 8), uint16_t, uint8_t>::type axis_bits_t;
typedef IF<(NUM_AXES > 8), uint16_t, uint8_t>::type linear_axis_bits_t;
//
// Loop over axes
//
#define LOOP_ABC(VAR) LOOP_S_LE_N(VAR, A_AXIS, C_AXIS)
#define LOOP_LINEAR_AXES(VAR) LOOP_S_L_N(VAR, X_AXIS, LINEAR_AXES)
#define LOOP_NUM_AXES(VAR) LOOP_S_L_N(VAR, X_AXIS, NUM_AXES)
#define LOOP_LOGICAL_AXES(VAR) LOOP_S_L_N(VAR, X_AXIS, LOGICAL_AXES)
#define LOOP_DISTINCT_AXES(VAR) LOOP_S_L_N(VAR, X_AXIS, DISTINCT_AXES)
#define LOOP_DISTINCT_E(VAR) LOOP_L_N(VAR, DISTINCT_E)
@ -313,10 +324,10 @@ struct XYval {
FI void set(const T px, const T py) { x = px; y = py; }
FI void set(const T (&arr)[XY]) { x = arr[0]; y = arr[1]; }
#endif
#if LINEAR_AXES > XY
FI void set(const T (&arr)[LINEAR_AXES]) { x = arr[0]; y = arr[1]; }
#if NUM_AXES > XY
FI void set(const T (&arr)[NUM_AXES]) { x = arr[0]; y = arr[1]; }
#endif
#if LOGICAL_AXES > LINEAR_AXES
#if LOGICAL_AXES > NUM_AXES
FI void set(const T (&arr)[LOGICAL_AXES]) { x = arr[0]; y = arr[1]; }
#if DISTINCT_AXES > LOGICAL_AXES
FI void set(const T (&arr)[DISTINCT_AXES]) { x = arr[0]; y = arr[1]; }
@ -438,29 +449,29 @@ struct XYval {
template<typename T>
struct XYZval {
union {
struct { T LINEAR_AXIS_ARGS(); };
struct { T LINEAR_AXIS_LIST(a, b, c, u, v, w); };
T pos[LINEAR_AXES];
struct { T NUM_AXIS_ARGS(); };
struct { T NUM_AXIS_LIST(a, b, c, _i, _j, _k, _u, _v, _w); };
T pos[NUM_AXES];
};
// Set all to 0
FI void reset() { LINEAR_AXIS_GANG(x =, y =, z =, i =, j =, k =) 0; }
FI void reset() { NUM_AXIS_GANG(x =, y =, z =, i =, j =, k =, u =, v =, w =) 0; }
// Setters taking struct types and arrays
FI void set(const T px) { x = px; }
FI void set(const T px, const T py) { x = px; y = py; }
FI void set(const XYval<T> pxy) { x = pxy.x; y = pxy.y; }
FI void set(const XYval<T> pxy, const T pz) { LINEAR_AXIS_CODE(x = pxy.x, y = pxy.y, z = pz, NOOP, NOOP, NOOP); }
FI void set(const XYval<T> pxy, const T pz) { NUM_AXIS_CODE(x = pxy.x, y = pxy.y, z = pz, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP); }
FI void set(const T (&arr)[XY]) { x = arr[0]; y = arr[1]; }
#if HAS_Z_AXIS
FI void set(const T (&arr)[LINEAR_AXES]) { LINEAR_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5]); }
FI void set(LINEAR_AXIS_ARGS(const T)) { LINEAR_AXIS_CODE(a = x, b = y, c = z, u = i, v = j, w = k ); }
FI void set(const T (&arr)[NUM_AXES]) { NUM_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5], u = arr[6], v = arr[7], w = arr[8]); }
FI void set(NUM_AXIS_ARGS(const T)) { NUM_AXIS_CODE(a = x, b = y, c = z, _i = i, _j = j, _k = k, _u = u, _v = v, _w = w ); }
#endif
#if LOGICAL_AXES > LINEAR_AXES
FI void set(const T (&arr)[LOGICAL_AXES]) { LINEAR_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5]); }
FI void set(LOGICAL_AXIS_ARGS(const T)) { LINEAR_AXIS_CODE(a = x, b = y, c = z, u = i, v = j, w = k ); }
#if LOGICAL_AXES > NUM_AXES
FI void set(const T (&arr)[LOGICAL_AXES]) { NUM_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5], u = arr[6], v = arr[7], w = arr[8]); }
FI void set(LOGICAL_AXIS_ARGS(const T)) { NUM_AXIS_CODE(a = x, b = y, c = z, _i = i, _j = j, _k = k, _u = u, _v = v, _w = w ); }
#if DISTINCT_AXES > LOGICAL_AXES
FI void set(const T (&arr)[DISTINCT_AXES]) { LINEAR_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5]); }
FI void set(const T (&arr)[DISTINCT_AXES]) { NUM_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5], u = arr[6], v = arr[7], w = arr[8]); }
#endif
#endif
#if HAS_I_AXIS
@ -472,26 +483,35 @@ struct XYZval {
#if HAS_K_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj) { x = px; y = py; z = pz; i = pi; j = pj; }
#endif
#if HAS_U_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; }
#endif
#if HAS_V_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk, const T pm) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; u = pu; }
#endif
#if HAS_W_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk, const T pm, const T po) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; u = pu; v = pv; }
#endif
// Length reduced to one dimension
FI T magnitude() const { return (T)sqrtf(LINEAR_AXIS_GANG(x*x, + y*y, + z*z, + i*i, + j*j, + k*k)); }
FI T magnitude() const { return (T)sqrtf(NUM_AXIS_GANG(x*x, + y*y, + z*z, + i*i, + j*j, + k*k, + u*u, + v*v, + w*w)); }
// Pointer to the data as a simple array
FI operator T* () { return pos; }
// If any element is true then it's true
FI operator bool() { return LINEAR_AXIS_GANG(x, || y, || z, || i, || j, || k); }
FI operator bool() { return NUM_AXIS_GANG(x, || y, || z, || i, || j, || k, || u, || v, || w); }
// Explicit copy and copies with conversion
FI XYZval<T> copy() const { XYZval<T> o = *this; return o; }
FI XYZval<T> ABS() const { return LINEAR_AXIS_ARRAY(T(_ABS(x)), T(_ABS(y)), T(_ABS(z)), T(_ABS(i)), T(_ABS(j)), T(_ABS(k))); }
FI XYZval<int16_t> asInt() { return LINEAR_AXIS_ARRAY(int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k)); }
FI XYZval<int16_t> asInt() const { return LINEAR_AXIS_ARRAY(int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k)); }
FI XYZval<int32_t> asLong() { return LINEAR_AXIS_ARRAY(int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k)); }
FI XYZval<int32_t> asLong() const { return LINEAR_AXIS_ARRAY(int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k)); }
FI XYZval<int32_t> ROUNDL() { return LINEAR_AXIS_ARRAY(int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k))); }
FI XYZval<int32_t> ROUNDL() const { return LINEAR_AXIS_ARRAY(int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k))); }
FI XYZval<float> asFloat() { return LINEAR_AXIS_ARRAY(static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k)); }
FI XYZval<float> asFloat() const { return LINEAR_AXIS_ARRAY(static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k)); }
FI XYZval<float> reciprocal() const { return LINEAR_AXIS_ARRAY(_RECIP(x), _RECIP(y), _RECIP(z), _RECIP(i), _RECIP(j), _RECIP(k)); }
FI XYZval<T> ABS() const { return NUM_AXIS_ARRAY(T(_ABS(x)), T(_ABS(y)), T(_ABS(z)), T(_ABS(i)), T(_ABS(j)), T(_ABS(k)), T(_ABS(u)), T(_ABS(v)), T(_ABS(w))); }
FI XYZval<int16_t> asInt() { return NUM_AXIS_ARRAY(int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k), int16_t(u), int16_t(v), int16_t(w)); }
FI XYZval<int16_t> asInt() const { return NUM_AXIS_ARRAY(int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k), int16_t(u), int16_t(v), int16_t(w)); }
FI XYZval<int32_t> asLong() { return NUM_AXIS_ARRAY(int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k), int32_t(u), int32_t(v), int32_t(w)); }
FI XYZval<int32_t> asLong() const { return NUM_AXIS_ARRAY(int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k), int32_t(u), int32_t(v), int32_t(w)); }
FI XYZval<int32_t> ROUNDL() { return NUM_AXIS_ARRAY(int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k)), int32_t(LROUND(u)), int32_t(LROUND(v)), int32_t(LROUND(w))); }
FI XYZval<int32_t> ROUNDL() const { return NUM_AXIS_ARRAY(int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k)), int32_t(LROUND(u)), int32_t(LROUND(v)), int32_t(LROUND(w))); }
FI XYZval<float> asFloat() { return NUM_AXIS_ARRAY(static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k), static_cast<float>(u), static_cast<float>(v), static_cast<float>(w)); }
FI XYZval<float> asFloat() const { return NUM_AXIS_ARRAY(static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k), static_cast<float>(u), static_cast<float>(v), static_cast<float>(w)); }
FI XYZval<float> reciprocal() const { return NUM_AXIS_ARRAY(_RECIP(x), _RECIP(y), _RECIP(z), _RECIP(i), _RECIP(j), _RECIP(k), _RECIP(u), _RECIP(v), _RECIP(w)); }
// Marlin workspace shifting is done with G92 and M206
FI XYZval<float> asLogical() const { XYZval<float> o = asFloat(); toLogical(o); return o; }
@ -502,78 +522,78 @@ struct XYZval {
FI operator const XYval<T>&() const { return *(const XYval<T>*)this; }
// Cast to a type with more fields by making a new object
FI operator XYZEval<T>() const { return LINEAR_AXIS_ARRAY(x, y, z, i, j, k); }
FI operator XYZEval<T>() const { return NUM_AXIS_ARRAY(x, y, z, i, j, k, u, v, w); }
// Accessor via an AxisEnum (or any integer) [index]
FI T& operator[](const int n) { return pos[n]; }
FI const T& operator[](const int n) const { return pos[n]; }
// Assignment operator overrides do the expected thing
FI XYZval<T>& operator= (const T v) { set(ARRAY_N_1(LINEAR_AXES, v)); return *this; }
FI XYZval<T>& operator= (const T v) { set(ARRAY_N_1(NUM_AXES, v)); return *this; }
FI XYZval<T>& operator= (const XYval<T> &rs) { set(rs.x, rs.y ); return *this; }
FI XYZval<T>& operator= (const XYZEval<T> &rs) { set(LINEAR_AXIS_ELEM(rs)); return *this; }
FI XYZval<T>& operator= (const XYZEval<T> &rs) { set(NUM_AXIS_ELEM(rs)); return *this; }
// Override other operators to get intuitive behaviors
FI XYZval<T> operator+ (const XYval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator+ (const XYval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator- (const XYval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator- (const XYval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator* (const XYval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator* (const XYval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator/ (const XYval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator/ (const XYval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator+ (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZval<T> operator+ (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZval<T> operator- (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZval<T> operator- (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZval<T> operator* (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZval<T> operator* (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZval<T> operator/ (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZval<T> operator/ (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZval<T> operator+ (const XYZEval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZval<T> operator+ (const XYZEval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZval<T> operator- (const XYZEval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZval<T> operator- (const XYZEval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZval<T> operator* (const XYZEval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZval<T> operator* (const XYZEval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZval<T> operator/ (const XYZEval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZval<T> operator/ (const XYZEval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZval<T> operator* (const float &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZval<T> operator* (const float &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZval<T> operator* (const int &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZval<T> operator* (const int &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZval<T> operator/ (const float &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZval<T> operator/ (const float &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZval<T> operator/ (const int &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZval<T> operator/ (const int &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZval<T> operator>>(const int &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(_RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k) ); return ls; }
FI XYZval<T> operator>>(const int &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(_RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k) ); return ls; }
FI XYZval<T> operator<<(const int &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(_LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k) ); return ls; }
FI XYZval<T> operator<<(const int &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(_LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k) ); return ls; }
FI const XYZval<T> operator-() const { XYZval<T> o = *this; LINEAR_AXIS_CODE(o.x = -x, o.y = -y, o.z = -z, o.i = -i, o.j = -j, o.k = -k); return o; }
FI XYZval<T> operator-() { XYZval<T> o = *this; LINEAR_AXIS_CODE(o.x = -x, o.y = -y, o.z = -z, o.i = -i, o.j = -j, o.k = -k); return o; }
FI XYZval<T> operator+ (const XYval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator+ (const XYval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator- (const XYval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator- (const XYval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator* (const XYval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator* (const XYval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator/ (const XYval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator/ (const XYval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator+ (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZval<T> operator+ (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZval<T> operator- (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZval<T> operator- (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZval<T> operator* (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZval<T> operator* (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZval<T> operator/ (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZval<T> operator/ (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZval<T> operator+ (const XYZEval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZval<T> operator+ (const XYZEval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZval<T> operator- (const XYZEval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZval<T> operator- (const XYZEval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZval<T> operator* (const XYZEval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZval<T> operator* (const XYZEval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZval<T> operator/ (const XYZEval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZval<T> operator/ (const XYZEval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZval<T> operator* (const float &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZval<T> operator* (const float &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZval<T> operator* (const int &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZval<T> operator* (const int &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZval<T> operator/ (const float &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZval<T> operator/ (const float &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZval<T> operator/ (const int &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZval<T> operator/ (const int &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZval<T> operator>>(const int &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(_RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k), _RS(ls.u), _RS(ls.v), _RS(ls.w) ); return ls; }
FI XYZval<T> operator>>(const int &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(_RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k), _RS(ls.u), _RS(ls.v), _RS(ls.w) ); return ls; }
FI XYZval<T> operator<<(const int &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(_LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k), _LS(ls.u), _LS(ls.v), _LS(ls.w) ); return ls; }
FI XYZval<T> operator<<(const int &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(_LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k), _LS(ls.u), _LS(ls.v), _LS(ls.w) ); return ls; }
FI const XYZval<T> operator-() const { XYZval<T> o = *this; NUM_AXIS_CODE(o.x = -x, o.y = -y, o.z = -z, o.i = -i, o.j = -j, o.k = -k, o.u = -u, o.v = -v, o.w = -w); return o; }
FI XYZval<T> operator-() { XYZval<T> o = *this; NUM_AXIS_CODE(o.x = -x, o.y = -y, o.z = -z, o.i = -i, o.j = -j, o.k = -k, o.u = -u, o.v = -v, o.w = -w); return o; }
// Modifier operators
FI XYZval<T>& operator+=(const XYval<T> &rs) { LINEAR_AXIS_CODE(x += rs.x, y += rs.y, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator-=(const XYval<T> &rs) { LINEAR_AXIS_CODE(x -= rs.x, y -= rs.y, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator*=(const XYval<T> &rs) { LINEAR_AXIS_CODE(x *= rs.x, y *= rs.y, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator/=(const XYval<T> &rs) { LINEAR_AXIS_CODE(x /= rs.x, y /= rs.y, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator+=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k); return *this; }
FI XYZval<T>& operator-=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k); return *this; }
FI XYZval<T>& operator*=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k); return *this; }
FI XYZval<T>& operator/=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k); return *this; }
FI XYZval<T>& operator+=(const XYZEval<T> &rs) { LINEAR_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k); return *this; }
FI XYZval<T>& operator-=(const XYZEval<T> &rs) { LINEAR_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k); return *this; }
FI XYZval<T>& operator*=(const XYZEval<T> &rs) { LINEAR_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k); return *this; }
FI XYZval<T>& operator/=(const XYZEval<T> &rs) { LINEAR_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k); return *this; }
FI XYZval<T>& operator*=(const float &v) { LINEAR_AXIS_CODE(x *= v, y *= v, z *= v, i *= v, j *= v, k *= v); return *this; }
FI XYZval<T>& operator*=(const int &v) { LINEAR_AXIS_CODE(x *= v, y *= v, z *= v, i *= v, j *= v, k *= v); return *this; }
FI XYZval<T>& operator>>=(const int &v) { LINEAR_AXIS_CODE(_RS(x), _RS(y), _RS(z), _RS(i), _RS(j), _RS(k)); return *this; }
FI XYZval<T>& operator<<=(const int &v) { LINEAR_AXIS_CODE(_LS(x), _LS(y), _LS(z), _LS(i), _LS(j), _LS(k)); return *this; }
FI XYZval<T>& operator+=(const XYval<T> &rs) { NUM_AXIS_CODE(x += rs.x, y += rs.y, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator-=(const XYval<T> &rs) { NUM_AXIS_CODE(x -= rs.x, y -= rs.y, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator*=(const XYval<T> &rs) { NUM_AXIS_CODE(x *= rs.x, y *= rs.y, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator/=(const XYval<T> &rs) { NUM_AXIS_CODE(x /= rs.x, y /= rs.y, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator+=(const XYZval<T> &rs) { NUM_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k, u += rs.u, v += rs.v, w += rs.w); return *this; }
FI XYZval<T>& operator-=(const XYZval<T> &rs) { NUM_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k, u -= rs.u, v -= rs.v, w -= rs.w); return *this; }
FI XYZval<T>& operator*=(const XYZval<T> &rs) { NUM_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k, u *= rs.u, v *= rs.v, w *= rs.w); return *this; }
FI XYZval<T>& operator/=(const XYZval<T> &rs) { NUM_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k, u /= rs.u, v /= rs.v, w /= rs.w); return *this; }
FI XYZval<T>& operator+=(const XYZEval<T> &rs) { NUM_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k, u += rs.u, v += rs.v, w += rs.w); return *this; }
FI XYZval<T>& operator-=(const XYZEval<T> &rs) { NUM_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k, u -= rs.u, v -= rs.v, w -= rs.w); return *this; }
FI XYZval<T>& operator*=(const XYZEval<T> &rs) { NUM_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k, u *= rs.u, v *= rs.v, w *= rs.w); return *this; }
FI XYZval<T>& operator/=(const XYZEval<T> &rs) { NUM_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k, u /= rs.u, v /= rs.v, w /= rs.w); return *this; }
FI XYZval<T>& operator*=(const float &v) { NUM_AXIS_CODE(x *= v, y *= v, z *= v, i *= v, j *= v, k *= v, u *= v, v *= v, w *= v); return *this; }
FI XYZval<T>& operator*=(const int &v) { NUM_AXIS_CODE(x *= v, y *= v, z *= v, i *= v, j *= v, k *= v, u *= v, v *= v, w *= v); return *this; }
FI XYZval<T>& operator>>=(const int &v) { NUM_AXIS_CODE(_RS(x), _RS(y), _RS(z), _RS(i), _RS(j), _RS(k), _RS(u), _RS(v), _RS(w)); return *this; }
FI XYZval<T>& operator<<=(const int &v) { NUM_AXIS_CODE(_LS(x), _LS(y), _LS(z), _LS(i), _LS(j), _LS(k), _LS(u), _LS(v), _LS(w)); return *this; }
// Exact comparisons. For floats a "NEAR" operation may be better.
FI bool operator==(const XYZEval<T> &rs) { return true LINEAR_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k); }
FI bool operator==(const XYZEval<T> &rs) const { return true LINEAR_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k); }
FI bool operator==(const XYZEval<T> &rs) { return true NUM_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k, && u == rs.u, && v == rs.v, && w == rs.w); }
FI bool operator==(const XYZEval<T> &rs) const { return true NUM_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k, && u == rs.u, && v == rs.v, && w == rs.w); }
FI bool operator!=(const XYZEval<T> &rs) { return !operator==(rs); }
FI bool operator!=(const XYZEval<T> &rs) const { return !operator==(rs); }
};
@ -585,11 +605,11 @@ template<typename T>
struct XYZEval {
union {
struct { T LOGICAL_AXIS_ARGS(); };
struct { T LOGICAL_AXIS_LIST(_e, a, b, c, u, v, w); };
struct { T LOGICAL_AXIS_LIST(_e, a, b, c, _i, _j, _k, _u, _v, _w); };
T pos[LOGICAL_AXES];
};
// Reset all to 0
FI void reset() { LOGICAL_AXIS_GANG(e =, x =, y =, z =, i =, j =, k =) 0; }
FI void reset() { LOGICAL_AXIS_GANG(e =, x =, y =, z =, i =, j =, k =, u =, v =, w =) 0; }
// Setters for some number of linear axes, not all
FI void set(const T px) { x = px; }
@ -603,38 +623,48 @@ struct XYZEval {
#if HAS_K_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj) { x = px; y = py; z = pz; i = pi; j = pj; }
#endif
#if HAS_U_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; }
#endif
#if HAS_V_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk, const T pm) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; u = pu; }
#endif
#if HAS_W_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk, const T pm, const T po) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; u = pm; v = pv; }
#endif
// Setters taking struct types and arrays
FI void set(const XYval<T> pxy) { x = pxy.x; y = pxy.y; }
FI void set(const XYZval<T> pxyz) { set(LINEAR_AXIS_ELEM(pxyz)); }
FI void set(const XYZval<T> pxyz) { set(NUM_AXIS_ELEM(pxyz)); }
#if HAS_Z_AXIS
FI void set(LINEAR_AXIS_ARGS(const T)) { LINEAR_AXIS_CODE(a = x, b = y, c = z, u = i, v = j, w = k); }
FI void set(NUM_AXIS_ARGS(const T)) { NUM_AXIS_CODE(a = x, b = y, c = z, _i = i, _j = j, _k = k, _u = u, _v = v, _w = w); }
#endif
FI void set(const XYval<T> pxy, const T pz) { set(pxy); TERN_(HAS_Z_AXIS, z = pz); }
#if LOGICAL_AXES > LINEAR_AXES
#if LOGICAL_AXES > NUM_AXES
FI void set(const XYval<T> pxy, const T pz, const T pe) { set(pxy, pz); e = pe; }
FI void set(const XYZval<T> pxyz, const T pe) { set(pxyz); e = pe; }
FI void set(LOGICAL_AXIS_ARGS(const T)) { LOGICAL_AXIS_CODE(_e = e, a = x, b = y, c = z, u = i, v = j, w = k); }
FI void set(LOGICAL_AXIS_ARGS(const T)) { LOGICAL_AXIS_CODE(_e = e, a = x, b = y, c = z, _i = i, _j = j, _k = k, _u = u, _v = v, _w = w); }
#endif
// Length reduced to one dimension
FI T magnitude() const { return (T)sqrtf(LOGICAL_AXIS_GANG(+ e*e, + x*x, + y*y, + z*z, + i*i, + j*j, + k*k)); }
FI T magnitude() const { return (T)sqrtf(LOGICAL_AXIS_GANG(+ e*e, + x*x, + y*y, + z*z, + i*i, + j*j, + k*k, + u*u, + v*v, + w*w)); }
// Pointer to the data as a simple array
FI operator T* () { return pos; }
// If any element is true then it's true
FI operator bool() { return 0 LOGICAL_AXIS_GANG(|| e, || x, || y, || z, || i, || j, || k); }
FI operator bool() { return 0 LOGICAL_AXIS_GANG(|| e, || x, || y, || z, || i, || j, || k, || u, || v, || w); }
// Explicit copy and copies with conversion
FI XYZEval<T> copy() const { XYZEval<T> o = *this; return o; }
FI XYZEval<T> ABS() const { return LOGICAL_AXIS_ARRAY(T(_ABS(e)), T(_ABS(x)), T(_ABS(y)), T(_ABS(z)), T(_ABS(i)), T(_ABS(j)), T(_ABS(k))); }
FI XYZEval<int16_t> asInt() { return LOGICAL_AXIS_ARRAY(int16_t(e), int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k)); }
FI XYZEval<int16_t> asInt() const { return LOGICAL_AXIS_ARRAY(int16_t(e), int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k)); }
FI XYZEval<int32_t> asLong() { return LOGICAL_AXIS_ARRAY(int32_t(e), int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k)); }
FI XYZEval<int32_t> asLong() const { return LOGICAL_AXIS_ARRAY(int32_t(e), int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k)); }
FI XYZEval<int32_t> ROUNDL() { return LOGICAL_AXIS_ARRAY(int32_t(LROUND(e)), int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k))); }
FI XYZEval<int32_t> ROUNDL() const { return LOGICAL_AXIS_ARRAY(int32_t(LROUND(e)), int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k))); }
FI XYZEval<float> asFloat() { return LOGICAL_AXIS_ARRAY(static_cast<float>(e), static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k)); }
FI XYZEval<float> asFloat() const { return LOGICAL_AXIS_ARRAY(static_cast<float>(e), static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k)); }
FI XYZEval<float> reciprocal() const { return LOGICAL_AXIS_ARRAY(_RECIP(e), _RECIP(x), _RECIP(y), _RECIP(z), _RECIP(i), _RECIP(j), _RECIP(k)); }
FI XYZEval<T> copy() const { XYZEval<T> v = *this; return v; }
FI XYZEval<T> ABS() const { return LOGICAL_AXIS_ARRAY(T(_ABS(e)), T(_ABS(x)), T(_ABS(y)), T(_ABS(z)), T(_ABS(i)), T(_ABS(j)), T(_ABS(k)), T(_ABS(u)), T(_ABS(v)), T(_ABS(w))); }
FI XYZEval<int16_t> asInt() { return LOGICAL_AXIS_ARRAY(int16_t(e), int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k), int16_t(u), int16_t(v), int16_t(w)); }
FI XYZEval<int16_t> asInt() const { return LOGICAL_AXIS_ARRAY(int16_t(e), int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k), int16_t(u), int16_t(v), int16_t(w)); }
FI XYZEval<int32_t> asLong() { return LOGICAL_AXIS_ARRAY(int32_t(e), int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k), int32_t(u), int32_t(v), int32_t(w)); }
FI XYZEval<int32_t> asLong() const { return LOGICAL_AXIS_ARRAY(int32_t(e), int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k), int32_t(u), int32_t(v), int32_t(w)); }
FI XYZEval<int32_t> ROUNDL() { return LOGICAL_AXIS_ARRAY(int32_t(LROUND(e)), int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k)), int32_t(LROUND(u)), int32_t(LROUND(v)), int32_t(LROUND(w))); }
FI XYZEval<int32_t> ROUNDL() const { return LOGICAL_AXIS_ARRAY(int32_t(LROUND(e)), int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k)), int32_t(LROUND(u)), int32_t(LROUND(v)), int32_t(LROUND(w))); }
FI XYZEval<float> asFloat() { return LOGICAL_AXIS_ARRAY(static_cast<float>(e), static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k), static_cast<float>(u), static_cast<float>(v), static_cast<float>(w)); }
FI XYZEval<float> asFloat() const { return LOGICAL_AXIS_ARRAY(static_cast<float>(e), static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k), static_cast<float>(u), static_cast<float>(v), static_cast<float>(w)); }
FI XYZEval<float> reciprocal() const { return LOGICAL_AXIS_ARRAY(_RECIP(e), _RECIP(x), _RECIP(y), _RECIP(z), _RECIP(i), _RECIP(j), _RECIP(k), _RECIP(u), _RECIP(v), _RECIP(w)); }
// Marlin workspace shifting is done with G92 and M206
FI XYZEval<float> asLogical() const { XYZEval<float> o = asFloat(); toLogical(o); return o; }
@ -651,9 +681,9 @@ struct XYZEval {
FI const T& operator[](const int n) const { return pos[n]; }
// Assignment operator overrides do the expected thing
FI XYZEval<T>& operator= (const T v) { set(LIST_N_1(LINEAR_AXES, v)); return *this; }
FI XYZEval<T>& operator= (const T v) { set(LIST_N_1(NUM_AXES, v)); return *this; }
FI XYZEval<T>& operator= (const XYval<T> &rs) { set(rs.x, rs.y); return *this; }
FI XYZEval<T>& operator= (const XYZval<T> &rs) { set(LINEAR_AXIS_ELEM(rs)); return *this; }
FI XYZEval<T>& operator= (const XYZval<T> &rs) { set(NUM_AXIS_ELEM(rs)); return *this; }
// Override other operators to get intuitive behaviors
FI XYZEval<T> operator+ (const XYval<T> &rs) const { XYZEval<T> ls = *this; ls.x += rs.x; ls.y += rs.y; return ls; }
@ -664,57 +694,57 @@ struct XYZEval {
FI XYZEval<T> operator* (const XYval<T> &rs) { XYZEval<T> ls = *this; ls.x *= rs.x; ls.y *= rs.y; return ls; }
FI XYZEval<T> operator/ (const XYval<T> &rs) const { XYZEval<T> ls = *this; ls.x /= rs.x; ls.y /= rs.y; return ls; }
FI XYZEval<T> operator/ (const XYval<T> &rs) { XYZEval<T> ls = *this; ls.x /= rs.x; ls.y /= rs.y; return ls; }
FI XYZEval<T> operator+ (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZEval<T> operator+ (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZEval<T> operator- (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZEval<T> operator- (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZEval<T> operator* (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZEval<T> operator* (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZEval<T> operator/ (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZEval<T> operator/ (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZEval<T> operator+ (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e += rs.e, ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZEval<T> operator+ (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e += rs.e, ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZEval<T> operator- (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e -= rs.e, ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZEval<T> operator- (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e -= rs.e, ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZEval<T> operator* (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= rs.e, ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZEval<T> operator* (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= rs.e, ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZEval<T> operator/ (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= rs.e, ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZEval<T> operator/ (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= rs.e, ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZEval<T> operator* (const float &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZEval<T> operator* (const float &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZEval<T> operator* (const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZEval<T> operator* (const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZEval<T> operator/ (const float &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZEval<T> operator/ (const float &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZEval<T> operator/ (const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZEval<T> operator/ (const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZEval<T> operator>>(const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_RS(ls.e), _RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k) ); return ls; }
FI XYZEval<T> operator>>(const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_RS(ls.e), _RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k) ); return ls; }
FI XYZEval<T> operator<<(const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_LS(ls.e), _LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k) ); return ls; }
FI XYZEval<T> operator<<(const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_LS(ls.e), _LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k) ); return ls; }
FI const XYZEval<T> operator-() const { return LOGICAL_AXIS_ARRAY(-e, -x, -y, -z, -i, -j, -k); }
FI XYZEval<T> operator-() { return LOGICAL_AXIS_ARRAY(-e, -x, -y, -z, -i, -j, -k); }
FI XYZEval<T> operator+ (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZEval<T> operator+ (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZEval<T> operator- (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZEval<T> operator- (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZEval<T> operator* (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZEval<T> operator* (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZEval<T> operator/ (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZEval<T> operator/ (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZEval<T> operator+ (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e += rs.e, ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZEval<T> operator+ (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e += rs.e, ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZEval<T> operator- (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e -= rs.e, ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZEval<T> operator- (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e -= rs.e, ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZEval<T> operator* (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= rs.e, ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZEval<T> operator* (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= rs.e, ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZEval<T> operator/ (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= rs.e, ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZEval<T> operator/ (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= rs.e, ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZEval<T> operator* (const float &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZEval<T> operator* (const float &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZEval<T> operator* (const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZEval<T> operator* (const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZEval<T> operator/ (const float &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZEval<T> operator/ (const float &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZEval<T> operator/ (const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZEval<T> operator/ (const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZEval<T> operator>>(const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_RS(ls.e), _RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k), _RS(ls.u), _RS(ls.v), _RS(ls.w) ); return ls; }
FI XYZEval<T> operator>>(const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_RS(ls.e), _RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k), _RS(ls.u), _RS(ls.v), _RS(ls.w) ); return ls; }
FI XYZEval<T> operator<<(const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_LS(ls.e), _LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k), _LS(ls.u), _LS(ls.v), _LS(ls.w) ); return ls; }
FI XYZEval<T> operator<<(const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_LS(ls.e), _LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k), _LS(ls.u), _LS(ls.v), _LS(ls.w) ); return ls; }
FI const XYZEval<T> operator-() const { return LOGICAL_AXIS_ARRAY(-e, -x, -y, -z, -i, -j, -k, -u, -v, -w); }
FI XYZEval<T> operator-() { return LOGICAL_AXIS_ARRAY(-e, -x, -y, -z, -i, -j, -k, -u, -v, -w); }
// Modifier operators
FI XYZEval<T>& operator+=(const XYval<T> &rs) { x += rs.x; y += rs.y; return *this; }
FI XYZEval<T>& operator-=(const XYval<T> &rs) { x -= rs.x; y -= rs.y; return *this; }
FI XYZEval<T>& operator*=(const XYval<T> &rs) { x *= rs.x; y *= rs.y; return *this; }
FI XYZEval<T>& operator/=(const XYval<T> &rs) { x /= rs.x; y /= rs.y; return *this; }
FI XYZEval<T>& operator+=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k); return *this; }
FI XYZEval<T>& operator-=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k); return *this; }
FI XYZEval<T>& operator*=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k); return *this; }
FI XYZEval<T>& operator/=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k); return *this; }
FI XYZEval<T>& operator+=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e += rs.e, x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k); return *this; }
FI XYZEval<T>& operator-=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e -= rs.e, x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k); return *this; }
FI XYZEval<T>& operator*=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e *= rs.e, x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k); return *this; }
FI XYZEval<T>& operator/=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e /= rs.e, x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k); return *this; }
FI XYZEval<T>& operator*=(const T &v) { LOGICAL_AXIS_CODE(e *= v, x *= v, y *= v, z *= v, i *= v, j *= v, k *= v); return *this; }
FI XYZEval<T>& operator>>=(const int &v) { LOGICAL_AXIS_CODE(_RS(e), _RS(x), _RS(y), _RS(z), _RS(i), _RS(j), _RS(k)); return *this; }
FI XYZEval<T>& operator<<=(const int &v) { LOGICAL_AXIS_CODE(_LS(e), _LS(x), _LS(y), _LS(z), _LS(i), _LS(j), _LS(k)); return *this; }
FI XYZEval<T>& operator+=(const XYZval<T> &rs) { NUM_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k, u += rs.u, v += rs.v, w += rs.w); return *this; }
FI XYZEval<T>& operator-=(const XYZval<T> &rs) { NUM_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k, u -= rs.u, v -= rs.v, w -= rs.w); return *this; }
FI XYZEval<T>& operator*=(const XYZval<T> &rs) { NUM_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k, u *= rs.u, v *= rs.v, w *= rs.w); return *this; }
FI XYZEval<T>& operator/=(const XYZval<T> &rs) { NUM_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k, u /= rs.u, v /= rs.v, w /= rs.w); return *this; }
FI XYZEval<T>& operator+=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e += rs.e, x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k, u += rs.u, v += rs.v, w += rs.w); return *this; }
FI XYZEval<T>& operator-=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e -= rs.e, x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k, u -= rs.u, v -= rs.v, w -= rs.w); return *this; }
FI XYZEval<T>& operator*=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e *= rs.e, x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k, u *= rs.u, v *= rs.v, w *= rs.w); return *this; }
FI XYZEval<T>& operator/=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e /= rs.e, x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k, u /= rs.u, v /= rs.v, w /= rs.w); return *this; }
FI XYZEval<T>& operator*=(const T &v) { LOGICAL_AXIS_CODE(e *= v, x *= v, y *= v, z *= v, i *= v, j *= v, k *= v, u *= v, v *= v, w *= v); return *this; }
FI XYZEval<T>& operator>>=(const int &v) { LOGICAL_AXIS_CODE(_RS(e), _RS(x), _RS(y), _RS(z), _RS(i), _RS(j), _RS(k), _RS(u), _RS(v), _RS(w)); return *this; }
FI XYZEval<T>& operator<<=(const int &v) { LOGICAL_AXIS_CODE(_LS(e), _LS(x), _LS(y), _LS(z), _LS(i), _LS(j), _LS(k), _LS(u), _LS(v), _LS(w)); return *this; }
// Exact comparisons. For floats a "NEAR" operation may be better.
FI bool operator==(const XYZval<T> &rs) { return true LINEAR_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k); }
FI bool operator==(const XYZval<T> &rs) const { return true LINEAR_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k); }
FI bool operator==(const XYZval<T> &rs) { return true NUM_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k, && u == rs.u, && v == rs.v, && w == rs.w); }
FI bool operator==(const XYZval<T> &rs) const { return true NUM_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k, && u == rs.u, && v == rs.v, && w == rs.w); }
FI bool operator!=(const XYZval<T> &rs) { return !operator==(rs); }
FI bool operator!=(const XYZval<T> &rs) const { return !operator==(rs); }
};

View File

@ -125,7 +125,7 @@ void safe_delay(millis_t ms) {
#endif
#if ABL_PLANAR
SERIAL_ECHOPGM("ABL Adjustment");
LOOP_LINEAR_AXES(a) {
LOOP_NUM_AXES(a) {
SERIAL_CHAR(' ', AXIS_CHAR(a));
serial_offset(planner.get_axis_position_mm(AxisEnum(a)) - current_position[a]);
}

View File

@ -77,10 +77,13 @@ public:
// in the range 0-100 while avoiding rounding artifacts
constexpr uint8_t ui8_to_percent(const uint8_t i) { return (int(i) * 100 + 127) / 255; }
const xyze_char_t axis_codes LOGICAL_AXIS_ARRAY('E', 'X', 'Y', 'Z', AXIS4_NAME, AXIS5_NAME, AXIS6_NAME);
#if LINEAR_AXES <= XYZ
// Axis names for G-code parsing, reports, etc.
const xyze_char_t axis_codes LOGICAL_AXIS_ARRAY('E', 'X', 'Y', 'Z', AXIS4_NAME, AXIS5_NAME, AXIS6_NAME, AXIS7_NAME, AXIS8_NAME, AXIS9_NAME);
#if NUM_AXES <= XYZ
#define AXIS_CHAR(A) ((char)('X' + A))
#define IAXIS_CHAR AXIS_CHAR
#else
const xyze_char_t iaxis_codes LOGICAL_AXIS_ARRAY('E', 'X', 'Y', 'Z', 'I', 'J', 'K', 'U', 'V', 'W');
#define AXIS_CHAR(A) axis_codes[A]
#define IAXIS_CHAR(A) iaxis_codes[A]
#endif

View File

@ -97,7 +97,7 @@ void Backlash::add_correction_steps(const int32_t &da, const int32_t &db, const
const float f_corr = float(correction) / all_on;
LOOP_LINEAR_AXES(axis) {
LOOP_NUM_AXES(axis) {
if (distance_mm[axis]) {
const bool reverse = TEST(dm, axis);
@ -145,7 +145,7 @@ void Backlash::add_correction_steps(const int32_t &da, const int32_t &db, const
}
int32_t Backlash::get_applied_steps(const AxisEnum axis) {
if (axis >= LINEAR_AXES) return 0;
if (axis >= NUM_AXES) return 0;
const bool reverse = TEST(last_direction_bits, axis);
@ -165,11 +165,11 @@ class Backlash::StepAdjuster {
xyz_long_t applied_steps;
public:
StepAdjuster() {
LOOP_LINEAR_AXES(axis) applied_steps[axis] = backlash.get_applied_steps((AxisEnum)axis);
LOOP_NUM_AXES(axis) applied_steps[axis] = backlash.get_applied_steps((AxisEnum)axis);
}
~StepAdjuster() {
// after backlash compensation parameter changes, ensure applied step count does not change
LOOP_LINEAR_AXES(axis) residual_error[axis] += backlash.get_applied_steps((AxisEnum)axis) - applied_steps[axis];
LOOP_NUM_AXES(axis) residual_error[axis] += backlash.get_applied_steps((AxisEnum)axis) - applied_steps[axis];
}
};

View File

@ -317,6 +317,42 @@ void unified_bed_leveling::G29() {
// Send 'N' to force homing before G29 (internal only)
if (axes_should_home() || parser.seen_test('N')) gcode.home_all_axes();
TERN_(HAS_MULTI_HOTEND, if (active_extruder != 0) tool_change(0, true));
// Position bed horizontally and Z probe vertically.
#if defined(SAFE_BED_LEVELING_START_X) || defined(SAFE_BED_LEVELING_START_Y) || defined(SAFE_BED_LEVELING_START_Z) \
|| defined(SAFE_BED_LEVELING_START_I) || defined(SAFE_BED_LEVELING_START_J) || defined(SAFE_BED_LEVELING_START_K) \
|| defined(SAFE_BED_LEVELING_START_U) || defined(SAFE_BED_LEVELING_START_V) || defined(SAFE_BED_LEVELING_START_W)
xyze_pos_t safe_position = current_position;
#ifdef SAFE_BED_LEVELING_START_X
safe_position.x = SAFE_BED_LEVELING_START_X;
#endif
#ifdef SAFE_BED_LEVELING_START_Y
safe_position.y = SAFE_BED_LEVELING_START_Y;
#endif
#ifdef SAFE_BED_LEVELING_START_Z
safe_position.z = SAFE_BED_LEVELING_START_Z;
#endif
#ifdef SAFE_BED_LEVELING_START_I
safe_position.i = SAFE_BED_LEVELING_START_I;
#endif
#ifdef SAFE_BED_LEVELING_START_J
safe_position.j = SAFE_BED_LEVELING_START_J;
#endif
#ifdef SAFE_BED_LEVELING_START_K
safe_position.k = SAFE_BED_LEVELING_START_K;
#endif
#ifdef SAFE_BED_LEVELING_START_U
safe_position.u = SAFE_BED_LEVELING_START_U;
#endif
#ifdef SAFE_BED_LEVELING_START_V
safe_position.v = SAFE_BED_LEVELING_START_V;
#endif
#ifdef SAFE_BED_LEVELING_START_W
safe_position.w = SAFE_BED_LEVELING_START_W;
#endif
do_blocking_move_to(safe_position);
#endif
}
// Invalidate one or more nearby mesh points, possibly all.

View File

@ -337,7 +337,7 @@ bool I2CPositionEncoder::test_axis() {
ec = false;
xyze_pos_t startCoord, endCoord;
LOOP_LINEAR_AXES(a) {
LOOP_NUM_AXES(a) {
startCoord[a] = planner.get_axis_position_mm((AxisEnum)a);
endCoord[a] = planner.get_axis_position_mm((AxisEnum)a);
}
@ -395,7 +395,7 @@ void I2CPositionEncoder::calibrate_steps_mm(const uint8_t iter) {
travelDistance = endDistance - startDistance;
xyze_pos_t startCoord, endCoord;
LOOP_LINEAR_AXES(a) {
LOOP_NUM_AXES(a) {
startCoord[a] = planner.get_axis_position_mm((AxisEnum)a);
endCoord[a] = planner.get_axis_position_mm((AxisEnum)a);
}

View File

@ -163,7 +163,7 @@ Joystick joystick;
// norm_jog values of [-1 .. 1] maps linearly to [-feedrate .. feedrate]
xyz_float_t move_dist{0};
float hypot2 = 0;
LOOP_LINEAR_AXES(i) if (norm_jog[i]) {
LOOP_NUM_AXES(i) if (norm_jog[i]) {
move_dist[i] = seg_time * norm_jog[i] * TERN(EXTENSIBLE_UI, manual_feedrate_mm_s, planner.settings.max_feedrate_mm_s)[i];
hypot2 += sq(move_dist[i]);
}

View File

@ -567,7 +567,7 @@ void PrintJobRecovery::resume() {
TERN_(HAS_HOME_OFFSET, home_offset = info.home_offset);
TERN_(HAS_POSITION_SHIFT, position_shift = info.position_shift);
#if HAS_HOME_OFFSET || HAS_POSITION_SHIFT
LOOP_LINEAR_AXES(i) update_workspace_offset((AxisEnum)i);
LOOP_NUM_AXES(i) update_workspace_offset((AxisEnum)i);
#endif
// Relative axis modes
@ -617,7 +617,7 @@ void PrintJobRecovery::resume() {
#if HAS_HOME_OFFSET
DEBUG_ECHOPGM("home_offset: ");
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
if (i) DEBUG_CHAR(',');
DEBUG_DECIMAL(info.home_offset[i]);
}
@ -626,7 +626,7 @@ void PrintJobRecovery::resume() {
#if HAS_POSITION_SHIFT
DEBUG_ECHOPGM("position_shift: ");
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
if (i) DEBUG_CHAR(',');
DEBUG_DECIMAL(info.position_shift[i]);
}

View File

@ -65,15 +65,18 @@ void stepper_driver_backward_check() {
TEST_BACKWARD(I, 8);
TEST_BACKWARD(J, 9);
TEST_BACKWARD(K, 10);
TEST_BACKWARD(U, 11);
TEST_BACKWARD(V, 12);
TEST_BACKWARD(W, 13);
TEST_BACKWARD(E0, 11);
TEST_BACKWARD(E1, 12);
TEST_BACKWARD(E2, 13);
TEST_BACKWARD(E3, 14);
TEST_BACKWARD(E4, 15);
TEST_BACKWARD(E5, 16);
TEST_BACKWARD(E6, 17);
TEST_BACKWARD(E7, 18);
TEST_BACKWARD(E0, 14);
TEST_BACKWARD(E1, 15);
TEST_BACKWARD(E2, 16);
TEST_BACKWARD(E3, 17);
TEST_BACKWARD(E4, 18);
TEST_BACKWARD(E5, 19);
TEST_BACKWARD(E6, 20);
TEST_BACKWARD(E7, 21);
if (!axis_plug_backward)
WRITE(SAFE_POWER_PIN, HIGH);
@ -103,15 +106,18 @@ void stepper_driver_backward_report() {
REPORT_BACKWARD(I, 8);
REPORT_BACKWARD(J, 9);
REPORT_BACKWARD(K, 10);
REPORT_BACKWARD(U, 11);
REPORT_BACKWARD(V, 12);
REPORT_BACKWARD(W, 13);
REPORT_BACKWARD(E0, 11);
REPORT_BACKWARD(E1, 12);
REPORT_BACKWARD(E2, 13);
REPORT_BACKWARD(E3, 14);
REPORT_BACKWARD(E4, 15);
REPORT_BACKWARD(E5, 16);
REPORT_BACKWARD(E6, 17);
REPORT_BACKWARD(E7, 18);
REPORT_BACKWARD(E0, 14);
REPORT_BACKWARD(E1, 15);
REPORT_BACKWARD(E2, 16);
REPORT_BACKWARD(E3, 17);
REPORT_BACKWARD(E4, 18);
REPORT_BACKWARD(E5, 19);
REPORT_BACKWARD(E6, 20);
REPORT_BACKWARD(E7, 21);
}
#endif // HAS_DRIVER_SAFE_POWER_PROTECT

View File

@ -429,6 +429,18 @@
if (monitor_tmc_driver(stepperK, need_update_error_counters, need_debug_reporting))
step_current_down(stepperK);
#endif
#if AXIS_IS_TMC(U)
if (monitor_tmc_driver(stepperU, need_update_error_counters, need_debug_reporting))
step_current_down(stepperU);
#endif
#if AXIS_IS_TMC(V)
if (monitor_tmc_driver(stepperV, need_update_error_counters, need_debug_reporting))
step_current_down(stepperV);
#endif
#if AXIS_IS_TMC(W)
if (monitor_tmc_driver(stepperW, need_update_error_counters, need_debug_reporting))
step_current_down(stepperW);
#endif
#if AXIS_IS_TMC(E0)
(void)monitor_tmc_driver(stepperE0, need_update_error_counters, need_debug_reporting);
@ -809,6 +821,15 @@
#if AXIS_IS_TMC(K)
if (k) tmc_status(stepperK, n);
#endif
#if AXIS_IS_TMC(U)
if (u) tmc_status(stepperU, n);
#endif
#if AXIS_IS_TMC(V)
if (v) tmc_status(stepperV, n);
#endif
#if AXIS_IS_TMC(W)
if (w) tmc_status(stepperW, n);
#endif
if (TERN0(HAS_EXTRUDERS, e)) {
#if AXIS_IS_TMC(E0)
@ -883,6 +904,15 @@
#if AXIS_IS_TMC(K)
if (k) tmc_parse_drv_status(stepperK, n);
#endif
#if AXIS_IS_TMC(U)
if (u) tmc_parse_drv_status(stepperU, n);
#endif
#if AXIS_IS_TMC(V)
if (v) tmc_parse_drv_status(stepperV, n);
#endif
#if AXIS_IS_TMC(W)
if (w) tmc_parse_drv_status(stepperW, n);
#endif
if (TERN0(HAS_EXTRUDERS, e)) {
#if AXIS_IS_TMC(E0)
@ -1088,6 +1118,15 @@
#if AXIS_IS_TMC(K)
if (k) tmc_get_registers(stepperK, n);
#endif
#if AXIS_IS_TMC(U)
if (u) tmc_get_registers(stepperU, n);
#endif
#if AXIS_IS_TMC(V)
if (v) tmc_get_registers(stepperV, n);
#endif
#if AXIS_IS_TMC(W)
if (w) tmc_get_registers(stepperW, n);
#endif
if (TERN0(HAS_EXTRUDERS, e)) {
#if AXIS_IS_TMC(E0)
@ -1244,6 +1283,15 @@ void test_tmc_connection(LOGICAL_AXIS_ARGS(const bool)) {
#if AXIS_IS_TMC(K)
if (k) axis_connection += test_connection(stepperK);
#endif
#if AXIS_IS_TMC(U)
if (u) axis_connection += test_connection(stepperU);
#endif
#if AXIS_IS_TMC(V)
if (v) axis_connection += test_connection(stepperV);
#endif
#if AXIS_IS_TMC(W)
if (w) axis_connection += test_connection(stepperW);
#endif
if (TERN0(HAS_EXTRUDERS, e)) {
#if AXIS_IS_TMC(E0)
@ -1313,6 +1361,15 @@ void test_tmc_connection(LOGICAL_AXIS_ARGS(const bool)) {
#if AXIS_HAS_SPI(K)
SET_CS_PIN(K);
#endif
#if AXIS_HAS_SPI(U)
SET_CS_PIN(U);
#endif
#if AXIS_HAS_SPI(V)
SET_CS_PIN(V);
#endif
#if AXIS_HAS_SPI(W)
SET_CS_PIN(W);
#endif
#if AXIS_HAS_SPI(E0)
SET_CS_PIN(E0);
#endif

View File

@ -348,7 +348,7 @@ void test_tmc_connection(LOGICAL_AXIS_DECL(const bool, true));
#if USE_SENSORLESS
// Track enabled status of stealthChop and only re-enable where applicable
struct sensorless_t { bool LINEAR_AXIS_ARGS(), x2, y2, z2, z3, z4; };
struct sensorless_t { bool NUM_AXIS_ARGS(), x2, y2, z2, z3, z4; };
#if ENABLED(IMPROVE_HOMING_RELIABILITY)
extern millis_t sg_guard_period;

View File

@ -453,6 +453,42 @@ G29_TYPE GcodeSuite::G29() {
#endif
}
// Position bed horizontally and Z probe vertically.
#if defined(SAFE_BED_LEVELING_START_X) || defined(SAFE_BED_LEVELING_START_Y) || defined(SAFE_BED_LEVELING_START_Z) \
|| defined(SAFE_BED_LEVELING_START_I) || defined(SAFE_BED_LEVELING_START_J) || defined(SAFE_BED_LEVELING_START_K) \
|| defined(SAFE_BED_LEVELING_START_U) || defined(SAFE_BED_LEVELING_START_V) || defined(SAFE_BED_LEVELING_START_W)
xyze_pos_t safe_position = current_position;
#ifdef SAFE_BED_LEVELING_START_X
safe_position.x = SAFE_BED_LEVELING_START_X;
#endif
#ifdef SAFE_BED_LEVELING_START_Y
safe_position.y = SAFE_BED_LEVELING_START_Y;
#endif
#ifdef SAFE_BED_LEVELING_START_Z
safe_position.z = SAFE_BED_LEVELING_START_Z;
#endif
#ifdef SAFE_BED_LEVELING_START_I
safe_position.i = SAFE_BED_LEVELING_START_I;
#endif
#ifdef SAFE_BED_LEVELING_START_J
safe_position.j = SAFE_BED_LEVELING_START_J;
#endif
#ifdef SAFE_BED_LEVELING_START_K
safe_position.k = SAFE_BED_LEVELING_START_K;
#endif
#ifdef SAFE_BED_LEVELING_START_U
safe_position.u = SAFE_BED_LEVELING_START_U;
#endif
#ifdef SAFE_BED_LEVELING_START_V
safe_position.v = SAFE_BED_LEVELING_START_V;
#endif
#ifdef SAFE_BED_LEVELING_START_W
safe_position.w = SAFE_BED_LEVELING_START_W;
#endif
do_blocking_move_to(safe_position);
#endif
// Disable auto bed leveling during G29.
// Be formal so G29 can be done successively without G28.
if (!no_action) set_bed_leveling_enabled(false);

View File

@ -106,6 +106,43 @@ void GcodeSuite::G29() {
queue.inject(parser.seen_test('N') ? F("G28" TERN(CAN_SET_LEVELING_AFTER_G28, "L0", "") "\nG29S2") : F("G29S2"));
TERN_(EXTENSIBLE_UI, ExtUI::onLevelingStart());
TERN_(DWIN_LCD_PROUI, DWIN_LevelingStart());
// Position bed horizontally and Z probe vertically.
#if defined(SAFE_BED_LEVELING_START_X) || defined(SAFE_BED_LEVELING_START_Y) || defined(SAFE_BED_LEVELING_START_Z) \
|| defined(SAFE_BED_LEVELING_START_I) || defined(SAFE_BED_LEVELING_START_J) || defined(SAFE_BED_LEVELING_START_K) \
|| defined(SAFE_BED_LEVELING_START_U) || defined(SAFE_BED_LEVELING_START_V) || defined(SAFE_BED_LEVELING_START_W)
xyze_pos_t safe_position = current_position;
#ifdef SAFE_BED_LEVELING_START_X
safe_position.x = SAFE_BED_LEVELING_START_X;
#endif
#ifdef SAFE_BED_LEVELING_START_Y
safe_position.y = SAFE_BED_LEVELING_START_Y;
#endif
#ifdef SAFE_BED_LEVELING_START_Z
safe_position.z = SAFE_BED_LEVELING_START_Z;
#endif
#ifdef SAFE_BED_LEVELING_START_I
safe_position.i = SAFE_BED_LEVELING_START_I;
#endif
#ifdef SAFE_BED_LEVELING_START_J
safe_position.j = SAFE_BED_LEVELING_START_J;
#endif
#ifdef SAFE_BED_LEVELING_START_K
safe_position.k = SAFE_BED_LEVELING_START_K;
#endif
#ifdef SAFE_BED_LEVELING_START_U
safe_position.u = SAFE_BED_LEVELING_START_U;
#endif
#ifdef SAFE_BED_LEVELING_START_V
safe_position.v = SAFE_BED_LEVELING_START_V;
#endif
#ifdef SAFE_BED_LEVELING_START_W
safe_position.w = SAFE_BED_LEVELING_START_W;
#endif
do_blocking_move_to(safe_position);
#endif
return;
}
state = MeshNext;

View File

@ -82,7 +82,7 @@
#if ENABLED(SENSORLESS_HOMING)
sensorless_t stealth_states {
LINEAR_AXIS_LIST(
NUM_AXIS_LIST(
TERN0(X_SENSORLESS, tmc_enable_stallguard(stepperX)),
TERN0(Y_SENSORLESS, tmc_enable_stallguard(stepperY)),
false, false, false, false
@ -214,7 +214,7 @@ void GcodeSuite::G28() {
#if ENABLED(MARLIN_DEV_MODE)
if (parser.seen_test('S')) {
LOOP_LINEAR_AXES(a) set_axis_is_at_home((AxisEnum)a);
LOOP_NUM_AXES(a) set_axis_is_at_home((AxisEnum)a);
sync_plan_position();
SERIAL_ECHOLNPGM("Simulated Homing");
report_current_position();
@ -258,7 +258,7 @@ void GcodeSuite::G28() {
reset_stepper_timeout();
#define HAS_CURRENT_HOME(N) (defined(N##_CURRENT_HOME) && N##_CURRENT_HOME != N##_CURRENT)
#if HAS_CURRENT_HOME(X) || HAS_CURRENT_HOME(X2) || HAS_CURRENT_HOME(Y) || HAS_CURRENT_HOME(Y2) || (ENABLED(DELTA) && HAS_CURRENT_HOME(Z)) || HAS_CURRENT_HOME(I) || HAS_CURRENT_HOME(J) || HAS_CURRENT_HOME(K)
#if HAS_CURRENT_HOME(X) || HAS_CURRENT_HOME(X2) || HAS_CURRENT_HOME(Y) || HAS_CURRENT_HOME(Y2) || (ENABLED(DELTA) && HAS_CURRENT_HOME(Z)) || HAS_CURRENT_HOME(I) || HAS_CURRENT_HOME(J) || HAS_CURRENT_HOME(K) || HAS_CURRENT_HOME(U) || HAS_CURRENT_HOME(V) || HAS_CURRENT_HOME(W)
#define HAS_HOMING_CURRENT 1
#endif
@ -286,21 +286,6 @@ void GcodeSuite::G28() {
stepperY2.rms_current(Y2_CURRENT_HOME);
if (DEBUGGING(LEVELING)) debug_current(F(STR_Y2), tmc_save_current_Y2, Y2_CURRENT_HOME);
#endif
#if HAS_CURRENT_HOME(I)
const int16_t tmc_save_current_I = stepperI.getMilliamps();
stepperI.rms_current(I_CURRENT_HOME);
if (DEBUGGING(LEVELING)) debug_current(F(STR_I), tmc_save_current_I, I_CURRENT_HOME);
#endif
#if HAS_CURRENT_HOME(J)
const int16_t tmc_save_current_J = stepperJ.getMilliamps();
stepperJ.rms_current(J_CURRENT_HOME);
if (DEBUGGING(LEVELING)) debug_current(F(STR_J), tmc_save_current_J, J_CURRENT_HOME);
#endif
#if HAS_CURRENT_HOME(K)
const int16_t tmc_save_current_K = stepperK.getMilliamps();
stepperK.rms_current(K_CURRENT_HOME);
if (DEBUGGING(LEVELING)) debug_current(F(STR_K), tmc_save_current_K, K_CURRENT_HOME);
#endif
#if HAS_CURRENT_HOME(Z) && ENABLED(DELTA)
const int16_t tmc_save_current_Z = stepperZ.getMilliamps();
stepperZ.rms_current(Z_CURRENT_HOME);
@ -321,6 +306,21 @@ void GcodeSuite::G28() {
stepperK.rms_current(K_CURRENT_HOME);
if (DEBUGGING(LEVELING)) debug_current(F(STR_K), tmc_save_current_K, K_CURRENT_HOME);
#endif
#if HAS_CURRENT_HOME(U)
const int16_t tmc_save_current_U = stepperU.getMilliamps();
stepperU.rms_current(U_CURRENT_HOME);
if (DEBUGGING(LEVELING)) debug_current(F(STR_U), tmc_save_current_U, U_CURRENT_HOME);
#endif
#if HAS_CURRENT_HOME(V)
const int16_t tmc_save_current_V = stepperV.getMilliamps();
stepperV.rms_current(V_CURRENT_HOME);
if (DEBUGGING(LEVELING)) debug_current(F(STR_V), tmc_save_current_V, V_CURRENT_HOME);
#endif
#if HAS_CURRENT_HOME(W)
const int16_t tmc_save_current_W = stepperW.getMilliamps();
stepperW.rms_current(W_CURRENT_HOME);
if (DEBUGGING(LEVELING)) debug_current(F(STR_W), tmc_save_current_W, W_CURRENT_HOME);
#endif
#if SENSORLESS_STALLGUARD_DELAY
safe_delay(SENSORLESS_STALLGUARD_DELAY); // Short delay needed to settle
#endif
@ -367,23 +367,28 @@ void GcodeSuite::G28() {
#define _UNSAFE(A) (homeZ && TERN0(Z_SAFE_HOMING, axes_should_home(_BV(A##_AXIS))))
const bool homeZ = TERN0(HAS_Z_AXIS, parser.seen_test('Z')),
LINEAR_AXIS_LIST( // Other axes should be homed before Z safe-homing
NUM_AXIS_LIST( // Other axes should be homed before Z safe-homing
needX = _UNSAFE(X), needY = _UNSAFE(Y), needZ = false, // UNUSED
needI = _UNSAFE(I), needJ = _UNSAFE(J), needK = _UNSAFE(K)
needI = _UNSAFE(I), needJ = _UNSAFE(J), needK = _UNSAFE(K),
needU = _UNSAFE(U), needV = _UNSAFE(V), needW = _UNSAFE(W)
),
LINEAR_AXIS_LIST( // Home each axis if needed or flagged
NUM_AXIS_LIST( // Home each axis if needed or flagged
homeX = needX || parser.seen_test('X'),
homeY = needY || parser.seen_test('Y'),
homeZZ = homeZ,
homeI = needI || parser.seen_test(AXIS4_NAME), homeJ = needJ || parser.seen_test(AXIS5_NAME), homeK = needK || parser.seen_test(AXIS6_NAME)
homeI = needI || parser.seen_test(AXIS4_NAME), homeJ = needJ || parser.seen_test(AXIS5_NAME),
homeK = needK || parser.seen_test(AXIS6_NAME), homeU = needU || parser.seen_test(AXIS7_NAME),
homeV = needV || parser.seen_test(AXIS8_NAME), homeW = needW || parser.seen_test(AXIS9_NAME)
),
home_all = LINEAR_AXIS_GANG( // Home-all if all or none are flagged
home_all = NUM_AXIS_GANG( // Home-all if all or none are flagged
homeX == homeX, && homeY == homeX, && homeZ == homeX,
&& homeI == homeX, && homeJ == homeX, && homeK == homeX
&& homeI == homeX, && homeJ == homeX, && homeK == homeX,
&& homeU == homeX, && homeV == homeX, && homeW == homeX
),
LINEAR_AXIS_LIST(
NUM_AXIS_LIST(
doX = home_all || homeX, doY = home_all || homeY, doZ = home_all || homeZ,
doI = home_all || homeI, doJ = home_all || homeJ, doK = home_all || homeK
doI = home_all || homeI, doJ = home_all || homeJ, doK = home_all || homeK,
doU = home_all || homeU, doV = home_all || homeV, doW = home_all || homeW
);
#if HAS_Z_AXIS
@ -397,7 +402,7 @@ void GcodeSuite::G28() {
const bool seenR = parser.seenval('R');
const float z_homing_height = seenR ? parser.value_linear_units() : Z_HOMING_HEIGHT;
if (z_homing_height && (seenR || LINEAR_AXIS_GANG(doX, || doY, || TERN0(Z_SAFE_HOMING, doZ), || doI, || doJ, || doK))) {
if (z_homing_height && (seenR || NUM_AXIS_GANG(doX, || doY, || TERN0(Z_SAFE_HOMING, doZ), || doI, || doJ, || doK, || doU, || doV, || doW))) {
// Raise Z before homing any other axes and z is not already high enough (never lower z)
if (DEBUGGING(LEVELING)) DEBUG_ECHOLNPGM("Raise Z (before homing) by ", z_homing_height);
do_z_clearance(z_homing_height);
@ -437,12 +442,26 @@ void GcodeSuite::G28() {
#endif
}
#if BOTH(FOAMCUTTER_XYUV, HAS_I_AXIS)
// Home I (after X)
if (doI) homeaxis(I_AXIS);
#endif
// Home Y (after X)
if (DISABLED(HOME_Y_BEFORE_X) && doY)
homeaxis(Y_AXIS);
#if BOTH(FOAMCUTTER_XYUV, HAS_J_AXIS)
// Home J (after Y)
if (doJ) homeaxis(J_AXIS);
#endif
TERN_(IMPROVE_HOMING_RELIABILITY, end_slow_homing(saved_motion_state));
#if ENABLED(FOAMCUTTER_XYUV)
// skip homing of unused Z axis for foamcutters
if (doZ) set_axis_is_at_home(Z_AXIS);
#else
// Home Z last if homing towards the bed
#if HAS_Z_AXIS && DISABLED(HOME_Z_FIRST)
if (doZ) {
@ -460,9 +479,15 @@ void GcodeSuite::G28() {
}
#endif
TERN_(HAS_I_AXIS, if (doI) homeaxis(I_AXIS));
TERN_(HAS_J_AXIS, if (doJ) homeaxis(J_AXIS));
TERN_(HAS_K_AXIS, if (doK) homeaxis(K_AXIS));
SECONDARY_AXIS_CODE(
if (doI) homeaxis(I_AXIS),
if (doJ) homeaxis(J_AXIS),
if (doK) homeaxis(K_AXIS),
if (doU) homeaxis(U_AXIS),
if (doV) homeaxis(V_AXIS),
if (doW) homeaxis(W_AXIS)
);
#endif
sync_plan_position();
@ -545,6 +570,15 @@ void GcodeSuite::G28() {
#if HAS_CURRENT_HOME(K)
stepperK.rms_current(tmc_save_current_K);
#endif
#if HAS_CURRENT_HOME(U)
stepperU.rms_current(tmc_save_current_U);
#endif
#if HAS_CURRENT_HOME(V)
stepperV.rms_current(tmc_save_current_V);
#endif
#if HAS_CURRENT_HOME(W)
stepperW.rms_current(tmc_save_current_W);
#endif
#if SENSORLESS_STALLGUARD_DELAY
safe_delay(SENSORLESS_STALLGUARD_DELAY); // Short delay needed to settle
#endif
@ -568,7 +602,7 @@ void GcodeSuite::G28() {
// If not, this will need a PROGMEM directive and an accessor.
#define _EN_ITEM(N) , E_AXIS
static constexpr AxisEnum L64XX_axis_xref[MAX_L64XX] = {
LINEAR_AXIS_LIST(X_AXIS, Y_AXIS, Z_AXIS, I_AXIS, J_AXIS, K_AXIS),
NUM_AXIS_LIST(X_AXIS, Y_AXIS, Z_AXIS, I_AXIS, J_AXIS, K_AXIS, U_AXIS, V_AXIS, W_AXIS),
X_AXIS, Y_AXIS, Z_AXIS, Z_AXIS, Z_AXIS
REPEAT(E_STEPPERS, _EN_ITEM)
};

View File

@ -343,7 +343,7 @@ static float auto_tune_a(const float dcr) {
abc_float_t delta_e = { 0.0f }, delta_t = { 0.0f };
delta_t.reset();
LOOP_LINEAR_AXES(axis) {
LOOP_NUM_AXES(axis) {
delta_t[axis] = diff;
calc_kinematics_diff_probe_points(z_pt, dcr, delta_e, delta_r, delta_t);
delta_t[axis] = 0;
@ -557,7 +557,7 @@ void GcodeSuite::G33() {
case 1:
test_precision = 0.0f; // forced end
LOOP_LINEAR_AXES(axis) e_delta[axis] = +Z4(CEN);
LOOP_NUM_AXES(axis) e_delta[axis] = +Z4(CEN);
break;
case 2:
@ -605,14 +605,14 @@ void GcodeSuite::G33() {
// Normalize angles to least-squares
if (_angle_results) {
float a_sum = 0.0f;
LOOP_LINEAR_AXES(axis) a_sum += delta_tower_angle_trim[axis];
LOOP_LINEAR_AXES(axis) delta_tower_angle_trim[axis] -= a_sum / 3.0f;
LOOP_NUM_AXES(axis) a_sum += delta_tower_angle_trim[axis];
LOOP_NUM_AXES(axis) delta_tower_angle_trim[axis] -= a_sum / 3.0f;
}
// adjust delta_height and endstops by the max amount
const float z_temp = _MAX(delta_endstop_adj.a, delta_endstop_adj.b, delta_endstop_adj.c);
delta_height -= z_temp;
LOOP_LINEAR_AXES(axis) delta_endstop_adj[axis] -= z_temp;
LOOP_NUM_AXES(axis) delta_endstop_adj[axis] -= z_temp;
}
recalc_delta_settings();
NOMORE(zero_std_dev_min, zero_std_dev);

View File

@ -85,10 +85,19 @@
#if ALL(HAS_K_AXIS, CALIBRATION_MEASURE_KMIN, CALIBRATION_MEASURE_KMAX)
#define HAS_K_CENTER 1
#endif
#if ALL(HAS_U_AXIS, CALIBRATION_MEASURE_UMIN, CALIBRATION_MEASURE_UMAX)
#define HAS_U_CENTER 1
#endif
#if ALL(HAS_V_AXIS, CALIBRATION_MEASURE_VMIN, CALIBRATION_MEASURE_VMAX)
#define HAS_V_CENTER 1
#endif
#if ALL(HAS_W_AXIS, CALIBRATION_MEASURE_WMIN, CALIBRATION_MEASURE_WMAX)
#define HAS_W_CENTER 1
#endif
enum side_t : uint8_t {
TOP, RIGHT, FRONT, LEFT, BACK, NUM_SIDES,
LIST_N(DOUBLE(SUB3(LINEAR_AXES)), IMINIMUM, IMAXIMUM, JMINIMUM, JMAXIMUM, KMINIMUM, KMAXIMUM)
LIST_N(DOUBLE(SECONDARY_AXES), IMINIMUM, IMAXIMUM, JMINIMUM, JMAXIMUM, KMINIMUM, KMAXIMUM, UMINIMUM, UMAXIMUM, VMINIMUM, VMAXIMUM, WMINIMUM, WMAXIMUM)
};
static constexpr xyz_pos_t true_center CALIBRATION_OBJECT_CENTER;
@ -282,6 +291,15 @@ inline void probe_side(measurements_t &m, const float uncertainty, const side_t
#if HAS_K_AXIS && AXIS_CAN_CALIBRATE(K)
_PCASE(K);
#endif
#if HAS_U_AXIS && AXIS_CAN_CALIBRATE(U)
_PCASE(U);
#endif
#if HAS_V_AXIS && AXIS_CAN_CALIBRATE(V)
_PCASE(V);
#endif
#if HAS_W_AXIS && AXIS_CAN_CALIBRATE(W)
_PCASE(W);
#endif
default: return;
}
@ -335,6 +353,12 @@ inline void probe_sides(measurements_t &m, const float uncertainty) {
TERN_(CALIBRATION_MEASURE_JMAX, probe_side(m, uncertainty, JMAXIMUM, probe_top_at_edge));
TERN_(CALIBRATION_MEASURE_KMIN, probe_side(m, uncertainty, KMINIMUM, probe_top_at_edge));
TERN_(CALIBRATION_MEASURE_KMAX, probe_side(m, uncertainty, KMAXIMUM, probe_top_at_edge));
TERN_(CALIBRATION_MEASURE_UMIN, probe_side(m, uncertainty, UMINIMUM, probe_top_at_edge));
TERN_(CALIBRATION_MEASURE_UMAX, probe_side(m, uncertainty, UMAXIMUM, probe_top_at_edge));
TERN_(CALIBRATION_MEASURE_VMIN, probe_side(m, uncertainty, VMINIMUM, probe_top_at_edge));
TERN_(CALIBRATION_MEASURE_VMAX, probe_side(m, uncertainty, VMAXIMUM, probe_top_at_edge));
TERN_(CALIBRATION_MEASURE_WMIN, probe_side(m, uncertainty, WMINIMUM, probe_top_at_edge));
TERN_(CALIBRATION_MEASURE_WMAX, probe_side(m, uncertainty, WMAXIMUM, probe_top_at_edge));
// Compute the measured center of the calibration object.
TERN_(HAS_X_CENTER, m.obj_center.x = (m.obj_side[LEFT] + m.obj_side[RIGHT]) / 2);
@ -342,6 +366,9 @@ inline void probe_sides(measurements_t &m, const float uncertainty) {
TERN_(HAS_I_CENTER, m.obj_center.i = (m.obj_side[IMINIMUM] + m.obj_side[IMAXIMUM]) / 2);
TERN_(HAS_J_CENTER, m.obj_center.j = (m.obj_side[JMINIMUM] + m.obj_side[JMAXIMUM]) / 2);
TERN_(HAS_K_CENTER, m.obj_center.k = (m.obj_side[KMINIMUM] + m.obj_side[KMAXIMUM]) / 2);
TERN_(HAS_U_CENTER, m.obj_center.u = (m.obj_side[UMINIMUM] + m.obj_side[UMAXIMUM]) / 2);
TERN_(HAS_V_CENTER, m.obj_center.v = (m.obj_side[VMINIMUM] + m.obj_side[VMAXIMUM]) / 2);
TERN_(HAS_W_CENTER, m.obj_center.w = (m.obj_side[WMINIMUM] + m.obj_side[WMAXIMUM]) / 2);
// Compute the outside diameter of the nozzle at the height
// at which it makes contact with the calibration object
@ -352,13 +379,16 @@ inline void probe_sides(measurements_t &m, const float uncertainty) {
// The difference between the known and the measured location
// of the calibration object is the positional error
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
m.pos_error.x = TERN0(HAS_X_CENTER, true_center.x - m.obj_center.x),
m.pos_error.y = TERN0(HAS_Y_CENTER, true_center.y - m.obj_center.y),
m.pos_error.z = true_center.z - m.obj_center.z,
m.pos_error.i = TERN0(HAS_I_CENTER, true_center.i - m.obj_center.i),
m.pos_error.j = TERN0(HAS_J_CENTER, true_center.j - m.obj_center.j),
m.pos_error.k = TERN0(HAS_K_CENTER, true_center.k - m.obj_center.k)
m.pos_error.k = TERN0(HAS_K_CENTER, true_center.k - m.obj_center.k),
m.pos_error.u = TERN0(HAS_U_CENTER, true_center.u - m.obj_center.u),
m.pos_error.v = TERN0(HAS_V_CENTER, true_center.v - m.obj_center.v),
m.pos_error.w = TERN0(HAS_W_CENTER, true_center.w - m.obj_center.w)
);
}
@ -406,6 +436,30 @@ inline void probe_sides(measurements_t &m, const float uncertainty) {
SERIAL_ECHOLNPGM(" " STR_K_MAX ": ", m.obj_side[KMAXIMUM]);
#endif
#endif
#if HAS_U_AXIS
#if ENABLED(CALIBRATION_MEASURE_UMIN)
SERIAL_ECHOLNPGM(" " STR_U_MIN ": ", m.obj_side[UMINIMUM]);
#endif
#if ENABLED(CALIBRATION_MEASURE_UMAX)
SERIAL_ECHOLNPGM(" " STR_U_MAX ": ", m.obj_side[UMAXIMUM]);
#endif
#endif
#if HAS_V_AXIS
#if ENABLED(CALIBRATION_MEASURE_VMIN)
SERIAL_ECHOLNPGM(" " STR_V_MIN ": ", m.obj_side[VMINIMUM]);
#endif
#if ENABLED(CALIBRATION_MEASURE_VMAX)
SERIAL_ECHOLNPGM(" " STR_V_MAX ": ", m.obj_side[VMAXIMUM]);
#endif
#endif
#if HAS_W_AXIS
#if ENABLED(CALIBRATION_MEASURE_WMIN)
SERIAL_ECHOLNPGM(" " STR_W_MIN ": ", m.obj_side[WMINIMUM]);
#endif
#if ENABLED(CALIBRATION_MEASURE_WMAX)
SERIAL_ECHOLNPGM(" " STR_W_MAX ": ", m.obj_side[WMAXIMUM]);
#endif
#endif
SERIAL_EOL();
}
@ -427,6 +481,15 @@ inline void probe_sides(measurements_t &m, const float uncertainty) {
#if HAS_K_CENTER
SERIAL_ECHOLNPGM_P(SP_K_STR, m.obj_center.k);
#endif
#if HAS_U_CENTER
SERIAL_ECHOLNPGM_P(SP_U_STR, m.obj_center.u);
#endif
#if HAS_V_CENTER
SERIAL_ECHOLNPGM_P(SP_V_STR, m.obj_center.v);
#endif
#if HAS_W_CENTER
SERIAL_ECHOLNPGM_P(SP_W_STR, m.obj_center.w);
#endif
SERIAL_EOL();
}
@ -475,6 +538,30 @@ inline void probe_sides(measurements_t &m, const float uncertainty) {
SERIAL_ECHOLNPGM(" " STR_K_MAX ": ", m.backlash[KMAXIMUM]);
#endif
#endif
#if HAS_U_AXIS && AXIS_CAN_CALIBRATE(U)
#if ENABLED(CALIBRATION_MEASURE_UMIN)
SERIAL_ECHOLNPGM(" " STR_U_MIN ": ", m.backlash[UMINIMUM]);
#endif
#if ENABLED(CALIBRATION_MEASURE_UMAX)
SERIAL_ECHOLNPGM(" " STR_U_MAX ": ", m.backlash[UMAXIMUM]);
#endif
#endif
#if HAS_V_AXIS && AXIS_CAN_CALIBRATE(V)
#if ENABLED(CALIBRATION_MEASURE_VMIN)
SERIAL_ECHOLNPGM(" " STR_V_MIN ": ", m.backlash[VMINIMUM]);
#endif
#if ENABLED(CALIBRATION_MEASURE_VMAX)
SERIAL_ECHOLNPGM(" " STR_V_MAX ": ", m.backlash[VMAXIMUM]);
#endif
#endif
#if HAS_W_AXIS && AXIS_CAN_CALIBRATE(W)
#if ENABLED(CALIBRATION_MEASURE_WMIN)
SERIAL_ECHOLNPGM(" " STR_W_MIN ": ", m.backlash[WMINIMUM]);
#endif
#if ENABLED(CALIBRATION_MEASURE_WMAX)
SERIAL_ECHOLNPGM(" " STR_W_MAX ": ", m.backlash[WMAXIMUM]);
#endif
#endif
SERIAL_EOL();
}
@ -498,7 +585,16 @@ inline void probe_sides(measurements_t &m, const float uncertainty) {
SERIAL_ECHOLNPGM_P(SP_J_STR, m.pos_error.j);
#endif
#if HAS_K_CENTER && AXIS_CAN_CALIBRATE(K)
SERIAL_ECHOLNPGM_P(SP_Z_STR, m.pos_error.z);
SERIAL_ECHOLNPGM_P(SP_K_STR, m.pos_error.k);
#endif
#if HAS_U_CENTER && AXIS_CAN_CALIBRATE(U)
SERIAL_ECHOLNPGM_P(SP_U_STR, m.pos_error.u);
#endif
#if HAS_V_CENTER && AXIS_CAN_CALIBRATE(V)
SERIAL_ECHOLNPGM_P(SP_V_STR, m.pos_error.v);
#endif
#if HAS_W_CENTER && AXIS_CAN_CALIBRATE(W)
SERIAL_ECHOLNPGM_P(SP_W_STR, m.pos_error.w);
#endif
SERIAL_EOL();
}
@ -587,6 +683,30 @@ inline void calibrate_backlash(measurements_t &m, const float uncertainty) {
backlash.set_distance_mm(K_AXIS, m.backlash[KMAXIMUM]);
#endif
#if HAS_U_CENTER
backlash.distance_mm.u = (m.backlash[UMINIMUM] + m.backlash[UMAXIMUM]) / 2;
#elif ENABLED(CALIBRATION_MEASURE_UMIN)
backlash.distance_mm.u = m.backlash[UMINIMUM];
#elif ENABLED(CALIBRATION_MEASURE_UMAX)
backlash.distance_mm.u = m.backlash[UMAXIMUM];
#endif
#if HAS_V_CENTER
backlash.distance_mm.v = (m.backlash[VMINIMUM] + m.backlash[VMAXIMUM]) / 2;
#elif ENABLED(CALIBRATION_MEASURE_VMIN)
backlash.distance_mm.v = m.backlash[VMINIMUM];
#elif ENABLED(CALIBRATION_MEASURE_UMAX)
backlash.distance_mm.v = m.backlash[VMAXIMUM];
#endif
#if HAS_W_CENTER
backlash.distance_mm.w = (m.backlash[WMINIMUM] + m.backlash[WMAXIMUM]) / 2;
#elif ENABLED(CALIBRATION_MEASURE_WMIN)
backlash.distance_mm.w = m.backlash[WMINIMUM];
#elif ENABLED(CALIBRATION_MEASURE_WMAX)
backlash.distance_mm.w = m.backlash[WMAXIMUM];
#endif
#endif // BACKLASH_GCODE
}
@ -597,9 +717,10 @@ inline void calibrate_backlash(measurements_t &m, const float uncertainty) {
// New scope for TEMPORARY_BACKLASH_CORRECTION
TEMPORARY_BACKLASH_CORRECTION(backlash.all_on);
TEMPORARY_BACKLASH_SMOOTHING(0.0f);
const xyz_float_t move = LINEAR_AXIS_ARRAY(
const xyz_float_t move = NUM_AXIS_ARRAY(
AXIS_CAN_CALIBRATE(X) * 3, AXIS_CAN_CALIBRATE(Y) * 3, AXIS_CAN_CALIBRATE(Z) * 3,
AXIS_CAN_CALIBRATE(I) * 3, AXIS_CAN_CALIBRATE(J) * 3, AXIS_CAN_CALIBRATE(K) * 3
AXIS_CAN_CALIBRATE(I) * 3, AXIS_CAN_CALIBRATE(J) * 3, AXIS_CAN_CALIBRATE(K) * 3,
AXIS_CAN_CALIBRATE(U) * 3, AXIS_CAN_CALIBRATE(V) * 3, AXIS_CAN_CALIBRATE(W) * 3
);
current_position += move; calibration_move();
current_position -= move; calibration_move();
@ -650,6 +771,9 @@ inline void calibrate_toolhead(measurements_t &m, const float uncertainty, const
TERN_(HAS_I_CENTER, update_measurements(m, I_AXIS));
TERN_(HAS_J_CENTER, update_measurements(m, J_AXIS));
TERN_(HAS_K_CENTER, update_measurements(m, K_AXIS));
TERN_(HAS_U_CENTER, update_measurements(m, U_AXIS));
TERN_(HAS_V_CENTER, update_measurements(m, V_AXIS));
TERN_(HAS_W_CENTER, update_measurements(m, W_AXIS));
sync_plan_position();
}

View File

@ -49,21 +49,24 @@ void GcodeSuite::M425() {
auto axis_can_calibrate = [](const uint8_t a) {
switch (a) {
default: return false;
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
case X_AXIS: return AXIS_CAN_CALIBRATE(X),
case Y_AXIS: return AXIS_CAN_CALIBRATE(Y),
case Z_AXIS: return AXIS_CAN_CALIBRATE(Z),
case I_AXIS: return AXIS_CAN_CALIBRATE(I),
case J_AXIS: return AXIS_CAN_CALIBRATE(J),
case K_AXIS: return AXIS_CAN_CALIBRATE(K)
case K_AXIS: return AXIS_CAN_CALIBRATE(K),
case U_AXIS: return AXIS_CAN_CALIBRATE(U),
case V_AXIS: return AXIS_CAN_CALIBRATE(V),
case W_AXIS: return AXIS_CAN_CALIBRATE(W)
);
}
};
LOOP_LINEAR_AXES(a) {
LOOP_NUM_AXES(a) {
if (axis_can_calibrate(a) && parser.seen(AXIS_CHAR(a))) {
planner.synchronize();
backlash.set_distance_mm(AxisEnum(a), parser.has_value() ? parser.value_linear_units() : backlash.get_measurement(AxisEnum(a)));
backlash.set_distance_mm((AxisEnum)a, parser.has_value() ? parser.value_axis_units((AxisEnum)a) : backlash.get_measurement((AxisEnum)a));
noArgs = false;
}
}
@ -88,7 +91,7 @@ void GcodeSuite::M425() {
SERIAL_ECHOLNPGM("active:");
SERIAL_ECHOLNPGM(" Correction Amount/Fade-out: F", backlash.get_correction(), " (F1.0 = full, F0.0 = none)");
SERIAL_ECHOPGM(" Backlash Distance (mm): ");
LOOP_LINEAR_AXES(a) if (axis_can_calibrate(a)) {
LOOP_NUM_AXES(a) if (axis_can_calibrate(a)) {
SERIAL_CHAR(' ', AXIS_CHAR(a));
SERIAL_ECHO(backlash.get_distance_mm(AxisEnum(a)));
SERIAL_EOL();
@ -101,7 +104,7 @@ void GcodeSuite::M425() {
#if ENABLED(MEASURE_BACKLASH_WHEN_PROBING)
SERIAL_ECHOPGM(" Average measured backlash (mm):");
if (backlash.has_any_measurement()) {
LOOP_LINEAR_AXES(a) if (axis_can_calibrate(a) && backlash.has_measurement(AxisEnum(a))) {
LOOP_NUM_AXES(a) if (axis_can_calibrate(a) && backlash.has_measurement(AxisEnum(a))) {
SERIAL_CHAR(' ', AXIS_CHAR(a));
SERIAL_ECHO(backlash.get_measurement(AxisEnum(a)));
}
@ -120,13 +123,16 @@ void GcodeSuite::M425_report(const bool forReplay/*=true*/) {
#ifdef BACKLASH_SMOOTHING_MM
, PSTR(" S"), LINEAR_UNIT(backlash.get_smoothing_mm())
#endif
, LIST_N(DOUBLE(LINEAR_AXES),
, LIST_N(DOUBLE(NUM_AXES),
SP_X_STR, LINEAR_UNIT(backlash.get_distance_mm(X_AXIS)),
SP_Y_STR, LINEAR_UNIT(backlash.get_distance_mm(Y_AXIS)),
SP_Z_STR, LINEAR_UNIT(backlash.get_distance_mm(Z_AXIS)),
SP_I_STR, LINEAR_UNIT(backlash.get_distance_mm(I_AXIS)),
SP_J_STR, LINEAR_UNIT(backlash.get_distance_mm(J_AXIS)),
SP_K_STR, LINEAR_UNIT(backlash.get_distance_mm(K_AXIS))
SP_I_STR, I_AXIS_UNIT(backlash.get_distance_mm(I_AXIS)),
SP_J_STR, J_AXIS_UNIT(backlash.get_distance_mm(J_AXIS)),
SP_K_STR, K_AXIS_UNIT(backlash.get_distance_mm(K_AXIS)),
SP_U_STR, U_AXIS_UNIT(backlash.get_distance_mm(U_AXIS)),
SP_V_STR, V_AXIS_UNIT(backlash.get_distance_mm(V_AXIS)),
SP_W_STR, W_AXIS_UNIT(backlash.get_distance_mm(W_AXIS))
)
);
}

View File

@ -44,7 +44,7 @@
void GcodeSuite::M666() {
DEBUG_SECTION(log_M666, "M666", DEBUGGING(LEVELING));
bool is_err = false, is_set = false;
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
if (parser.seen(AXIS_CHAR(i))) {
is_set = true;
const float v = parser.value_linear_units();

View File

@ -144,13 +144,16 @@ void GcodeSuite::M201() {
void GcodeSuite::M201_report(const bool forReplay/*=true*/) {
report_heading_etc(forReplay, F(STR_MAX_ACCELERATION));
SERIAL_ECHOLNPGM_P(
LIST_N(DOUBLE(LINEAR_AXES),
LIST_N(DOUBLE(NUM_AXES),
PSTR(" M201 X"), LINEAR_UNIT(planner.settings.max_acceleration_mm_per_s2[X_AXIS]),
SP_Y_STR, LINEAR_UNIT(planner.settings.max_acceleration_mm_per_s2[Y_AXIS]),
SP_Z_STR, LINEAR_UNIT(planner.settings.max_acceleration_mm_per_s2[Z_AXIS]),
SP_I_STR, LINEAR_UNIT(planner.settings.max_acceleration_mm_per_s2[I_AXIS]),
SP_J_STR, LINEAR_UNIT(planner.settings.max_acceleration_mm_per_s2[J_AXIS]),
SP_K_STR, LINEAR_UNIT(planner.settings.max_acceleration_mm_per_s2[K_AXIS])
SP_I_STR, I_AXIS_UNIT(planner.settings.max_acceleration_mm_per_s2[I_AXIS]),
SP_J_STR, J_AXIS_UNIT(planner.settings.max_acceleration_mm_per_s2[J_AXIS]),
SP_K_STR, K_AXIS_UNIT(planner.settings.max_acceleration_mm_per_s2[K_AXIS]),
SP_U_STR, U_AXIS_UNIT(planner.settings.max_acceleration_mm_per_s2[U_AXIS]),
SP_V_STR, V_AXIS_UNIT(planner.settings.max_acceleration_mm_per_s2[V_AXIS]),
SP_W_STR, W_AXIS_UNIT(planner.settings.max_acceleration_mm_per_s2[W_AXIS])
)
#if HAS_EXTRUDERS && DISABLED(DISTINCT_E_FACTORS)
, SP_E_STR, VOLUMETRIC_UNIT(planner.settings.max_acceleration_mm_per_s2[E_AXIS])
@ -189,13 +192,16 @@ void GcodeSuite::M203() {
void GcodeSuite::M203_report(const bool forReplay/*=true*/) {
report_heading_etc(forReplay, F(STR_MAX_FEEDRATES));
SERIAL_ECHOLNPGM_P(
LIST_N(DOUBLE(LINEAR_AXES),
LIST_N(DOUBLE(NUM_AXES),
PSTR(" M203 X"), LINEAR_UNIT(planner.settings.max_feedrate_mm_s[X_AXIS]),
SP_Y_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[Y_AXIS]),
SP_Z_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[Z_AXIS]),
SP_I_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[I_AXIS]),
SP_J_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[J_AXIS]),
SP_K_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[K_AXIS])
SP_K_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[K_AXIS]),
SP_U_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[U_AXIS]),
SP_V_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[V_AXIS]),
SP_W_STR, LINEAR_UNIT(planner.settings.max_feedrate_mm_s[W_AXIS])
)
#if HAS_EXTRUDERS && DISABLED(DISTINCT_E_FACTORS)
, SP_E_STR, VOLUMETRIC_UNIT(planner.settings.max_feedrate_mm_s[E_AXIS])
@ -282,9 +288,12 @@ void GcodeSuite::M205() {
if (parser.seenval('X')) planner.set_max_jerk(X_AXIS, parser.value_linear_units()),
if (parser.seenval('Y')) planner.set_max_jerk(Y_AXIS, parser.value_linear_units()),
if ((seenZ = parser.seenval('Z'))) planner.set_max_jerk(Z_AXIS, parser.value_linear_units()),
if (parser.seenval(AXIS4_NAME)) planner.set_max_jerk(I_AXIS, parser.value_linear_units()),
if (parser.seenval(AXIS5_NAME)) planner.set_max_jerk(J_AXIS, parser.value_linear_units()),
if (parser.seenval(AXIS6_NAME)) planner.set_max_jerk(K_AXIS, parser.value_linear_units())
if (parser.seenval(AXIS4_NAME)) planner.set_max_jerk(I_AXIS, parser.TERN(AXIS4_ROTATES, value_float, value_linear_units)()),
if (parser.seenval(AXIS5_NAME)) planner.set_max_jerk(J_AXIS, parser.TERN(AXIS5_ROTATES, value_float, value_linear_units)()),
if (parser.seenval(AXIS6_NAME)) planner.set_max_jerk(K_AXIS, parser.TERN(AXIS6_ROTATES, value_float, value_linear_units)()),
if (parser.seenval(AXIS7_NAME)) planner.set_max_jerk(U_AXIS, parser.TERN(AXIS7_ROTATES, value_float, value_linear_units)()),
if (parser.seenval(AXIS8_NAME)) planner.set_max_jerk(V_AXIS, parser.TERN(AXIS8_ROTATES, value_float, value_linear_units)()),
if (parser.seenval(AXIS9_NAME)) planner.set_max_jerk(W_AXIS, parser.TERN(AXIS9_ROTATES, value_float, value_linear_units)())
);
#if HAS_MESH && DISABLED(LIMITED_JERK_EDITING)
if (seenZ && planner.max_jerk.z <= 0.1f)
@ -298,9 +307,10 @@ void GcodeSuite::M205_report(const bool forReplay/*=true*/) {
"Advanced (B<min_segment_time_us> S<min_feedrate> T<min_travel_feedrate>"
TERN_(HAS_JUNCTION_DEVIATION, " J<junc_dev>")
#if HAS_CLASSIC_JERK
LINEAR_AXIS_GANG(
NUM_AXIS_GANG(
" X<max_jerk>", " Y<max_jerk>", " Z<max_jerk>",
" " STR_I "<max_jerk>", " " STR_J "<max_jerk>", " " STR_K "<max_jerk>"
" " STR_I "<max_jerk>", " " STR_J "<max_jerk>", " " STR_K "<max_jerk>",
" " STR_U "<max_jerk>", " " STR_V "<max_jerk>", " " STR_W "<max_jerk>"
)
#endif
TERN_(HAS_CLASSIC_E_JERK, " E<max_jerk>")
@ -314,13 +324,16 @@ void GcodeSuite::M205_report(const bool forReplay/*=true*/) {
, PSTR(" J"), LINEAR_UNIT(planner.junction_deviation_mm)
#endif
#if HAS_CLASSIC_JERK
, LIST_N(DOUBLE(LINEAR_AXES),
, LIST_N(DOUBLE(NUM_AXES),
SP_X_STR, LINEAR_UNIT(planner.max_jerk.x),
SP_Y_STR, LINEAR_UNIT(planner.max_jerk.y),
SP_Z_STR, LINEAR_UNIT(planner.max_jerk.z),
SP_I_STR, LINEAR_UNIT(planner.max_jerk.i),
SP_J_STR, LINEAR_UNIT(planner.max_jerk.j),
SP_K_STR, LINEAR_UNIT(planner.max_jerk.k)
SP_I_STR, I_AXIS_UNIT(planner.max_jerk.i),
SP_J_STR, J_AXIS_UNIT(planner.max_jerk.j),
SP_K_STR, K_AXIS_UNIT(planner.max_jerk.k),
SP_U_STR, U_AXIS_UNIT(planner.max_jerk.u),
SP_V_STR, V_AXIS_UNIT(planner.max_jerk.v),
SP_W_STR, W_AXIS_UNIT(planner.max_jerk.w)
)
#if HAS_CLASSIC_E_JERK
, SP_E_STR, LINEAR_UNIT(planner.max_jerk.e)

View File

@ -50,9 +50,12 @@
* W[linear] 0/1 Enable park & Z Raise
* X[linear] Park X (Requires TOOLCHANGE_PARK)
* Y[linear] Park Y (Requires TOOLCHANGE_PARK)
* I[linear] Park I (Requires TOOLCHANGE_PARK and LINEAR_AXES >= 4)
* J[linear] Park J (Requires TOOLCHANGE_PARK and LINEAR_AXES >= 5)
* K[linear] Park K (Requires TOOLCHANGE_PARK and LINEAR_AXES >= 6)
* I[linear] Park I (Requires TOOLCHANGE_PARK and NUM_AXES >= 4)
* J[linear] Park J (Requires TOOLCHANGE_PARK and NUM_AXES >= 5)
* K[linear] Park K (Requires TOOLCHANGE_PARK and NUM_AXES >= 6)
* C[linear] Park U (Requires TOOLCHANGE_PARK and NUM_AXES >= 7)
* H[linear] Park V (Requires TOOLCHANGE_PARK and NUM_AXES >= 8)
* O[linear] Park W (Requires TOOLCHANGE_PARK and NUM_AXES >= 9)
* Z[linear] Z Raise
* F[speed] Fan Speed 0-255
* D[seconds] Fan time
@ -95,13 +98,22 @@ void GcodeSuite::M217() {
if (parser.seenval('Y')) { const int16_t v = parser.value_linear_units(); toolchange_settings.change_point.y = constrain(v, Y_MIN_POS, Y_MAX_POS); }
#endif
#if HAS_I_AXIS
if (parser.seenval('I')) { const int16_t v = parser.value_linear_units(); toolchange_settings.change_point.i = constrain(v, I_MIN_POS, I_MAX_POS); }
if (parser.seenval('I')) { const int16_t v = parser.TERN(AXIS4_ROTATES, value_int, value_linear_units)(); toolchange_settings.change_point.i = constrain(v, I_MIN_POS, I_MAX_POS); }
#endif
#if HAS_J_AXIS
if (parser.seenval('J')) { const int16_t v = parser.value_linear_units(); toolchange_settings.change_point.j = constrain(v, J_MIN_POS, J_MAX_POS); }
if (parser.seenval('J')) { const int16_t v = parser.TERN(AXIS5_ROTATES, value_int, value_linear_units)(); toolchange_settings.change_point.j = constrain(v, J_MIN_POS, J_MAX_POS); }
#endif
#if HAS_K_AXIS
if (parser.seenval('K')) { const int16_t v = parser.value_linear_units(); toolchange_settings.change_point.k = constrain(v, K_MIN_POS, K_MAX_POS); }
if (parser.seenval('K')) { const int16_t v = parser.TERN(AXIS6_ROTATES, value_int, value_linear_units)(); toolchange_settings.change_point.k = constrain(v, K_MIN_POS, K_MAX_POS); }
#endif
#if HAS_U_AXIS
if (parser.seenval('C')) { const int16_t v = parser.TERN(AXIS7_ROTATES, value_int, value_linear_units)(); toolchange_settings.change_point.u = constrain(v, U_MIN_POS, U_MAX_POS); }
#endif
#if HAS_V_AXIS
if (parser.seenval('H')) { const int16_t v = parser.TERN(AXIS8_ROTATES, value_int, value_linear_units)(); toolchange_settings.change_point.v = constrain(v, V_MIN_POS, V_MAX_POS); }
#endif
#if HAS_W_AXIS
if (parser.seenval('O')) { const int16_t v = parser.TERN(AXIS9_ROTATES, value_int, value_linear_units)(); toolchange_settings.change_point.w = constrain(v, W_MIN_POS, W_MAX_POS); }
#endif
#endif
@ -167,24 +179,23 @@ void GcodeSuite::M217_report(const bool forReplay/*=true*/) {
#endif
#if ENABLED(TOOLCHANGE_PARK)
{
SERIAL_ECHOPGM(" W", LINEAR_UNIT(toolchange_settings.enable_park));
SERIAL_ECHOPGM_P(
SP_X_STR, LINEAR_UNIT(toolchange_settings.change_point.x)
#if HAS_Y_AXIS
, SP_Y_STR, LINEAR_UNIT(toolchange_settings.change_point.y)
#endif
#if HAS_I_AXIS
, SP_I_STR, LINEAR_UNIT(toolchange_settings.change_point.i)
#endif
#if HAS_J_AXIS
, SP_J_STR, LINEAR_UNIT(toolchange_settings.change_point.j)
#endif
#if HAS_K_AXIS
, SP_K_STR, LINEAR_UNIT(toolchange_settings.change_point.k)
#if SECONDARY_AXES >= 1
, LIST_N(DOUBLE(SECONDARY_AXES)
, SP_I_STR, I_AXIS_UNIT(toolchange_settings.change_point.i)
, SP_J_STR, J_AXIS_UNIT(toolchange_settings.change_point.j)
, SP_K_STR, K_AXIS_UNIT(toolchange_settings.change_point.k)
, SP_C_STR, U_AXIS_UNIT(toolchange_settings.change_point.u)
, PSTR(" H"), V_AXIS_UNIT(toolchange_settings.change_point.v)
, PSTR(" O"), W_AXIS_UNIT(toolchange_settings.change_point.w)
)
#endif
);
}
#endif
#if ENABLED(TOOLCHANGE_FS_PRIME_FIRST_USED)

View File

@ -24,7 +24,7 @@
#include "../../module/planner.h"
/**
* M92: Set axis steps-per-unit for one or more axes, X, Y, Z, [I, [J, [K]]] and E.
* M92: Set axis steps-per-unit for one or more axes, X, Y, Z, [I, [J, [K, [U, [V, [W,]]]]]] and E.
* (Follows the same syntax as G92)
*
* With multiple extruders use T to specify which one.
@ -92,14 +92,17 @@ void GcodeSuite::M92() {
void GcodeSuite::M92_report(const bool forReplay/*=true*/, const int8_t e/*=-1*/) {
report_heading_etc(forReplay, F(STR_STEPS_PER_UNIT));
SERIAL_ECHOPGM_P(LIST_N(DOUBLE(LINEAR_AXES),
SERIAL_ECHOPGM_P(LIST_N(DOUBLE(NUM_AXES),
PSTR(" M92 X"), LINEAR_UNIT(planner.settings.axis_steps_per_mm[X_AXIS]),
SP_Y_STR, LINEAR_UNIT(planner.settings.axis_steps_per_mm[Y_AXIS]),
SP_Z_STR, LINEAR_UNIT(planner.settings.axis_steps_per_mm[Z_AXIS]),
SP_I_STR, LINEAR_UNIT(planner.settings.axis_steps_per_mm[I_AXIS]),
SP_J_STR, LINEAR_UNIT(planner.settings.axis_steps_per_mm[J_AXIS]),
SP_K_STR, LINEAR_UNIT(planner.settings.axis_steps_per_mm[K_AXIS]))
);
SP_I_STR, I_AXIS_UNIT(planner.settings.axis_steps_per_mm[I_AXIS]),
SP_J_STR, J_AXIS_UNIT(planner.settings.axis_steps_per_mm[J_AXIS]),
SP_K_STR, K_AXIS_UNIT(planner.settings.axis_steps_per_mm[K_AXIS]),
SP_U_STR, U_AXIS_UNIT(planner.settings.axis_steps_per_mm[U_AXIS]),
SP_V_STR, V_AXIS_UNIT(planner.settings.axis_steps_per_mm[V_AXIS]),
SP_W_STR, W_AXIS_UNIT(planner.settings.axis_steps_per_mm[W_AXIS])
));
#if HAS_EXTRUDERS && DISABLED(DISTINCT_E_FACTORS)
SERIAL_ECHOPGM_P(SP_E_STR, VOLUMETRIC_UNIT(planner.settings.axis_steps_per_mm[E_AXIS]));
#endif

View File

@ -46,13 +46,16 @@ inline stepper_flags_t selected_axis_bits() {
selected.bits = selected.e_bits();
}
#endif
selected.bits |= LINEAR_AXIS_GANG(
selected.bits |= NUM_AXIS_GANG(
(parser.seen_test('X') << X_AXIS),
| (parser.seen_test('Y') << Y_AXIS),
| (parser.seen_test('Z') << Z_AXIS),
| (parser.seen_test(AXIS4_NAME) << I_AXIS),
| (parser.seen_test(AXIS5_NAME) << J_AXIS),
| (parser.seen_test(AXIS6_NAME) << K_AXIS)
| (parser.seen_test(AXIS6_NAME) << K_AXIS),
| (parser.seen_test(AXIS7_NAME) << U_AXIS),
| (parser.seen_test(AXIS8_NAME) << V_AXIS),
| (parser.seen_test(AXIS9_NAME) << W_AXIS)
);
return selected;
}
@ -69,7 +72,7 @@ void do_enable(const stepper_flags_t to_enable) {
ena_mask_t also_enabled = 0; // Track steppers enabled due to overlap
// Enable all flagged axes
LOOP_LINEAR_AXES(a) {
LOOP_NUM_AXES(a) {
if (TEST(shall_enable, a)) {
stepper.enable_axis(AxisEnum(a)); // Mark and enable the requested axis
DEBUG_ECHOLNPGM("Enabled ", axis_codes[a], " (", a, ") with overlap ", hex_word(enable_overlap[a]), " ... Enabled: ", hex_word(stepper.axis_enabled.bits));
@ -89,7 +92,7 @@ void do_enable(const stepper_flags_t to_enable) {
if ((also_enabled &= ~(shall_enable | was_enabled))) {
SERIAL_CHAR('(');
LOOP_LINEAR_AXES(a) if (TEST(also_enabled, a)) SERIAL_CHAR(axis_codes[a], ' ');
LOOP_NUM_AXES(a) if (TEST(also_enabled, a)) SERIAL_CHAR(AXIS_CHAR(a), ' ');
#if HAS_EXTRUDERS
#define _EN_ALSO(N) if (TEST(also_enabled, INDEX_OF_AXIS(E_AXIS, N))) SERIAL_CHAR('E', '0' + N, ' ');
REPEAT(EXTRUDERS, _EN_ALSO)
@ -125,13 +128,16 @@ void GcodeSuite::M17() {
stepper.enable_e_steppers();
}
#endif
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
if (parser.seen_test('X')) stepper.enable_axis(X_AXIS),
if (parser.seen_test('Y')) stepper.enable_axis(Y_AXIS),
if (parser.seen_test('Z')) stepper.enable_axis(Z_AXIS),
if (parser.seen_test(AXIS4_NAME)) stepper.enable_axis(I_AXIS),
if (parser.seen_test(AXIS5_NAME)) stepper.enable_axis(J_AXIS),
if (parser.seen_test(AXIS6_NAME)) stepper.enable_axis(K_AXIS)
if (parser.seen_test(AXIS6_NAME)) stepper.enable_axis(K_AXIS),
if (parser.seen_test(AXIS7_NAME)) stepper.enable_axis(U_AXIS),
if (parser.seen_test(AXIS8_NAME)) stepper.enable_axis(V_AXIS),
if (parser.seen_test(AXIS9_NAME)) stepper.enable_axis(W_AXIS)
);
}
}
@ -149,7 +155,7 @@ void try_to_disable(const stepper_flags_t to_disable) {
if (!still_enabled) return;
// Attempt to disable all flagged axes
LOOP_LINEAR_AXES(a)
LOOP_NUM_AXES(a)
if (TEST(to_disable.bits, a)) {
DEBUG_ECHOPGM("Try to disable ", axis_codes[a], " (", a, ") with overlap ", hex_word(enable_overlap[a]), " ... ");
if (stepper.disable_axis(AxisEnum(a))) { // Mark the requested axis and request to disable
@ -178,7 +184,7 @@ void try_to_disable(const stepper_flags_t to_disable) {
auto overlap_warning = [](const ena_mask_t axis_bits) {
SERIAL_ECHOPGM(" not disabled. Shared with");
LOOP_LINEAR_AXES(a) if (TEST(axis_bits, a)) SERIAL_CHAR(' ', axis_codes[a]);
LOOP_NUM_AXES(a) if (TEST(axis_bits, a)) SERIAL_CHAR(' ', axis_codes[a]);
#if HAS_EXTRUDERS
#define _EN_STILLON(N) if (TEST(axis_bits, INDEX_OF_AXIS(E_AXIS, N))) SERIAL_CHAR(' ', 'E', '0' + N);
REPEAT(EXTRUDERS, _EN_STILLON)
@ -187,7 +193,7 @@ void try_to_disable(const stepper_flags_t to_disable) {
};
// If any of the requested axes are still enabled, give a warning
LOOP_LINEAR_AXES(a) {
LOOP_NUM_AXES(a) {
if (TEST(still_enabled, a)) {
SERIAL_CHAR(axis_codes[a]);
overlap_warning(stepper.axis_enabled.bits & enable_overlap[a]);
@ -238,13 +244,16 @@ void GcodeSuite::M18_M84() {
stepper.disable_e_steppers();
}
#endif
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
if (parser.seen_test('X')) stepper.disable_axis(X_AXIS),
if (parser.seen_test('Y')) stepper.disable_axis(Y_AXIS),
if (parser.seen_test('Z')) stepper.disable_axis(Z_AXIS),
if (parser.seen_test(AXIS4_NAME)) stepper.disable_axis(I_AXIS),
if (parser.seen_test(AXIS5_NAME)) stepper.disable_axis(J_AXIS),
if (parser.seen_test(AXIS6_NAME)) stepper.disable_axis(K_AXIS)
if (parser.seen_test(AXIS6_NAME)) stepper.disable_axis(K_AXIS),
if (parser.seen_test(AXIS7_NAME)) stepper.disable_axis(U_AXIS),
if (parser.seen_test(AXIS8_NAME)) stepper.disable_axis(V_AXIS),
if (parser.seen_test(AXIS9_NAME)) stepper.disable_axis(W_AXIS)
);
}
}

View File

@ -146,7 +146,7 @@
HOTEND_LOOP() {
DEBUG_ECHOPGM_P(SP_T_STR, e);
LOOP_LINEAR_AXES(a) DEBUG_ECHOPGM(" hotend_offset[", e, "].", AS_CHAR(AXIS_CHAR(a) | 0x20), "=", hotend_offset[e][a]);
LOOP_NUM_AXES(a) DEBUG_ECHOPGM(" hotend_offset[", e, "].", AS_CHAR(AXIS_CHAR(a) | 0x20), "=", hotend_offset[e][a]);
DEBUG_EOL();
}
DEBUG_EOL();

View File

@ -285,6 +285,25 @@ void GcodeSuite::M906() {
break;
#endif
#if AXIS_IS_L64XX(I)
case I_AXIS: L6470_SET_KVAL_HOLD(I); break;
#endif
#if AXIS_IS_L64XX(J)
case J_AXIS: L6470_SET_KVAL_HOLD(J); break;
#endif
#if AXIS_IS_L64XX(K)
case K_AXIS: L6470_SET_KVAL_HOLD(K); break;
#endif
#if AXIS_IS_L64XX(U)
case U_AXIS: L6470_SET_KVAL_HOLD(U); break;
#endif
#if AXIS_IS_L64XX(V)
case V_AXIS: L6470_SET_KVAL_HOLD(V); break;
#endif
#if AXIS_IS_L64XX(W)
case W_AXIS: L6470_SET_KVAL_HOLD(W); break;
#endif
#if AXIS_IS_L64XX(E0) || AXIS_IS_L64XX(E1) || AXIS_IS_L64XX(E2) || AXIS_IS_L64XX(E3) || AXIS_IS_L64XX(E4) || AXIS_IS_L64XX(E5) || AXIS_IS_L64XX(E6) || AXIS_IS_L64XX(E7)
case E_AXIS: {
const int8_t eindex = get_target_e_stepper_from_command(-2);
@ -346,6 +365,24 @@ void GcodeSuite::M906() {
#if AXIS_IS_L64XX(Z4)
L64XX_REPORT_CURRENT(Z4);
#endif
#if AXIS_IS_L64XX(I)
L64XX_REPORT_CURRENT(I);
#endif
#if AXIS_IS_L64XX(J)
L64XX_REPORT_CURRENT(J);
#endif
#if AXIS_IS_L64XX(K)
L64XX_REPORT_CURRENT(K);
#endif
#if AXIS_IS_L64XX(U)
L64XX_REPORT_CURRENT(U);
#endif
#if AXIS_IS_L64XX(V)
L64XX_REPORT_CURRENT(V);
#endif
#if AXIS_IS_L64XX(W)
L64XX_REPORT_CURRENT(W);
#endif
#if AXIS_IS_L64XX(E0)
L64XX_REPORT_CURRENT(E0);
#endif

View File

@ -39,7 +39,7 @@
#endif
/**
* M907: Set digital trimpot motor current using axis codes X [Y] [Z] [E]
* M907: Set digital trimpot motor current using axis codes X [Y] [Z] [I] [J] [K] [U] [V] [W] [E]
* B<current> - Special case for 4th (E) axis
* S<current> - Special case to set first 3 axes
*/
@ -49,15 +49,15 @@ void GcodeSuite::M907() {
if (!parser.seen("BS" LOGICAL_AXES_STRING))
return M907_report();
LOOP_LOGICAL_AXES(i) if (parser.seenval(axis_codes[i])) stepper.set_digipot_current(i, parser.value_int());
LOOP_LOGICAL_AXES(i) if (parser.seenval(IAXIS_CHAR(i))) stepper.set_digipot_current(i, parser.value_int());
if (parser.seenval('B')) stepper.set_digipot_current(4, parser.value_int());
if (parser.seenval('S')) LOOP_LE_N(i, 4) stepper.set_digipot_current(i, parser.value_int());
#elif HAS_MOTOR_CURRENT_PWM
if (!parser.seen(
#if ANY_PIN(MOTOR_CURRENT_PWM_X, MOTOR_CURRENT_PWM_Y, MOTOR_CURRENT_PWM_XY)
"XY"
#if ANY_PIN(MOTOR_CURRENT_PWM_X, MOTOR_CURRENT_PWM_Y, MOTOR_CURRENT_PWM_XY, MOTOR_CURRENT_PWM_I, MOTOR_CURRENT_PWM_J, MOTOR_CURRENT_PWM_K, MOTOR_CURRENT_PWM_U, MOTOR_CURRENT_PWM_V, MOTOR_CURRENT_PWM_W)
"XY" SECONDARY_AXIS_GANG("I", "J", "K", "U", "V", "W")
#endif
#if PIN_EXISTS(MOTOR_CURRENT_PWM_Z)
"Z"
@ -67,8 +67,12 @@ void GcodeSuite::M907() {
#endif
)) return M907_report();
#if ANY_PIN(MOTOR_CURRENT_PWM_X, MOTOR_CURRENT_PWM_Y, MOTOR_CURRENT_PWM_XY)
if (parser.seenval('X') || parser.seenval('Y')) stepper.set_digipot_current(0, parser.value_int());
#if ANY_PIN(MOTOR_CURRENT_PWM_X, MOTOR_CURRENT_PWM_Y, MOTOR_CURRENT_PWM_XY, MOTOR_CURRENT_PWM_I, MOTOR_CURRENT_PWM_J, MOTOR_CURRENT_PWM_K, MOTOR_CURRENT_PWM_U, MOTOR_CURRENT_PWM_V, MOTOR_CURRENT_PWM_W)
if (NUM_AXIS_GANG(
parser.seenval('X'), || parser.seenval('Y'), || false,
|| parser.seenval('I'), || parser.seenval('J'), || parser.seenval('K'),
|| parser.seenval('U'), || parser.seenval('V'), || parser.seenval('W')
)) stepper.set_digipot_current(0, parser.value_int());
#endif
#if PIN_EXISTS(MOTOR_CURRENT_PWM_Z)
if (parser.seenval('Z')) stepper.set_digipot_current(1, parser.value_int());
@ -81,7 +85,7 @@ void GcodeSuite::M907() {
#if HAS_MOTOR_CURRENT_I2C
// this one uses actual amps in floating point
LOOP_LOGICAL_AXES(i) if (parser.seenval(axis_codes[i])) digipot_i2c.set_current(i, parser.value_float());
LOOP_LOGICAL_AXES(i) if (parser.seenval(IAXIS_CHAR(i))) digipot_i2c.set_current(i, parser.value_float());
// Additional extruders use B,C,D for channels 4,5,6.
// TODO: Change these parameters because 'E' is used. B<index>?
#if HAS_EXTRUDERS
@ -95,7 +99,7 @@ void GcodeSuite::M907() {
const float dac_percent = parser.value_float();
LOOP_LE_N(i, 4) stepper_dac.set_current_percent(i, dac_percent);
}
LOOP_LOGICAL_AXES(i) if (parser.seenval(axis_codes[i])) stepper_dac.set_current_percent(i, parser.value_float());
LOOP_LOGICAL_AXES(i) if (parser.seenval(IAXIS_CHAR(i))) stepper_dac.set_current_percent(i, parser.value_float());
#endif
}
@ -105,14 +109,14 @@ void GcodeSuite::M907() {
report_heading_etc(forReplay, F(STR_STEPPER_MOTOR_CURRENTS));
#if HAS_MOTOR_CURRENT_PWM
SERIAL_ECHOLNPGM_P( // PWM-based has 3 values:
PSTR(" M907 X"), stepper.motor_current_setting[0] // X and Y
PSTR(" M907 X"), stepper.motor_current_setting[0] // X, Y, (I, J, K, U, V, W)
, SP_Z_STR, stepper.motor_current_setting[1] // Z
, SP_E_STR, stepper.motor_current_setting[2] // E
);
#elif HAS_MOTOR_CURRENT_SPI
SERIAL_ECHOPGM(" M907"); // SPI-based has 5 values:
LOOP_LOGICAL_AXES(q) { // X Y Z (I J K) E (map to X Y Z (I J K) E0 by default)
SERIAL_CHAR(' ', axis_codes[q]);
LOOP_LOGICAL_AXES(q) { // X Y Z (I J K U V W) E (map to X Y Z (I J K U V W) E0 by default)
SERIAL_CHAR(' ', IAXIS_CHAR(q));
SERIAL_ECHO(stepper.motor_current_setting[q]);
}
SERIAL_CHAR(' ', 'B'); // B (maps to E1 by default)

View File

@ -48,10 +48,14 @@ void GcodeSuite::G60() {
#if ENABLED(SAVED_POSITIONS_DEBUG)
{
DEBUG_ECHOPGM(STR_SAVED_POS " S", slot, " :");
const xyze_pos_t &pos = stored_position[slot];
DEBUG_ECHOPGM(STR_SAVED_POS " S", slot, " :");
DEBUG_ECHOLNPGM_P(
LIST_N(DOUBLE(LINEAR_AXES), PSTR(" : X"), pos.x, SP_Y_STR, pos.y, SP_Z_STR, pos.z, SP_I_STR, pos.i, SP_J_STR, pos.j, SP_K_STR, pos.k)
LIST_N(DOUBLE(NUM_AXES),
SP_X_LBL, pos.x, SP_Y_LBL, pos.y, SP_Z_LBL, pos.z,
SP_I_LBL, pos.i, SP_J_LBL, pos.j, SP_K_LBL, pos.k,
SP_U_LBL, pos.u, SP_V_LBL, pos.v, SP_W_LBL, pos.w
)
#if HAS_EXTRUDERS
, SP_E_LBL, pos.e
#endif

View File

@ -68,9 +68,9 @@ void GcodeSuite::G61() {
SYNC_E(stored_position[slot].e);
}
else {
if (parser.seen(LINEAR_AXIS_GANG("X", "Y", "Z", STR_I, STR_J, STR_K))) {
if (parser.seen(NUM_AXIS_GANG("X", "Y", "Z", STR_I, STR_J, STR_K, STR_U, STR_V, STR_W))) {
DEBUG_ECHOPGM(STR_RESTORING_POS " S", slot);
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
destination[i] = parser.seen(AXIS_CHAR(i))
? stored_position[slot][i] + parser.value_axis_units((AxisEnum)i)
: current_position[i];

View File

@ -52,6 +52,9 @@
* A<pos> = Override park position A (requires AXIS*_NAME 'A')
* B<pos> = Override park position B (requires AXIS*_NAME 'B')
* C<pos> = Override park position C (requires AXIS*_NAME 'C')
* U<pos> = Override park position U (requires AXIS*_NAME 'U')
* V<pos> = Override park position V (requires AXIS*_NAME 'V')
* W<pos> = Override park position W (requires AXIS*_NAME 'W')
* Z<linear> = Override Z raise
*
* With an LCD menu:
@ -64,17 +67,22 @@ void GcodeSuite::M125() {
xyz_pos_t park_point = NOZZLE_PARK_POINT;
// Move to filament change position or given position
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
if (parser.seenval('X')) park_point.x = RAW_X_POSITION(parser.linearval('X')),
if (parser.seenval('Y')) park_point.y = RAW_Y_POSITION(parser.linearval('Y')),
NOOP,
if (parser.seenval(AXIS4_NAME)) park_point.i = RAW_I_POSITION(parser.linearval(AXIS4_NAME)),
if (parser.seenval(AXIS5_NAME)) park_point.j = RAW_J_POSITION(parser.linearval(AXIS5_NAME)),
if (parser.seenval(AXIS6_NAME)) park_point.k = RAW_K_POSITION(parser.linearval(AXIS6_NAME))
if (parser.seenval(AXIS4_NAME)) park_point.i = RAW_X_POSITION(parser.linearval(AXIS4_NAME)),
if (parser.seenval(AXIS5_NAME)) park_point.j = RAW_X_POSITION(parser.linearval(AXIS5_NAME)),
if (parser.seenval(AXIS6_NAME)) park_point.k = RAW_X_POSITION(parser.linearval(AXIS6_NAME)),
if (parser.seenval(AXIS7_NAME)) park_point.u = RAW_X_POSITION(parser.linearval(AXIS7_NAME)),
if (parser.seenval(AXIS8_NAME)) park_point.v = RAW_X_POSITION(parser.linearval(AXIS8_NAME)),
if (parser.seenval(AXIS9_NAME)) park_point.w = RAW_X_POSITION(parser.linearval(AXIS9_NAME))
);
// Lift Z axis
#if HAS_Z_AXIS
if (parser.seenval('Z')) park_point.z = parser.linearval('Z');
#endif
#if HAS_HOTEND_OFFSET && NONE(DUAL_X_CARRIAGE, DELTA)
park_point += hotend_offset[active_extruder];

View File

@ -54,8 +54,14 @@
*
* E[distance] - Retract the filament this far
* Z[distance] - Move the Z axis by this distance
* X[position] - Move to this X position, with Y
* Y[position] - Move to this Y position, with X
* X[position] - Move to this X position (instead of NOZZLE_PARK_POINT.x)
* Y[position] - Move to this Y position (instead of NOZZLE_PARK_POINT.y)
* I[position] - Move to this I position (instead of NOZZLE_PARK_POINT.i)
* J[position] - Move to this J position (instead of NOZZLE_PARK_POINT.j)
* K[position] - Move to this K position (instead of NOZZLE_PARK_POINT.k)
* C[position] - Move to this U position (instead of NOZZLE_PARK_POINT.u)
* H[position] - Move to this V position (instead of NOZZLE_PARK_POINT.v)
* O[position] - Move to this W position (instead of NOZZLE_PARK_POINT.w)
* U[distance] - Retract distance for removal (manual reload)
* L[distance] - Extrude distance for insertion (manual reload)
* B[count] - Number of times to beep, -1 for indefinite (if equipped with a buzzer)
@ -117,26 +123,25 @@ void GcodeSuite::M600() {
xyz_pos_t park_point NOZZLE_PARK_POINT;
// Move XY axes to filament change position or given position
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
if (parser.seenval('X')) park_point.x = parser.linearval('X'),
if (parser.seenval('Y')) park_point.y = parser.linearval('Y'),
if (parser.seenval('Z')) park_point.z = parser.linearval('Z'), // Lift Z axis
if (parser.seenval(AXIS4_NAME)) park_point.i = parser.linearval(AXIS4_NAME),
if (parser.seenval(AXIS5_NAME)) park_point.j = parser.linearval(AXIS5_NAME),
if (parser.seenval(AXIS6_NAME)) park_point.k = parser.linearval(AXIS6_NAME)
if (parser.seenval('I')) park_point.i = parser.linearval('I'),
if (parser.seenval('J')) park_point.j = parser.linearval('J'),
if (parser.seenval('K')) park_point.k = parser.linearval('K'),
if (parser.seenval('C')) park_point.u = parser.linearval('C'), // U axis
if (parser.seenval('H')) park_point.v = parser.linearval('H'), // V axis
if (parser.seenval('O')) park_point.w = parser.linearval('O') // W axis
);
#if HAS_HOTEND_OFFSET && NONE(DUAL_X_CARRIAGE, DELTA)
park_point += hotend_offset[active_extruder];
#endif
#if ENABLED(MMU2_MENUS)
// Unload filament
// For MMU2, when enabled, reset retract value so it doesn't mess with MMU filament handling
const float unload_length = standardM600 ? -ABS(parser.axisunitsval('U', E_AXIS, fc_settings[active_extruder].unload_length)) : 0.5f;
#else
// Unload filament
const float unload_length = -ABS(parser.axisunitsval('U', E_AXIS, fc_settings[active_extruder].unload_length));
#endif
const int beep_count = parser.intval('B', -1
#ifdef FILAMENT_CHANGE_ALERT_BEEPS

View File

@ -85,6 +85,15 @@ static void set_stealth_status(const bool enable, const int8_t eindex) {
#if K_HAS_STEALTHCHOP
case K_AXIS: TMC_SET_STEALTH(K); break;
#endif
#if U_HAS_STEALTHCHOP
case U_AXIS: TMC_SET_STEALTH(U); break;
#endif
#if V_HAS_STEALTHCHOP
case V_AXIS: TMC_SET_STEALTH(V); break;
#endif
#if W_HAS_STEALTHCHOP
case W_AXIS: TMC_SET_STEALTH(W); break;
#endif
#if E_STEPPERS
case E_AXIS: {
@ -115,6 +124,9 @@ static void say_stealth_status() {
OPTCODE( I_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(I))
OPTCODE( J_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(J))
OPTCODE( K_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(K))
OPTCODE( U_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(U))
OPTCODE( V_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(V))
OPTCODE( W_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(W))
OPTCODE(E0_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(E0))
OPTCODE(E1_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(E1))
OPTCODE(E2_HAS_STEALTHCHOP, TMC_SAY_STEALTH_STATUS(E2))
@ -157,17 +169,23 @@ void GcodeSuite::M569_report(const bool forReplay/*=true*/) {
chop_z = TERN0(Z_HAS_STEALTHCHOP, stepperZ.get_stored_stealthChop()),
chop_i = TERN0(I_HAS_STEALTHCHOP, stepperI.get_stored_stealthChop()),
chop_j = TERN0(J_HAS_STEALTHCHOP, stepperJ.get_stored_stealthChop()),
chop_k = TERN0(K_HAS_STEALTHCHOP, stepperK.get_stored_stealthChop());
chop_k = TERN0(K_HAS_STEALTHCHOP, stepperK.get_stored_stealthChop()),
chop_u = TERN0(U_HAS_STEALTHCHOP, stepperU.get_stored_stealthChop()),
chop_v = TERN0(V_HAS_STEALTHCHOP, stepperV.get_stored_stealthChop()),
chop_w = TERN0(W_HAS_STEALTHCHOP, stepperW.get_stored_stealthChop());
if (chop_x || chop_y || chop_z || chop_i || chop_j || chop_k) {
if (chop_x || chop_y || chop_z || chop_i || chop_j || chop_k || chop_u || chop_v || chop_w) {
say_M569(forReplay);
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
if (chop_x) SERIAL_ECHOPGM_P(SP_X_STR),
if (chop_y) SERIAL_ECHOPGM_P(SP_Y_STR),
if (chop_z) SERIAL_ECHOPGM_P(SP_Z_STR),
if (chop_i) SERIAL_ECHOPGM_P(SP_I_STR),
if (chop_j) SERIAL_ECHOPGM_P(SP_J_STR),
if (chop_k) SERIAL_ECHOPGM_P(SP_K_STR)
if (chop_k) SERIAL_ECHOPGM_P(SP_K_STR),
if (chop_u) SERIAL_ECHOPGM_P(SP_U_STR),
if (chop_v) SERIAL_ECHOPGM_P(SP_V_STR),
if (chop_w) SERIAL_ECHOPGM_P(SP_W_STR)
);
SERIAL_EOL();
}
@ -190,6 +208,9 @@ void GcodeSuite::M569_report(const bool forReplay/*=true*/) {
if (TERN0( I_HAS_STEALTHCHOP, stepperI.get_stored_stealthChop())) { say_M569(forReplay, FPSTR(SP_I_STR), true); }
if (TERN0( J_HAS_STEALTHCHOP, stepperJ.get_stored_stealthChop())) { say_M569(forReplay, FPSTR(SP_J_STR), true); }
if (TERN0( K_HAS_STEALTHCHOP, stepperK.get_stored_stealthChop())) { say_M569(forReplay, FPSTR(SP_K_STR), true); }
if (TERN0( U_HAS_STEALTHCHOP, stepperU.get_stored_stealthChop())) { say_M569(forReplay, FPSTR(SP_U_STR), true); }
if (TERN0( V_HAS_STEALTHCHOP, stepperV.get_stored_stealthChop())) { say_M569(forReplay, FPSTR(SP_V_STR), true); }
if (TERN0( W_HAS_STEALTHCHOP, stepperW.get_stored_stealthChop())) { say_M569(forReplay, FPSTR(SP_W_STR), true); }
if (TERN0(E0_HAS_STEALTHCHOP, stepperE0.get_stored_stealthChop())) { say_M569(forReplay, F("T0 E"), true); }
if (TERN0(E1_HAS_STEALTHCHOP, stepperE1.get_stored_stealthChop())) { say_M569(forReplay, F("T1 E"), true); }

View File

@ -44,6 +44,9 @@ static void tmc_print_current(TMC &st) {
* A[current] - Set mA current for A driver(s) (Requires AXIS*_NAME 'A')
* B[current] - Set mA current for B driver(s) (Requires AXIS*_NAME 'B')
* C[current] - Set mA current for C driver(s) (Requires AXIS*_NAME 'C')
* U[current] - Set mA current for U driver(s) (Requires AXIS*_NAME 'U')
* V[current] - Set mA current for V driver(s) (Requires AXIS*_NAME 'V')
* W[current] - Set mA current for W driver(s) (Requires AXIS*_NAME 'W')
* E[current] - Set mA current for E driver(s)
*
* I[index] - Axis sub-index (Omit or 0 for X, Y, Z; 1 for X2, Y2, Z2; 2 for Z3; 3 for Z4.)
@ -114,6 +117,15 @@ void GcodeSuite::M906() {
#if AXIS_IS_TMC(K)
case K_AXIS: TMC_SET_CURRENT(K); break;
#endif
#if AXIS_IS_TMC(U)
case U_AXIS: TMC_SET_CURRENT(U); break;
#endif
#if AXIS_IS_TMC(V)
case V_AXIS: TMC_SET_CURRENT(V); break;
#endif
#if AXIS_IS_TMC(W)
case W_AXIS: TMC_SET_CURRENT(W); break;
#endif
#if AXIS_IS_TMC(E0) || AXIS_IS_TMC(E1) || AXIS_IS_TMC(E2) || AXIS_IS_TMC(E3) || AXIS_IS_TMC(E4) || AXIS_IS_TMC(E5) || AXIS_IS_TMC(E6) || AXIS_IS_TMC(E7)
case E_AXIS: {
@ -181,6 +193,16 @@ void GcodeSuite::M906() {
#if AXIS_IS_TMC(K)
TMC_SAY_CURRENT(K);
#endif
#if AXIS_IS_TMC(U)
TMC_SAY_CURRENT(U);
#endif
#if AXIS_IS_TMC(V)
TMC_SAY_CURRENT(V);
#endif
#if AXIS_IS_TMC(W)
TMC_SAY_CURRENT(W);
#endif
#if AXIS_IS_TMC(E0)
TMC_SAY_CURRENT(E0);
#endif
@ -217,7 +239,8 @@ void GcodeSuite::M906_report(const bool forReplay/*=true*/) {
};
#if AXIS_IS_TMC(X) || AXIS_IS_TMC(Y) || AXIS_IS_TMC(Z) \
|| AXIS_IS_TMC(I) || AXIS_IS_TMC(J) || AXIS_IS_TMC(K)
|| AXIS_IS_TMC(I) || AXIS_IS_TMC(J) || AXIS_IS_TMC(K) \
|| AXIS_IS_TMC(U) || AXIS_IS_TMC(V) || AXIS_IS_TMC(W)
say_M906(forReplay);
#if AXIS_IS_TMC(X)
SERIAL_ECHOPGM_P(SP_X_STR, stepperX.getMilliamps());
@ -237,6 +260,15 @@ void GcodeSuite::M906_report(const bool forReplay/*=true*/) {
#if AXIS_IS_TMC(K)
SERIAL_ECHOPGM_P(SP_K_STR, stepperK.getMilliamps());
#endif
#if AXIS_IS_TMC(U)
SERIAL_ECHOPGM_P(SP_U_STR, stepperU.getMilliamps());
#endif
#if AXIS_IS_TMC(V)
SERIAL_ECHOPGM_P(SP_V_STR, stepperV.getMilliamps());
#endif
#if AXIS_IS_TMC(W)
SERIAL_ECHOPGM_P(SP_W_STR, stepperW.getMilliamps());
#endif
SERIAL_EOL();
#endif

View File

@ -53,12 +53,21 @@
#if HAS_K_AXIS && M91x_USE(K)
#define M91x_USE_K 1
#endif
#if HAS_U_AXIS && M91x_USE(U)
#define M91x_USE_U 1
#endif
#if HAS_V_AXIS && M91x_USE(V)
#define M91x_USE_V 1
#endif
#if HAS_W_AXIS && M91x_USE(W)
#define M91x_USE_W 1
#endif
#if M91x_USE_E(0) || M91x_USE_E(1) || M91x_USE_E(2) || M91x_USE_E(3) || M91x_USE_E(4) || M91x_USE_E(5) || M91x_USE_E(6) || M91x_USE_E(7)
#define M91x_SOME_E 1
#endif
#if !M91x_SOME_X && !M91x_SOME_Y && !M91x_SOME_Z && !M91x_USE_I && !M91x_USE_J && !M91x_USE_K && !M91x_SOME_E
#if !M91x_SOME_X && !M91x_SOME_Y && !M91x_SOME_Z && !M91x_USE_I && !M91x_USE_J && !M91x_USE_K && !M91x_USE_U && !M91x_USE_V && !M91x_USE_W && !M91x_SOME_E
#error "MONITOR_DRIVER_STATUS requires at least one TMC2130, 2160, 2208, 2209, 2660, 5130, or 5160."
#endif
@ -109,6 +118,9 @@
TERN_(M91x_USE_I, tmc_report_otpw(stepperI));
TERN_(M91x_USE_J, tmc_report_otpw(stepperJ));
TERN_(M91x_USE_K, tmc_report_otpw(stepperK));
TERN_(M91x_USE_U, tmc_report_otpw(stepperU));
TERN_(M91x_USE_V, tmc_report_otpw(stepperV));
TERN_(M91x_USE_W, tmc_report_otpw(stepperW));
#if M91x_USE_E(0)
tmc_report_otpw(stepperE0);
#endif
@ -137,7 +149,7 @@
/**
* M912: Clear TMC stepper driver overtemperature pre-warn flag held by the library
* Specify one or more axes with X, Y, Z, X1, Y1, Z1, X2, Y2, Z2, Z3, Z4 and E[index].
* Specify one or more axes with X, Y, Z, X1, Y1, Z1, X2, Y2, Z2, Z3, Z4, A, B, C, U, V, W, and E[index].
* If no axes are given, clear all.
*
* Examples:
@ -154,9 +166,12 @@
hasI = TERN0(M91x_USE_I, parser.seen(axis_codes.i)),
hasJ = TERN0(M91x_USE_J, parser.seen(axis_codes.j)),
hasK = TERN0(M91x_USE_K, parser.seen(axis_codes.k)),
hasU = TERN0(M91x_USE_U, parser.seen(axis_codes.u)),
hasV = TERN0(M91x_USE_V, parser.seen(axis_codes.v)),
hasW = TERN0(M91x_USE_W, parser.seen(axis_codes.w)),
hasE = TERN0(M91x_SOME_E, parser.seen(axis_codes.e));
const bool hasNone = !hasE && !hasX && !hasY && !hasZ && !hasI && !hasJ && !hasK;
const bool hasNone = !hasE && !hasX && !hasY && !hasZ && !hasI && !hasJ && !hasK && !hasU && !hasV && !hasW;
#if M91x_SOME_X
const int8_t xval = int8_t(parser.byteval(axis_codes.x, 0xFF));
@ -206,6 +221,18 @@
const int8_t kval = int8_t(parser.byteval(axis_codes.k, 0xFF));
if (hasNone || kval == 1 || (hasK && kval < 0)) tmc_clear_otpw(stepperK);
#endif
#if M91x_USE_U
const int8_t uval = int8_t(parser.byteval(axis_codes.u, 0xFF));
if (hasNone || uval == 1 || (hasU && uval < 0)) tmc_clear_otpw(stepperU);
#endif
#if M91x_USE_V
const int8_t vval = int8_t(parser.byteval(axis_codes.v, 0xFF));
if (hasNone || vval == 1 || (hasV && vval < 0)) tmc_clear_otpw(stepperV);
#endif
#if M91x_USE_W
const int8_t wval = int8_t(parser.byteval(axis_codes.w, 0xFF));
if (hasNone || wval == 1 || (hasW && wval < 0)) tmc_clear_otpw(stepperW);
#endif
#if M91x_SOME_E
const int8_t eval = int8_t(parser.byteval(axis_codes.e, 0xFF));
@ -296,6 +323,15 @@
#if K_HAS_STEALTHCHOP
case K_AXIS: TMC_SET_PWMTHRS(K,K); break;
#endif
#if U_HAS_STEALTHCHOP
case U_AXIS: TMC_SET_PWMTHRS(U,U); break;
#endif
#if V_HAS_STEALTHCHOP
case V_AXIS: TMC_SET_PWMTHRS(V,V); break;
#endif
#if W_HAS_STEALTHCHOP
case W_AXIS: TMC_SET_PWMTHRS(W,W); break;
#endif
#if E0_HAS_STEALTHCHOP || E1_HAS_STEALTHCHOP || E2_HAS_STEALTHCHOP || E3_HAS_STEALTHCHOP || E4_HAS_STEALTHCHOP || E5_HAS_STEALTHCHOP || E6_HAS_STEALTHCHOP || E7_HAS_STEALTHCHOP
case E_AXIS: {
@ -326,6 +362,9 @@
TERN_( I_HAS_STEALTHCHOP, TMC_SAY_PWMTHRS(I,I));
TERN_( J_HAS_STEALTHCHOP, TMC_SAY_PWMTHRS(J,J));
TERN_( K_HAS_STEALTHCHOP, TMC_SAY_PWMTHRS(K,K));
TERN_( U_HAS_STEALTHCHOP, TMC_SAY_PWMTHRS(U,U));
TERN_( V_HAS_STEALTHCHOP, TMC_SAY_PWMTHRS(V,V));
TERN_( W_HAS_STEALTHCHOP, TMC_SAY_PWMTHRS(W,W));
TERN_(E0_HAS_STEALTHCHOP, TMC_SAY_PWMTHRS_E(0));
TERN_(E1_HAS_STEALTHCHOP, TMC_SAY_PWMTHRS_E(1));
@ -397,6 +436,18 @@
say_M913(forReplay);
SERIAL_ECHOLNPGM_P(SP_K_STR, stepperK.get_pwm_thrs());
#endif
#if U_HAS_STEALTHCHOP
say_M913(forReplay);
SERIAL_ECHOLNPGM_P(SP_U_STR, stepperU.get_pwm_thrs());
#endif
#if V_HAS_STEALTHCHOP
say_M913(forReplay);
SERIAL_ECHOLNPGM_P(SP_V_STR, stepperV.get_pwm_thrs());
#endif
#if W_HAS_STEALTHCHOP
say_M913(forReplay);
SERIAL_ECHOLNPGM_P(SP_W_STR, stepperW.get_pwm_thrs());
#endif
#if E0_HAS_STEALTHCHOP
say_M913(forReplay);
@ -451,7 +502,7 @@
bool report = true;
const uint8_t index = parser.byteval('I');
LOOP_LINEAR_AXES(i) if (parser.seen(AXIS_CHAR(i))) {
LOOP_NUM_AXES(i) if (parser.seen(AXIS_CHAR(i))) {
const int16_t value = parser.value_int();
report = false;
switch (i) {
@ -484,6 +535,15 @@
#if K_SENSORLESS
case K_AXIS: stepperK.homing_threshold(value); break;
#endif
#if U_SENSORLESS && AXIS_HAS_STALLGUARD(U)
case U_AXIS: stepperU.homing_threshold(value); break;
#endif
#if V_SENSORLESS && AXIS_HAS_STALLGUARD(V)
case V_AXIS: stepperV.homing_threshold(value); break;
#endif
#if W_SENSORLESS && AXIS_HAS_STALLGUARD(W)
case W_AXIS: stepperW.homing_threshold(value); break;
#endif
}
}
@ -499,6 +559,9 @@
TERN_(I_SENSORLESS, tmc_print_sgt(stepperI));
TERN_(J_SENSORLESS, tmc_print_sgt(stepperJ));
TERN_(K_SENSORLESS, tmc_print_sgt(stepperK));
TERN_(U_SENSORLESS, tmc_print_sgt(stepperU));
TERN_(V_SENSORLESS, tmc_print_sgt(stepperV));
TERN_(W_SENSORLESS, tmc_print_sgt(stepperW));
}
}
@ -561,6 +624,18 @@
say_M914(forReplay);
SERIAL_ECHOLNPGM_P(SP_K_STR, stepperK.homing_threshold());
#endif
#if U_SENSORLESS
say_M914(forReplay);
SERIAL_ECHOLNPGM_P(SP_U_STR, stepperU.homing_threshold());
#endif
#if V_SENSORLESS
say_M914(forReplay);
SERIAL_ECHOLNPGM_P(SP_V_STR, stepperV.homing_threshold());
#endif
#if W_SENSORLESS
say_M914(forReplay);
SERIAL_ECHOLNPGM_P(SP_W_STR, stepperW.homing_threshold());
#endif
}
#endif // USE_SENSORLESS

View File

@ -88,7 +88,10 @@ axis_bits_t GcodeSuite::axis_relative = 0 LOGICAL_AXIS_GANG(
| (ar_init.z << REL_Z),
| (ar_init.i << REL_I),
| (ar_init.j << REL_J),
| (ar_init.k << REL_K)
| (ar_init.k << REL_K),
| (ar_init.u << REL_U),
| (ar_init.v << REL_V),
| (ar_init.w << REL_W)
);
#if EITHER(HAS_AUTO_REPORTING, HOST_KEEPALIVE_FEATURE)
@ -179,7 +182,7 @@ void GcodeSuite::get_destination_from_command() {
#endif
// Get new XYZ position, whether absolute or relative
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
if ( (seen[i] = parser.seenval(AXIS_CHAR(i))) ) {
const float v = parser.value_axis_units((AxisEnum)i);
if (skip_move)

View File

@ -339,7 +339,7 @@
#endif
enum AxisRelative : uint8_t {
LOGICAL_AXIS_LIST(REL_E, REL_X, REL_Y, REL_Z, REL_I, REL_J, REL_K)
LOGICAL_AXIS_LIST(REL_E, REL_X, REL_Y, REL_Z, REL_I, REL_J, REL_K, REL_U, REL_V, REL_W)
#if HAS_EXTRUDERS
, E_MODE_ABS, E_MODE_REL
#endif
@ -365,7 +365,8 @@ public:
axis_relative = rel ? (0 LOGICAL_AXIS_GANG(
| _BV(REL_E),
| _BV(REL_X), | _BV(REL_Y), | _BV(REL_Z),
| _BV(REL_I), | _BV(REL_J), | _BV(REL_K)
| _BV(REL_I), | _BV(REL_J), | _BV(REL_K),
| _BV(REL_U), | _BV(REL_V), | _BV(REL_W)
)) : 0;
}
#if HAS_EXTRUDERS

View File

@ -39,7 +39,7 @@ bool GcodeSuite::select_coordinate_system(const int8_t _new) {
xyz_float_t new_offset{0};
if (WITHIN(_new, 0, MAX_COORDINATE_SYSTEMS - 1))
new_offset = coordinate_system[_new];
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
if (position_shift[i] != new_offset[i]) {
position_shift[i] = new_offset[i];
update_workspace_offset((AxisEnum)i);

View File

@ -29,7 +29,7 @@
#endif
/**
* G92: Set the Current Position to the given X [Y [Z [A [B [C [E]]]]]] values.
* G92: Set the Current Position to the given X [Y [Z [A [B [C [U [V [W ]]]]]]]] [E] values.
*
* Behind the scenes the G92 command may modify the Current Position
* or the Position Shift depending on settings and sub-commands.
@ -37,14 +37,14 @@
* Since E has no Workspace Offset, it is always set directly.
*
* Without Workspace Offsets (e.g., with NO_WORKSPACE_OFFSETS):
* G92 : Set NATIVE Current Position to the given X [Y [Z [A [B [C [E]]]]]].
* G92 : Set NATIVE Current Position to the given X [Y [Z [A [B [C [U [V [W ]]]]]]]] [E].
*
* Using Workspace Offsets (default Marlin behavior):
* G92 : Modify Workspace Offsets so the reported position shows the given X [Y [Z [A [B [C [E]]]]]].
* G92 : Modify Workspace Offsets so the reported position shows the given X [Y [Z [A [B [C [U [V [W ]]]]]]]] [E].
* G92.1 : Zero XYZ Workspace Offsets (so the reported position = the native position).
*
* With POWER_LOSS_RECOVERY:
* G92.9 : Set NATIVE Current Position to the given X [Y [Z [A [B [C [E]]]]]].
* G92.9 : Set NATIVE Current Position to the given X [Y [Z [A [B [C [U [V [W ]]]]]]]] [E].
*/
void GcodeSuite::G92() {
@ -64,7 +64,7 @@ void GcodeSuite::G92() {
#if ENABLED(CNC_COORDINATE_SYSTEMS) && !IS_SCARA
case 1: // G92.1 - Zero the Workspace Offset
LOOP_LINEAR_AXES(i) if (position_shift[i]) {
LOOP_NUM_AXES(i) if (position_shift[i]) {
position_shift[i] = 0;
update_workspace_offset((AxisEnum)i);
}

View File

@ -39,11 +39,17 @@
*/
void GcodeSuite::M206() {
if (!parser.seen_any()) return M206_report();
LOOP_LINEAR_AXES(i)
if (parser.seen(AXIS_CHAR(i)))
set_home_offset((AxisEnum)i, parser.value_linear_units());
NUM_AXIS_CODE(
if (parser.seen('X')) set_home_offset(X_AXIS, parser.value_linear_units()),
if (parser.seen('Y')) set_home_offset(Y_AXIS, parser.value_linear_units()),
if (parser.seen('Z')) set_home_offset(Z_AXIS, parser.value_linear_units()),
if (parser.seen(AXIS4_NAME)) set_home_offset(I_AXIS, parser.TERN(AXIS4_ROTATES, value_float, value_linear_units)()),
if (parser.seen(AXIS5_NAME)) set_home_offset(J_AXIS, parser.TERN(AXIS5_ROTATES, value_float, value_linear_units)()),
if (parser.seen(AXIS6_NAME)) set_home_offset(K_AXIS, parser.TERN(AXIS6_ROTATES, value_float, value_linear_units)()),
if (parser.seen(AXIS7_NAME)) set_home_offset(U_AXIS, parser.TERN(AXIS7_ROTATES, value_float, value_linear_units)()),
if (parser.seen(AXIS8_NAME)) set_home_offset(V_AXIS, parser.TERN(AXIS8_ROTATES, value_float, value_linear_units)()),
if (parser.seen(AXIS9_NAME)) set_home_offset(W_AXIS, parser.TERN(AXIS9_ROTATES, value_float, value_linear_units)())
);
#if ENABLED(MORGAN_SCARA)
if (parser.seen('T')) set_home_offset(A_AXIS, parser.value_float()); // Theta
if (parser.seen('P')) set_home_offset(B_AXIS, parser.value_float()); // Psi
@ -56,13 +62,16 @@ void GcodeSuite::M206_report(const bool forReplay/*=true*/) {
report_heading_etc(forReplay, F(STR_HOME_OFFSET));
SERIAL_ECHOLNPGM_P(
#if IS_CARTESIAN
LIST_N(DOUBLE(LINEAR_AXES),
LIST_N(DOUBLE(NUM_AXES),
PSTR(" M206 X"), LINEAR_UNIT(home_offset.x),
SP_Y_STR, LINEAR_UNIT(home_offset.y),
SP_Z_STR, LINEAR_UNIT(home_offset.z),
SP_I_STR, LINEAR_UNIT(home_offset.i),
SP_J_STR, LINEAR_UNIT(home_offset.j),
SP_K_STR, LINEAR_UNIT(home_offset.k)
SP_I_STR, I_AXIS_UNIT(home_offset.i),
SP_J_STR, J_AXIS_UNIT(home_offset.j),
SP_K_STR, K_AXIS_UNIT(home_offset.k),
SP_U_STR, U_AXIS_UNIT(home_offset.u),
SP_V_STR, V_AXIS_UNIT(home_offset.v),
SP_W_STR, W_AXIS_UNIT(home_offset.w)
)
#else
PSTR(" M206 Z"), LINEAR_UNIT(home_offset.z)
@ -85,7 +94,7 @@ void GcodeSuite::M428() {
if (homing_needed_error()) return;
xyz_float_t diff;
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
diff[i] = base_home_pos((AxisEnum)i) - current_position[i];
if (!WITHIN(diff[i], -20, 20) && home_dir((AxisEnum)i) > 0)
diff[i] = -current_position[i];
@ -97,7 +106,7 @@ void GcodeSuite::M428() {
}
}
LOOP_LINEAR_AXES(i) set_home_offset((AxisEnum)i, diff[i]);
LOOP_NUM_AXES(i) set_home_offset((AxisEnum)i, diff[i]);
report_current_position();
LCD_MESSAGE(MSG_HOME_OFFSETS_APPLIED);
OKAY_BUZZ();

View File

@ -34,7 +34,7 @@
#include "../../core/debug_out.h"
#endif
void report_all_axis_pos(const xyze_pos_t &pos, const uint8_t n=XYZE, const uint8_t precision=3) {
void report_all_axis_pos(const xyze_pos_t &pos, const uint8_t n=LOGICAL_AXES, const uint8_t precision=3) {
char str[12];
LOOP_L_N(a, n) {
SERIAL_CHAR(' ', axis_codes[a], ':');
@ -47,7 +47,7 @@
void report_linear_axis_pos(const xyz_pos_t &pos, const uint8_t precision=3) {
char str[12];
LOOP_LINEAR_AXES(a) {
LOOP_NUM_AXES(a) {
SERIAL_CHAR(' ', AXIS_CHAR(a), ':');
SERIAL_ECHO(dtostrf(pos[a], 1, precision, str));
}
@ -134,6 +134,15 @@
#if AXIS_IS_L64XX(K)
REPORT_ABSOLUTE_POS(K);
#endif
#if AXIS_IS_L64XX(U)
REPORT_ABSOLUTE_POS(U);
#endif
#if AXIS_IS_L64XX(V)
REPORT_ABSOLUTE_POS(V);
#endif
#if AXIS_IS_L64XX(W)
REPORT_ABSOLUTE_POS(W);
#endif
#if AXIS_IS_L64XX(E0)
REPORT_ABSOLUTE_POS(E0);
#endif
@ -184,7 +193,10 @@
cartes.x, cartes.y, cartes.z,
planner.get_axis_position_mm(I_AXIS),
planner.get_axis_position_mm(J_AXIS),
planner.get_axis_position_mm(K_AXIS)
planner.get_axis_position_mm(K_AXIS),
planner.get_axis_position_mm(U_AXIS),
planner.get_axis_position_mm(V_AXIS),
planner.get_axis_position_mm(W_AXIS)
);
report_all_axis_pos(from_steppers);

View File

@ -65,8 +65,8 @@ void GcodeSuite::M115() {
"PROTOCOL_VERSION:" PROTOCOL_VERSION " "
"MACHINE_TYPE:" MACHINE_NAME " "
"EXTRUDER_COUNT:" STRINGIFY(EXTRUDERS) " "
#if LINEAR_AXES != XYZ
"AXIS_COUNT:" STRINGIFY(LINEAR_AXES) " "
#if NUM_AXES != XYZ
"AXIS_COUNT:" STRINGIFY(NUM_AXES) " "
#endif
#ifdef MACHINE_UUID
"UUID:" MACHINE_UUID

View File

@ -49,13 +49,16 @@ void GcodeSuite::G0_G1(TERN_(HAS_FAST_MOVES, const bool fast_move/*=false*/)) {
if (IsRunning()
#if ENABLED(NO_MOTION_BEFORE_HOMING)
&& !homing_needed_error(
LINEAR_AXIS_GANG(
NUM_AXIS_GANG(
(parser.seen_test('X') ? _BV(X_AXIS) : 0),
| (parser.seen_test('Y') ? _BV(Y_AXIS) : 0),
| (parser.seen_test('Z') ? _BV(Z_AXIS) : 0),
| (parser.seen_test(AXIS4_NAME) ? _BV(I_AXIS) : 0),
| (parser.seen_test(AXIS5_NAME) ? _BV(J_AXIS) : 0),
| (parser.seen_test(AXIS6_NAME) ? _BV(K_AXIS) : 0))
| (parser.seen_test(AXIS6_NAME) ? _BV(K_AXIS) : 0),
| (parser.seen_test(AXIS7_NAME) ? _BV(U_AXIS) : 0),
| (parser.seen_test(AXIS8_NAME) ? _BV(V_AXIS) : 0),
| (parser.seen_test(AXIS9_NAME) ? _BV(W_AXIS) : 0))
)
#endif
) {
@ -89,7 +92,7 @@ void GcodeSuite::G0_G1(TERN_(HAS_FAST_MOVES, const bool fast_move/*=false*/)) {
if (MIN_AUTORETRACT <= MAX_AUTORETRACT) {
// When M209 Autoretract is enabled, convert E-only moves to firmware retract/recover moves
if (fwretract.autoretract_enabled && parser.seen_test('E')
&& !parser.seen(LINEAR_AXIS_GANG("X", "Y", "Z", STR_I, STR_J, STR_K))
&& !parser.seen(NUM_AXIS_GANG("X", "Y", "Z", STR_I, STR_J, STR_K, STR_U, STR_V, STR_W))
) {
const float echange = destination.e - current_position.e;
// Is this a retract or recover move?

View File

@ -48,8 +48,8 @@
#define MIN_ARC_SEGMENT_MM MAX_ARC_SEGMENT_MM
#endif
#define ARC_LIJK_CODE(L,I,J,K) CODE_N(SUB2(LINEAR_AXES),L,I,J,K)
#define ARC_LIJKE_CODE(L,I,J,K,E) ARC_LIJK_CODE(L,I,J,K); CODE_ITEM_E(E)
#define ARC_LIJKUVW_CODE(L,I,J,K,U,V,W) CODE_N(SUB2(NUM_AXES),L,I,J,K,U,V,W)
#define ARC_LIJKUVWE_CODE(L,I,J,K,U,V,W,E) ARC_LIJKUVW_CODE(L,I,J,K,U,V,W); CODE_ITEM_E(E)
/**
* Plan an arc in 2 dimensions, with linear motion in the other axes.
@ -82,11 +82,14 @@ void plan_arc(
rt_X = cart[axis_p] - center_P,
rt_Y = cart[axis_q] - center_Q;
ARC_LIJK_CODE(
ARC_LIJKUVW_CODE(
const float start_L = current_position[axis_l],
const float start_I = current_position.i,
const float start_J = current_position.j,
const float start_K = current_position.k
const float start_K = current_position.k,
const float start_U = current_position.u,
const float start_V = current_position.v,
const float start_W = current_position.w
);
// Angle of rotation between position and target from the circle center.
@ -122,11 +125,14 @@ void plan_arc(
min_segments = CEIL((MIN_CIRCLE_SEGMENTS) * portion_of_circle); // Minimum segments for the arc
}
ARC_LIJKE_CODE(
ARC_LIJKUVWE_CODE(
float travel_L = cart[axis_l] - start_L,
float travel_I = cart.i - start_I,
float travel_J = cart.j - start_J,
float travel_K = cart.k - start_K,
float travel_U = cart.u - start_U,
float travel_V = cart.v - start_V,
float travel_W = cart.w - start_W,
float travel_E = cart.e - current_position.e
);
@ -135,30 +141,39 @@ void plan_arc(
const float total_angular = abs_angular_travel + circles * RADIANS(360), // Total rotation with all circles and remainder
part_per_circle = RADIANS(360) / total_angular; // Each circle's part of the total
ARC_LIJKE_CODE(
ARC_LIJKUVWE_CODE(
const float per_circle_L = travel_L * part_per_circle, // L movement per circle
const float per_circle_I = travel_I * part_per_circle,
const float per_circle_J = travel_J * part_per_circle,
const float per_circle_K = travel_K * part_per_circle,
const float per_circle_U = travel_U * part_per_circle,
const float per_circle_V = travel_V * part_per_circle,
const float per_circle_W = travel_W * part_per_circle,
const float per_circle_E = travel_E * part_per_circle // E movement per circle
);
xyze_pos_t temp_position = current_position;
for (uint16_t n = circles; n--;) {
ARC_LIJKE_CODE( // Destination Linear Axes
ARC_LIJKUVWE_CODE( // Destination Linear Axes
temp_position[axis_l] += per_circle_L,
temp_position.i += per_circle_I,
temp_position.j += per_circle_J,
temp_position.k += per_circle_K,
temp_position.u += per_circle_U,
temp_position.v += per_circle_V,
temp_position.w += per_circle_W,
temp_position.e += per_circle_E // Destination E axis
);
plan_arc(temp_position, offset, clockwise, 0); // Plan a single whole circle
}
ARC_LIJKE_CODE(
ARC_LIJKUVWE_CODE(
travel_L = cart[axis_l] - current_position[axis_l],
travel_I = cart.i - current_position.i,
travel_J = cart.j - current_position.j,
travel_K = cart.k - current_position.k,
travel_U = cart.u - current_position.u,
travel_V = cart.v - current_position.v,
travel_W = cart.w - current_position.w,
travel_E = cart.e - current_position.e
);
}
@ -168,11 +183,14 @@ void plan_arc(
// Return if the move is near zero
if (flat_mm < 0.0001f
GANG_N(SUB2(LINEAR_AXES),
GANG_N(SUB2(NUM_AXES),
&& travel_L < 0.0001f,
&& travel_I < 0.0001f,
&& travel_J < 0.0001f,
&& travel_K < 0.0001f
&& travel_K < 0.0001f,
&& travel_U < 0.0001f,
&& travel_V < 0.0001f,
&& travel_W < 0.0001f
)
) return;
@ -236,11 +254,14 @@ void plan_arc(
cos_T = 1 - 0.5f * sq_theta_per_segment; // Small angle approximation
#if DISABLED(AUTO_BED_LEVELING_UBL)
ARC_LIJK_CODE(
ARC_LIJKUVW_CODE(
const float per_segment_L = proportion * travel_L / segments,
const float per_segment_I = proportion * travel_I / segments,
const float per_segment_J = proportion * travel_J / segments,
const float per_segment_K = proportion * travel_K / segments
const float per_segment_K = proportion * travel_K / segments,
const float per_segment_U = proportion * travel_U / segments,
const float per_segment_V = proportion * travel_V / segments,
const float per_segment_W = proportion * travel_W / segments
);
#endif
@ -250,11 +271,14 @@ void plan_arc(
if (tooshort) segments++;
// Initialize all linear axes and E
ARC_LIJKE_CODE(
ARC_LIJKUVWE_CODE(
raw[axis_l] = current_position[axis_l],
raw.i = current_position.i,
raw.j = current_position.j,
raw.k = current_position.k,
raw.u = current_position.u,
raw.v = current_position.v,
raw.w = current_position.w,
raw.e = current_position.e
);
@ -303,11 +327,15 @@ void plan_arc(
// Update raw location
raw[axis_p] = center_P + rvec.a;
raw[axis_q] = center_Q + rvec.b;
ARC_LIJKE_CODE(
ARC_LIJKUVWE_CODE(
#if ENABLED(AUTO_BED_LEVELING_UBL)
raw[axis_l] = start_L, raw.i = start_I, raw.j = start_J, raw.k = start_K
raw[axis_l] = start_L,
raw.i = start_I, raw.j = start_J, raw.k = start_K,
raw.u = start_U, raw.v = start_V, raw.w = start_V
#else
raw[axis_l] += per_segment_L, raw.i += per_segment_I, raw.j += per_segment_J, raw.k += per_segment_K
raw[axis_l] += per_segment_L,
raw.i += per_segment_I, raw.j += per_segment_J, raw.k += per_segment_K,
raw.u += per_segment_U, raw.v += per_segment_V, raw.w += per_segment_W
#endif
, raw.e += extruder_per_segment
);
@ -325,7 +353,11 @@ void plan_arc(
// Ensure last segment arrives at target location.
raw = cart;
#if ENABLED(AUTO_BED_LEVELING_UBL)
ARC_LIJK_CODE(raw[axis_l] = start_L, raw.i = start_I, raw.j = start_J, raw.k = start_K);
ARC_LIJKUVW_CODE(
raw[axis_l] = start_L,
raw.i = start_I, raw.j = start_J, raw.k = start_K,
raw.u = start_U, raw.v = start_V, raw.w = start_W
);
#endif
apply_motion_limits(raw);
@ -337,7 +369,11 @@ void plan_arc(
planner.buffer_line(raw, scaled_fr_mm_s, active_extruder, 0 OPTARG(SCARA_FEEDRATE_SCALING, inv_duration));
#if ENABLED(AUTO_BED_LEVELING_UBL)
ARC_LIJK_CODE(raw[axis_l] = start_L, raw.i = start_I, raw.j = start_J, raw.k = start_K);
ARC_LIJKUVW_CODE(
raw[axis_l] = start_L,
raw.i = start_I, raw.j = start_J, raw.k = start_K,
raw.u = start_U, raw.v = start_V, raw.w = start_W
);
#endif
current_position = raw;
@ -380,7 +416,7 @@ void GcodeSuite::G2_G3(const bool clockwise) {
relative_mode = true;
#endif
get_destination_from_command(); // Get X Y [Z[I[J[K]]]] [E] F (and set cutter power)
get_destination_from_command(); // Get X Y [Z[I[J[K...]]]] [E] F (and set cutter power)
TERN_(SF_ARC_FIX, relative_mode = relative_mode_backup);

View File

@ -69,7 +69,7 @@
*/
void GcodeSuite::M290() {
#if ENABLED(BABYSTEP_XY)
LOOP_LINEAR_AXES(a)
LOOP_NUM_AXES(a)
if (parser.seenval(AXIS_CHAR(a)) || (a == Z_AXIS && parser.seenval('S'))) {
const float offs = constrain(parser.value_axis_units((AxisEnum)a), -2, 2);
babystep.add_mm((AxisEnum)a, offs);
@ -87,7 +87,7 @@ void GcodeSuite::M290() {
}
#endif
if (!parser.seen(LINEAR_AXIS_GANG("X", "Y", "Z", STR_I, STR_J, STR_K)) || parser.seen('R')) {
if (!parser.seen(NUM_AXIS_GANG("X", "Y", "Z", STR_I, STR_J, STR_K, STR_U, STR_V, STR_W)) || parser.seen('R')) {
SERIAL_ECHO_START();
#if ENABLED(BABYSTEP_ZPROBE_OFFSET)

View File

@ -248,7 +248,7 @@ void GCodeParser::parse(char *p) {
case 'R': if (!WITHIN(motion_mode_codenum, 2, 3)) return;
#endif
LOGICAL_AXIS_GANG(case 'E':, case 'X':, case 'Y':, case 'Z':, case AXIS4_NAME:, case AXIS5_NAME:, case AXIS6_NAME:)
LOGICAL_AXIS_GANG(case 'E':, case 'X':, case 'Y':, case 'Z':, case AXIS4_NAME:, case AXIS5_NAME:, case AXIS6_NAME:, case AXIS7_NAME:, case AXIS8_NAME:, case AXIS9_NAME:)
case 'F':
if (motion_mode_codenum < 0) return;
command_letter = 'G';

View File

@ -309,13 +309,18 @@ public:
}
static float axis_unit_factor(const AxisEnum axis) {
return (
if (false
|| TERN0(AXIS4_ROTATES, axis == I_AXIS)
|| TERN0(AXIS5_ROTATES, axis == J_AXIS)
|| TERN0(AXIS6_ROTATES, axis == K_AXIS)
|| TERN0(AXIS7_ROTATES, axis == U_AXIS)
|| TERN0(AXIS8_ROTATES, axis == V_AXIS)
|| TERN0(AXIS9_ROTATES, axis == W_AXIS)
) return 1.0f;
#if HAS_EXTRUDERS
axis >= E_AXIS && volumetric_enabled ? volumetric_unit_factor : linear_unit_factor
#else
linear_unit_factor
if (axis >= E_AXIS && volumetric_enabled) return volumetric_unit_factor;
#endif
);
return linear_unit_factor;
}
static float linear_value_to_mm(const_float_t v) { return v * linear_unit_factor; }
@ -340,6 +345,13 @@ public:
#define LINEAR_UNIT(V) parser.mm_to_linear_unit(V)
#define VOLUMETRIC_UNIT(V) parser.mm_to_volumetric_unit(V)
#define I_AXIS_UNIT(V) TERN(AXIS4_ROTATES, (V), LINEAR_UNIT(V))
#define J_AXIS_UNIT(V) TERN(AXIS5_ROTATES, (V), LINEAR_UNIT(V))
#define K_AXIS_UNIT(V) TERN(AXIS6_ROTATES, (V), LINEAR_UNIT(V))
#define U_AXIS_UNIT(V) TERN(AXIS7_ROTATES, (V), LINEAR_UNIT(V))
#define V_AXIS_UNIT(V) TERN(AXIS8_ROTATES, (V), LINEAR_UNIT(V))
#define W_AXIS_UNIT(V) TERN(AXIS9_ROTATES, (V), LINEAR_UNIT(V))
static float value_linear_units() { return linear_value_to_mm(value_float()); }
static float value_axis_units(const AxisEnum axis) { return axis_value_to_mm(axis, value_float()); }
static float value_per_axis_units(const AxisEnum axis) { return per_axis_value(axis, value_float()); }

View File

@ -49,7 +49,7 @@ inline bool G38_run_probe() {
#if MULTIPLE_PROBING > 1
// Get direction of move and retract
xyz_float_t retract_mm;
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
const float dist = destination[i] - current_position[i];
retract_mm[i] = ABS(dist) < G38_MINIMUM_MOVE ? 0 : home_bump_mm((AxisEnum)i) * (dist > 0 ? -1 : 1);
}
@ -119,7 +119,7 @@ void GcodeSuite::G38(const int8_t subcode) {
;
// If any axis has enough movement, do the move
LOOP_LINEAR_AXES(i)
LOOP_NUM_AXES(i)
if (ABS(destination[i] - current_position[i]) >= G38_MINIMUM_MOVE) {
if (!parser.seenval('F')) feedrate_mm_s = homing_feedrate((AxisEnum)i);
// If G38.2 fails throw an error

View File

@ -666,7 +666,7 @@
#endif
/**
* Number of Linear Axes (e.g., XYZ)
* Number of Linear Axes (e.g., XYZIJKUVW)
* All the logical axes except for the tool (E) axis
*/
#ifdef LINEAR_AXES
@ -674,22 +674,28 @@
#define LINEAR_AXES_WARNING 1
#endif
#ifdef K_DRIVER_TYPE
#define LINEAR_AXES 6
#ifdef W_DRIVER_TYPE
#define NUM_AXES 9
#elif defined(V_DRIVER_TYPE)
#define NUM_AXES 8
#elif defined(U_DRIVER_TYPE)
#define NUM_AXES 7
#elif defined(K_DRIVER_TYPE)
#define NUM_AXES 6
#elif defined(J_DRIVER_TYPE)
#define LINEAR_AXES 5
#define NUM_AXES 5
#elif defined(I_DRIVER_TYPE)
#define LINEAR_AXES 4
#define NUM_AXES 4
#elif defined(Z_DRIVER_TYPE)
#define LINEAR_AXES 3
#define NUM_AXES 3
#elif defined(Y_DRIVER_TYPE)
#define LINEAR_AXES 2
#define NUM_AXES 2
#else
#define LINEAR_AXES 1
#define NUM_AXES 1
#endif
#if LINEAR_AXES >= XY
#if NUM_AXES >= XY
#define HAS_Y_AXIS 1
#if LINEAR_AXES >= XYZ
#if NUM_AXES >= XYZ
#define HAS_Z_AXIS 1
#ifdef Z4_DRIVER_TYPE
#define NUM_Z_STEPPERS 4
@ -700,12 +706,21 @@
#else
#define NUM_Z_STEPPERS 1
#endif
#if LINEAR_AXES >= 4
#if NUM_AXES >= 4
#define HAS_I_AXIS 1
#if LINEAR_AXES >= 5
#if NUM_AXES >= 5
#define HAS_J_AXIS 1
#if LINEAR_AXES >= 6
#if NUM_AXES >= 6
#define HAS_K_AXIS 1
#if NUM_AXES >= 7
#define HAS_U_AXIS 1
#if NUM_AXES >= 8
#define HAS_V_AXIS 1
#if NUM_AXES >= 9
#define HAS_W_AXIS 1
#endif
#endif
#endif
#endif
#endif
#endif
@ -863,14 +878,58 @@
#endif
/**
* Number of Logical Axes (e.g., XYZE)
* All the logical axes that can be commanded directly by G-code.
* Number of Primary Linear Axes (e.g., XYZ)
* X, XY, or XYZ axes. Excluding duplicate axes (X2, Y2. Z2. Z3, Z4)
*/
#if NUM_AXES >= 3
#define PRIMARY_LINEAR_AXES 3
#else
#define PRIMARY_LINEAR_AXES NUM_AXES
#endif
/**
* Number of Secondary Axes (e.g., IJKUVW)
* All linear/rotational axes between XYZ and E.
*/
#define SECONDARY_AXES SUB3(NUM_AXES)
/**
* Number of Rotational Axes (e.g., IJK)
* All axes for which AXIS*_ROTATES is defined.
* For these axes, positions are specified in angular degrees.
*/
#if ENABLED(AXIS9_ROTATES)
#define ROTATIONAL_AXES 6
#elif ENABLED(AXIS8_ROTATES)
#define ROTATIONAL_AXES 5
#elif ENABLED(AXIS7_ROTATES)
#define ROTATIONAL_AXES 4
#elif ENABLED(AXIS6_ROTATES)
#define ROTATIONAL_AXES 3
#elif ENABLED(AXIS5_ROTATES)
#define ROTATIONAL_AXES 2
#elif ENABLED(AXIS4_ROTATES)
#define ROTATIONAL_AXES 1
#else
#define ROTATIONAL_AXES 0
#endif
/**
* Number of Secondary Linear Axes (e.g., UVW)
* All secondary axes for which AXIS*_ROTATES is not defined.
* Excluding primary axes and excluding duplicate axes (X2, Y2, Z2, Z3, Z4)
*/
#define SECONDARY_LINEAR_AXES (NUM_AXES - PRIMARY_LINEAR_AXES - ROTATIONAL_AXES)
/**
* Number of Logical Axes (e.g., XYZIJKUVWE)
* All logical axes that can be commanded directly by G-code.
* Delta maps stepper-specific values to ABC steppers.
*/
#if HAS_EXTRUDERS
#define LOGICAL_AXES INCREMENT(LINEAR_AXES)
#define LOGICAL_AXES INCREMENT(NUM_AXES)
#else
#define LOGICAL_AXES LINEAR_AXES
#define LOGICAL_AXES NUM_AXES
#endif
/**
@ -888,7 +947,7 @@
* distinguished.
*/
#if ENABLED(DISTINCT_E_FACTORS) && E_STEPPERS > 1
#define DISTINCT_AXES (LINEAR_AXES + E_STEPPERS)
#define DISTINCT_AXES (NUM_AXES + E_STEPPERS)
#define DISTINCT_E E_STEPPERS
#define E_INDEX_N(E) (E)
#else
@ -1118,6 +1177,21 @@
#elif K_HOME_DIR < 0
#define K_HOME_TO_MIN 1
#endif
#if U_HOME_DIR > 0
#define U_HOME_TO_MAX 1
#elif U_HOME_DIR < 0
#define U_HOME_TO_MIN 1
#endif
#if V_HOME_DIR > 0
#define V_HOME_TO_MAX 1
#elif V_HOME_DIR < 0
#define V_HOME_TO_MIN 1
#endif
#if W_HOME_DIR > 0
#define W_HOME_TO_MAX 1
#elif W_HOME_DIR < 0
#define W_HOME_TO_MIN 1
#endif
/**
* Conditionals based on the type of Bed Probe

View File

@ -911,19 +911,31 @@
#endif
// Remove unused STEALTHCHOP flags
#if LINEAR_AXES < 6
#if NUM_AXES < 9
#undef STEALTHCHOP_W
#undef CALIBRATION_MEASURE_WMIN
#undef CALIBRATION_MEASURE_WMAX
#if NUM_AXES < 8
#undef STEALTHCHOP_V
#undef CALIBRATION_MEASURE_VMIN
#undef CALIBRATION_MEASURE_VMAX
#if NUM_AXES < 7
#undef STEALTHCHOP_U
#undef CALIBRATION_MEASURE_UMIN
#undef CALIBRATION_MEASURE_UMAX
#if NUM_AXES < 6
#undef STEALTHCHOP_K
#undef CALIBRATION_MEASURE_KMIN
#undef CALIBRATION_MEASURE_KMAX
#if LINEAR_AXES < 5
#if NUM_AXES < 5
#undef STEALTHCHOP_J
#undef CALIBRATION_MEASURE_JMIN
#undef CALIBRATION_MEASURE_JMAX
#if LINEAR_AXES < 4
#if NUM_AXES < 4
#undef STEALTHCHOP_I
#undef CALIBRATION_MEASURE_IMIN
#undef CALIBRATION_MEASURE_IMAX
#if LINEAR_AXES < 3
#if NUM_AXES < 3
#undef Z_IDLE_HEIGHT
#undef STEALTHCHOP_Z
#undef Z_PROBE_SLED
@ -933,13 +945,16 @@
#undef ENABLE_LEVELING_FADE_HEIGHT
#undef NUM_Z_STEPPERS
#undef CNC_WORKSPACE_PLANES
#if LINEAR_AXES < 2
#if NUM_AXES < 2
#undef STEALTHCHOP_Y
#endif
#endif
#endif
#endif
#endif
#endif
#endif
#endif
//
// SD Card connection methods

View File

@ -87,6 +87,19 @@
#if HAS_K_AXIS && !defined(AXIS6_NAME)
#define AXIS6_NAME 'C'
#endif
#if HAS_U_AXIS && !defined(AXIS7_NAME)
#define AXIS7_NAME 'U'
#endif
#if HAS_V_AXIS && !defined(AXIS8_NAME)
#define AXIS8_NAME 'V'
#endif
#if HAS_W_AXIS && !defined(AXIS9_NAME)
#define AXIS9_NAME 'W'
#endif
#if ANY(AXIS4_ROTATES, AXIS5_ROTATES, AXIS6_ROTATES, AXIS7_ROTATES, AXIS8_ROTATES, AXIS9_ROTATES)
#define HAS_ROTATIONAL_AXES 1
#endif
#define X_MAX_LENGTH (X_MAX_POS - (X_MIN_POS))
#if HAS_Y_AXIS
@ -106,6 +119,15 @@
#if HAS_K_AXIS
#define K_MAX_LENGTH (K_MAX_POS - (K_MIN_POS))
#endif
#if HAS_U_AXIS
#define U_MAX_LENGTH (U_MAX_POS - (U_MIN_POS))
#endif
#if HAS_V_AXIS
#define V_MAX_LENGTH (V_MAX_POS - (V_MIN_POS))
#endif
#if HAS_W_AXIS
#define W_MAX_LENGTH (W_MAX_POS - (W_MIN_POS))
#endif
// Defined only if the sanity-check is bypassed
#ifndef X_BED_SIZE
@ -123,6 +145,15 @@
#if HAS_K_AXIS && !defined(K_BED_SIZE)
#define K_BED_SIZE K_MAX_LENGTH
#endif
#if HAS_U_AXIS && !defined(U_BED_SIZE)
#define U_BED_SIZE U_MAX_LENGTH
#endif
#if HAS_V_AXIS && !defined(V_BED_SIZE)
#define V_BED_SIZE V_MAX_LENGTH
#endif
#if HAS_W_AXIS && !defined(W_BED_SIZE)
#define W_BED_SIZE W_MAX_LENGTH
#endif
// Require 0,0 bed center for Delta and SCARA
#if IS_KINEMATIC
@ -143,6 +174,15 @@
#if HAS_K_AXIS
#define _K_HALF_KMAX ((K_BED_SIZE) / 2)
#endif
#if HAS_U_AXIS
#define _U_HALF_UMAX ((U_BED_SIZE) / 2)
#endif
#if HAS_V_AXIS
#define _V_HALF_VMAX ((V_BED_SIZE) / 2)
#endif
#if HAS_W_AXIS
#define _W_HALF_WMAX ((W_BED_SIZE) / 2)
#endif
#define X_CENTER TERN(BED_CENTER_AT_0_0, 0, _X_HALF_BED)
#if HAS_Y_AXIS
@ -158,6 +198,15 @@
#if HAS_K_AXIS
#define K_CENTER TERN(BED_CENTER_AT_0_0, 0, _K_HALF_BED)
#endif
#if HAS_U_AXIS
#define U_CENTER TERN(BED_CENTER_AT_0_0, 0, _U_HALF_BED)
#endif
#if HAS_V_AXIS
#define V_CENTER TERN(BED_CENTER_AT_0_0, 0, _V_HALF_BED)
#endif
#if HAS_W_AXIS
#define W_CENTER TERN(BED_CENTER_AT_0_0, 0, _W_HALF_BED)
#endif
// Get the linear boundaries of the bed
#define X_MIN_BED (X_CENTER - _X_HALF_BED)
@ -178,6 +227,18 @@
#define K_MINIM (K_CENTER - _K_HALF_BED_SIZE)
#define K_MAXIM (K_MINIM + K_BED_SIZE)
#endif
#if HAS_U_AXIS
#define U_MINIM (U_CENTER - _U_HALF_BED_SIZE)
#define U_MAXIM (U_MINIM + U_BED_SIZE)
#endif
#if HAS_V_AXIS
#define V_MINIM (V_CENTER - _V_HALF_BED_SIZE)
#define V_MAXIM (V_MINIM + V_BED_SIZE)
#endif
#if HAS_W_AXIS
#define W_MINIM (W_CENTER - _W_HALF_BED_SIZE)
#define W_MAXIM (W_MINIM + W_BED_SIZE)
#endif
/**
* Dual X Carriage
@ -274,6 +335,27 @@
#define K_HOME_POS TERN(K_HOME_TO_MIN, K_MIN_POS, K_MAX_POS)
#endif
#endif
#if HAS_U_AXIS
#ifdef MANUAL_U_HOME_POS
#define U_HOME_POS MANUAL_U_HOME_POS
#else
#define U_HOME_POS (U_HOME_DIR < 0 ? U_MIN_POS : U_MAX_POS)
#endif
#endif
#if HAS_V_AXIS
#ifdef MANUAL_V_HOME_POS
#define V_HOME_POS MANUAL_V_HOME_POS
#else
#define V_HOME_POS (V_HOME_DIR < 0 ? V_MIN_POS : V_MAX_POS)
#endif
#endif
#if HAS_W_AXIS
#ifdef MANUAL_W_HOME_POS
#define W_HOME_POS MANUAL_W_HOME_POS
#else
#define W_HOME_POS (W_HOME_DIR < 0 ? W_MIN_POS : W_MAX_POS)
#endif
#endif
/**
* If DELTA_HEIGHT isn't defined use the old setting
@ -1440,6 +1522,15 @@
#if ENABLED(USE_KMAX_PLUG)
#define ENDSTOPPULLUP_KMAX
#endif
#if ENABLED(USE_UMAX_PLUG)
#define ENDSTOPPULLUP_UMAX
#endif
#if ENABLED(USE_VMAX_PLUG)
#define ENDSTOPPULLUP_VMAX
#endif
#if ENABLED(USE_WMAX_PLUG)
#define ENDSTOPPULLUP_WMAX
#endif
#if ENABLED(USE_XMIN_PLUG)
#define ENDSTOPPULLUP_XMIN
#endif
@ -1458,6 +1549,15 @@
#if ENABLED(USE_KMIN_PLUG)
#define ENDSTOPPULLUP_KMIN
#endif
#if ENABLED(USE_UMIN_PLUG)
#define ENDSTOPPULLUP_UMIN
#endif
#if ENABLED(USE_VMIN_PLUG)
#define ENDSTOPPULLUP_VMIN
#endif
#if ENABLED(USE_WMIN_PLUG)
#define ENDSTOPPULLUP_WMIN
#endif
#endif
/**
@ -1680,6 +1780,66 @@
#undef DISABLE_INACTIVE_K
#endif
#if HAS_U_AXIS
#if PIN_EXISTS(U_ENABLE) || AXIS_IS_L64XX(U) || (ENABLED(SOFTWARE_DRIVER_ENABLE) && AXIS_IS_TMC(U))
#define HAS_U_ENABLE 1
#endif
#if PIN_EXISTS(U_DIR)
#define HAS_U_DIR 1
#endif
#if PIN_EXISTS(U_STEP)
#define HAS_U_STEP 1
#endif
#if PIN_EXISTS(U_MS1)
#define HAS_U_MS_PINS 1
#endif
#if !defined(DISABLE_INACTIVE_U) && ENABLED(DISABLE_U)
#define DISABLE_INACTIVE_U 1
#endif
#else
#undef DISABLE_INACTIVE_U
#endif
#if HAS_V_AXIS
#if PIN_EXISTS(V_ENABLE) || AXIS_IS_L64XX(V) || (ENABLED(SOFTWARE_DRIVER_ENABLE) && AXIS_IS_TMC(V))
#define HAS_V_ENABLE 1
#endif
#if PIN_EXISTS(V_DIR)
#define HAS_V_DIR 1
#endif
#if PIN_EXISTS(V_STEP)
#define HAS_V_STEP 1
#endif
#if PIN_EXISTS(V_MS1)
#define HAS_V_MS_PINS 1
#endif
#if !defined(DISABLE_INACTIVE_V) && ENABLED(DISABLE_V)
#define DISABLE_INACTIVE_V 1
#endif
#else
#undef DISABLE_INACTIVE_V
#endif
#if HAS_W_AXIS
#if PIN_EXISTS(W_ENABLE) || AXIS_IS_L64XX(W) || (ENABLED(SOFTWARE_DRIVER_ENABLE) && AXIS_IS_TMC(W))
#define HAS_W_ENABLE 1
#endif
#if PIN_EXISTS(W_DIR)
#define HAS_W_DIR 1
#endif
#if PIN_EXISTS(W_STEP)
#define HAS_W_STEP 1
#endif
#if PIN_EXISTS(W_MS1)
#define HAS_W_MS_PINS 1
#endif
#if !defined(DISABLE_INACTIVE_W) && ENABLED(DISABLE_W)
#define DISABLE_INACTIVE_W 1
#endif
#else
#undef DISABLE_INACTIVE_W
#endif
// Extruder steppers and solenoids
#if HAS_EXTRUDERS
@ -1848,7 +2008,7 @@
//
#if HAS_TRINAMIC_CONFIG
#if ANY(STEALTHCHOP_E, STEALTHCHOP_XY, STEALTHCHOP_Z, STEALTHCHOP_I, STEALTHCHOP_J, STEALTHCHOP_K)
#if ANY(STEALTHCHOP_E, STEALTHCHOP_XY, STEALTHCHOP_Z, STEALTHCHOP_I, STEALTHCHOP_J, STEALTHCHOP_K, STEALTHCHOP_U, STEALTHCHOP_V, STEALTHCHOP_W)
#define STEALTHCHOP_ENABLED 1
#endif
#if EITHER(SENSORLESS_HOMING, SENSORLESS_PROBING)
@ -1937,6 +2097,15 @@
#define Y2_SLAVE_ADDRESS 0
#endif
#endif
#if HAS_U_AXIS
#define U_SPI_SENSORLESS U_SENSORLESS
#endif
#if HAS_V_AXIS
#define V_SPI_SENSORLESS V_SENSORLESS
#endif
#if HAS_W_AXIS
#define W_SPI_SENSORLESS W_SENSORLESS
#endif
#endif
#if AXIS_IS_TMC(Z)
@ -2074,6 +2243,69 @@
#endif
#endif
#if AXIS_IS_TMC(U)
#if defined(U_STALL_SENSITIVITY) && AXIS_HAS_STALLGUARD(U)
#define U_SENSORLESS 1
#endif
#if AXIS_HAS_STEALTHCHOP(U)
#define U_HAS_STEALTHCHOP 1
#endif
#if ENABLED(SPI_ENDSTOPS)
#define U_SPI_SENSORLESS U_SENSORLESS
#endif
#ifndef U_INTERPOLATE
#define U_INTERPOLATE INTERPOLATE
#endif
#ifndef U_HOLD_MULTIPLIER
#define U_HOLD_MULTIPLIER HOLD_MULTIPLIER
#endif
#ifndef U_SLAVE_ADDRESS
#define U_SLAVE_ADDRESS 0
#endif
#endif
#if AXIS_IS_TMC(V)
#if defined(V_STALL_SENSITIVITY) && AXIS_HAS_STALLGUARD(V)
#define V_SENSORLESS 1
#endif
#if AXIS_HAS_STEALTHCHOP(V)
#define V_HAS_STEALTHCHOP 1
#endif
#if ENABLED(SPI_ENDSTOPS)
#define V_SPI_SENSORLESS V_SENSORLESS
#endif
#ifndef V_INTERPOLATE
#define V_INTERPOLATE INTERPOLATE
#endif
#ifndef V_HOLD_MULTIPLIER
#define V_HOLD_MULTIPLIER HOLD_MULTIPLIER
#endif
#ifndef V_SLAVE_ADDRESS
#define V_SLAVE_ADDRESS 0
#endif
#endif
#if AXIS_IS_TMC(W)
#if defined(W_STALL_SENSITIVITY) && AXIS_HAS_STALLGUARD(W)
#define W_SENSORLESS 1
#endif
#if AXIS_HAS_STEALTHCHOP(W)
#define W_HAS_STEALTHCHOP 1
#endif
#if ENABLED(SPI_ENDSTOPS)
#define W_SPI_SENSORLESS W_SENSORLESS
#endif
#ifndef W_INTERPOLATE
#define W_INTERPOLATE INTERPOLATE
#endif
#ifndef W_HOLD_MULTIPLIER
#define W_HOLD_MULTIPLIER HOLD_MULTIPLIER
#endif
#ifndef W_SLAVE_ADDRESS
#define W_SLAVE_ADDRESS 0
#endif
#endif
#if AXIS_IS_TMC(E0)
#if AXIS_HAS_STEALTHCHOP(E0)
#define E0_HAS_STEALTHCHOP 1
@ -2215,6 +2447,7 @@
#define ANY_SERIAL_IS(N) ( CONF_SERIAL_IS(N) \
|| TMC_UART_IS(X, N) || TMC_UART_IS(Y , N) || TMC_UART_IS(Z , N) \
|| TMC_UART_IS(I, N) || TMC_UART_IS(J , N) || TMC_UART_IS(K , N) \
|| TMC_UART_IS(U, N) || TMC_UART_IS(V , N) || TMC_UART_IS(W , N) \
|| TMC_UART_IS(X2, N) || TMC_UART_IS(Y2, N) || TMC_UART_IS(Z2, N) || TMC_UART_IS(Z3, N) || TMC_UART_IS(Z4, N) \
|| TMC_UART_IS(E0, N) || TMC_UART_IS(E1, N) || TMC_UART_IS(E2, N) || TMC_UART_IS(E3, N) || TMC_UART_IS(E4, N) )
@ -2349,6 +2582,24 @@
#if _HAS_STOP(K,MAX)
#define HAS_K_MAX 1
#endif
#if _HAS_STOP(U,MIN)
#define HAS_U_MIN 1
#endif
#if _HAS_STOP(U,MAX)
#define HAS_U_MAX 1
#endif
#if _HAS_STOP(V,MIN)
#define HAS_V_MIN 1
#endif
#if _HAS_STOP(V,MAX)
#define HAS_V_MAX 1
#endif
#if _HAS_STOP(W,MIN)
#define HAS_W_MIN 1
#endif
#if _HAS_STOP(W,MAX)
#define HAS_W_MAX 1
#endif
#if PIN_EXISTS(X2_MIN)
#define HAS_X2_MIN 1
#endif
@ -2849,7 +3100,7 @@
#if HAS_EXTRUDERS && PIN_EXISTS(MOTOR_CURRENT_PWM_E)
#define HAS_MOTOR_CURRENT_PWM_E 1
#endif
#if HAS_MOTOR_CURRENT_PWM_E || ANY_PIN(MOTOR_CURRENT_PWM_X, MOTOR_CURRENT_PWM_Y, MOTOR_CURRENT_PWM_XY, MOTOR_CURRENT_PWM_Z, MOTOR_CURRENT_PWM_I, MOTOR_CURRENT_PWM_J, MOTOR_CURRENT_PWM_K)
#if HAS_MOTOR_CURRENT_PWM_E || ANY_PIN(MOTOR_CURRENT_PWM_X, MOTOR_CURRENT_PWM_Y, MOTOR_CURRENT_PWM_XY, MOTOR_CURRENT_PWM_Z, MOTOR_CURRENT_PWM_I, MOTOR_CURRENT_PWM_J, MOTOR_CURRENT_PWM_K, MOTOR_CURRENT_PWM_U, MOTOR_CURRENT_PWM_V, MOTOR_CURRENT_PWM_W)
#define HAS_MOTOR_CURRENT_PWM 1
#endif
@ -2859,7 +3110,7 @@
#if ANY(HAS_E0_MS_PINS, HAS_E1_MS_PINS, HAS_E2_MS_PINS, HAS_E3_MS_PINS, HAS_E4_MS_PINS, HAS_E5_MS_PINS, HAS_E6_MS_PINS, HAS_E7_MS_PINS)
#define HAS_SOME_E_MS_PINS 1
#endif
#if ANY(HAS_X_MS_PINS, HAS_X2_MS_PINS, HAS_Y_MS_PINS, HAS_Y2_MS_PINS, HAS_SOME_Z_MS_PINS, HAS_I_MS_PINS, HAS_J_MS_PINS, HAS_K_MS_PINS, HAS_SOME_E_MS_PINS)
#if ANY(HAS_X_MS_PINS, HAS_X2_MS_PINS, HAS_Y_MS_PINS, HAS_Y2_MS_PINS, HAS_SOME_Z_MS_PINS, HAS_I_MS_PINS, HAS_J_MS_PINS, HAS_K_MS_PINS, HAS_U_MS_PINS, HAS_V_MS_PINS, HAS_W_MS_PINS, HAS_SOME_E_MS_PINS)
#define HAS_MICROSTEPS 1
#endif

View File

@ -35,8 +35,8 @@
#endif
// Strings for sanity check messages
#define _LINEAR_AXES_STR LINEAR_AXIS_GANG("X ", "Y ", "Z ", "I ", "J ", "K ")
#define _LOGICAL_AXES_STR LOGICAL_AXIS_GANG("E ", "X ", "Y ", "Z ", "I ", "J ", "K ")
#define _NUM_AXES_STR NUM_AXIS_GANG("X ", "Y ", "Z ", "I ", "J ", "K ", "U ", "V ", "W ")
#define _LOGICAL_AXES_STR LOGICAL_AXIS_GANG("E ", "X ", "Y ", "Z ", "I ", "J ", "K ", "U ", "V ", "W ")
// Make sure macros aren't borked
#define TEST1
@ -806,6 +806,12 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#error "Enable only one of ENDSTOPPULLUP_J_MAX or ENDSTOPPULLDOWN_J_MAX."
#elif BOTH(ENDSTOPPULLUP_KMAX, ENDSTOPPULLDOWN_KMAX)
#error "Enable only one of ENDSTOPPULLUP_K_MAX or ENDSTOPPULLDOWN_K_MAX."
#elif BOTH(ENDSTOPPULLUP_UMAX, ENDSTOPPULLDOWN_UMAX)
#error "Enable only one of ENDSTOPPULLUP_U_MAX or ENDSTOPPULLDOWN_U_MAX."
#elif BOTH(ENDSTOPPULLUP_VMAX, ENDSTOPPULLDOWN_VMAX)
#error "Enable only one of ENDSTOPPULLUP_V_MAX or ENDSTOPPULLDOWN_V_MAX."
#elif BOTH(ENDSTOPPULLUP_WMAX, ENDSTOPPULLDOWN_WMAX)
#error "Enable only one of ENDSTOPPULLUP_W_MAX or ENDSTOPPULLDOWN_W_MAX."
#elif BOTH(ENDSTOPPULLUP_XMIN, ENDSTOPPULLDOWN_XMIN)
#error "Enable only one of ENDSTOPPULLUP_X_MIN or ENDSTOPPULLDOWN_X_MIN."
#elif BOTH(ENDSTOPPULLUP_YMIN, ENDSTOPPULLDOWN_YMIN)
@ -818,6 +824,12 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#error "Enable only one of ENDSTOPPULLUP_J_MIN or ENDSTOPPULLDOWN_J_MIN."
#elif BOTH(ENDSTOPPULLUP_KMIN, ENDSTOPPULLDOWN_KMIN)
#error "Enable only one of ENDSTOPPULLUP_K_MIN or ENDSTOPPULLDOWN_K_MIN."
#elif BOTH(ENDSTOPPULLUP_UMIN, ENDSTOPPULLDOWN_UMIN)
#error "Enable only one of ENDSTOPPULLUP_U_MIN or ENDSTOPPULLDOWN_U_MIN."
#elif BOTH(ENDSTOPPULLUP_VMIN, ENDSTOPPULLDOWN_VMIN)
#error "Enable only one of ENDSTOPPULLUP_V_MIN or ENDSTOPPULLDOWN_V_MIN."
#elif BOTH(ENDSTOPPULLUP_WMIN, ENDSTOPPULLDOWN_WMIN)
#error "Enable only one of ENDSTOPPULLUP_W_MIN or ENDSTOPPULLDOWN_W_MIN."
#endif
/**
@ -1453,16 +1465,18 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#endif
/**
* Features that require a min/max/specific LINEAR_AXES
* Features that require a min/max/specific NUM_AXES
*/
#if HAS_LEVELING && !HAS_Z_AXIS
#error "Leveling in Marlin requires three or more axes, with Z as the vertical axis."
#elif ENABLED(CNC_WORKSPACE_PLANES) && !HAS_Z_AXIS
#error "CNC_WORKSPACE_PLANES currently requires LINEAR_AXES >= 3"
#elif ENABLED(DIRECT_STEPPING) && LINEAR_AXES > XYZ
#error "DIRECT_STEPPING currently requires LINEAR_AXES 3"
#elif ENABLED(FOAMCUTTER_XYUV) && LINEAR_AXES < 5
#error "FOAMCUTTER_XYUV requires LINEAR_AXES >= 5."
#error "CNC_WORKSPACE_PLANES currently requires NUM_AXES >= 3"
#elif ENABLED(DIRECT_STEPPING) && NUM_AXES > XYZ
#error "DIRECT_STEPPING currently requires NUM_AXES 3"
#elif ENABLED(FOAMCUTTER_XYUV) && NUM_AXES < 5
#error "FOAMCUTTER_XYUV requires NUM_AXES >= 5."
#elif ENABLED(LINEAR_ADVANCE) && HAS_I_AXIS
#error "LINEAR_ADVANCE currently requires NUM_AXES <= 3."
#endif
/**
@ -1470,33 +1484,76 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
*/
#if HAS_I_AXIS
#if !defined(I_MIN_POS) || !defined(I_MAX_POS)
#error "I_MIN_POS and I_MAX_POS are required with LINEAR_AXES >= 4."
#error "I_MIN_POS and I_MAX_POS are required with NUM_AXES >= 4."
#elif !defined(I_HOME_DIR)
#error "I_HOME_DIR is required with LINEAR_AXES >= 4."
#error "I_HOME_DIR is required with NUM_AXES >= 4."
#elif HAS_I_ENABLE && !defined(I_ENABLE_ON)
#error "I_ENABLE_ON is required for your I driver with LINEAR_AXES >= 4."
#error "I_ENABLE_ON is required for your I driver with NUM_AXES >= 4."
#endif
#endif
#if HAS_J_AXIS
#if AXIS5_NAME == AXIS4_NAME
#error "AXIS5_NAME must be unique."
#elif ENABLED(AXIS5_ROTATES) && DISABLED(AXIS4_ROTATES)
#error "AXIS5_ROTATES requires AXIS4_ROTATES."
#elif !defined(J_MIN_POS) || !defined(J_MAX_POS)
#error "J_MIN_POS and J_MAX_POS are required with LINEAR_AXES >= 5."
#error "J_MIN_POS and J_MAX_POS are required with NUM_AXES >= 5."
#elif !defined(J_HOME_DIR)
#error "J_HOME_DIR is required with LINEAR_AXES >= 5."
#error "J_HOME_DIR is required with NUM_AXES >= 5."
#elif HAS_J_ENABLE && !defined(J_ENABLE_ON)
#error "J_ENABLE_ON is required for your J driver with LINEAR_AXES >= 5."
#error "J_ENABLE_ON is required for your J driver with NUM_AXES >= 5."
#endif
#endif
#if HAS_K_AXIS
#if AXIS6_NAME == AXIS5_NAME || AXIS6_NAME == AXIS4_NAME
#error "AXIS6_NAME must be unique."
#elif ENABLED(AXIS6_ROTATES) && DISABLED(AXIS5_ROTATES)
#error "AXIS6_ROTATES requires AXIS5_ROTATES."
#elif !defined(K_MIN_POS) || !defined(K_MAX_POS)
#error "K_MIN_POS and K_MAX_POS are required with LINEAR_AXES >= 6."
#error "K_MIN_POS and K_MAX_POS are required with NUM_AXES >= 6."
#elif !defined(K_HOME_DIR)
#error "K_HOME_DIR is required with LINEAR_AXES >= 6."
#error "K_HOME_DIR is required with NUM_AXES >= 6."
#elif HAS_K_ENABLE && !defined(K_ENABLE_ON)
#error "K_ENABLE_ON is required for your K driver with LINEAR_AXES >= 6."
#error "K_ENABLE_ON is required for your K driver with NUM_AXES >= 6."
#endif
#endif
#if HAS_U_AXIS
#if AXIS7_NAME == AXIS6_NAME || AXIS7_NAME == AXIS5_NAME || AXIS7_NAME == AXIS4_NAME
#error "AXIS7_NAME must be unique."
#elif ENABLED(AXIS7_ROTATES) && DISABLED(AXIS6_ROTATES)
#error "AXIS7_ROTATES requires AXIS6_ROTATES."
#elif !defined(U_MIN_POS) || !defined(U_MAX_POS)
#error "U_MIN_POS and U_MAX_POS are required with NUM_AXES >= 7."
#elif !defined(U_HOME_DIR)
#error "U_HOME_DIR is required with NUM_AXES >= 7."
#elif HAS_U_ENABLE && !defined(U_ENABLE_ON)
#error "U_ENABLE_ON is required for your U driver with NUM_AXES >= 7."
#endif
#endif
#if HAS_V_AXIS
#if AXIS8_NAME == AXIS7_NAME || AXIS8_NAME == AXIS6_NAME || AXIS8_NAME == AXIS5_NAME || AXIS8_NAME == AXIS4_NAME
#error "AXIS8_NAME must be unique."
#elif ENABLED(AXIS8_ROTATES) && DISABLED(AXIS7_ROTATES)
#error "AXIS8_ROTATES requires AXIS7_ROTATES."
#elif !defined(V_MIN_POS) || !defined(V_MAX_POS)
#error "V_MIN_POS and V_MAX_POS are required with NUM_AXES >= 8."
#elif !defined(V_HOME_DIR)
#error "V_HOME_DIR is required with NUM_AXES >= 8."
#elif HAS_V_ENABLE && !defined(V_ENABLE_ON)
#error "V_ENABLE_ON is required for your V driver with NUM_AXES >= 8."
#endif
#endif
#if HAS_W_AXIS
#if AXIS9_NAME == AXIS8_NAME || AXIS9_NAME == AXIS7_NAME || AXIS9_NAME == AXIS6_NAME || AXIS9_NAME == AXIS5_NAME || AXIS9_NAME == AXIS4_NAME
#error "AXIS9_NAME must be unique."
#elif ENABLED(AXIS9_ROTATES) && DISABLED(AXIS8_ROTATES)
#error "AXIS9_ROTATES requires AXIS8_ROTATES."
#elif !defined(W_MIN_POS) || !defined(W_MAX_POS)
#error "W_MIN_POS and W_MAX_POS are required with NUM_AXES >= 9."
#elif !defined(W_HOME_DIR)
#error "W_HOME_DIR is required with NUM_AXES >= 9."
#elif HAS_W_ENABLE && !defined(W_ENABLE_ON)
#error "W_ENABLE_ON is required for your W driver with NUM_AXES >= 9."
#endif
#endif
@ -1886,49 +1943,61 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#error "Required setting HOMING_BUMP_DIVISOR is missing!"
#else
constexpr float hbm[] = HOMING_BUMP_MM, hbd[] = HOMING_BUMP_DIVISOR;
static_assert(COUNT(hbm) == LINEAR_AXES, "HOMING_BUMP_MM must have " _LINEAR_AXES_STR "elements (and no others).");
LINEAR_AXIS_CODE(
static_assert(COUNT(hbm) == NUM_AXES, "HOMING_BUMP_MM must have " _NUM_AXES_STR "elements (and no others).");
NUM_AXIS_CODE(
static_assert(hbm[X_AXIS] >= 0, "HOMING_BUMP_MM.X must be greater than or equal to 0."),
static_assert(hbm[Y_AXIS] >= 0, "HOMING_BUMP_MM.Y must be greater than or equal to 0."),
static_assert(hbm[Z_AXIS] >= 0, "HOMING_BUMP_MM.Z must be greater than or equal to 0."),
static_assert(hbm[I_AXIS] >= 0, "HOMING_BUMP_MM.I must be greater than or equal to 0."),
static_assert(hbm[J_AXIS] >= 0, "HOMING_BUMP_MM.J must be greater than or equal to 0."),
static_assert(hbm[K_AXIS] >= 0, "HOMING_BUMP_MM.K must be greater than or equal to 0.")
static_assert(hbm[K_AXIS] >= 0, "HOMING_BUMP_MM.K must be greater than or equal to 0."),
static_assert(hbm[U_AXIS] >= 0, "HOMING_BUMP_MM.U must be greater than or equal to 0."),
static_assert(hbm[V_AXIS] >= 0, "HOMING_BUMP_MM.V must be greater than or equal to 0."),
static_assert(hbm[W_AXIS] >= 0, "HOMING_BUMP_MM.W must be greater than or equal to 0.")
);
static_assert(COUNT(hbd) == LINEAR_AXES, "HOMING_BUMP_DIVISOR must have " _LINEAR_AXES_STR "elements (and no others).");
LINEAR_AXIS_CODE(
static_assert(COUNT(hbd) == NUM_AXES, "HOMING_BUMP_DIVISOR must have " _NUM_AXES_STR "elements (and no others).");
NUM_AXIS_CODE(
static_assert(hbd[X_AXIS] >= 1, "HOMING_BUMP_DIVISOR.X must be greater than or equal to 1."),
static_assert(hbd[Y_AXIS] >= 1, "HOMING_BUMP_DIVISOR.Y must be greater than or equal to 1."),
static_assert(hbd[Z_AXIS] >= 1, "HOMING_BUMP_DIVISOR.Z must be greater than or equal to 1."),
static_assert(hbd[I_AXIS] >= 1, "HOMING_BUMP_DIVISOR.I must be greater than or equal to 1."),
static_assert(hbd[J_AXIS] >= 1, "HOMING_BUMP_DIVISOR.J must be greater than or equal to 1."),
static_assert(hbd[K_AXIS] >= 1, "HOMING_BUMP_DIVISOR.K must be greater than or equal to 1.")
static_assert(hbd[K_AXIS] >= 1, "HOMING_BUMP_DIVISOR.K must be greater than or equal to 1."),
static_assert(hbd[U_AXIS] >= 1, "HOMING_BUMP_DIVISOR.U must be greater than or equal to 1."),
static_assert(hbd[V_AXIS] >= 1, "HOMING_BUMP_DIVISOR.V must be greater than or equal to 1."),
static_assert(hbd[W_AXIS] >= 1, "HOMING_BUMP_DIVISOR.W must be greater than or equal to 1.")
);
#endif
#ifdef HOMING_BACKOFF_POST_MM
constexpr float hbp[] = HOMING_BACKOFF_POST_MM;
static_assert(COUNT(hbp) == LINEAR_AXES, "HOMING_BACKOFF_POST_MM must have " _LINEAR_AXES_STR "elements (and no others).");
LINEAR_AXIS_CODE(
static_assert(COUNT(hbp) == NUM_AXES, "HOMING_BACKOFF_POST_MM must have " _NUM_AXES_STR "elements (and no others).");
NUM_AXIS_CODE(
static_assert(hbp[X_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.X must be greater than or equal to 0."),
static_assert(hbp[Y_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.Y must be greater than or equal to 0."),
static_assert(hbp[Z_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.Z must be greater than or equal to 0."),
static_assert(hbp[I_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.I must be greater than or equal to 0."),
static_assert(hbp[J_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.J must be greater than or equal to 0."),
static_assert(hbp[K_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.K must be greater than or equal to 0.")
static_assert(hbp[K_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.K must be greater than or equal to 0."),
static_assert(hbp[U_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.U must be greater than or equal to 0."),
static_assert(hbp[V_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.V must be greater than or equal to 0."),
static_assert(hbp[W_AXIS] >= 0, "HOMING_BACKOFF_POST_MM.W must be greater than or equal to 0.")
);
#endif
#ifdef SENSORLESS_BACKOFF_MM
constexpr float sbm[] = SENSORLESS_BACKOFF_MM;
static_assert(COUNT(sbm) == LINEAR_AXES, "SENSORLESS_BACKOFF_MM must have " _LINEAR_AXES_STR "elements (and no others).");
LINEAR_AXIS_CODE(
static_assert(COUNT(sbm) == NUM_AXES, "SENSORLESS_BACKOFF_MM must have " _NUM_AXES_STR "elements (and no others).");
NUM_AXIS_CODE(
static_assert(sbm[X_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.X must be greater than or equal to 0."),
static_assert(sbm[Y_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.Y must be greater than or equal to 0."),
static_assert(sbm[Z_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.Z must be greater than or equal to 0."),
static_assert(sbm[I_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.I must be greater than or equal to 0."),
static_assert(sbm[J_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.J must be greater than or equal to 0."),
static_assert(sbm[K_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.K must be greater than or equal to 0.")
static_assert(sbm[K_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.K must be greater than or equal to 0."),
static_assert(sbm[U_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.U must be greater than or equal to 0."),
static_assert(sbm[V_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.V must be greater than or equal to 0."),
static_assert(sbm[W_AXIS] >= 0, "SENSORLESS_BACKOFF_MM.W must be greater than or equal to 0.")
);
#endif
@ -1951,9 +2020,9 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
/**
* Make sure DISABLE_[XYZ] compatible with selected homing options
*/
#if ANY(DISABLE_X, DISABLE_Y, DISABLE_Z, DISABLE_I, DISABLE_J, DISABLE_K)
#if ANY(DISABLE_X, DISABLE_Y, DISABLE_Z, DISABLE_I, DISABLE_J, DISABLE_K, DISABLE_U, DISABLE_V, DISABLE_W)
#if EITHER(HOME_AFTER_DEACTIVATE, Z_SAFE_HOMING)
#error "DISABLE_[XYZIJK] is not compatible with HOME_AFTER_DEACTIVATE or Z_SAFE_HOMING."
#error "DISABLE_[XYZIJKUVW] is not compatible with HOME_AFTER_DEACTIVATE or Z_SAFE_HOMING."
#endif
#endif
@ -2453,7 +2522,9 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#define _PLUG_UNUSED_TEST(A,P) (DISABLED(USE_##P##MIN_PLUG, USE_##P##MAX_PLUG) \
&& !(ENABLED(A##_DUAL_ENDSTOPS) && WITHIN(A##2_USE_ENDSTOP, _##P##MAX_, _##P##MIN_)) \
&& !(ENABLED(A##_MULTI_ENDSTOPS) && WITHIN(A##2_USE_ENDSTOP, _##P##MAX_, _##P##MIN_)) )
#define _AXIS_PLUG_UNUSED_TEST(A) (1 LINEAR_AXIS_GANG(&& _PLUG_UNUSED_TEST(A,X), && _PLUG_UNUSED_TEST(A,Y), && _PLUG_UNUSED_TEST(A,Z), && _PLUG_UNUSED_TEST(A,I), && _PLUG_UNUSED_TEST(A,J), && _PLUG_UNUSED_TEST(A,K) ) )
#define _AXIS_PLUG_UNUSED_TEST(A) (1 NUM_AXIS_GANG(&& _PLUG_UNUSED_TEST(A,X), && _PLUG_UNUSED_TEST(A,Y), && _PLUG_UNUSED_TEST(A,Z), \
&& _PLUG_UNUSED_TEST(A,I), && _PLUG_UNUSED_TEST(A,J), && _PLUG_UNUSED_TEST(A,K), \
&& _PLUG_UNUSED_TEST(A,U), && _PLUG_UNUSED_TEST(A,V), && _PLUG_UNUSED_TEST(A,W) ) )
// A machine with endstops must have a minimum of 3
#if HAS_ENDSTOPS
@ -2475,6 +2546,15 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#if HAS_K_AXIS && _AXIS_PLUG_UNUSED_TEST(K)
#error "You must enable USE_KMIN_PLUG or USE_KMAX_PLUG."
#endif
#if HAS_U_AXIS && _AXIS_PLUG_UNUSED_TEST(U)
#error "You must enable USE_UMIN_PLUG or USE_UMAX_PLUG."
#endif
#if HAS_V_AXIS && _AXIS_PLUG_UNUSED_TEST(V)
#error "You must enable USE_VMIN_PLUG or USE_VMAX_PLUG."
#endif
#if HAS_W_AXIS && _AXIS_PLUG_UNUSED_TEST(W)
#error "You must enable USE_WMIN_PLUG or USE_WMAX_PLUG."
#endif
// Delta and Cartesian use 3 homing endstops
#if NONE(IS_SCARA, SPI_ENDSTOPS)
@ -2498,6 +2578,18 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#error "Enable USE_KMIN_PLUG when homing K to MIN."
#elif HAS_K_AXIS && K_HOME_TO_MAX && DISABLED(USE_KMAX_PLUG)
#error "Enable USE_KMAX_PLUG when homing K to MAX."
#elif HAS_U_AXIS && U_HOME_TO_MIN && DISABLED(USE_UMIN_PLUG)
#error "Enable USE_UMIN_PLUG when homing U to MIN."
#elif HAS_U_AXIS && U_HOME_TO_MAX && DISABLED(USE_UMAX_PLUG)
#error "Enable USE_UMAX_PLUG when homing U to MAX."
#elif HAS_V_AXIS && V_HOME_TO_MIN && DISABLED(USE_VMIN_PLUG)
#error "Enable USE_VMIN_PLUG when homing V to MIN."
#elif HAS_V_AXIS && V_HOME_TO_MAX && DISABLED(USE_VMAX_PLUG)
#error "Enable USE_VMAX_PLUG when homing V to MAX."
#elif HAS_W_AXIS && W_HOME_TO_MIN && DISABLED(USE_WMIN_PLUG)
#error "Enable USE_WMIN_PLUG when homing W to MIN."
#elif HAS_W_AXIS && W_HOME_TO_MAX && DISABLED(USE_WMAX_PLUG)
#error "Enable USE_WMAX_PLUG when homing W to MAX."
#endif
#endif
@ -2994,6 +3086,12 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#error "An SPI driven TMC on J requires J_CS_PIN."
#elif INVALID_TMC_SPI(K)
#error "An SPI driven TMC on K requires K_CS_PIN."
#elif INVALID_TMC_SPI(U)
#error "An SPI driven TMC on U requires U_CS_PIN."
#elif INVALID_TMC_SPI(V)
#error "An SPI driven TMC on V requires V_CS_PIN."
#elif INVALID_TMC_SPI(W)
#error "An SPI driven TMC on W requires W_CS_PIN."
#endif
#undef INVALID_TMC_SPI
@ -3039,6 +3137,13 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#error "TMC2208 or TMC2209 on J requires J_HARDWARE_SERIAL or J_SERIAL_(RX|TX)_PIN."
#elif HAS_K_AXIS && INVALID_TMC_UART(K)
#error "TMC2208 or TMC2209 on K requires K_HARDWARE_SERIAL or K_SERIAL_(RX|TX)_PIN."
#elif HAS_U_AXIS && INVALID_TMC_UART(U)
#error "TMC2208 or TMC2209 on U requires U_HARDWARE_SERIAL or U_SERIAL_(RX|TX)_PIN."
#elif HAS_V_AXIS && INVALID_TMC_UART(V)
#error "TMC2208 or TMC2209 on V requires V_HARDWARE_SERIAL or V_SERIAL_(RX|TX)_PIN."
#elif HAS_W_AXIS && INVALID_TMC_UART(W)
#error "TMC2208 or TMC2209 on W requires W_HARDWARE_SERIAL or W_SERIAL_(RX|TX)_PIN."
#endif
#undef INVALID_TMC_UART
@ -3068,6 +3173,12 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
INVALID_TMC_ADDRESS(J);
#elif AXIS_DRIVER_TYPE_K(TMC2209)
INVALID_TMC_ADDRESS(K);
#elif AXIS_DRIVER_TYPE_U(TMC2209)
INVALID_TMC_ADDRESS(U);
#elif AXIS_DRIVER_TYPE_V(TMC2209)
INVALID_TMC_ADDRESS(V);
#elif AXIS_DRIVER_TYPE_W(TMC2209)
INVALID_TMC_ADDRESS(W);
#elif AXIS_DRIVER_TYPE_E0(TMC2209)
INVALID_TMC_ADDRESS(E0);
#elif AXIS_DRIVER_TYPE_E1(TMC2209)
@ -3129,6 +3240,12 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
INVALID_TMC_MS(J)
#elif HAS_K_AXIS && !TMC_MICROSTEP_IS_VALID(K)
INVALID_TMC_MS(K)
#elif HAS_U_AXIS && !TMC_MICROSTEP_IS_VALID(U)
INVALID_TMC_MS(U)
#elif HAS_V_AXIS && !TMC_MICROSTEP_IS_VALID(V)
INVALID_TMC_MS(V)
#elif HAS_W_AXIS && !TMC_MICROSTEP_IS_VALID(W)
INVALID_TMC_MS(W)
#endif
#undef INVALID_TMC_MS
#undef TMC_MICROSTEP_IS_VALID
@ -3158,6 +3275,15 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#if HAS_K_AXIS
#define K_ENDSTOP_INVERTING !AXIS_DRIVER_TYPE(K,TMC2209)
#endif
#if HAS_U_AXIS
#define U_ENDSTOP_INVERTING !AXIS_DRIVER_TYPE(U,TMC2209)
#endif
#if HAS_V_AXIS
#define V_ENDSTOP_INVERTING !AXIS_DRIVER_TYPE(V,TMC2209)
#endif
#if HAS_W_AXIS
#define W_ENDSTOP_INVERTING !AXIS_DRIVER_TYPE(W,TMC2209)
#endif
#if NONE(SPI_ENDSTOPS, ONBOARD_ENDSTOPPULLUPS, ENDSTOPPULLUPS)
#if X_SENSORLESS && X_HOME_TO_MIN && DISABLED(ENDSTOPPULLUP_XMIN)
@ -3184,6 +3310,19 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#error "SENSORLESS_HOMING requires ENDSTOPPULLUP_KMIN (or ENDSTOPPULLUPS) when homing to K_MIN."
#elif ALL(HAS_K_AXIS, K_SENSORLESS, K_HOME_TO_MAX) && DISABLED(ENDSTOPPULLUP_KMAX)
#error "SENSORLESS_HOMING requires ENDSTOPPULLUP_KMAX (or ENDSTOPPULLUPS) when homing to K_MAX."
#elif HAS_U_AXIS && U_SENSORLESS && U_HOME_TO_MIN && DISABLED(ENDSTOPPULLUP_UMIN)
#error "SENSORLESS_HOMING requires ENDSTOPPULLUP_UMIN (or ENDSTOPPULLUPS) when homing to U_MIN."
#elif HAS_U_AXIS && U_SENSORLESS && U_HOME_TO_MAX && DISABLED(ENDSTOPPULLUP_UMAX)
#error "SENSORLESS_HOMING requires ENDSTOPPULLUP_UMAX (or ENDSTOPPULLUPS) when homing to U_MAX."
#elif HAS_V_AXIS && V_SENSORLESS && V_HOME_TO_MIN && DISABLED(ENDSTOPPULLUP_VMIN)
#error "SENSORLESS_HOMING requires ENDSTOPPULLUP_VMIN (or ENDSTOPPULLUPS) when homing to V_MIN."
#elif HAS_V_AXIS && V_SENSORLESS && V_HOME_TO_MAX && DISABLED(ENDSTOPPULLUP_VMAX)
#error "SENSORLESS_HOMING requires ENDSTOPPULLUP_VMAX (or ENDSTOPPULLUPS) when homing to V_MAX."
#elif HAS_W_AXIS && W_SENSORLESS && W_HOME_TO_MIN && DISABLED(ENDSTOPPULLUP_WMIN)
#error "SENSORLESS_HOMING requires ENDSTOPPULLUP_WMIN (or ENDSTOPPULLUPS) when homing to W_MIN."
#elif HAS_W_AXIS && W_SENSORLESS && W_HOME_TO_MAX && DISABLED(ENDSTOPPULLUP_WMAX)
#error "SENSORLESS_HOMING requires ENDSTOPPULLUP_WMAX (or ENDSTOPPULLUPS) when homing to W_MAX."
#endif
#endif
@ -3264,6 +3403,42 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#else
#error "SENSORLESS_HOMING requires K_MAX_ENDSTOP_INVERTING = false when homing TMC2209 to K_MAX."
#endif
#elif ALL(HAS_U_AXIS, U_SENSORLESS, U_HOME_TO_MIN) && U_MIN_ENDSTOP_INVERTING != U_ENDSTOP_INVERTING
#if U_ENDSTOP_INVERTING
#error "SENSORLESS_HOMING requires U_MIN_ENDSTOP_INVERTING = true when homing to U_MIN."
#else
#error "SENSORLESS_HOMING requires U_MIN_ENDSTOP_INVERTING = false when homing TMC2209 to U_MIN."
#endif
#elif ALL(HAS_U_AXIS, U_SENSORLESS, U_HOME_TO_MAX) && U_MAX_ENDSTOP_INVERTING != U_ENDSTOP_INVERTING
#if U_ENDSTOP_INVERTING
#error "SENSORLESS_HOMING requires U_MAX_ENDSTOP_INVERTING = true when homing to U_MAX."
#else
#error "SENSORLESS_HOMING requires U_MAX_ENDSTOP_INVERTING = false when homing TMC2209 to U_MAX."
#endif
#elif ALL(HAS_V_AXIS, V_SENSORLESS, V_HOME_TO_MIN) && V_MIN_ENDSTOP_INVERTING != V_ENDSTOP_INVERTING
#if V_ENDSTOP_INVERTING
#error "SENSORLESS_HOMING requires V_MIN_ENDSTOP_INVERTING = true when homing to V_MIN."
#else
#error "SENSORLESS_HOMING requires V_MIN_ENDSTOP_INVERTING = false when homing TMC2209 to V_MIN."
#endif
#elif ALL(HAS_V_AXIS, V_SENSORLESS, V_HOME_TO_MAX) && V_MAX_ENDSTOP_INVERTING != V_ENDSTOP_INVERTING
#if V_ENDSTOP_INVERTING
#error "SENSORLESS_HOMING requires V_MAX_ENDSTOP_INVERTING = true when homing to V_MAX."
#else
#error "SENSORLESS_HOMING requires V_MAX_ENDSTOP_INVERTING = false when homing TMC2209 to V_MAX."
#endif
#elif ALL(HAS_W_AXIS, W_SENSORLESS, W_HOME_TO_MIN) && W_MIN_ENDSTOP_INVERTING != W_ENDSTOP_INVERTING
#if W_ENDSTOP_INVERTING
#error "SENSORLESS_HOMING requires W_MIN_ENDSTOP_INVERTING = true when homing to W_MIN."
#else
#error "SENSORLESS_HOMING requires W_MIN_ENDSTOP_INVERTING = false when homing TMC2209 to W_MIN."
#endif
#elif ALL(HAS_W_AXIS, W_SENSORLESS, W_HOME_TO_MAX0) && W_MAX_ENDSTOP_INVERTING != W_ENDSTOP_INVERTING
#if W_ENDSTOP_INVERTING
#error "SENSORLESS_HOMING requires W_MAX_ENDSTOP_INVERTING = true when homing to W_MAX."
#else
#error "SENSORLESS_HOMING requires W_MAX_ENDSTOP_INVERTING = false when homing TMC2209 to W_MAX."
#endif
#endif
#endif
@ -3281,6 +3456,9 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#undef I_ENDSTOP_INVERTING
#undef J_ENDSTOP_INVERTING
#undef K_ENDSTOP_INVERTING
#undef U_ENDSTOP_INVERTING
#undef V_ENDSTOP_INVERTING
#undef W_ENDSTOP_INVERTING
#endif
// Sensorless probing requirements
@ -3349,6 +3527,12 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#define CS_COMPARE J_CS_PIN
#elif IN_CHAIN(K)
#define CS_COMPARE K_CS_PIN
#elif IN_CHAIN(U)
#define CS_COMPARE U_CS_PIN
#elif IN_CHAIN(V)
#define CS_COMPARE V_CS_PIN
#elif IN_CHAIN(W)
#define CS_COMPARE W_CS_PIN
#elif IN_CHAIN(E0)
#define CS_COMPARE E0_CS_PIN
#elif IN_CHAIN(E1)
@ -3369,6 +3553,7 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#define BAD_CS_PIN(A) (IN_CHAIN(A) && A##_CS_PIN != CS_COMPARE)
#if BAD_CS_PIN(X ) || BAD_CS_PIN(Y ) || BAD_CS_PIN(Z ) || BAD_CS_PIN(X2) || BAD_CS_PIN(Y2) || BAD_CS_PIN(Z2) || BAD_CS_PIN(Z3) || BAD_CS_PIN(Z4) \
|| BAD_CS_PIN(I) || BAD_CS_PIN(J) || BAD_CS_PIN(K) \
|| BAD_CS_PIN(U) || BAD_CS_PIN(V) || BAD_CS_PIN(W) \
|| BAD_CS_PIN(E0) || BAD_CS_PIN(E1) || BAD_CS_PIN(E2) || BAD_CS_PIN(E3) || BAD_CS_PIN(E4) || BAD_CS_PIN(E5) || BAD_CS_PIN(E6) || BAD_CS_PIN(E7)
#error "All chained TMC drivers must use the same CS pin."
#endif
@ -3382,8 +3567,8 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
/**
* L64XX requirement
*/
#if HAS_L64XX && HAS_I_AXIS
#error "L64XX requires LINEAR_AXES <= 3. Homing with L64XX is not yet implemented for LINEAR_AXES > 3."
#if HAS_L64XX && NUM_AXES > 3
#error "L64XX requires NUM_AXES <= 3. Homing with L64XX is not yet implemented for NUM_AXES > 3."
#endif
/**
@ -3407,7 +3592,7 @@ static_assert(Y_MAX_LENGTH >= Y_BED_SIZE, "Movement bounds (Y_MIN_POS, Y_MAX_POS
#if HAS_MULTI_EXTRUDER
#define _EXTRA_NOTE " (Did you forget to enable DISTINCT_E_FACTORS?)"
#else
#define _EXTRA_NOTE " (Should be " STRINGIFY(LINEAR_AXES) "+" STRINGIFY(E_STEPPERS) ")"
#define _EXTRA_NOTE " (Should be " STRINGIFY(NUM_AXES) "+" STRINGIFY(E_STEPPERS) ")"
#endif
constexpr float sanity_arr_1[] = DEFAULT_AXIS_STEPS_PER_UNIT;
@ -3426,7 +3611,7 @@ static_assert(COUNT(sanity_arr_3) <= DISTINCT_AXES, "DEFAULT_MAX_ACCELERATION ha
static_assert(_PLUS_TEST(3), "DEFAULT_MAX_ACCELERATION values must be positive.");
constexpr float sanity_arr_4[] = HOMING_FEEDRATE_MM_M;
static_assert(COUNT(sanity_arr_4) == LINEAR_AXES, "HOMING_FEEDRATE_MM_M requires " _LINEAR_AXES_STR "elements (and no others).");
static_assert(COUNT(sanity_arr_4) == NUM_AXES, "HOMING_FEEDRATE_MM_M requires " _NUM_AXES_STR "elements (and no others).");
static_assert(_PLUS_TEST(4), "HOMING_FEEDRATE_MM_M values must be positive.");
#ifdef MAX_ACCEL_EDIT_VALUES
@ -3872,6 +4057,15 @@ static_assert(_PLUS_TEST(4), "HOMING_FEEDRATE_MM_M values must be positive.");
#if _BAD_DRIVER(K)
#error "K_DRIVER_TYPE is not recognized."
#endif
#if _BAD_DRIVER(U)
#error "U_DRIVER_TYPE is not recognized."
#endif
#if _BAD_DRIVER(V)
#error "V_DRIVER_TYPE is not recognized."
#endif
#if _BAD_DRIVER(W)
#error "W_DRIVER_TYPE is not recognized."
#endif
#if _BAD_DRIVER(X2)
#error "X2_DRIVER_TYPE is not recognized."
#endif
@ -3944,7 +4138,7 @@ static_assert(_PLUS_TEST(4), "HOMING_FEEDRATE_MM_M values must be positive.");
// Misc. Cleanup
#undef _TEST_PWM
#undef _LINEAR_AXES_STR
#undef _NUM_AXES_STR
#undef _LOGICAL_AXES_STR
// JTAG support in the HAL

View File

@ -540,6 +540,163 @@
#endif
#endif
#if AUTO_ASSIGNED_U_STEPPER
#warning "Note: Auto-assigned U STEP/DIR/ENABLE_PINs to unused En_STEP/DIR/ENABLE_PINs. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_U_CS
#warning "Note: Auto-assigned U_CS_PIN to an unused En_CS_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_U_MS1
#warning "Note: Auto-assigned U_MS1_PIN to an unused En_MS1_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_U_MS2
#warning "Note: Auto-assigned U_MS2_PIN to an unused En_MS2_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_U_MS3
#warning "Note: Auto-assigned U_MS3_PIN to an unused En_MS3_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_U_DIAG
#if U_USE_ENDSTOP == _XMIN_
#warning "Note: Auto-assigned U_DIAG_PIN to X_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _XMAX_
#warning "Note: Auto-assigned U_DIAG_PIN to X_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif K_USE_ENDSTOP == _YMIN_
#warning "Note: Auto-assigned U_DIAG_PIN to Y_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _YMAX_
#warning "Note: Auto-assigned U_DIAG_PIN to Y_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _ZMIN_
#warning "Note: Auto-assigned U_DIAG_PIN to Z_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _ZMAX_
#warning "Note: Auto-assigned U_DIAG_PIN to Z_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _XDIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to X_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _YDIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to Y_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _ZDIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to Z_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _E0DIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to E0_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _E1DIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to E1_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _E2DIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to E2_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _E3DIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to E3_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _E4DIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to E4_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _E5DIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to E5_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _E6DIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to E6_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif U_USE_ENDSTOP == _E7DIAG_
#warning "Note: Auto-assigned U_DIAG_PIN to E7_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#endif
#if AUTO_ASSIGNED_V_STEPPER
#warning "Note: Auto-assigned V STEP/DIR/ENABLE_PINs to unused En_STEP/DIR/ENABLE_PINs. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_V_CS
#warning "Note: Auto-assigned V_CS_PIN to an unused En_CS_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_V_MS1
#warning "Note: Auto-assigned V_MS1_PIN to an unused En_MS1_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_V_MS2
#warning "Note: Auto-assigned V_MS2_PIN to an unused En_MS2_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_V_MS3
#warning "Note: Auto-assigned V_MS3_PIN to an unused En_MS3_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_V_DIAG
#if V_USE_ENDSTOP == _XMIN_
#warning "Note: Auto-assigned V_DIAG_PIN to X_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _XMAX_
#warning "Note: Auto-assigned V_DIAG_PIN to X_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _YMIN_
#warning "Note: Auto-assigned V_DIAG_PIN to Y_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _YMAX_
#warning "Note: Auto-assigned V_DIAG_PIN to Y_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _ZMIN_
#warning "Note: Auto-assigned V_DIAG_PIN to Z_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _ZMAX_
#warning "Note: Auto-assigned V_DIAG_PIN to Z_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _XDIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to X_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _YDIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to Y_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _ZDIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to Z_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _E0DIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to E0_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _E1DIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to E1_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _E2DIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to E2_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _E3DIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to E3_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _E4DIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to E4_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _E5DIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to E5_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _E6DIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to E6_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif V_USE_ENDSTOP == _E7DIAG_
#warning "Note: Auto-assigned V_DIAG_PIN to E7_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#endif
#if AUTO_ASSIGNED_W_STEPPER
#warning "Note: Auto-assigned W STEP/DIR/ENABLE_PINs to unused En_STEP/DIR/ENABLE_PINs. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_W_CS
#warning "Note: Auto-assigned W_CS_PIN to an unused En_CS_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_W_MS1
#warning "Note: Auto-assigned W_MS1_PIN to an unused En_MS1_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_W_MS2
#warning "Note: Auto-assigned W_MS2_PIN to an unused En_MS2_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_W_MS3
#warning "Note: Auto-assigned W_MS3_PIN to an unused En_MS3_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#if AUTO_ASSIGNED_W_DIAG
#if W_USE_ENDSTOP == _XMIN_
#warning "Note: Auto-assigned W_DIAG_PIN to X_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _XMAX_
#warning "Note: Auto-assigned W_DIAG_PIN to X_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _YMIN_
#warning "Note: Auto-assigned W_DIAG_PIN to Y_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _YMAX_
#warning "Note: Auto-assigned W_DIAG_PIN to Y_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _ZMIN_
#warning "Note: Auto-assigned W_DIAG_PIN to Z_MIN_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _ZMAX_
#warning "Note: Auto-assigned W_DIAG_PIN to Z_MAX_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _XDIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to X_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _YDIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to Y_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _ZDIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to Z_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _E0DIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to E0_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _E1DIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to E1_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _E2DIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to E2_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _E3DIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to E3_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _E4DIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to E4_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _E5DIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to E5_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _E6DIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to E6_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#elif W_USE_ENDSTOP == _E7DIAG_
#warning "Note: Auto-assigned W_DIAG_PIN to E7_DIAG_PIN. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif
#endif
#if ENABLED(CHAMBER_FAN) && !defined(CHAMBER_FAN_INDEX)
#warning "Note: Auto-assigned CHAMBER_FAN_INDEX to the first free FAN pin. (Define NO_AUTO_ASSIGN_WARNING to suppress this warning.)"
#endif

View File

@ -286,7 +286,7 @@ void DGUSTxHandler::TempMax(DGUS_VP &vp) {
}
void DGUSTxHandler::StepperStatus(DGUS_VP &vp) {
const bool motor_on = stepper.axis_enabled.bits & (_BV(LINEAR_AXES) - 1);
const bool motor_on = stepper.axis_enabled.bits & (_BV(NUM_AXES) - 1);
dgus_display.Write((uint16_t)vp.addr, Swap16(uint16_t(motor_on ? DGUS_Data::Status::ENABLED : DGUS_Data::Status::DISABLED)));
}

View File

@ -45,7 +45,7 @@
*/
#define __DECL_DATA_IF_INCLUDED(CLASS) struct CLASS ## Data CLASS ;
#define _DECL_DATA_IF_INCLUDED(CLASS) __DECL_DATA_IF_INCLUDED(CLASS)
#define DECL_DATA_IF_INCLUDED(HEADER) TERN(HEADER, _DECL_DATA_IF_INCLUDED(HEADER ## _CLASS), )
#define DECL_DATA_IF_INCLUDED(HEADER) TERN_(HEADER, _DECL_DATA_IF_INCLUDED(HEADER ## _CLASS))
union screen_data_t {
DECL_DATA_IF_INCLUDED(FTDI_INTERFACE_SETTINGS_SCREEN)

View File

@ -420,6 +420,15 @@ namespace ExtUI {
#if AXIS_IS_TMC(K)
case K: return stepperK.getMilliamps();
#endif
#if AXIS_IS_TMC(U)
case U: return stepperU.getMilliamps();
#endif
#if AXIS_IS_TMC(V)
case V: return stepperV.getMilliamps();
#endif
#if AXIS_IS_TMC(W)
case W: return stepperW.getMilliamps();
#endif
#if AXIS_IS_TMC(X2)
case X2: return stepperX2.getMilliamps();
#endif
@ -489,6 +498,15 @@ namespace ExtUI {
#if AXIS_IS_TMC(K)
case K: stepperK.rms_current(constrain(mA, 400, 1500)); break;
#endif
#if AXIS_IS_TMC(U)
case U: stepperU.rms_current(constrain(mA, 400, 1500)); break;
#endif
#if AXIS_IS_TMC(V)
case V: stepperV.rms_current(constrain(mA, 400, 1500)); break;
#endif
#if AXIS_IS_TMC(W)
case W: stepperW.rms_current(constrain(mA, 400, 1500)); break;
#endif
#if AXIS_IS_TMC(X2)
case X2: stepperX2.rms_current(constrain(mA, 400, 1500)); break;
#endif
@ -546,6 +564,9 @@ namespace ExtUI {
OPTCODE(I_SENSORLESS, case I: return stepperI.homing_threshold())
OPTCODE(J_SENSORLESS, case J: return stepperJ.homing_threshold())
OPTCODE(K_SENSORLESS, case K: return stepperK.homing_threshold())
OPTCODE(U_SENSORLESS, case U: return stepperU.homing_threshold())
OPTCODE(V_SENSORLESS, case V: return stepperV.homing_threshold())
OPTCODE(W_SENSORLESS, case W: return stepperW.homing_threshold())
OPTCODE(X2_SENSORLESS, case X2: return stepperX2.homing_threshold())
OPTCODE(Y2_SENSORLESS, case Y2: return stepperY2.homing_threshold())
OPTCODE(Z2_SENSORLESS, case Z2: return stepperZ2.homing_threshold())
@ -575,6 +596,15 @@ namespace ExtUI {
#if K_SENSORLESS
case K: stepperK.homing_threshold(value); break;
#endif
#if U_SENSORLESS
case U: stepperU.homing_threshold(value); break;
#endif
#if V_SENSORLESS
case V: stepperV.homing_threshold(value); break;
#endif
#if W_SENSORLESS
case W: stepperW.homing_threshold(value); break;
#endif
#if X2_SENSORLESS
case X2: stepperX2.homing_threshold(value); break;
#endif

View File

@ -57,7 +57,7 @@ namespace ExtUI {
static constexpr size_t eeprom_data_size = 48;
enum axis_t : uint8_t { X, Y, Z, I, J, K, X2, Y2, Z2, Z3, Z4 };
enum axis_t : uint8_t { X, Y, Z, I, J, K, U, V, W, X2, Y2, Z2, Z3, Z4 };
enum extruder_t : uint8_t { E0, E1, E2, E3, E4, E5, E6, E7 };
enum heater_t : uint8_t { H0, H1, H2, H3, H4, H5, BED, CHAMBER, COOLER };
enum fan_t : uint8_t { FAN0, FAN1, FAN2, FAN3, FAN4, FAN5, FAN6, FAN7 };

View File

@ -417,7 +417,7 @@ void menu_backlash();
#elif ENABLED(LIMITED_MAX_FR_EDITING)
DEFAULT_MAX_FEEDRATE
#else
LOGICAL_AXIS_ARRAY(9999, 9999, 9999, 9999, 9999, 9999, 9999)
LOGICAL_AXIS_ARRAY(9999, 9999, 9999, 9999, 9999, 9999, 9999, 9999, 9999, 9999)
#endif
;
#if ENABLED(LIMITED_MAX_FR_EDITING) && !defined(MAX_FEEDRATE_EDIT_VALUES)
@ -429,7 +429,7 @@ void menu_backlash();
START_MENU();
BACK_ITEM(MSG_ADVANCED_SETTINGS);
LOOP_LINEAR_AXES(a)
LOOP_NUM_AXES(a)
EDIT_ITEM_FAST_N(float5, a, MSG_VMAX_N, &planner.settings.max_feedrate_mm_s[a], 1, max_fr_edit_scaled[a]);
#if E_STEPPERS
@ -460,7 +460,7 @@ void menu_backlash();
#elif ENABLED(LIMITED_MAX_ACCEL_EDITING)
DEFAULT_MAX_ACCELERATION
#else
LOGICAL_AXIS_ARRAY(99000, 99000, 99000, 99000, 99000, 99000, 99000)
LOGICAL_AXIS_ARRAY(99000, 99000, 99000, 99000, 99000, 99000, 99000, 99000, 99000, 99000)
#endif
;
#if ENABLED(LIMITED_MAX_ACCEL_EDITING) && !defined(MAX_ACCEL_EDIT_VALUES)
@ -484,9 +484,10 @@ void menu_backlash();
EDIT_ITEM_FAST(float5_25, MSG_A_TRAVEL, &planner.settings.travel_acceleration, 25, max_accel);
#define EDIT_AMAX(Q,L) EDIT_ITEM_FAST(long5_25, MSG_AMAX_##Q, &planner.settings.max_acceleration_mm_per_s2[_AXIS(Q)], L, max_accel_edit_scaled[_AXIS(Q)], []{ planner.reset_acceleration_rates(); })
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
EDIT_AMAX(A, 100), EDIT_AMAX(B, 100), EDIT_AMAX(C, 10),
EDIT_AMAX(I, 10), EDIT_AMAX(J, 10), EDIT_AMAX(K, 10)
EDIT_AMAX(I, 10), EDIT_AMAX(J, 10), EDIT_AMAX(K, 10),
EDIT_AMAX(U, 10), EDIT_AMAX(V, 10), EDIT_AMAX(W, 10)
);
#if ENABLED(DISTINCT_E_FACTORS)
@ -527,9 +528,10 @@ void menu_backlash();
#elif ENABLED(LIMITED_JERK_EDITING)
{ LOGICAL_AXIS_LIST((DEFAULT_EJERK) * 2,
(DEFAULT_XJERK) * 2, (DEFAULT_YJERK) * 2, (DEFAULT_ZJERK) * 2,
(DEFAULT_IJERK) * 2, (DEFAULT_JJERK) * 2, (DEFAULT_KJERK) * 2) }
(DEFAULT_IJERK) * 2, (DEFAULT_JJERK) * 2, (DEFAULT_KJERK) * 2,
(DEFAULT_UJERK) * 2, (DEFAULT_VJERK) * 2, (DEFAULT_WJERK) * 2) }
#else
{ LOGICAL_AXIS_LIST(990, 990, 990, 990, 990, 990, 990) }
{ LOGICAL_AXIS_LIST(990, 990, 990, 990, 990, 990, 990, 990, 990, 990) }
#endif
;
@ -575,7 +577,7 @@ void menu_advanced_steps_per_mm() {
START_MENU();
BACK_ITEM(MSG_ADVANCED_SETTINGS);
LOOP_LINEAR_AXES(a)
LOOP_NUM_AXES(a)
EDIT_ITEM_FAST_N(float61, a, MSG_N_STEPS, &planner.settings.axis_steps_per_mm[a], 5, 9999, []{ planner.refresh_positioning(); });
#if ENABLED(DISTINCT_E_FACTORS)

View File

@ -66,6 +66,15 @@ void menu_backlash() {
#if HAS_K_AXIS && _CAN_CALI(K)
EDIT_BACKLASH_DISTANCE(K);
#endif
#if HAS_U_AXIS && _CAN_CALI(U)
EDIT_BACKLASH_DISTANCE(U);
#endif
#if HAS_V_AXIS && _CAN_CALI(V)
EDIT_BACKLASH_DISTANCE(V);
#endif
#if HAS_W_AXIS && _CAN_CALI(W)
EDIT_BACKLASH_DISTANCE(W);
#endif
#ifdef BACKLASH_SMOOTHING_MM
editable.decimal = backlash.get_smoothing_mm();

View File

@ -108,6 +108,15 @@ void lcd_move_x() { _lcd_move_xyz(GET_TEXT_F(MSG_MOVE_X), X_AXIS); }
#if HAS_K_AXIS
void lcd_move_k() { _lcd_move_xyz(GET_TEXT_F(MSG_MOVE_K), K_AXIS); }
#endif
#if HAS_U_AXIS
void lcd_move_u() { _lcd_move_xyz(GET_TEXT_F(MSG_MOVE_U), U_AXIS); }
#endif
#if HAS_V_AXIS
void lcd_move_v() { _lcd_move_xyz(GET_TEXT_F(MSG_MOVE_V), V_AXIS); }
#endif
#if HAS_W_AXIS
void lcd_move_w() { _lcd_move_xyz(GET_TEXT_F(MSG_MOVE_W), W_AXIS); }
#endif
#if E_MANUAL
@ -252,6 +261,15 @@ void menu_move() {
#if HAS_K_AXIS
SUBMENU(MSG_MOVE_K, []{ _menu_move_distance(K_AXIS, lcd_move_k); });
#endif
#if HAS_U_AXIS
SUBMENU(MSG_MOVE_U, []{ _menu_move_distance(U_AXIS, lcd_move_u); });
#endif
#if HAS_V_AXIS
SUBMENU(MSG_MOVE_V, []{ _menu_move_distance(V_AXIS, lcd_move_v); });
#endif
#if HAS_W_AXIS
SUBMENU(MSG_MOVE_W, []{ _menu_move_distance(W_AXIS, lcd_move_w); });
#endif
}
else
GCODES_ITEM(MSG_AUTO_HOME, FPSTR(G28_STR));
@ -343,6 +361,15 @@ void menu_move() {
#if HAS_K_AXIS
GCODES_ITEM_N(K_AXIS, MSG_AUTO_HOME_A, F("G28" STR_K));
#endif
#if HAS_U_AXIS
GCODES_ITEM_N(U_AXIS, MSG_AUTO_HOME_A, F("G28" STR_U));
#endif
#if HAS_V_AXIS
GCODES_ITEM_N(V_AXIS, MSG_AUTO_HOME_A, F("G28" STR_V));
#endif
#if HAS_W_AXIS
GCODES_ITEM_N(W_AXIS, MSG_AUTO_HOME_A, F("G28" STR_W));
#endif
END_MENU();
}
@ -396,6 +423,15 @@ void menu_motion() {
#if HAS_K_AXIS
GCODES_ITEM_N(K_AXIS, MSG_AUTO_HOME_A, F("G28" STR_K));
#endif
#if HAS_U_AXIS
GCODES_ITEM_N(U_AXIS, MSG_AUTO_HOME_A, F("G28" STR_U));
#endif
#if HAS_V_AXIS
GCODES_ITEM_N(V_AXIS, MSG_AUTO_HOME_A, F("G28" STR_V));
#endif
#if HAS_W_AXIS
GCODES_ITEM_N(W_AXIS, MSG_AUTO_HOME_A, F("G28" STR_W));
#endif
#endif
#endif

View File

@ -134,6 +134,9 @@ void menu_tmc_current() {
TERN_( I_SENSORLESS, TMC_EDIT_STORED_SGT(I));
TERN_( J_SENSORLESS, TMC_EDIT_STORED_SGT(J));
TERN_( K_SENSORLESS, TMC_EDIT_STORED_SGT(K));
TERN_( U_SENSORLESS, TMC_EDIT_STORED_SGT(U));
TERN_( V_SENSORLESS, TMC_EDIT_STORED_SGT(V));
TERN_( W_SENSORLESS, TMC_EDIT_STORED_SGT(W));
END_MENU();
}

View File

@ -37,7 +37,7 @@ L64XX_Marlin L64xxManager;
#include "../../module/planner.h"
#include "../../HAL/shared/Delay.h"
static const char LINEAR_AXIS_LIST(
static const char NUM_AXIS_LIST(
str_X[] PROGMEM = "X ", str_Y[] PROGMEM = "Y ", str_Z[] PROGMEM = "Z ",
str_I[] PROGMEM = STR_I " ", str_J[] PROGMEM = STR_J " ", str_K[] PROGMEM = STR_K " "
),
@ -53,7 +53,7 @@ static const char LINEAR_AXIS_LIST(
#define _EN_ITEM(N) , str_E##N
PGM_P const L64XX_Marlin::index_to_axis[] PROGMEM = {
LINEAR_AXIS_LIST(str_X, str_Y, str_Z, str_I, str_J, str_K),
NUM_AXIS_LIST(str_X, str_Y, str_Z, str_I, str_J, str_K),
str_X2, str_Y2, str_Z2, str_Z3, str_Z4
REPEAT(E_STEPPERS, _EN_ITEM)
};
@ -68,7 +68,7 @@ uint8_t L64XX_Marlin::dir_commands[MAX_L64XX]; // array to hold direction comma
#define _EN_ITEM(N) , ENABLED(INVERT_E##N##_DIR)
const uint8_t L64XX_Marlin::index_to_dir[MAX_L64XX] = {
NUM_AXIS_LIST(ENABLED(INVERT_X_DIR), ENABLED(INVERT_Y_DIR), ENABLED(INVERT_Z_DIR), ENABLED(INVERT_I_DIR), ENABLED(INVERT_J_DIR), ENABLED(INVERT_K_DIR))
NUM_AXIS_LIST(ENABLED(INVERT_X_DIR), ENABLED(INVERT_Y_DIR), ENABLED(INVERT_Z_DIR), ENABLED(INVERT_I_DIR), ENABLED(INVERT_J_DIR), ENABLED(INVERT_K_DIR), ENABLED(INVERT_U_DIR), ENABLED(INVERT_V_DIR), ENABLED(INVERT_W_DIR))
, ENABLED(INVERT_X_DIR) ^ BOTH(HAS_DUAL_X_STEPPERS, INVERT_X2_VS_X_DIR) // X2
, ENABLED(INVERT_Y_DIR) ^ BOTH(HAS_DUAL_Y_STEPPERS, INVERT_Y2_VS_Y_DIR) // Y2
, ENABLED(INVERT_Z_DIR) ^ ENABLED(INVERT_Z2_VS_Z_DIR) // Z2
@ -415,8 +415,8 @@ uint8_t L64XX_Marlin::get_user_input(uint8_t &driver_count, L64XX_axis_t axis_in
LOOP_LOGICAL_AXES(i) if (uint16_t _displacement = parser.intval(axis_codes[i])) {
found_displacement = true;
displacement = _displacement;
uint8_t axis_offset = parser.byteval('J');
axis_mon[0][0] = axis_codes[i]; // Axis first character, one of XYZE
const uint8_t axis_offset = parser.byteval('J');
axis_mon[0][0] = axis_codes[i]; // Axis first character, one of XYZ...E
const bool single_or_e = axis_offset >= 2 || axis_mon[0][0] == 'E',
one_or_more = !single_or_e && axis_offset == 0;
uint8_t driver_count_local = 0; // Can't use "driver_count" directly as a subscript because it's passed by reference

View File

@ -36,7 +36,7 @@
#define HAS_L64XX_EXTRUDER (AXIS_IS_L64XX(E0) || AXIS_IS_L64XX(E1) || AXIS_IS_L64XX(E2) || AXIS_IS_L64XX(E3) || AXIS_IS_L64XX(E4) || AXIS_IS_L64XX(E5) || AXIS_IS_L64XX(E6) || AXIS_IS_L64XX(E7))
#define _EN_ITEM(N) , E##N
enum L64XX_axis_t : uint8_t { LINEAR_AXIS_LIST(X, Y, Z, I, J, K), X2, Y2, Z2, Z3, Z4 REPEAT(E_STEPPERS, _EN_ITEM), MAX_L64XX };
enum L64XX_axis_t : uint8_t { NUM_AXIS_LIST(X, Y, Z, I, J, K, U, V, W), X2, Y2, Z2, Z3, Z4 REPEAT(E_STEPPERS, _EN_ITEM), MAX_L64XX };
#undef _EN_ITEM
class L64XX_Marlin : public L64XXHelper {

View File

@ -237,6 +237,9 @@ void home_delta() {
TERN_(I_SENSORLESS, sensorless_t stealth_states_i = start_sensorless_homing_per_axis(I_AXIS));
TERN_(J_SENSORLESS, sensorless_t stealth_states_j = start_sensorless_homing_per_axis(J_AXIS));
TERN_(K_SENSORLESS, sensorless_t stealth_states_k = start_sensorless_homing_per_axis(K_AXIS));
TERN_(U_SENSORLESS, sensorless_t stealth_states_u = start_sensorless_homing_per_axis(U_AXIS));
TERN_(V_SENSORLESS, sensorless_t stealth_states_v = start_sensorless_homing_per_axis(V_AXIS));
TERN_(W_SENSORLESS, sensorless_t stealth_states_w = start_sensorless_homing_per_axis(W_AXIS));
#if SENSORLESS_STALLGUARD_DELAY
safe_delay(SENSORLESS_STALLGUARD_DELAY); // Short delay needed to settle
#endif
@ -256,6 +259,9 @@ void home_delta() {
TERN_(I_SENSORLESS, end_sensorless_homing_per_axis(I_AXIS, stealth_states_i));
TERN_(J_SENSORLESS, end_sensorless_homing_per_axis(J_AXIS, stealth_states_j));
TERN_(K_SENSORLESS, end_sensorless_homing_per_axis(K_AXIS, stealth_states_k));
TERN_(U_SENSORLESS, end_sensorless_homing_per_axis(U_AXIS, stealth_states_u));
TERN_(V_SENSORLESS, end_sensorless_homing_per_axis(V_AXIS, stealth_states_v));
TERN_(W_SENSORLESS, end_sensorless_homing_per_axis(W_AXIS, stealth_states_w));
#if SENSORLESS_STALLGUARD_DELAY
safe_delay(SENSORLESS_STALLGUARD_DELAY); // Short delay needed to settle
#endif

View File

@ -322,6 +322,66 @@ void Endstops::init() {
#endif
#endif
#if HAS_U_MIN
#if ENABLED(ENDSTOPPULLUP_UMIN)
SET_INPUT_PULLUP(U_MIN_PIN);
#elif ENABLED(ENDSTOPPULLDOWN_UMIN)
SET_INPUT_PULLDOWN(U_MIN_PIN);
#else
SET_INPUT(U_MIN_PIN);
#endif
#endif
#if HAS_U_MAX
#if ENABLED(ENDSTOPPULLUP_UMAX)
SET_INPUT_PULLUP(U_MAX_PIN);
#elif ENABLED(ENDSTOPPULLDOWN_UMIN)
SET_INPUT_PULLDOWN(U_MAX_PIN);
#else
SET_INPUT(U_MAX_PIN);
#endif
#endif
#if HAS_V_MIN
#if ENABLED(ENDSTOPPULLUP_VMIN)
SET_INPUT_PULLUP(V_MIN_PIN);
#elif ENABLED(ENDSTOPPULLDOWN_VMIN)
SET_INPUT_PULLDOWN(V_MIN_PIN);
#else
SET_INPUT(V_MIN_PIN);
#endif
#endif
#if HAS_V_MAX
#if ENABLED(ENDSTOPPULLUP_VMAX)
SET_INPUT_PULLUP(V_MAX_PIN);
#elif ENABLED(ENDSTOPPULLDOWN_VMIN)
SET_INPUT_PULLDOWN(V_MAX_PIN);
#else
SET_INPUT(V_MAX_PIN);
#endif
#endif
#if HAS_W_MIN
#if ENABLED(ENDSTOPPULLUP_WMIN)
SET_INPUT_PULLUP(W_MIN_PIN);
#elif ENABLED(ENDSTOPPULLDOWN_WMIN)
SET_INPUT_PULLDOWN(W_MIN_PIN);
#else
SET_INPUT(W_MIN_PIN);
#endif
#endif
#if HAS_W_MAX
#if ENABLED(ENDSTOPPULLUP_WMAX)
SET_INPUT_PULLUP(W_MAX_PIN);
#elif ENABLED(ENDSTOPPULLDOWN_WMIN)
SET_INPUT_PULLDOWN(W_MAX_PIN);
#else
SET_INPUT(W_MAX_PIN);
#endif
#endif
#if PIN_EXISTS(CALIBRATION)
#if ENABLED(CALIBRATION_PIN_PULLUP)
SET_INPUT_PULLUP(CALIBRATION_PIN);
@ -427,7 +487,7 @@ void Endstops::event_handler() {
prev_hit_state = hit_state;
if (hit_state) {
#if HAS_STATUS_MESSAGE
char LINEAR_AXIS_LIST(chrX = ' ', chrY = ' ', chrZ = ' ', chrI = ' ', chrJ = ' ', chrK = ' '),
char NUM_AXIS_LIST(chrX = ' ', chrY = ' ', chrZ = ' ', chrI = ' ', chrJ = ' ', chrK = ' ', chrU = ' ', chrV = ' ', chrW = ' '),
chrP = ' ';
#define _SET_STOP_CHAR(A,C) (chr## A = C)
#else
@ -447,16 +507,22 @@ void Endstops::event_handler() {
#define ENDSTOP_HIT_TEST_I() _ENDSTOP_HIT_TEST(I,'I')
#define ENDSTOP_HIT_TEST_J() _ENDSTOP_HIT_TEST(J,'J')
#define ENDSTOP_HIT_TEST_K() _ENDSTOP_HIT_TEST(K,'K')
#define ENDSTOP_HIT_TEST_U() _ENDSTOP_HIT_TEST(U,'U')
#define ENDSTOP_HIT_TEST_V() _ENDSTOP_HIT_TEST(V,'V')
#define ENDSTOP_HIT_TEST_W() _ENDSTOP_HIT_TEST(W,'W')
SERIAL_ECHO_START();
SERIAL_ECHOPGM(STR_ENDSTOPS_HIT);
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
ENDSTOP_HIT_TEST_X(),
ENDSTOP_HIT_TEST_Y(),
ENDSTOP_HIT_TEST_Z(),
_ENDSTOP_HIT_TEST(I,'I'),
_ENDSTOP_HIT_TEST(J,'J'),
_ENDSTOP_HIT_TEST(K,'K')
_ENDSTOP_HIT_TEST(K,'K'),
_ENDSTOP_HIT_TEST(U,'U'),
_ENDSTOP_HIT_TEST(V,'V'),
_ENDSTOP_HIT_TEST(W,'W')
);
#if USES_Z_MIN_PROBE_PIN
@ -467,9 +533,9 @@ void Endstops::event_handler() {
TERN_(HAS_STATUS_MESSAGE,
ui.status_printf(0,
F(S_FMT GANG_N_1(LINEAR_AXES, " %c") " %c"),
F(S_FMT GANG_N_1(NUM_AXES, " %c") " %c"),
GET_TEXT(MSG_LCD_ENDSTOPS),
LINEAR_AXIS_LIST(chrX, chrY, chrZ, chrI, chrJ, chrK), chrP
NUM_AXIS_LIST(chrX, chrY, chrZ, chrI, chrJ, chrK, chrU, chrV, chrW), chrP
)
);
@ -567,6 +633,24 @@ void __O2 Endstops::report_states() {
#if HAS_K_MAX
ES_REPORT(K_MAX);
#endif
#if HAS_U_MIN
ES_REPORT(U_MIN);
#endif
#if HAS_U_MAX
ES_REPORT(U_MAX);
#endif
#if HAS_V_MIN
ES_REPORT(V_MIN);
#endif
#if HAS_V_MAX
ES_REPORT(V_MAX);
#endif
#if HAS_W_MIN
ES_REPORT(W_MIN);
#endif
#if HAS_W_MAX
ES_REPORT(W_MAX);
#endif
#if ENABLED(PROBE_ACTIVATION_SWITCH)
print_es_state(probe_switch_activated(), F(STR_PROBE_EN));
#endif
@ -652,6 +736,9 @@ void Endstops::update() {
#define I_AXIS_HEAD I_AXIS
#define J_AXIS_HEAD J_AXIS
#define K_AXIS_HEAD K_AXIS
#define U_AXIS_HEAD U_AXIS
#define V_AXIS_HEAD V_AXIS
#define W_AXIS_HEAD W_AXIS
/**
* Check and update endstops
@ -838,6 +925,82 @@ void Endstops::update() {
#endif
#endif
#if HAS_U_MIN && !U_SPI_SENSORLESS
#if ENABLED(U_DUAL_ENDSTOPS)
UPDATE_ENDSTOP_BIT(U, MIN);
#if HAS_U2_MIN
UPDATE_ENDSTOP_BIT(U2, MIN);
#else
COPY_LIVE_STATE(U_MIN, U2_MIN);
#endif
#else
UPDATE_ENDSTOP_BIT(U, MIN);
#endif
#endif
#if HAS_U_MAX && !U_SPI_SENSORLESS
#if ENABLED(U_DUAL_ENDSTOPS)
UPDATE_ENDSTOP_BIT(U, MAX);
#if HAS_U2_MAX
UPDATE_ENDSTOP_BIT(U2, MAX);
#else
COPY_LIVE_STATE(U_MAX, U2_MAX);
#endif
#else
UPDATE_ENDSTOP_BIT(U, MAX);
#endif
#endif
#if HAS_V_MIN && !V_SPI_SENSORLESS
#if ENABLED(V_DUAL_ENDSTOPS)
UPDATE_ENDSTOP_BIT(V, MIN);
#if HAS_V2_MIN
UPDATE_ENDSTOP_BIT(V2, MIN);
#else
COPY_LIVE_STATE(V_MIN, V2_MIN);
#endif
#else
UPDATE_ENDSTOP_BIT(V, MIN);
#endif
#endif
#if HAS_V_MAX && !V_SPI_SENSORLESS
#if ENABLED(O_DUAL_ENDSTOPS)
UPDATE_ENDSTOP_BIT(V, MAX);
#if HAS_V2_MAX
UPDATE_ENDSTOP_BIT(V2, MAX);
#else
COPY_LIVE_STATE(V_MAX, V2_MAX);
#endif
#else
UPDATE_ENDSTOP_BIT(V, MAX);
#endif
#endif
#if HAS_W_MIN && !W_SPI_SENSORLESS
#if ENABLED(W_DUAL_ENDSTOPS)
UPDATE_ENDSTOP_BIT(W, MIN);
#if HAS_W2_MIN
UPDATE_ENDSTOP_BIT(W2, MIN);
#else
COPY_LIVE_STATE(W_MIN, W2_MIN);
#endif
#else
UPDATE_ENDSTOP_BIT(W, MIN);
#endif
#endif
#if HAS_W_MAX && !W_SPI_SENSORLESS
#if ENABLED(W_DUAL_ENDSTOPS)
UPDATE_ENDSTOP_BIT(W, MAX);
#if HAS_W2_MAX
UPDATE_ENDSTOP_BIT(W2, MAX);
#else
COPY_LIVE_STATE(W_MAX, W2_MAX);
#endif
#else
UPDATE_ENDSTOP_BIT(W, MAX);
#endif
#endif
#if ENDSTOP_NOISE_THRESHOLD
/**
@ -938,7 +1101,7 @@ void Endstops::update() {
#define PROCESS_ENDSTOP_Z(MINMAX) PROCESS_DUAL_ENDSTOP(Z, MINMAX)
#endif
#if HAS_G38_PROBE
#if HAS_G38_PROBE // TODO (DerAndere): Add support for HAS_I_AXIS
#define _G38_OPEN_STATE TERN(G38_PROBE_AWAY, (G38_move >= 4), LOW)
// For G38 moves check the probe's pin for ALL movement
if (G38_move && TEST_ENDSTOP(_ENDSTOP(Z, TERN(USES_Z_MIN_PROBE_PIN, MIN_PROBE, MIN))) != _G38_OPEN_STATE) {
@ -1108,6 +1271,51 @@ void Endstops::update() {
}
}
#endif
#if HAS_U_AXIS
if (stepper.axis_is_moving(U_AXIS)) {
if (stepper.motor_direction(U_AXIS_HEAD)) { // -direction
#if HAS_U_MIN || (U_SPI_SENSORLESS && U_HOME_TO_MIN)
PROCESS_ENDSTOP(U, MIN);
#endif
}
else { // +direction
#if HAS_U_MAX || (U_SPI_SENSORLESS && U_HOME_TO_MAX)
PROCESS_ENDSTOP(U, MAX);
#endif
}
}
#endif
#if HAS_V_AXIS
if (stepper.axis_is_moving(V_AXIS)) {
if (stepper.motor_direction(V_AXIS_HEAD)) { // -direction
#if HAS_V_MIN || (V_SPI_SENSORLESS && V_HOME_TO_MIN)
PROCESS_ENDSTOP(V, MIN);
#endif
}
else { // +direction
#if HAS_V_MAX || (V_SPI_SENSORLESS && V_HOME_TO_MAX)
PROCESS_ENDSTOP(V, MAX);
#endif
}
}
#endif
#if HAS_W_AXIS
if (stepper.axis_is_moving(W_AXIS)) {
if (stepper.motor_direction(W_AXIS_HEAD)) { // -direction
#if HAS_W_MIN || (W_SPI_SENSORLESS && W_HOME_TO_MIN)
PROCESS_ENDSTOP(W, MIN);
#endif
}
else { // +direction
#if HAS_W_MAX || (W_SPI_SENSORLESS && W_HOME_TO_MAX)
PROCESS_ENDSTOP(W, MAX);
#endif
}
}
#endif
} // Endstops::update()
#if ENABLED(SPI_ENDSTOPS)
@ -1169,6 +1377,24 @@ void Endstops::update() {
hit = true;
}
#endif
#if U_SPI_SENSORLESS
if (tmc_spi_homing.u && stepperU.test_stall_status()) {
SBI(live_state, U_ENDSTOP);
hit = true;
}
#endif
#if V_SPI_SENSORLESS
if (tmc_spi_homing.v && stepperV.test_stall_status()) {
SBI(live_state, V_ENDSTOP);
hit = true;
}
#endif
#if W_SPI_SENSORLESS
if (tmc_spi_homing.w && stepperW.test_stall_status()) {
SBI(live_state, W_ENDSTOP);
hit = true;
}
#endif
if (TERN0(ENDSTOP_INTERRUPTS_FEATURE, hit)) update();
@ -1182,6 +1408,9 @@ void Endstops::update() {
TERN_(I_SPI_SENSORLESS, CBI(live_state, I_ENDSTOP));
TERN_(J_SPI_SENSORLESS, CBI(live_state, J_ENDSTOP));
TERN_(K_SPI_SENSORLESS, CBI(live_state, K_ENDSTOP));
TERN_(U_SPI_SENSORLESS, CBI(live_state, U_ENDSTOP));
TERN_(V_SPI_SENSORLESS, CBI(live_state, V_ENDSTOP));
TERN_(W_SPI_SENSORLESS, CBI(live_state, W_ENDSTOP));
}
#endif // SPI_ENDSTOPS
@ -1276,6 +1505,24 @@ void Endstops::update() {
#if HAS_K_MIN
ES_GET_STATE(K_MIN);
#endif
#if HAS_U_MAX
ES_GET_STATE(U_MAX);
#endif
#if HAS_U_MIN
ES_GET_STATE(U_MIN);
#endif
#if HAS_V_MAX
ES_GET_STATE(V_MAX);
#endif
#if HAS_V_MIN
ES_GET_STATE(V_MIN);
#endif
#if HAS_W_MAX
ES_GET_STATE(W_MAX);
#endif
#if HAS_W_MIN
ES_GET_STATE(W_MIN);
#endif
uint16_t endstop_change = live_state_local ^ old_live_state_local;
#define ES_REPORT_CHANGE(S) if (TEST(endstop_change, S)) SERIAL_ECHOPGM(" " STRINGIFY(S) ":", TEST(live_state_local, S))
@ -1350,6 +1597,25 @@ void Endstops::update() {
#if HAS_K_MAX
ES_REPORT_CHANGE(K_MAX);
#endif
#if HAS_U_MIN
ES_REPORT_CHANGE(U_MIN);
#endif
#if HAS_U_MAX
ES_REPORT_CHANGE(U_MAX);
#endif
#if HAS_V_MIN
ES_REPORT_CHANGE(V_MIN);
#endif
#if HAS_V_MAX
ES_REPORT_CHANGE(V_MAX);
#endif
#if HAS_W_MIN
ES_REPORT_CHANGE(W_MIN);
#endif
#if HAS_W_MAX
ES_REPORT_CHANGE(W_MAX);
#endif
SERIAL_ECHOLNPGM("\n");
hal.set_pwm_duty(pin_t(LED_PIN), local_LED_status);
local_LED_status ^= 255;

View File

@ -45,6 +45,12 @@ enum EndstopEnum : char {
_ES_ITEM(HAS_J_MAX, J_MAX)
_ES_ITEM(HAS_K_MIN, K_MIN)
_ES_ITEM(HAS_K_MAX, K_MAX)
_ES_ITEM(HAS_U_MIN, U_MIN)
_ES_ITEM(HAS_U_MAX, U_MAX)
_ES_ITEM(HAS_V_MIN, V_MIN)
_ES_ITEM(HAS_V_MAX, V_MAX)
_ES_ITEM(HAS_W_MIN, W_MIN)
_ES_ITEM(HAS_W_MAX, W_MAX)
// Extra Endstops for XYZ
#if ENABLED(X_DUAL_ENDSTOPS)
@ -234,7 +240,7 @@ class Endstops {
typedef struct {
union {
bool any;
struct { bool LINEAR_AXIS_LIST(x:1, y:1, z:1, i:1, j:1, k:1); };
struct { bool NUM_AXIS_LIST(x:1, y:1, z:1, i:1, j:1, k:1); };
};
} tmc_spi_homing_t;
static tmc_spi_homing_t tmc_spi_homing;

View File

@ -84,7 +84,7 @@ bool relative_mode; // = false;
#define Z_INIT_POS Z_HOME_POS
#endif
xyze_pos_t current_position = LOGICAL_AXIS_ARRAY(0, X_HOME_POS, Y_HOME_POS, Z_INIT_POS, I_HOME_POS, J_HOME_POS, K_HOME_POS);
xyze_pos_t current_position = LOGICAL_AXIS_ARRAY(0, X_HOME_POS, Y_HOME_POS, Z_INIT_POS, I_HOME_POS, J_HOME_POS, K_HOME_POS, U_HOME_POS, V_HOME_POS, W_HOME_POS);
/**
* Cartesian Destination
@ -189,13 +189,16 @@ inline void report_more_positions() {
inline void report_logical_position(const xyze_pos_t &rpos) {
const xyze_pos_t lpos = rpos.asLogical();
SERIAL_ECHOPGM_P(
LIST_N(DOUBLE(LINEAR_AXES),
LIST_N(DOUBLE(NUM_AXES),
X_LBL, lpos.x,
SP_Y_LBL, lpos.y,
SP_Z_LBL, lpos.z,
SP_I_LBL, lpos.i,
SP_J_LBL, lpos.j,
SP_K_LBL, lpos.k
SP_K_LBL, lpos.k,
SP_U_LBL, lpos.u,
SP_V_LBL, lpos.v,
SP_W_LBL, lpos.w
)
#if HAS_EXTRUDERS
, SP_E_LBL, lpos.e
@ -210,7 +213,8 @@ void report_real_position() {
xyze_pos_t npos = LOGICAL_AXIS_ARRAY(
planner.get_axis_position_mm(E_AXIS),
cartes.x, cartes.y, cartes.z,
cartes.i, cartes.j, cartes.k
cartes.i, cartes.j, cartes.k,
cartes.u, cartes.v, cartes.w
);
TERN_(HAS_POSITION_MODIFIERS, planner.unapply_modifiers(npos, true));
@ -257,13 +261,16 @@ void report_current_position_projected() {
const xyz_pos_t lpos = cartes.asLogical();
SERIAL_ECHOPGM_P(
LIST_N(DOUBLE(LINEAR_AXES),
LIST_N(DOUBLE(NUM_AXES),
X_LBL, lpos.x,
SP_Y_LBL, lpos.y,
SP_Z_LBL, lpos.z,
SP_I_LBL, lpos.i,
SP_J_LBL, lpos.j,
SP_K_LBL, lpos.k
SP_K_LBL, lpos.k,
SP_U_LBL, lpos.u,
SP_V_LBL, lpos.v,
SP_W_LBL, lpos.w
)
#if HAS_EXTRUDERS
, SP_E_LBL, current_position.e
@ -354,13 +361,16 @@ void get_cartesian_from_steppers() {
);
cartes.z = planner.get_axis_position_mm(Z_AXIS);
#else
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
cartes.x = planner.get_axis_position_mm(X_AXIS),
cartes.y = planner.get_axis_position_mm(Y_AXIS),
cartes.z = planner.get_axis_position_mm(Z_AXIS),
cartes.i = planner.get_axis_position_mm(I_AXIS),
cartes.j = planner.get_axis_position_mm(J_AXIS),
cartes.k = planner.get_axis_position_mm(K_AXIS)
cartes.k = planner.get_axis_position_mm(K_AXIS),
cartes.u = planner.get_axis_position_mm(U_AXIS),
cartes.v = planner.get_axis_position_mm(V_AXIS),
cartes.w = planner.get_axis_position_mm(W_AXIS)
);
#endif
}
@ -467,24 +477,23 @@ void _internal_move_to_destination(const_feedRate_t fr_mm_s/*=0.0f*/
* - Delta may lower Z first to get into the free motion zone.
* - Before returning, wait for the planner buffer to empty.
*/
void do_blocking_move_to(LINEAR_AXIS_ARGS(const float), const_feedRate_t fr_mm_s/*=0.0f*/) {
void do_blocking_move_to(NUM_AXIS_ARGS(const float), const_feedRate_t fr_mm_s/*=0.0f*/) {
DEBUG_SECTION(log_move, "do_blocking_move_to", DEBUGGING(LEVELING));
if (DEBUGGING(LEVELING)) DEBUG_XYZ("> ", LINEAR_AXIS_ARGS());
if (DEBUGGING(LEVELING)) DEBUG_XYZ("> ", NUM_AXIS_ARGS());
const feedRate_t xy_feedrate = fr_mm_s ?: feedRate_t(XY_PROBE_FEEDRATE_MM_S);
#if HAS_Z_AXIS
const feedRate_t z_feedrate = fr_mm_s ?: homing_feedrate(Z_AXIS);
#endif
#if HAS_I_AXIS
const feedRate_t i_feedrate = fr_mm_s ?: homing_feedrate(I_AXIS);
#endif
#if HAS_J_AXIS
const feedRate_t j_feedrate = fr_mm_s ?: homing_feedrate(J_AXIS);
#endif
#if HAS_K_AXIS
const feedRate_t k_feedrate = fr_mm_s ?: homing_feedrate(K_AXIS);
#endif
SECONDARY_AXIS_CODE(
const feedRate_t i_feedrate = fr_mm_s ?: homing_feedrate(I_AXIS),
const feedRate_t j_feedrate = fr_mm_s ?: homing_feedrate(J_AXIS),
const feedRate_t k_feedrate = fr_mm_s ?: homing_feedrate(K_AXIS),
const feedRate_t u_feedrate = fr_mm_s ?: homing_feedrate(U_AXIS),
const feedRate_t v_feedrate = fr_mm_s ?: homing_feedrate(V_AXIS),
const feedRate_t w_feedrate = fr_mm_s ?: homing_feedrate(W_AXIS)
);
#if IS_KINEMATIC
if (!position_is_reachable(x, y)) return;
@ -553,7 +562,18 @@ void do_blocking_move_to(LINEAR_AXIS_ARGS(const float), const_feedRate_t fr_mm_s
#if HAS_K_AXIS
current_position.k = k; line_to_current_position(k_feedrate);
#endif
#if HAS_Z_AXIS // If Z needs to lower, do it after moving XY...
#if HAS_U_AXIS
current_position.u = u; line_to_current_position(u_feedrate);
#endif
#if HAS_V_AXIS
current_position.v = v; line_to_current_position(v_feedrate);
#endif
#if HAS_W_AXIS
current_position.w = w; line_to_current_position(w_feedrate);
#endif
#if HAS_Z_AXIS
// If Z needs to lower, do it after moving XY
if (current_position.z > z) { current_position.z = z; line_to_current_position(z_feedrate); }
#endif
@ -563,17 +583,19 @@ void do_blocking_move_to(LINEAR_AXIS_ARGS(const float), const_feedRate_t fr_mm_s
}
void do_blocking_move_to(const xy_pos_t &raw, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(LINEAR_AXIS_LIST(raw.x, raw.y, current_position.z, current_position.i, current_position.j, current_position.k), fr_mm_s);
do_blocking_move_to(NUM_AXIS_LIST(raw.x, raw.y, current_position.z, current_position.i, current_position.j, current_position.k,
current_position.u, current_position.v, current_position.w), fr_mm_s);
}
void do_blocking_move_to(const xyz_pos_t &raw, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(LINEAR_AXIS_ELEM(raw), fr_mm_s);
do_blocking_move_to(NUM_AXIS_ELEM(raw), fr_mm_s);
}
void do_blocking_move_to(const xyze_pos_t &raw, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(LINEAR_AXIS_ELEM(raw), fr_mm_s);
do_blocking_move_to(NUM_AXIS_ELEM(raw), fr_mm_s);
}
void do_blocking_move_to_x(const_float_t rx, const_feedRate_t fr_mm_s/*=0.0*/) {
do_blocking_move_to(
LINEAR_AXIS_LIST(rx, current_position.y, current_position.z, current_position.i, current_position.j, current_position.k),
NUM_AXIS_LIST(rx, current_position.y, current_position.z, current_position.i, current_position.j, current_position.k,
current_position.u, current_position.v, current_position.w),
fr_mm_s
);
}
@ -581,7 +603,8 @@ void do_blocking_move_to_x(const_float_t rx, const_feedRate_t fr_mm_s/*=0.0*/) {
#if HAS_Y_AXIS
void do_blocking_move_to_y(const_float_t ry, const_feedRate_t fr_mm_s/*=0.0*/) {
do_blocking_move_to(
LINEAR_AXIS_LIST(current_position.x, ry, current_position.z, current_position.i, current_position.j, current_position.k),
NUM_AXIS_LIST(current_position.x, ry, current_position.z, current_position.i, current_position.j, current_position.k,
current_position.u, current_position.v, current_position.w),
fr_mm_s
);
}
@ -599,7 +622,7 @@ void do_blocking_move_to_x(const_float_t rx, const_feedRate_t fr_mm_s/*=0.0*/) {
}
void do_blocking_move_to_xyz_i(const xyze_pos_t &raw, const_float_t i, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(
LINEAR_AXIS_LIST(raw.x, raw.y, raw.z, i, raw.j, raw.k),
NUM_AXIS_LIST(raw.x, raw.y, raw.z, i, raw.j, raw.k, raw.u, raw.v, raw.w),
fr_mm_s
);
}
@ -611,7 +634,7 @@ void do_blocking_move_to_x(const_float_t rx, const_feedRate_t fr_mm_s/*=0.0*/) {
}
void do_blocking_move_to_xyzi_j(const xyze_pos_t &raw, const_float_t j, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(
LINEAR_AXIS_LIST(raw.x, raw.y, raw.z, raw.i, j, raw.k),
NUM_AXIS_LIST(raw.x, raw.y, raw.z, raw.i, j, raw.k, raw.u, raw.v, raw.w),
fr_mm_s
);
}
@ -623,7 +646,43 @@ void do_blocking_move_to_x(const_float_t rx, const_feedRate_t fr_mm_s/*=0.0*/) {
}
void do_blocking_move_to_xyzij_k(const xyze_pos_t &raw, const_float_t k, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(
LINEAR_AXIS_LIST(raw.x, raw.y, raw.z, raw.i, raw.j, k),
NUM_AXIS_LIST(raw.x, raw.y, raw.z, raw.i, raw.j, k, raw.u, raw.v, raw.w),
fr_mm_s
);
}
#endif
#if HAS_U_AXIS
void do_blocking_move_to_u(const_float_t ru, const_feedRate_t fr_mm_s/*=0.0*/) {
do_blocking_move_to_xyzijk_u(current_position, ru, fr_mm_s);
}
void do_blocking_move_to_xyzijk_u(const xyze_pos_t &raw, const_float_t u, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(
NUM_AXIS_LIST(raw.x, raw.y, raw.z, raw.i, raw.j, raw.k, u, raw.v, raw.w),
fr_mm_s
);
}
#endif
#if HAS_V_AXIS
void do_blocking_move_to_v(const_float_t rv, const_feedRate_t fr_mm_s/*=0.0*/) {
do_blocking_move_to_xyzijku_v(current_position, rv, fr_mm_s);
}
void do_blocking_move_to_xyzijku_v(const xyze_pos_t &raw, const_float_t v, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(
NUM_AXIS_LIST(raw.x, raw.y, raw.z, raw.i, raw.j, raw.k, raw.u, v, raw.w),
fr_mm_s
);
}
#endif
#if HAS_W_AXIS
void do_blocking_move_to_w(const_float_t rw, const_feedRate_t fr_mm_s/*=0.0*/) {
do_blocking_move_to_xyzijkuv_w(current_position, rw, fr_mm_s);
}
void do_blocking_move_to_xyzijkuv_w(const xyze_pos_t &raw, const_float_t w, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(
NUM_AXIS_LIST(raw.x, raw.y, raw.z, raw.i, raw.j, raw.k, raw.u, raw.v, w),
fr_mm_s
);
}
@ -632,7 +691,8 @@ void do_blocking_move_to_x(const_float_t rx, const_feedRate_t fr_mm_s/*=0.0*/) {
#if HAS_Y_AXIS
void do_blocking_move_to_xy(const_float_t rx, const_float_t ry, const_feedRate_t fr_mm_s/*=0.0*/) {
do_blocking_move_to(
LINEAR_AXIS_LIST(rx, ry, current_position.z, current_position.i, current_position.j, current_position.k),
NUM_AXIS_LIST(rx, ry, current_position.z, current_position.i, current_position.j, current_position.k,
current_position.u, current_position.v, current_position.w),
fr_mm_s
);
}
@ -644,7 +704,8 @@ void do_blocking_move_to_x(const_float_t rx, const_feedRate_t fr_mm_s/*=0.0*/) {
#if HAS_Z_AXIS
void do_blocking_move_to_xy_z(const xy_pos_t &raw, const_float_t z, const_feedRate_t fr_mm_s/*=0.0f*/) {
do_blocking_move_to(
LINEAR_AXIS_LIST(raw.x, raw.y, z, current_position.i, current_position.j, current_position.k),
NUM_AXIS_LIST(raw.x, raw.y, z, current_position.i, current_position.j, current_position.k,
current_position.u, current_position.v, current_position.w),
fr_mm_s
);
}
@ -679,8 +740,8 @@ void restore_feedrate_and_scaling() {
// Software Endstops are based on the configured limits.
soft_endstops_t soft_endstop = {
true, false,
LINEAR_AXIS_ARRAY(X_MIN_POS, Y_MIN_POS, Z_MIN_POS, I_MIN_POS, J_MIN_POS, K_MIN_POS),
LINEAR_AXIS_ARRAY(X_MAX_BED, Y_MAX_BED, Z_MAX_POS, I_MAX_POS, J_MAX_POS, K_MAX_POS)
NUM_AXIS_ARRAY(X_MIN_POS, Y_MIN_POS, Z_MIN_POS, I_MIN_POS, J_MIN_POS, K_MIN_POS, U_MIN_POS, V_MIN_POS, W_MIN_POS),
NUM_AXIS_ARRAY(X_MAX_BED, Y_MAX_BED, Z_MAX_POS, I_MAX_POS, J_MAX_POS, K_MAX_POS, U_MAX_POS, V_MAX_POS, W_MAX_POS)
};
/**
@ -859,6 +920,36 @@ void restore_feedrate_and_scaling() {
#endif
}
#endif
#if HAS_U_AXIS
if (axis_was_homed(U_AXIS)) {
#if !HAS_SOFTWARE_ENDSTOPS || ENABLED(MIN_SOFTWARE_ENDSTOP_U)
NOLESS(target.u, soft_endstop.min.u);
#endif
#if !HAS_SOFTWARE_ENDSTOPS || ENABLED(MAX_SOFTWARE_ENDSTOP_U)
NOMORE(target.u, soft_endstop.max.u);
#endif
}
#endif
#if HAS_V_AXIS
if (axis_was_homed(V_AXIS)) {
#if !HAS_SOFTWARE_ENDSTOPS || ENABLED(MIN_SOFTWARE_ENDSTOP_V)
NOLESS(target.v, soft_endstop.min.v);
#endif
#if !HAS_SOFTWARE_ENDSTOPS || ENABLED(MAX_SOFTWARE_ENDSTOP_V)
NOMORE(target.v, soft_endstop.max.v);
#endif
}
#endif
#if HAS_W_AXIS
if (axis_was_homed(W_AXIS)) {
#if !HAS_SOFTWARE_ENDSTOPS || ENABLED(MIN_SOFTWARE_ENDSTOP_W)
NOLESS(target.w, soft_endstop.min.w);
#endif
#if !HAS_SOFTWARE_ENDSTOPS || ENABLED(MAX_SOFTWARE_ENDSTOP_W)
NOMORE(target.w, soft_endstop.max.w);
#endif
}
#endif
}
#else // !HAS_SOFTWARE_ENDSTOPS
@ -1297,9 +1388,10 @@ void prepare_line_to_destination() {
CBI(b, a);
};
// Clear test bits that are trusted
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
set_should(axis_bits, X_AXIS), set_should(axis_bits, Y_AXIS), set_should(axis_bits, Z_AXIS),
set_should(axis_bits, I_AXIS), set_should(axis_bits, J_AXIS), set_should(axis_bits, K_AXIS)
set_should(axis_bits, I_AXIS), set_should(axis_bits, J_AXIS), set_should(axis_bits, K_AXIS),
set_should(axis_bits, U_AXIS), set_should(axis_bits, V_AXIS), set_should(axis_bits, W_AXIS)
);
return axis_bits;
}
@ -1309,13 +1401,16 @@ void prepare_line_to_destination() {
PGM_P home_first = GET_TEXT(MSG_HOME_FIRST);
char msg[strlen_P(home_first)+1];
sprintf_P(msg, home_first,
LINEAR_AXIS_LIST(
TEST(axis_bits, X_AXIS) ? "X" : "",
TEST(axis_bits, Y_AXIS) ? "Y" : "",
TEST(axis_bits, Z_AXIS) ? "Z" : "",
NUM_AXIS_LIST(
TEST(axis_bits, X_AXIS) ? STR_A : "",
TEST(axis_bits, Y_AXIS) ? STR_B : "",
TEST(axis_bits, Z_AXIS) ? STR_C : "",
TEST(axis_bits, I_AXIS) ? STR_I : "",
TEST(axis_bits, J_AXIS) ? STR_J : "",
TEST(axis_bits, K_AXIS) ? STR_K : ""
TEST(axis_bits, K_AXIS) ? STR_K : "",
TEST(axis_bits, U_AXIS) ? STR_U : "",
TEST(axis_bits, V_AXIS) ? STR_V : "",
TEST(axis_bits, W_AXIS) ? STR_W : ""
)
);
SERIAL_ECHO_START();
@ -1395,6 +1490,15 @@ void prepare_line_to_destination() {
#if K_SENSORLESS
case K_AXIS: stealth_states.k = tmc_enable_stallguard(stepperK); break;
#endif
#if U_SENSORLESS
case U_AXIS: stealth_states.u = tmc_enable_stallguard(stepperU); break;
#endif
#if V_SENSORLESS
case V_AXIS: stealth_states.v = tmc_enable_stallguard(stepperV); break;
#endif
#if W_SENSORLESS
case W_AXIS: stealth_states.w = tmc_enable_stallguard(stepperW); break;
#endif
}
#if ENABLED(SPI_ENDSTOPS)
@ -1415,6 +1519,15 @@ void prepare_line_to_destination() {
#if HAS_K_AXIS
case K_AXIS: if (ENABLED(K_SPI_SENSORLESS)) endstops.tmc_spi_homing.k = true; break;
#endif
#if HAS_U_AXIS
case U_AXIS: if (ENABLED(U_SPI_SENSORLESS)) endstops.tmc_spi_homing.u = true; break;
#endif
#if HAS_V_AXIS
case V_AXIS: if (ENABLED(V_SPI_SENSORLESS)) endstops.tmc_spi_homing.v = true; break;
#endif
#if HAS_W_AXIS
case W_AXIS: if (ENABLED(W_SPI_SENSORLESS)) endstops.tmc_spi_homing.w = true; break;
#endif
default: break;
}
#endif
@ -1471,6 +1584,15 @@ void prepare_line_to_destination() {
#if K_SENSORLESS
case K_AXIS: tmc_disable_stallguard(stepperK, enable_stealth.k); break;
#endif
#if U_SENSORLESS
case U_AXIS: tmc_disable_stallguard(stepperU, enable_stealth.u); break;
#endif
#if V_SENSORLESS
case V_AXIS: tmc_disable_stallguard(stepperV, enable_stealth.v); break;
#endif
#if W_SENSORLESS
case W_AXIS: tmc_disable_stallguard(stepperW, enable_stealth.w); break;
#endif
}
#if ENABLED(SPI_ENDSTOPS)
@ -1491,6 +1613,15 @@ void prepare_line_to_destination() {
#if HAS_K_AXIS
case K_AXIS: if (ENABLED(K_SPI_SENSORLESS)) endstops.tmc_spi_homing.k = false; break;
#endif
#if HAS_U_AXIS
case U_AXIS: if (ENABLED(U_SPI_SENSORLESS)) endstops.tmc_spi_homing.u = false; break;
#endif
#if HAS_V_AXIS
case V_AXIS: if (ENABLED(V_SPI_SENSORLESS)) endstops.tmc_spi_homing.v = false; break;
#endif
#if HAS_W_AXIS
case W_AXIS: if (ENABLED(W_SPI_SENSORLESS)) endstops.tmc_spi_homing.w = false; break;
#endif
default: break;
}
#endif
@ -1677,6 +1808,30 @@ void prepare_line_to_destination() {
stepperBackoutDir = IF_DISABLED(INVERT_K_DIR, -)effectorBackoutDir;
break;
#endif
#ifdef U_MICROSTEPS
case U_AXIS:
phasePerUStep = PHASE_PER_MICROSTEP(U);
phaseCurrent = stepperU.get_microstep_counter();
effectorBackoutDir = -U_HOME_DIR;
stepperBackoutDir = IF_DISABLED(INVERT_U_DIR, -)effectorBackoutDir;
break;
#endif
#ifdef V_MICROSTEPS
case V_AXIS:
phasePerUStep = PHASE_PER_MICROSTEP(V);
phaseCurrent = stepperV.get_microstep_counter();
effectorBackoutDir = -V_HOME_DIR;
stepperBackoutDir = IF_DISABLED(INVERT_V_DIR, -)effectorBackoutDir;
break;
#endif
#ifdef W_MICROSTEPS
case W_AXIS:
phasePerUStep = PHASE_PER_MICROSTEP(W);
phaseCurrent = stepperW.get_microstep_counter();
effectorBackoutDir = -W_HOME_DIR;
stepperBackoutDir = IF_DISABLED(INVERT_W_DIR, -)effectorBackoutDir;
break;
#endif
default: return;
}
@ -1733,13 +1888,16 @@ void prepare_line_to_destination() {
|| TERN0(A##_HOME_TO_MIN, A##_MIN_PIN > -1) \
|| TERN0(A##_HOME_TO_MAX, A##_MAX_PIN > -1) \
))
if (LINEAR_AXIS_GANG(
if (NUM_AXIS_GANG(
!_CAN_HOME(X),
&& !_CAN_HOME(Y),
&& !_CAN_HOME(Z),
&& !_CAN_HOME(I),
&& !_CAN_HOME(J),
&& !_CAN_HOME(K))
&& !_CAN_HOME(K),
&& !_CAN_HOME(U),
&& !_CAN_HOME(V),
&& !_CAN_HOME(W))
) return;
#endif
@ -1832,6 +1990,15 @@ void prepare_line_to_destination() {
#if HAS_K_AXIS
case K_AXIS: es = K_ENDSTOP; break;
#endif
#if HAS_U_AXIS
case U_AXIS: es = U_ENDSTOP; break;
#endif
#if HAS_V_AXIS
case V_AXIS: es = V_ENDSTOP; break;
#endif
#if HAS_W_AXIS
case W_AXIS: es = W_ENDSTOP; break;
#endif
}
if (TEST(endstops.state(), es)) {
SERIAL_ECHO_MSG("Bad ", AS_CHAR(AXIS_CHAR(axis)), " Endstop?");

View File

@ -44,7 +44,7 @@ extern xyze_pos_t current_position, // High-level current tool position
// G60/G61 Position Save and Return
#if SAVED_POSITIONS
extern uint8_t saved_slots[(SAVED_POSITIONS + 7) >> 3]; // TODO: Add support for LINEAR_AXES >= 4
extern uint8_t saved_slots[(SAVED_POSITIONS + 7) >> 3]; // TODO: Add support for HAS_I_AXIS
extern xyze_pos_t stored_position[SAVED_POSITIONS];
#endif
@ -77,13 +77,16 @@ constexpr xyz_feedrate_t homing_feedrate_mm_m = HOMING_FEEDRATE_MM_M;
FORCE_INLINE feedRate_t homing_feedrate(const AxisEnum a) {
float v = TERN0(HAS_Z_AXIS, homing_feedrate_mm_m.z);
#if DISABLED(DELTA)
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
if (a == X_AXIS) v = homing_feedrate_mm_m.x,
else if (a == Y_AXIS) v = homing_feedrate_mm_m.y,
else if (a == Z_AXIS) v = homing_feedrate_mm_m.z,
else if (a == I_AXIS) v = homing_feedrate_mm_m.i,
else if (a == J_AXIS) v = homing_feedrate_mm_m.j,
else if (a == K_AXIS) v = homing_feedrate_mm_m.k
else if (a == K_AXIS) v = homing_feedrate_mm_m.k,
else if (a == U_AXIS) v = homing_feedrate_mm_m.u,
else if (a == V_AXIS) v = homing_feedrate_mm_m.v,
else if (a == W_AXIS) v = homing_feedrate_mm_m.w
);
#endif
return MMM_TO_MMS(v);
@ -124,7 +127,7 @@ inline int8_t pgm_read_any(const int8_t *p) { return TERN(__IMXRT1062__, *p, pgm
#define XYZ_DEFS(T, NAME, OPT) \
inline T NAME(const AxisEnum axis) { \
static const XYZval<T> NAME##_P DEFS_PROGMEM = LINEAR_AXIS_ARRAY(X_##OPT, Y_##OPT, Z_##OPT, I_##OPT, J_##OPT, K_##OPT); \
static const XYZval<T> NAME##_P DEFS_PROGMEM = NUM_AXIS_ARRAY(X_##OPT, Y_##OPT, Z_##OPT, I_##OPT, J_##OPT, K_##OPT, U_##OPT, V_##OPT, W_##OPT); \
return pgm_read_any(&NAME##_P[axis]); \
}
XYZ_DEFS(float, base_min_pos, MIN_POS);
@ -198,6 +201,24 @@ inline float home_bump_mm(const AxisEnum axis) {
TERN_(MIN_SOFTWARE_ENDSTOP_K, amax = max.k);
break;
#endif
#if HAS_U_AXIS
case U_AXIS:
TERN_(MIN_SOFTWARE_ENDSTOP_U, amin = min.u);
TERN_(MIN_SOFTWARE_ENDSTOP_U, amax = max.u);
break;
#endif
#if HAS_V_AXIS
case V_AXIS:
TERN_(MIN_SOFTWARE_ENDSTOP_V, amin = min.v);
TERN_(MIN_SOFTWARE_ENDSTOP_V, amax = max.v);
break;
#endif
#if HAS_W_AXIS
case W_AXIS:
TERN_(MIN_SOFTWARE_ENDSTOP_W, amin = min.w);
TERN_(MIN_SOFTWARE_ENDSTOP_W, amax = max.w);
break;
#endif
default: break;
}
#endif
@ -323,7 +344,7 @@ inline void prepare_internal_move_to_destination(const_feedRate_t fr_mm_s=0.0f)
/**
* Blocking movement and shorthand functions
*/
void do_blocking_move_to(LINEAR_AXIS_ARGS(const float), const_feedRate_t fr_mm_s=0.0f);
void do_blocking_move_to(NUM_AXIS_ARGS(const float), const_feedRate_t fr_mm_s=0.0f);
void do_blocking_move_to(const xy_pos_t &raw, const_feedRate_t fr_mm_s=0.0f);
void do_blocking_move_to(const xyz_pos_t &raw, const_feedRate_t fr_mm_s=0.0f);
void do_blocking_move_to(const xyze_pos_t &raw, const_feedRate_t fr_mm_s=0.0f);
@ -347,6 +368,18 @@ void do_blocking_move_to_x(const_float_t rx, const_feedRate_t fr_mm_s=0.0f);
void do_blocking_move_to_k(const_float_t rk, const_feedRate_t fr_mm_s=0.0f);
void do_blocking_move_to_xyzij_k(const xyze_pos_t &raw, const_float_t k, const_feedRate_t fr_mm_s=0.0f);
#endif
#if HAS_U_AXIS
void do_blocking_move_to_u(const_float_t ru, const_feedRate_t fr_mm_s=0.0f);
void do_blocking_move_to_xyzijk_u(const xyze_pos_t &raw, const_float_t u, const_feedRate_t fr_mm_s=0.0f);
#endif
#if HAS_V_AXIS
void do_blocking_move_to_v(const_float_t rv, const_feedRate_t fr_mm_s=0.0f);
void do_blocking_move_to_xyzijku_v(const xyze_pos_t &raw, const_float_t v, const_feedRate_t fr_mm_s=0.0f);
#endif
#if HAS_W_AXIS
void do_blocking_move_to_w(const float rw, const feedRate_t &fr_mm_s=0.0f);
void do_blocking_move_to_xyzijkuv_w(const xyze_pos_t &raw, const float w, const feedRate_t &fr_mm_s=0.0f);
#endif
#if HAS_Y_AXIS
void do_blocking_move_to_xy(const_float_t rx, const_float_t ry, const_feedRate_t fr_mm_s=0.0f);
@ -374,8 +407,8 @@ void restore_feedrate_and_scaling();
/**
* Homing and Trusted Axes
*/
typedef IF<(LINEAR_AXES > 8), uint16_t, uint8_t>::type linear_axis_bits_t;
constexpr linear_axis_bits_t linear_bits = _BV(LINEAR_AXES) - 1;
typedef IF<(NUM_AXES > 8), uint16_t, uint8_t>::type linear_axis_bits_t;
constexpr linear_axis_bits_t linear_bits = _BV(NUM_AXES) - 1;
void set_axis_is_at_home(const AxisEnum axis);
@ -490,6 +523,18 @@ void home_if_needed(const bool keeplev=false);
#define LOGICAL_K_POSITION(POS) NATIVE_TO_LOGICAL(POS, K_AXIS)
#define RAW_K_POSITION(POS) LOGICAL_TO_NATIVE(POS, K_AXIS)
#endif
#if HAS_U_AXIS
#define LOGICAL_U_POSITION(POS) NATIVE_TO_LOGICAL(POS, U_AXIS)
#define RAW_U_POSITION(POS) LOGICAL_TO_NATIVE(POS, U_AXIS)
#endif
#if HAS_V_AXIS
#define LOGICAL_V_POSITION(POS) NATIVE_TO_LOGICAL(POS, V_AXIS)
#define RAW_V_POSITION(POS) LOGICAL_TO_NATIVE(POS, V_AXIS)
#endif
#if HAS_W_AXIS
#define LOGICAL_W_POSITION(POS) NATIVE_TO_LOGICAL(POS, W_AXIS)
#define RAW_W_POSITION(POS) LOGICAL_TO_NATIVE(POS, W_AXIS)
#endif
/**
* position_is_reachable family of functions

View File

@ -1300,7 +1300,7 @@ void Planner::recalculate() {
*/
void Planner::check_axes_activity() {
#if ANY(DISABLE_X, DISABLE_Y, DISABLE_Z, DISABLE_I, DISABLE_J, DISABLE_K, DISABLE_E)
#if ANY(DISABLE_X, DISABLE_Y, DISABLE_Z, DISABLE_I, DISABLE_J, DISABLE_K, DISABLE_U, DISABLE_V, DISABLE_W, DISABLE_E)
xyze_bool_t axis_active = { false };
#endif
@ -1350,7 +1350,10 @@ void Planner::check_axes_activity() {
if (TERN0(DISABLE_Z, bnext->steps.z)) axis_active.z = true,
if (TERN0(DISABLE_I, bnext->steps.i)) axis_active.i = true,
if (TERN0(DISABLE_J, bnext->steps.j)) axis_active.j = true,
if (TERN0(DISABLE_K, bnext->steps.k)) axis_active.k = true
if (TERN0(DISABLE_K, bnext->steps.k)) axis_active.k = true,
if (TERN0(DISABLE_U, bnext->steps.u)) axis_active.u = true,
if (TERN0(DISABLE_V, bnext->steps.v)) axis_active.v = true,
if (TERN0(DISABLE_W, bnext->steps.w)) axis_active.w = true
);
}
#endif
@ -1385,7 +1388,10 @@ void Planner::check_axes_activity() {
if (TERN0(DISABLE_Z, !axis_active.z)) stepper.disable_axis(Z_AXIS),
if (TERN0(DISABLE_I, !axis_active.i)) stepper.disable_axis(I_AXIS),
if (TERN0(DISABLE_J, !axis_active.j)) stepper.disable_axis(J_AXIS),
if (TERN0(DISABLE_K, !axis_active.k)) stepper.disable_axis(K_AXIS)
if (TERN0(DISABLE_K, !axis_active.k)) stepper.disable_axis(K_AXIS),
if (TERN0(DISABLE_U, !axis_active.u)) stepper.disable_axis(U_AXIS),
if (TERN0(DISABLE_V, !axis_active.v)) stepper.disable_axis(V_AXIS),
if (TERN0(DISABLE_W, !axis_active.w)) stepper.disable_axis(W_AXIS)
);
//
@ -1453,7 +1459,7 @@ void Planner::check_axes_activity() {
float high = 0.0f;
for (uint8_t b = block_buffer_tail; b != block_buffer_head; b = next_block_index(b)) {
const block_t * const block = &block_buffer[b];
if (LINEAR_AXIS_GANG(block->steps.x, || block->steps.y, || block->steps.z, || block->steps.i, || block->steps.j, || block->steps.k)) {
if (NUM_AXIS_GANG(block->steps.x, || block->steps.y, || block->steps.z, || block->steps.i, || block->steps.j, || block->steps.k, || block->steps.u, || block->steps.v, || block->steps.w)) {
const float se = (float)block->steps.e / block->step_event_count * SQRT(block->nominal_speed_sqr); // mm/sec;
NOLESS(high, se);
}
@ -1843,15 +1849,22 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
dc = target.c - position.c,
di = target.i - position.i,
dj = target.j - position.j,
dk = target.k - position.k
dk = target.k - position.k,
du = target.u - position.u,
dv = target.v - position.v,
dw = target.w - position.w
);
/* <-- add a slash to enable
SERIAL_ECHOLNPGM(
" _populate_block FR:", fr_mm_s,
" A:", target.a, " (", da, " steps)"
#if HAS_Y_AXIS
" B:", target.b, " (", db, " steps)"
#endif
#if HAS_Z_AXIS
" C:", target.c, " (", dc, " steps)"
#endif
#if HAS_I_AXIS
" " STR_I ":", target.i, " (", di, " steps)"
#endif
@ -1861,6 +1874,14 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
#if HAS_K_AXIS
" " STR_K ":", target.k, " (", dk, " steps)"
#endif
#if HAS_U_AXIS
" " STR_U ":", target.u, " (", du, " steps)"
#endif
#if HAS_V_AXIS
" " STR_V ":", target.v, " (", dv, " steps)"
#endif
#if HAS_W_AXIS
" " STR_W ":", target.w, " (", dw, " steps)"
#if HAS_EXTRUDERS
" E:", target.e, " (", de, " steps)"
#endif
@ -1925,15 +1946,6 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
if (db + dc < 0) SBI(dm, B_AXIS); // Motor B direction
if (CORESIGN(db - dc) < 0) SBI(dm, C_AXIS); // Motor C direction
#endif
#if HAS_I_AXIS
if (di < 0) SBI(dm, I_AXIS);
#endif
#if HAS_J_AXIS
if (dj < 0) SBI(dm, J_AXIS);
#endif
#if HAS_K_AXIS
if (dk < 0) SBI(dm, K_AXIS);
#endif
#elif ENABLED(MARKFORGED_XY)
if (da + db < 0) SBI(dm, A_AXIS); // Motor A direction
if (db < 0) SBI(dm, B_AXIS); // Motor B direction
@ -1941,16 +1953,22 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
if (da < 0) SBI(dm, A_AXIS); // Motor A direction
if (db + da < 0) SBI(dm, B_AXIS); // Motor B direction
#else
LINEAR_AXIS_CODE(
XYZ_CODE(
if (da < 0) SBI(dm, X_AXIS),
if (db < 0) SBI(dm, Y_AXIS),
if (dc < 0) SBI(dm, Z_AXIS),
if (di < 0) SBI(dm, I_AXIS),
if (dj < 0) SBI(dm, J_AXIS),
if (dk < 0) SBI(dm, K_AXIS)
if (dc < 0) SBI(dm, Z_AXIS)
);
#endif
SECONDARY_AXIS_CODE(
if (di < 0) SBI(dm, I_AXIS),
if (dj < 0) SBI(dm, J_AXIS),
if (dk < 0) SBI(dm, K_AXIS),
if (du < 0) SBI(dm, U_AXIS),
if (dv < 0) SBI(dm, V_AXIS),
if (dw < 0) SBI(dm, W_AXIS)
);
#if HAS_EXTRUDERS
if (de < 0) SBI(dm, E_AXIS);
const float esteps_float = de * e_factor[extruder];
@ -1974,22 +1992,24 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
// Number of steps for each axis
// See https://www.corexy.com/theory.html
block->steps.set(NUM_AXIS_LIST(
#if CORE_IS_XY
block->steps.set(LINEAR_AXIS_LIST(ABS(da + db), ABS(da - db), ABS(dc), ABS(di), ABS(dj), ABS(dk)));
ABS(da + db), ABS(da - db), ABS(dc)
#elif CORE_IS_XZ
block->steps.set(LINEAR_AXIS_LIST(ABS(da + dc), ABS(db), ABS(da - dc), ABS(di), ABS(dj), ABS(dk)));
ABS(da + dc), ABS(db), ABS(da - dc)
#elif CORE_IS_YZ
block->steps.set(LINEAR_AXIS_LIST(ABS(da), ABS(db + dc), ABS(db - dc), ABS(di), ABS(dj), ABS(dk)));
ABS(da), ABS(db + dc), ABS(db - dc)
#elif ENABLED(MARKFORGED_XY)
block->steps.set(LINEAR_AXIS_LIST(ABS(da + db), ABS(db), ABS(dc), ABS(di), ABS(dj), ABS(dk)));
ABS(da + db), ABS(db), ABS(dc)
#elif ENABLED(MARKFORGED_YX)
block->steps.set(LINEAR_AXIS_LIST(ABS(da), ABS(db + da), ABS(dc), ABS(di), ABS(dj), ABS(dk)));
ABS(da), ABS(db + da), ABS(dc)
#elif IS_SCARA
block->steps.set(LINEAR_AXIS_LIST(ABS(da), ABS(db), ABS(dc), ABS(di), ABS(dj), ABS(dk)));
#else
// default non-h-bot planning
block->steps.set(LINEAR_AXIS_LIST(ABS(da), ABS(db), ABS(dc), ABS(di), ABS(dj), ABS(dk)));
ABS(da), ABS(db), ABS(dc)
#else // default non-h-bot planning
ABS(da), ABS(db), ABS(dc)
#endif
, ABS(di), ABS(dj), ABS(dk), ABS(du), ABS(dv), ABS(dw)
));
/**
* This part of the code calculates the total length of the movement.
@ -2027,9 +2047,6 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
steps_dist_mm.b = (db + dc) * mm_per_step[B_AXIS];
steps_dist_mm.c = CORESIGN(db - dc) * mm_per_step[C_AXIS];
#endif
TERN_(HAS_I_AXIS, steps_dist_mm.i = di * mm_per_step[I_AXIS]);
TERN_(HAS_J_AXIS, steps_dist_mm.j = dj * mm_per_step[J_AXIS]);
TERN_(HAS_K_AXIS, steps_dist_mm.k = dk * mm_per_step[K_AXIS]);
#elif ENABLED(MARKFORGED_XY)
steps_dist_mm.a = (da - db) * mm_per_step[A_AXIS];
steps_dist_mm.b = db * mm_per_step[B_AXIS];
@ -2037,27 +2054,40 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
steps_dist_mm.a = da * mm_per_step[A_AXIS];
steps_dist_mm.b = (db - da) * mm_per_step[B_AXIS];
#else
LINEAR_AXIS_CODE(
XYZ_CODE(
steps_dist_mm.a = da * mm_per_step[A_AXIS],
steps_dist_mm.b = db * mm_per_step[B_AXIS],
steps_dist_mm.c = dc * mm_per_step[C_AXIS],
steps_dist_mm.i = di * mm_per_step[I_AXIS],
steps_dist_mm.j = dj * mm_per_step[J_AXIS],
steps_dist_mm.k = dk * mm_per_step[K_AXIS]
steps_dist_mm.c = dc * mm_per_step[C_AXIS]
);
#endif
SECONDARY_AXIS_CODE(
steps_dist_mm.i = di * mm_per_step[I_AXIS],
steps_dist_mm.j = dj * mm_per_step[J_AXIS],
steps_dist_mm.k = dk * mm_per_step[K_AXIS],
steps_dist_mm.u = du * mm_per_step[U_AXIS],
steps_dist_mm.v = dv * mm_per_step[V_AXIS],
steps_dist_mm.w = dw * mm_per_step[W_AXIS]
);
TERN_(HAS_EXTRUDERS, steps_dist_mm.e = esteps_float * mm_per_step[E_AXIS_N(extruder)]);
TERN_(LCD_SHOW_E_TOTAL, e_move_accumulator += steps_dist_mm.e);
if (true LINEAR_AXIS_GANG(
#if BOTH(HAS_ROTATIONAL_AXES, INCH_MODE_SUPPORT)
bool cartesian_move = true;
#endif
if (true NUM_AXIS_GANG(
&& block->steps.a < MIN_STEPS_PER_SEGMENT,
&& block->steps.b < MIN_STEPS_PER_SEGMENT,
&& block->steps.c < MIN_STEPS_PER_SEGMENT,
&& block->steps.i < MIN_STEPS_PER_SEGMENT,
&& block->steps.j < MIN_STEPS_PER_SEGMENT,
&& block->steps.k < MIN_STEPS_PER_SEGMENT
&& block->steps.k < MIN_STEPS_PER_SEGMENT,
&& block->steps.u < MIN_STEPS_PER_SEGMENT,
&& block->steps.v < MIN_STEPS_PER_SEGMENT,
&& block->steps.w < MIN_STEPS_PER_SEGMENT
)
) {
block->millimeters = TERN0(HAS_EXTRUDERS, ABS(steps_dist_mm.e));
@ -2066,36 +2096,71 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
if (millimeters)
block->millimeters = millimeters;
else {
block->millimeters = SQRT(
#if ANY(CORE_IS_XY, MARKFORGED_XY, MARKFORGED_YX)
LINEAR_AXIS_GANG(
sq(steps_dist_mm.head.x), + sq(steps_dist_mm.head.y), + sq(steps_dist_mm.z),
+ sq(steps_dist_mm.i), + sq(steps_dist_mm.j), + sq(steps_dist_mm.k)
)
#elif CORE_IS_XZ
LINEAR_AXIS_GANG(
sq(steps_dist_mm.head.x), + sq(steps_dist_mm.y), + sq(steps_dist_mm.head.z),
+ sq(steps_dist_mm.i), + sq(steps_dist_mm.j), + sq(steps_dist_mm.k)
)
#elif CORE_IS_YZ
LINEAR_AXIS_GANG(
sq(steps_dist_mm.x) + sq(steps_dist_mm.head.y) + sq(steps_dist_mm.head.z)
+ sq(steps_dist_mm.i), + sq(steps_dist_mm.j), + sq(steps_dist_mm.k)
)
/**
* Distance for interpretation of feedrate in accordance with LinuxCNC (the successor of NIST
* RS274NGC interpreter - version 3) and its default CANON_XYZ feed reference mode.
* Assume that X, Y, Z are the primary linear axes and U, V, W are secondary linear axes and A, B, C are
* rotational axes. Then dX, dY, dZ are the displacements of the primary linear axes and dU, dV, dW are the displacements of linear axes and
* dA, dB, dC are the displacements of rotational axes.
* The time it takes to execute move command with feedrate F is t = D/F, where D is the total distance, calculated as follows:
* D^2 = dX^2 + dY^2 + dZ^2
* if D^2 == 0 (none of XYZ move but any secondary linear axes move, whether other axes are moved or not):
* D^2 = dU^2 + dV^2 + dW^2
* if D^2 == 0 (only rotational axes are moved):
* D^2 = dA^2 + dB^2 + dC^2
*/
float distance_sqr = (
#if ENABLED(ARTICULATED_ROBOT_ARM)
// For articulated robots, interpreting feedrate like LinuxCNC would require inverse kinematics. As a workaround, pretend that motors sit on n mutually orthogonal
// axes and assume that we could think of distance as magnitude of an n-vector in an n-dimensional Euclidian space.
NUM_AXIS_GANG(
sq(steps_dist_mm.x), + sq(steps_dist_mm.y), + sq(steps_dist_mm.z),
+ sq(steps_dist_mm.i), + sq(steps_dist_mm.j), + sq(steps_dist_mm.k),
+ sq(steps_dist_mm.u), + sq(steps_dist_mm.v), + sq(steps_dist_mm.w)
);
#elif ENABLED(FOAMCUTTER_XYUV)
// Return the largest distance move from either X/Y or I/J plane
#if HAS_J_AXIS
// Special 5 axis kinematics. Return the largest distance move from either X/Y or I/J plane
_MAX(sq(steps_dist_mm.x) + sq(steps_dist_mm.y), sq(steps_dist_mm.i) + sq(steps_dist_mm.j))
#else
#else // Foamcutter with only two axes (XY)
sq(steps_dist_mm.x) + sq(steps_dist_mm.y)
#endif
#elif ANY(CORE_IS_XY, MARKFORGED_XY, MARKFORGED_YX)
XYZ_GANG(sq(steps_dist_mm.head.x), + sq(steps_dist_mm.head.y), + sq(steps_dist_mm.z))
#elif CORE_IS_XZ
XYZ_GANG(sq(steps_dist_mm.head.x), + sq(steps_dist_mm.y), + sq(steps_dist_mm.head.z))
#elif CORE_IS_YZ
XYZ_GANG(sq(steps_dist_mm.x), + sq(steps_dist_mm.head.y), + sq(steps_dist_mm.head.z))
#else
LINEAR_AXIS_GANG(
sq(steps_dist_mm.x), + sq(steps_dist_mm.y), + sq(steps_dist_mm.z),
+ sq(steps_dist_mm.i), + sq(steps_dist_mm.j), + sq(steps_dist_mm.k)
)
XYZ_GANG(sq(steps_dist_mm.x), + sq(steps_dist_mm.y), + sq(steps_dist_mm.z))
#endif
);
#if SECONDARY_LINEAR_AXES >= 1 && NONE(FOAMCUTTER_XYUV, ARTICULATED_ROBOT_ARM)
if (NEAR_ZERO(distance_sqr)) {
// Move does not involve any primary linear axes (xyz) but might involve secondary linear axes
distance_sqr = (0.0
SECONDARY_AXIS_GANG(
IF_DISABLED(AXIS4_ROTATES, + sq(steps_dist_mm.i)),
IF_DISABLED(AXIS5_ROTATES, + sq(steps_dist_mm.j)),
IF_DISABLED(AXIS6_ROTATES, + sq(steps_dist_mm.k)),
IF_DISABLED(AXIS7_ROTATES, + sq(steps_dist_mm.u)),
IF_DISABLED(AXIS8_ROTATES, + sq(steps_dist_mm.v)),
IF_DISABLED(AXIS9_ROTATES, + sq(steps_dist_mm.w))
)
);
}
#endif
#if HAS_ROTATIONAL_AXES && NONE(FOAMCUTTER_XYUV, ARTICULATED_ROBOT_ARM)
if (NEAR_ZERO(distance_sqr)) {
// Move involves only rotational axes. Calculate angular distance in accordance with LinuxCNC
TERN_(INCH_MODE_SUPPORT, cartesian_move = false);
distance_sqr = ROTATIONAL_AXIS_GANG(sq(steps_dist_mm.i), + sq(steps_dist_mm.j), + sq(steps_dist_mm.k), + sq(steps_dist_mm.u), + sq(steps_dist_mm.v), + sq(steps_dist_mm.w));
}
#endif
block->millimeters = SQRT(distance_sqr);
}
/**
@ -2112,8 +2177,10 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
TERN_(HAS_EXTRUDERS, block->steps.e = esteps);
block->step_event_count = _MAX(LOGICAL_AXIS_LIST(
esteps, block->steps.a, block->steps.b, block->steps.c, block->steps.i, block->steps.j, block->steps.k
block->step_event_count = _MAX(LOGICAL_AXIS_LIST(esteps,
block->steps.a, block->steps.b, block->steps.c,
block->steps.i, block->steps.j, block->steps.k,
block->steps.u, block->steps.v, block->steps.w
));
// Bail if this is a zero-length block
@ -2135,13 +2202,16 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
E_TERN_(block->extruder = extruder);
#if ENABLED(AUTO_POWER_CONTROL)
if (LINEAR_AXIS_GANG(
if (NUM_AXIS_GANG(
block->steps.x,
|| block->steps.y,
|| block->steps.z,
|| block->steps.i,
|| block->steps.j,
|| block->steps.k
|| block->steps.k,
|| block->steps.u,
|| block->steps.v,
|| block->steps.w
)) powerManager.power_on();
#endif
@ -2167,19 +2237,27 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
}
if (block->steps.x) stepper.enable_axis(X_AXIS);
#else
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
if (block->steps.x) stepper.enable_axis(X_AXIS),
if (block->steps.y) stepper.enable_axis(Y_AXIS),
if (TERN(Z_LATE_ENABLE, 0, block->steps.z)) stepper.enable_axis(Z_AXIS),
if (block->steps.i) stepper.enable_axis(I_AXIS),
if (block->steps.j) stepper.enable_axis(J_AXIS),
if (block->steps.k) stepper.enable_axis(K_AXIS)
if (block->steps.k) stepper.enable_axis(K_AXIS),
if (block->steps.u) stepper.enable_axis(U_AXIS),
if (block->steps.v) stepper.enable_axis(V_AXIS),
if (block->steps.w) stepper.enable_axis(W_AXIS)
);
#endif
#if ANY(CORE_IS_XY, MARKFORGED_XY, MARKFORGED_YX)
TERN_(HAS_I_AXIS, if (block->steps.i) stepper.enable_axis(I_AXIS));
TERN_(HAS_J_AXIS, if (block->steps.j) stepper.enable_axis(J_AXIS));
TERN_(HAS_K_AXIS, if (block->steps.k) stepper.enable_axis(K_AXIS));
SECONDARY_AXIS_CODE(
if (block->steps.i) stepper.enable_axis(I_AXIS),
if (block->steps.j) stepper.enable_axis(J_AXIS),
if (block->steps.k) stepper.enable_axis(K_AXIS),
if (block->steps.u) stepper.enable_axis(U_AXIS),
if (block->steps.v) stepper.enable_axis(V_AXIS),
if (block->steps.w) stepper.enable_axis(W_AXIS)
);
#endif
// Enable extruder(s)
@ -2226,8 +2304,14 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
const float inverse_millimeters = 1.0f / block->millimeters; // Inverse millimeters to remove multiple divides
// Calculate inverse time for this move. No divide by zero due to previous checks.
// Example: At 120mm/s a 60mm move takes 0.5s. So this will give 2.0.
float inverse_secs = fr_mm_s * inverse_millimeters;
// Example: At 120mm/s a 60mm move involving XYZ axes takes 0.5s. So this will give 2.0.
// Example 2: At 120°/s a 60° move involving only rotational axes takes 0.5s. So this will give 2.0.
float inverse_secs;
#if BOTH(HAS_ROTATIONAL_AXES, INCH_MODE_SUPPORT)
inverse_secs = inverse_millimeters * (cartesian_move ? fr_mm_s : LINEAR_UNIT(fr_mm_s));
#else
inverse_secs = fr_mm_s * inverse_millimeters;
#endif
// Get the number of non busy movements in queue (non busy means that they can be altered)
const uint8_t moves_queued = nonbusy_movesplanned();
@ -2273,13 +2357,13 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
filwidth.advance_e(steps_dist_mm.e);
#endif
// Calculate and limit speed in mm/sec
// Calculate and limit speed in mm/sec (linear) or degrees/sec (rotational)
xyze_float_t current_speed;
float speed_factor = 1.0f; // factor <1 decreases speed
// Linear axes first with less logic
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
current_speed[i] = steps_dist_mm[i] * inverse_secs;
const feedRate_t cs = ABS(current_speed[i]),
max_fr = settings.max_feedrate_mm_s[i];
@ -2367,9 +2451,10 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
// Compute and limit the acceleration rate for the trapezoid generator.
const float steps_per_mm = block->step_event_count * inverse_millimeters;
uint32_t accel;
if (LINEAR_AXIS_GANG(
if (NUM_AXIS_GANG(
!block->steps.a, && !block->steps.b, && !block->steps.c,
&& !block->steps.i, && !block->steps.j, && !block->steps.k)
&& !block->steps.i, && !block->steps.j, && !block->steps.k,
&& !block->steps.u, && !block->steps.v, && !block->steps.w)
) { // Is this a retract / recover move?
accel = CEIL(settings.retract_acceleration * steps_per_mm); // Convert to: acceleration steps/sec^2
TERN_(LIN_ADVANCE, block->use_advance_lead = false); // No linear advance for simple retract/recover
@ -2442,7 +2527,10 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
LIMIT_ACCEL_LONG(C_AXIS, 0),
LIMIT_ACCEL_LONG(I_AXIS, 0),
LIMIT_ACCEL_LONG(J_AXIS, 0),
LIMIT_ACCEL_LONG(K_AXIS, 0)
LIMIT_ACCEL_LONG(K_AXIS, 0),
LIMIT_ACCEL_LONG(U_AXIS, 0),
LIMIT_ACCEL_LONG(V_AXIS, 0),
LIMIT_ACCEL_LONG(W_AXIS, 0)
);
}
else {
@ -2453,7 +2541,10 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
LIMIT_ACCEL_FLOAT(C_AXIS, 0),
LIMIT_ACCEL_FLOAT(I_AXIS, 0),
LIMIT_ACCEL_FLOAT(J_AXIS, 0),
LIMIT_ACCEL_FLOAT(K_AXIS, 0)
LIMIT_ACCEL_FLOAT(K_AXIS, 0),
LIMIT_ACCEL_FLOAT(U_AXIS, 0),
LIMIT_ACCEL_FLOAT(V_AXIS, 0),
LIMIT_ACCEL_FLOAT(W_AXIS, 0)
);
}
}
@ -2518,7 +2609,7 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
#if HAS_DIST_MM_ARG
cart_dist_mm
#else
LOGICAL_AXIS_ARRAY(steps_dist_mm.e, steps_dist_mm.x, steps_dist_mm.y, steps_dist_mm.z, steps_dist_mm.i, steps_dist_mm.j, steps_dist_mm.k)
LOGICAL_AXIS_ARRAY(steps_dist_mm.e, steps_dist_mm.x, steps_dist_mm.y, steps_dist_mm.z, steps_dist_mm.i, steps_dist_mm.j, steps_dist_mm.k, steps_dist_mm.u, steps_dist_mm.v, steps_dist_mm.w)
#endif
;
@ -2544,7 +2635,10 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
+ (-prev_unit_vec.z * unit_vec.z),
+ (-prev_unit_vec.i * unit_vec.i),
+ (-prev_unit_vec.j * unit_vec.j),
+ (-prev_unit_vec.k * unit_vec.k)
+ (-prev_unit_vec.k * unit_vec.k),
+ (-prev_unit_vec.u * unit_vec.u),
+ (-prev_unit_vec.v * unit_vec.v),
+ (-prev_unit_vec.w * unit_vec.w)
);
// NOTE: Computed without any expensive trig, sin() or acos(), by trig half angle identity of cos(theta).
@ -2691,7 +2785,7 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
const float extra_xyjerk = TERN0(HAS_EXTRUDERS, de <= 0) ? TRAVEL_EXTRA_XYJERK : 0;
uint8_t limited = 0;
TERN(HAS_LINEAR_E_JERK, LOOP_LINEAR_AXES, LOOP_LOGICAL_AXES)(i) {
TERN(HAS_LINEAR_E_JERK, LOOP_NUM_AXES, LOOP_LOGICAL_AXES)(i) {
const float jerk = ABS(current_speed[i]), // cs : Starting from zero, change in speed for this axis
maxj = (max_jerk[i] + (i == X_AXIS || i == Y_AXIS ? extra_xyjerk : 0.0f)); // mj : The max jerk setting for this axis
if (jerk > maxj) { // cs > mj : New current speed too fast?
@ -2729,7 +2823,7 @@ bool Planner::_populate_block(block_t * const block, bool split_move,
vmax_junction = previous_nominal_speed;
// Now limit the jerk in all axes.
TERN(HAS_LINEAR_E_JERK, LOOP_LINEAR_AXES, LOOP_LOGICAL_AXES)(axis) {
TERN(HAS_LINEAR_E_JERK, LOOP_NUM_AXES, LOOP_LOGICAL_AXES)(axis) {
// Limit an axis. We have to differentiate: coasting, reversal of an axis, full stop.
float v_exit = previous_speed[axis] * smaller_speed_factor,
v_entry = current_speed[axis];
@ -2831,7 +2925,7 @@ void Planner::buffer_sync_block(TERN_(LASER_SYNCHRONOUS_M106_M107, uint8_t sync_
block->position = position;
#if ENABLED(BACKLASH_COMPENSATION)
LOOP_LINEAR_AXES(axis) block->position[axis] += backlash.get_applied_steps((AxisEnum)axis);
LOOP_NUM_AXES(axis) block->position[axis] += backlash.get_applied_steps((AxisEnum)axis);
#endif
#if BOTH(HAS_FAN, LASER_SYNCHRONOUS_M106_M107)
@ -2893,7 +2987,10 @@ bool Planner::buffer_segment(const abce_pos_t &abce
int32_t(LROUND(abce.c * settings.axis_steps_per_mm[C_AXIS])),
int32_t(LROUND(abce.i * settings.axis_steps_per_mm[I_AXIS])),
int32_t(LROUND(abce.j * settings.axis_steps_per_mm[J_AXIS])),
int32_t(LROUND(abce.k * settings.axis_steps_per_mm[K_AXIS]))
int32_t(LROUND(abce.k * settings.axis_steps_per_mm[K_AXIS])),
int32_t(LROUND(abce.u * settings.axis_steps_per_mm[U_AXIS])),
int32_t(LROUND(abce.v * settings.axis_steps_per_mm[V_AXIS])),
int32_t(LROUND(abce.w * settings.axis_steps_per_mm[W_AXIS]))
)
};
@ -2945,6 +3042,21 @@ bool Planner::buffer_segment(const abce_pos_t &abce
SERIAL_ECHOPGM(" (", position.k, "->", target.k);
SERIAL_CHAR(')');
#endif
#if HAS_U_AXIS
SERIAL_ECHOPGM_P(SP_U_LBL, abce.u);
SERIAL_ECHOPGM(" (", position.u, "->", target.u);
SERIAL_CHAR(')');
#endif
#if HAS_V_AXIS
SERIAL_ECHOPGM_P(SP_V_LBL, abce.v);
SERIAL_ECHOPGM(" (", position.v, "->", target.v);
SERIAL_CHAR(')');
#endif
#if HAS_W_AXIS
SERIAL_ECHOPGM_P(SP_W_LBL, abce.w);
SERIAL_ECHOPGM(" (", position.w, "->", target.w);
SERIAL_CHAR(')');
#endif
#if HAS_EXTRUDERS
SERIAL_ECHOPGM_P(SP_E_LBL, abce.e);
SERIAL_ECHOLNPGM(" (", position.e, "->", target.e, ")");
@ -2987,12 +3099,14 @@ bool Planner::buffer_line(const xyze_pos_t &cart, const_feedRate_t fr_mm_s, cons
const xyze_pos_t cart_dist_mm = LOGICAL_AXIS_ARRAY(
cart.e - position_cart.e,
cart.x - position_cart.x, cart.y - position_cart.y, cart.z - position_cart.z,
cart.i - position_cart.i, cart.j - position_cart.j, cart.j - position_cart.k
cart.i - position_cart.i, cart.j - position_cart.j, cart.k - position_cart.k,
cart.u - position_cart.u, cart.v - position_cart.v, cart.w - position_cart.w
);
#else
const xyz_pos_t cart_dist_mm = LINEAR_AXIS_ARRAY(
const xyz_pos_t cart_dist_mm = NUM_AXIS_ARRAY(
cart.x - position_cart.x, cart.y - position_cart.y, cart.z - position_cart.z,
cart.i - position_cart.i, cart.j - position_cart.j, cart.j - position_cart.k
cart.i - position_cart.i, cart.j - position_cart.j, cart.k - position_cart.k,
cart.u - position_cart.u, cart.v - position_cart.v, cart.w - position_cart.w
);
#endif
@ -3097,7 +3211,10 @@ void Planner::set_machine_position_mm(const abce_pos_t &abce) {
LROUND(abce.c * settings.axis_steps_per_mm[C_AXIS]),
LROUND(abce.i * settings.axis_steps_per_mm[I_AXIS]),
LROUND(abce.j * settings.axis_steps_per_mm[J_AXIS]),
LROUND(abce.k * settings.axis_steps_per_mm[K_AXIS])
LROUND(abce.k * settings.axis_steps_per_mm[K_AXIS]),
LROUND(abce.u * settings.axis_steps_per_mm[U_AXIS]),
LROUND(abce.v * settings.axis_steps_per_mm[V_AXIS]),
LROUND(abce.w * settings.axis_steps_per_mm[W_AXIS])
)
);
@ -3109,7 +3226,7 @@ void Planner::set_machine_position_mm(const abce_pos_t &abce) {
else {
#if ENABLED(BACKLASH_COMPENSATION)
abce_long_t stepper_pos = position;
LOOP_LINEAR_AXES(axis) stepper_pos[axis] += backlash.get_applied_steps((AxisEnum)axis);
LOOP_NUM_AXES(axis) stepper_pos[axis] += backlash.get_applied_steps((AxisEnum)axis);
stepper.set_position(stepper_pos);
#else
stepper.set_position(position);

View File

@ -84,7 +84,8 @@
constexpr xyze_feedrate_t _mf = MANUAL_FEEDRATE,
manual_feedrate_mm_s = LOGICAL_AXIS_ARRAY(_mf.e / 60.0f,
_mf.x / 60.0f, _mf.y / 60.0f, _mf.z / 60.0f,
_mf.i / 60.0f, _mf.j / 60.0f, _mf.k / 60.0f);
_mf.i / 60.0f, _mf.j / 60.0f, _mf.k / 60.0f,
_mf.u / 60.0f, _mf.v / 60.0f, _mf.w / 60.0f);
#endif
#if IS_KINEMATIC && HAS_JUNCTION_DEVIATION
@ -843,7 +844,8 @@ class Planner {
const abce_pos_t out = LOGICAL_AXIS_ARRAY(
get_axis_position_mm(E_AXIS),
get_axis_position_mm(A_AXIS), get_axis_position_mm(B_AXIS), get_axis_position_mm(C_AXIS),
get_axis_position_mm(I_AXIS), get_axis_position_mm(J_AXIS), get_axis_position_mm(K_AXIS)
get_axis_position_mm(I_AXIS), get_axis_position_mm(J_AXIS), get_axis_position_mm(K_AXIS),
get_axis_position_mm(U_AXIS), get_axis_position_mm(V_AXIS), get_axis_position_mm(W_AXIS)
);
return out;
}

View File

@ -188,7 +188,10 @@ void cubic_b_spline(
interp(position.z, target.z, t), // FIXME. Wrong, since t is not linear in the distance.
interp(position.i, target.i, t), // FIXME. Wrong, since t is not linear in the distance.
interp(position.j, target.j, t), // FIXME. Wrong, since t is not linear in the distance.
interp(position.k, target.k, t) // FIXME. Wrong, since t is not linear in the distance.
interp(position.k, target.k, t), // FIXME. Wrong, since t is not linear in the distance.
interp(position.u, target.u, t), // FIXME. Wrong, since t is not linear in the distance.
interp(position.v, target.v, t), // FIXME. Wrong, since t is not linear in the distance.
interp(position.w, target.w, t) // FIXME. Wrong, since t is not linear in the distance.
);
apply_motion_limits(new_bez);
bez_target = new_bez;

View File

@ -809,9 +809,10 @@ float Probe::probe_at_point(const_float_t rx, const_float_t ry, const ProbePtRai
#endif
// On delta keep Z below clip height or do_blocking_move_to will abort
xyz_pos_t npos = LINEAR_AXIS_ARRAY(
xyz_pos_t npos = NUM_AXIS_ARRAY(
rx, ry, TERN(DELTA, _MIN(delta_clip_start_height, current_position.z), current_position.z),
current_position.i, current_position.j, current_position.k
current_position.i, current_position.j, current_position.k,
current_position.u, current_position.v, current_position.w
);
if (!can_reach(npos, probe_relative)) {
if (DEBUGGING(LEVELING)) DEBUG_ECHOLNPGM("Position Not Reachable");

View File

@ -146,7 +146,7 @@ public:
#else
static constexpr xyz_pos_t offset = xyz_pos_t(LINEAR_AXIS_ARRAY(0, 0, 0, 0, 0, 0)); // See #16767
static constexpr xyz_pos_t offset = xyz_pos_t(NUM_AXIS_ARRAY(0, 0, 0, 0, 0, 0)); // See #16767
static bool set_deployed(const bool) { return false; }

View File

@ -254,7 +254,7 @@ float segments_per_second = TERN(AXEL_TPARA, TPARA_SEGMENTS_PER_SECOND, SCARA_SE
// Do this here all at once for Delta, because
// XYZ isn't ABC. Applying this per-tower would
// give the impression that they are the same.
LOOP_LINEAR_AXES(i) set_axis_is_at_home((AxisEnum)i);
LOOP_NUM_AXES(i) set_axis_is_at_home((AxisEnum)i);
sync_plan_position();
}

View File

@ -180,10 +180,10 @@
#define _EN_ITEM(N) , E##N
#define _EN1_ITEM(N) , E##N:1
typedef struct { uint16_t LINEAR_AXIS_LIST(X, Y, Z, I, J, K), X2, Y2, Z2, Z3, Z4 REPEAT(E_STEPPERS, _EN_ITEM); } per_stepper_uint16_t;
typedef struct { uint32_t LINEAR_AXIS_LIST(X, Y, Z, I, J, K), X2, Y2, Z2, Z3, Z4 REPEAT(E_STEPPERS, _EN_ITEM); } per_stepper_uint32_t;
typedef struct { int16_t LINEAR_AXIS_LIST(X, Y, Z, I, J, K), X2, Y2, Z2, Z3, Z4; } mot_stepper_int16_t;
typedef struct { bool LINEAR_AXIS_LIST(X:1, Y:1, Z:1, I:1, J:1, K:1), X2:1, Y2:1, Z2:1, Z3:1, Z4:1 REPEAT(E_STEPPERS, _EN1_ITEM); } per_stepper_bool_t;
typedef struct { uint16_t NUM_AXIS_LIST(X, Y, Z, I, J, K, U, V, W), X2, Y2, Z2, Z3, Z4 REPEAT(E_STEPPERS, _EN_ITEM); } per_stepper_uint16_t;
typedef struct { uint32_t NUM_AXIS_LIST(X, Y, Z, I, J, K, U, V, W), X2, Y2, Z2, Z3, Z4 REPEAT(E_STEPPERS, _EN_ITEM); } per_stepper_uint32_t;
typedef struct { int16_t NUM_AXIS_LIST(X, Y, Z, I, J, K, U, V, W), X2, Y2, Z2, Z3, Z4; } mot_stepper_int16_t;
typedef struct { bool NUM_AXIS_LIST(X:1, Y:1, Z:1, I:1, J:1, K:1, U:1, V:1, W:1), X2:1, Y2:1, Z2:1, Z3:1, Z4:1 REPEAT(E_STEPPERS, _EN1_ITEM); } per_stepper_bool_t;
#undef _EN_ITEM
@ -211,7 +211,7 @@ typedef struct SettingsDataStruct {
//
// DISTINCT_E_FACTORS
//
uint8_t e_factors; // DISTINCT_AXES - LINEAR_AXES
uint8_t e_factors; // DISTINCT_AXES - NUM_AXES
//
// Planner settings
@ -447,7 +447,7 @@ typedef struct SettingsDataStruct {
// HAS_MOTOR_CURRENT_PWM
//
#ifndef MOTOR_CURRENT_COUNT
#define MOTOR_CURRENT_COUNT LINEAR_AXES
#define MOTOR_CURRENT_COUNT NUM_AXES
#endif
uint32_t motor_current_setting[MOTOR_CURRENT_COUNT]; // M907 X Z E ...
@ -600,7 +600,7 @@ void MarlinSettings::postprocess() {
#endif
// Software endstops depend on home_offset
LOOP_LINEAR_AXES(i) {
LOOP_NUM_AXES(i) {
update_workspace_offset((AxisEnum)i);
update_software_endstops((AxisEnum)i);
}
@ -750,7 +750,7 @@ void MarlinSettings::postprocess() {
working_crc = 0; // clear before first "real data"
const uint8_t e_factors = DISTINCT_AXES - (LINEAR_AXES);
const uint8_t e_factors = DISTINCT_AXES - (NUM_AXES);
_FIELD_TEST(e_factors);
EEPROM_WRITE(e_factors);
@ -767,7 +767,7 @@ void MarlinSettings::postprocess() {
EEPROM_WRITE(dummyf);
#endif
#else
const xyze_pos_t planner_max_jerk = LOGICAL_AXIS_ARRAY(float(DEFAULT_EJERK), 10, 10, 0.4, 0.4, 0.4, 0.4);
const xyze_pos_t planner_max_jerk = LOGICAL_AXIS_ARRAY(float(DEFAULT_EJERK), 10, 10, 0.4, 0.4, 0.4, 0.4, 0.4, 0.4, 0.4);
EEPROM_WRITE(planner_max_jerk);
#endif
@ -1248,6 +1248,15 @@ void MarlinSettings::postprocess() {
#if AXIS_IS_TMC(K)
tmc_stepper_current.K = stepperK.getMilliamps();
#endif
#if AXIS_IS_TMC(U)
tmc_stepper_current.U = stepperU.getMilliamps();
#endif
#if AXIS_IS_TMC(V)
tmc_stepper_current.V = stepperV.getMilliamps();
#endif
#if AXIS_IS_TMC(W)
tmc_stepper_current.W = stepperW.getMilliamps();
#endif
#if AXIS_IS_TMC(X2)
tmc_stepper_current.X2 = stepperX2.getMilliamps();
#endif
@ -1305,6 +1314,9 @@ void MarlinSettings::postprocess() {
TERN_(I_HAS_STEALTHCHOP, tmc_hybrid_threshold.I = stepperI.get_pwm_thrs());
TERN_(J_HAS_STEALTHCHOP, tmc_hybrid_threshold.J = stepperJ.get_pwm_thrs());
TERN_(K_HAS_STEALTHCHOP, tmc_hybrid_threshold.K = stepperK.get_pwm_thrs());
TERN_(U_HAS_STEALTHCHOP, tmc_hybrid_threshold.U = stepperU.get_pwm_thrs());
TERN_(V_HAS_STEALTHCHOP, tmc_hybrid_threshold.V = stepperV.get_pwm_thrs());
TERN_(W_HAS_STEALTHCHOP, tmc_hybrid_threshold.W = stepperW.get_pwm_thrs());
TERN_(X2_HAS_STEALTHCHOP, tmc_hybrid_threshold.X2 = stepperX2.get_pwm_thrs());
TERN_(Y2_HAS_STEALTHCHOP, tmc_hybrid_threshold.Y2 = stepperY2.get_pwm_thrs());
TERN_(Z2_HAS_STEALTHCHOP, tmc_hybrid_threshold.Z2 = stepperZ2.get_pwm_thrs());
@ -1321,7 +1333,7 @@ void MarlinSettings::postprocess() {
#else
#define _EN_ITEM(N) , .E##N = 30
const per_stepper_uint32_t tmc_hybrid_threshold = {
LINEAR_AXIS_LIST(.X = 100, .Y = 100, .Z = 3, .I = 3, .J = 3, .K = 3),
NUM_AXIS_LIST(.X = 100, .Y = 100, .Z = 3, .I = 3, .J = 3, .K = 3, .U = 3, .V = 3, .W = 3),
.X2 = 100, .Y2 = 100, .Z2 = 3, .Z3 = 3, .Z4 = 3
REPEAT(E_STEPPERS, _EN_ITEM)
};
@ -1336,13 +1348,16 @@ void MarlinSettings::postprocess() {
{
mot_stepper_int16_t tmc_sgt{0};
#if USE_SENSORLESS
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
TERN_(X_SENSORLESS, tmc_sgt.X = stepperX.homing_threshold()),
TERN_(Y_SENSORLESS, tmc_sgt.Y = stepperY.homing_threshold()),
TERN_(Z_SENSORLESS, tmc_sgt.Z = stepperZ.homing_threshold()),
TERN_(I_SENSORLESS, tmc_sgt.I = stepperI.homing_threshold()),
TERN_(J_SENSORLESS, tmc_sgt.J = stepperJ.homing_threshold()),
TERN_(K_SENSORLESS, tmc_sgt.K = stepperK.homing_threshold())
TERN_(K_SENSORLESS, tmc_sgt.K = stepperK.homing_threshold()),
TERN_(U_SENSORLESS, tmc_sgt.U = stepperU.homing_threshold()),
TERN_(V_SENSORLESS, tmc_sgt.V = stepperV.homing_threshold()),
TERN_(W_SENSORLESS, tmc_sgt.W = stepperW.homing_threshold())
);
TERN_(X2_SENSORLESS, tmc_sgt.X2 = stepperX2.homing_threshold());
TERN_(Y2_SENSORLESS, tmc_sgt.Y2 = stepperY2.homing_threshold());
@ -1366,6 +1381,9 @@ void MarlinSettings::postprocess() {
TERN_(I_HAS_STEALTHCHOP, tmc_stealth_enabled.I = stepperI.get_stored_stealthChop());
TERN_(J_HAS_STEALTHCHOP, tmc_stealth_enabled.J = stepperJ.get_stored_stealthChop());
TERN_(K_HAS_STEALTHCHOP, tmc_stealth_enabled.K = stepperK.get_stored_stealthChop());
TERN_(U_HAS_STEALTHCHOP, tmc_stealth_enabled.U = stepperU.get_stored_stealthChop());
TERN_(V_HAS_STEALTHCHOP, tmc_stealth_enabled.V = stepperV.get_stored_stealthChop());
TERN_(W_HAS_STEALTHCHOP, tmc_stealth_enabled.W = stepperW.get_stored_stealthChop());
TERN_(X2_HAS_STEALTHCHOP, tmc_stealth_enabled.X2 = stepperX2.get_stored_stealthChop());
TERN_(Y2_HAS_STEALTHCHOP, tmc_stealth_enabled.Y2 = stepperY2.get_stored_stealthChop());
TERN_(Z2_HAS_STEALTHCHOP, tmc_stealth_enabled.Z2 = stepperZ2.get_stored_stealthChop());
@ -1455,7 +1473,7 @@ void MarlinSettings::postprocess() {
{
#if ENABLED(BACKLASH_GCODE)
xyz_float_t backlash_distance_mm;
LOOP_LINEAR_AXES(axis) backlash_distance_mm[axis] = backlash.get_distance_mm((AxisEnum)axis);
LOOP_NUM_AXES(axis) backlash_distance_mm[axis] = backlash.get_distance_mm((AxisEnum)axis);
const uint8_t backlash_correction = backlash.get_correction_uint8();
#else
const xyz_float_t backlash_distance_mm{0};
@ -1675,16 +1693,16 @@ void MarlinSettings::postprocess() {
{
// Get only the number of E stepper parameters previously stored
// Any steppers added later are set to their defaults
uint32_t tmp1[LINEAR_AXES + e_factors];
float tmp2[LINEAR_AXES + e_factors];
feedRate_t tmp3[LINEAR_AXES + e_factors];
uint32_t tmp1[NUM_AXES + e_factors];
float tmp2[NUM_AXES + e_factors];
feedRate_t tmp3[NUM_AXES + e_factors];
EEPROM_READ((uint8_t *)tmp1, sizeof(tmp1)); // max_acceleration_mm_per_s2
EEPROM_READ(planner.settings.min_segment_time_us);
EEPROM_READ((uint8_t *)tmp2, sizeof(tmp2)); // axis_steps_per_mm
EEPROM_READ((uint8_t *)tmp3, sizeof(tmp3)); // max_feedrate_mm_s
if (!validating) LOOP_DISTINCT_AXES(i) {
const bool in = (i < e_factors + LINEAR_AXES);
const bool in = (i < e_factors + NUM_AXES);
planner.settings.max_acceleration_mm_per_s2[i] = in ? tmp1[i] : pgm_read_dword(&_DMA[ALIM(i, _DMA)]);
planner.settings.axis_steps_per_mm[i] = in ? tmp2[i] : pgm_read_float(&_DASU[ALIM(i, _DASU)]);
planner.settings.max_feedrate_mm_s[i] = in ? tmp3[i] : pgm_read_float(&_DMF[ALIM(i, _DMF)]);
@ -2199,6 +2217,15 @@ void MarlinSettings::postprocess() {
#if AXIS_IS_TMC(K)
SET_CURR(K);
#endif
#if AXIS_IS_TMC(U)
SET_CURR(U);
#endif
#if AXIS_IS_TMC(V)
SET_CURR(V);
#endif
#if AXIS_IS_TMC(W)
SET_CURR(W);
#endif
#if AXIS_IS_TMC(E0)
SET_CURR(E0);
#endif
@ -2246,6 +2273,9 @@ void MarlinSettings::postprocess() {
TERN_(I_HAS_STEALTHCHOP, stepperI.set_pwm_thrs(tmc_hybrid_threshold.I));
TERN_(J_HAS_STEALTHCHOP, stepperJ.set_pwm_thrs(tmc_hybrid_threshold.J));
TERN_(K_HAS_STEALTHCHOP, stepperK.set_pwm_thrs(tmc_hybrid_threshold.K));
TERN_(U_HAS_STEALTHCHOP, stepperU.set_pwm_thrs(tmc_hybrid_threshold.U));
TERN_(V_HAS_STEALTHCHOP, stepperV.set_pwm_thrs(tmc_hybrid_threshold.V));
TERN_(W_HAS_STEALTHCHOP, stepperW.set_pwm_thrs(tmc_hybrid_threshold.W));
TERN_(E0_HAS_STEALTHCHOP, stepperE0.set_pwm_thrs(tmc_hybrid_threshold.E0));
TERN_(E1_HAS_STEALTHCHOP, stepperE1.set_pwm_thrs(tmc_hybrid_threshold.E1));
TERN_(E2_HAS_STEALTHCHOP, stepperE2.set_pwm_thrs(tmc_hybrid_threshold.E2));
@ -2267,13 +2297,16 @@ void MarlinSettings::postprocess() {
EEPROM_READ(tmc_sgt);
#if USE_SENSORLESS
if (!validating) {
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
TERN_(X_SENSORLESS, stepperX.homing_threshold(tmc_sgt.X)),
TERN_(Y_SENSORLESS, stepperY.homing_threshold(tmc_sgt.Y)),
TERN_(Z_SENSORLESS, stepperZ.homing_threshold(tmc_sgt.Z)),
TERN_(I_SENSORLESS, stepperI.homing_threshold(tmc_sgt.I)),
TERN_(J_SENSORLESS, stepperJ.homing_threshold(tmc_sgt.J)),
TERN_(K_SENSORLESS, stepperK.homing_threshold(tmc_sgt.K))
TERN_(K_SENSORLESS, stepperK.homing_threshold(tmc_sgt.K)),
TERN_(U_SENSORLESS, stepperU.homing_threshold(tmc_sgt.U)),
TERN_(V_SENSORLESS, stepperV.homing_threshold(tmc_sgt.V)),
TERN_(W_SENSORLESS, stepperW.homing_threshold(tmc_sgt.W))
);
TERN_(X2_SENSORLESS, stepperX2.homing_threshold(tmc_sgt.X2));
TERN_(Y2_SENSORLESS, stepperY2.homing_threshold(tmc_sgt.Y2));
@ -2301,6 +2334,9 @@ void MarlinSettings::postprocess() {
TERN_(I_HAS_STEALTHCHOP, SET_STEPPING_MODE(I));
TERN_(J_HAS_STEALTHCHOP, SET_STEPPING_MODE(J));
TERN_(K_HAS_STEALTHCHOP, SET_STEPPING_MODE(K));
TERN_(U_HAS_STEALTHCHOP, SET_STEPPING_MODE(U));
TERN_(V_HAS_STEALTHCHOP, SET_STEPPING_MODE(V));
TERN_(W_HAS_STEALTHCHOP, SET_STEPPING_MODE(W));
TERN_(X2_HAS_STEALTHCHOP, SET_STEPPING_MODE(X2));
TERN_(Y2_HAS_STEALTHCHOP, SET_STEPPING_MODE(Y2));
TERN_(Z2_HAS_STEALTHCHOP, SET_STEPPING_MODE(Z2));
@ -2421,7 +2457,7 @@ void MarlinSettings::postprocess() {
EEPROM_READ(backlash_smoothing_mm);
#if ENABLED(BACKLASH_GCODE)
LOOP_LINEAR_AXES(axis) backlash.set_distance_mm((AxisEnum)axis, backlash_distance_mm[axis]);
LOOP_NUM_AXES(axis) backlash.set_distance_mm((AxisEnum)axis, backlash_distance_mm[axis]);
backlash.set_correction_uint8(backlash_correction);
#ifdef BACKLASH_SMOOTHING_MM
backlash.set_smoothing_mm(backlash_smoothing_mm);
@ -2807,8 +2843,17 @@ void MarlinSettings::reset() {
#if HAS_K_AXIS && !defined(DEFAULT_KJERK)
#define DEFAULT_KJERK 0
#endif
#if HAS_U_AXIS && !defined(DEFAULT_UJERK)
#define DEFAULT_UJERK 0
#endif
#if HAS_V_AXIS && !defined(DEFAULT_VJERK)
#define DEFAULT_VJERK 0
#endif
#if HAS_W_AXIS && !defined(DEFAULT_WJERK)
#define DEFAULT_WJERK 0
#endif
planner.max_jerk.set(
LINEAR_AXIS_LIST(DEFAULT_XJERK, DEFAULT_YJERK, DEFAULT_ZJERK, DEFAULT_IJERK, DEFAULT_JJERK, DEFAULT_KJERK)
NUM_AXIS_LIST(DEFAULT_XJERK, DEFAULT_YJERK, DEFAULT_ZJERK, DEFAULT_IJERK, DEFAULT_JJERK, DEFAULT_KJERK, DEFAULT_UJERK, DEFAULT_VJERK, DEFAULT_WJERK)
);
TERN_(HAS_CLASSIC_E_JERK, planner.max_jerk.e = DEFAULT_EJERK);
#endif
@ -2870,7 +2915,7 @@ void MarlinSettings::reset() {
#if ENABLED(BACKLASH_GCODE)
backlash.set_correction(BACKLASH_CORRECTION);
constexpr xyz_float_t tmp = BACKLASH_DISTANCE_MM;
LOOP_LINEAR_AXES(axis) backlash.set_distance_mm((AxisEnum)axis, tmp[axis]);
LOOP_NUM_AXES(axis) backlash.set_distance_mm((AxisEnum)axis, tmp[axis]);
#ifdef BACKLASH_SMOOTHING_MM
backlash.set_smoothing_mm(BACKLASH_SMOOTHING_MM);
#endif
@ -2916,11 +2961,11 @@ void MarlinSettings::reset() {
//
#if HAS_BED_PROBE
constexpr float dpo[] = NOZZLE_TO_PROBE_OFFSET;
static_assert(COUNT(dpo) == LINEAR_AXES, "NOZZLE_TO_PROBE_OFFSET must contain offsets for each linear axis X, Y, Z....");
static_assert(COUNT(dpo) == NUM_AXES, "NOZZLE_TO_PROBE_OFFSET must contain offsets for each linear axis X, Y, Z....");
#if HAS_PROBE_XY_OFFSET
LOOP_LINEAR_AXES(a) probe.offset[a] = dpo[a];
LOOP_NUM_AXES(a) probe.offset[a] = dpo[a];
#else
probe.offset.set(LINEAR_AXIS_LIST(0, 0, dpo[Z_AXIS], 0, 0, 0));
probe.offset.set(NUM_AXIS_LIST(0, 0, dpo[Z_AXIS], 0, 0, 0, 0, 0, 0));
#endif
#endif

View File

@ -447,6 +447,18 @@ xyze_int8_t Stepper::count_direction{0};
#define K_APPLY_DIR(v,Q) K_DIR_WRITE(v)
#define K_APPLY_STEP(v,Q) K_STEP_WRITE(v)
#endif
#if HAS_U_AXIS
#define U_APPLY_DIR(v,Q) U_DIR_WRITE(v)
#define U_APPLY_STEP(v,Q) U_STEP_WRITE(v)
#endif
#if HAS_V_AXIS
#define V_APPLY_DIR(v,Q) V_DIR_WRITE(v)
#define V_APPLY_STEP(v,Q) V_STEP_WRITE(v)
#endif
#if HAS_W_AXIS
#define W_APPLY_DIR(v,Q) W_DIR_WRITE(v)
#define W_APPLY_STEP(v,Q) W_STEP_WRITE(v)
#endif
#if DISABLED(MIXING_EXTRUDER)
#define E_APPLY_STEP(v,Q) E_STEP_WRITE(stepper_extruder, v)
@ -486,9 +498,10 @@ xyze_int8_t Stepper::count_direction{0};
void Stepper::enable_axis(const AxisEnum axis) {
#define _CASE_ENABLE(N) case N##_AXIS: ENABLE_AXIS_##N(); break;
switch (axis) {
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
_CASE_ENABLE(X), _CASE_ENABLE(Y), _CASE_ENABLE(Z),
_CASE_ENABLE(I), _CASE_ENABLE(J), _CASE_ENABLE(K)
_CASE_ENABLE(I), _CASE_ENABLE(J), _CASE_ENABLE(K),
_CASE_ENABLE(U), _CASE_ENABLE(V), _CASE_ENABLE(W)
);
default: break;
}
@ -505,9 +518,10 @@ bool Stepper::disable_axis(const AxisEnum axis) {
if (can_disable) {
#define _CASE_DISABLE(N) case N##_AXIS: DISABLE_AXIS_##N(); break;
switch (axis) {
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
_CASE_DISABLE(X), _CASE_DISABLE(Y), _CASE_DISABLE(Z),
_CASE_DISABLE(I), _CASE_DISABLE(J), _CASE_DISABLE(K)
_CASE_DISABLE(I), _CASE_DISABLE(J), _CASE_DISABLE(K),
_CASE_DISABLE(U), _CASE_DISABLE(V), _CASE_DISABLE(W)
);
default: break;
}
@ -550,9 +564,10 @@ bool Stepper::disable_axis(const AxisEnum axis) {
void Stepper::enable_all_steppers() {
TERN_(AUTO_POWER_CONTROL, powerManager.power_on());
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
enable_axis(X_AXIS), enable_axis(Y_AXIS), enable_axis(Z_AXIS),
enable_axis(I_AXIS), enable_axis(J_AXIS), enable_axis(K_AXIS)
enable_axis(I_AXIS), enable_axis(J_AXIS), enable_axis(K_AXIS),
enable_axis(U_AXIS), enable_axis(V_AXIS), enable_axis(W_AXIS)
);
enable_e_steppers();
@ -560,9 +575,10 @@ void Stepper::enable_all_steppers() {
}
void Stepper::disable_all_steppers() {
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
disable_axis(X_AXIS), disable_axis(Y_AXIS), disable_axis(Z_AXIS),
disable_axis(I_AXIS), disable_axis(J_AXIS), disable_axis(K_AXIS)
disable_axis(I_AXIS), disable_axis(J_AXIS), disable_axis(K_AXIS),
disable_axis(U_AXIS), disable_axis(V_AXIS), disable_axis(W_AXIS)
);
disable_e_steppers();
@ -596,6 +612,9 @@ void Stepper::set_directions() {
TERN_(HAS_I_DIR, SET_STEP_DIR(I));
TERN_(HAS_J_DIR, SET_STEP_DIR(J));
TERN_(HAS_K_DIR, SET_STEP_DIR(K));
TERN_(HAS_U_DIR, SET_STEP_DIR(U));
TERN_(HAS_V_DIR, SET_STEP_DIR(V));
TERN_(HAS_W_DIR, SET_STEP_DIR(W));
#if DISABLED(LIN_ADVANCE)
#if ENABLED(MIXING_EXTRUDER)
@ -1816,6 +1835,15 @@ void Stepper::pulse_phase_isr() {
#if HAS_K_STEP
PULSE_PREP(K);
#endif
#if HAS_U_STEP
PULSE_PREP(U);
#endif
#if HAS_V_STEP
PULSE_PREP(V);
#endif
#if HAS_W_STEP
PULSE_PREP(W);
#endif
#if EITHER(LIN_ADVANCE, MIXING_EXTRUDER)
delta_error.e += advance_dividend.e;
@ -1860,6 +1888,15 @@ void Stepper::pulse_phase_isr() {
#if HAS_K_STEP
PULSE_START(K);
#endif
#if HAS_U_STEP
PULSE_START(U);
#endif
#if HAS_V_STEP
PULSE_START(V);
#endif
#if HAS_W_STEP
PULSE_START(W);
#endif
#if DISABLED(LIN_ADVANCE)
#if ENABLED(MIXING_EXTRUDER)
@ -1898,6 +1935,15 @@ void Stepper::pulse_phase_isr() {
#if HAS_K_STEP
PULSE_STOP(K);
#endif
#if HAS_U_STEP
PULSE_STOP(U);
#endif
#if HAS_V_STEP
PULSE_STOP(V);
#endif
#if HAS_W_STEP
PULSE_STOP(W);
#endif
#if DISABLED(LIN_ADVANCE)
#if ENABLED(MIXING_EXTRUDER)
@ -2243,13 +2289,16 @@ uint32_t Stepper::block_phase_isr() {
#endif
axis_bits_t axis_bits = 0;
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
if (X_MOVE_TEST) SBI(axis_bits, A_AXIS),
if (Y_MOVE_TEST) SBI(axis_bits, B_AXIS),
if (Z_MOVE_TEST) SBI(axis_bits, C_AXIS),
if (current_block->steps.i) SBI(axis_bits, I_AXIS),
if (current_block->steps.j) SBI(axis_bits, J_AXIS),
if (current_block->steps.k) SBI(axis_bits, K_AXIS)
if (current_block->steps.k) SBI(axis_bits, K_AXIS),
if (current_block->steps.u) SBI(axis_bits, U_AXIS),
if (current_block->steps.v) SBI(axis_bits, V_AXIS),
if (current_block->steps.w) SBI(axis_bits, W_AXIS)
);
//if (current_block->steps.e) SBI(axis_bits, E_AXIS);
//if (current_block->steps.a) SBI(axis_bits, X_HEAD);
@ -2589,6 +2638,15 @@ void Stepper::init() {
#if HAS_K_DIR
K_DIR_INIT();
#endif
#if HAS_U_DIR
U_DIR_INIT();
#endif
#if HAS_V_DIR
V_DIR_INIT();
#endif
#if HAS_W_DIR
W_DIR_INIT();
#endif
#if HAS_E0_DIR
E0_DIR_INIT();
#endif
@ -2659,6 +2717,18 @@ void Stepper::init() {
K_ENABLE_INIT();
if (!K_ENABLE_ON) K_ENABLE_WRITE(HIGH);
#endif
#if HAS_U_ENABLE
U_ENABLE_INIT();
if (!U_ENABLE_ON) U_ENABLE_WRITE(HIGH);
#endif
#if HAS_V_ENABLE
V_ENABLE_INIT();
if (!V_ENABLE_ON) V_ENABLE_WRITE(HIGH);
#endif
#if HAS_W_ENABLE
W_ENABLE_INIT();
if (!W_ENABLE_ON) W_ENABLE_WRITE(HIGH);
#endif
#if HAS_E0_ENABLE
E0_ENABLE_INIT();
if (!E_ENABLE_ON) E0_ENABLE_WRITE(HIGH);
@ -2744,6 +2814,15 @@ void Stepper::init() {
#if HAS_K_STEP
AXIS_INIT(K, K);
#endif
#if HAS_U_STEP
AXIS_INIT(U, U);
#endif
#if HAS_V_STEP
AXIS_INIT(V, V);
#endif
#if HAS_W_STEP
AXIS_INIT(W, W);
#endif
#if E_STEPPERS && HAS_E0_STEP
E_AXIS_INIT(0);
@ -2778,13 +2857,16 @@ void Stepper::init() {
// Init direction bits for first moves
set_directions(0
LINEAR_AXIS_GANG(
NUM_AXIS_GANG(
| TERN0(INVERT_X_DIR, _BV(X_AXIS)),
| TERN0(INVERT_Y_DIR, _BV(Y_AXIS)),
| TERN0(INVERT_Z_DIR, _BV(Z_AXIS)),
| TERN0(INVERT_I_DIR, _BV(I_AXIS)),
| TERN0(INVERT_J_DIR, _BV(J_AXIS)),
| TERN0(INVERT_K_DIR, _BV(K_AXIS))
| TERN0(INVERT_K_DIR, _BV(K_AXIS)),
| TERN0(INVERT_U_DIR, _BV(U_AXIS)),
| TERN0(INVERT_V_DIR, _BV(V_AXIS)),
| TERN0(INVERT_W_DIR, _BV(W_AXIS))
)
);
@ -2820,6 +2902,14 @@ void Stepper::_set_position(const abce_long_t &spos) {
#elif ENABLED(MARKFORGED_YX)
count_position.set(spos.a, spos.b - spos.a, spos.c);
#endif
SECONDARY_AXIS_CODE(
count_position.i = spos.i,
count_position.j = spos.j,
count_position.k = spos.k,
count_position.u = spos.u,
count_position.v = spos.v,
count_position.w = spos.w
);
TERN_(HAS_EXTRUDERS, count_position.e = spos.e);
#else
// default non-h-bot planning
@ -2934,13 +3024,16 @@ int32_t Stepper::triggered_position(const AxisEnum axis) {
void Stepper::report_a_position(const xyz_long_t &pos) {
SERIAL_ECHOLNPGM_P(
LIST_N(DOUBLE(LINEAR_AXES),
LIST_N(DOUBLE(NUM_AXES),
TERN(SAYS_A, PSTR(STR_COUNT_A), PSTR(STR_COUNT_X)), pos.x,
TERN(SAYS_B, PSTR("B:"), SP_Y_LBL), pos.y,
TERN(SAYS_C, PSTR("C:"), SP_Z_LBL), pos.z,
SP_I_LBL, pos.i,
SP_J_LBL, pos.j,
SP_K_LBL, pos.k
SP_K_LBL, pos.k,
SP_U_LBL, pos.u,
SP_V_LBL, pos.v,
SP_W_LBL, pos.w
)
);
}
@ -3096,16 +3189,18 @@ void Stepper::report_positions() {
const bool z_direction = direction ^ BABYSTEP_INVERT_Z;
LINEAR_AXIS_CODE(
NUM_AXIS_CODE(
enable_axis(X_AXIS), enable_axis(Y_AXIS), enable_axis(Z_AXIS),
enable_axis(I_AXIS), enable_axis(J_AXIS), enable_axis(K_AXIS)
enable_axis(I_AXIS), enable_axis(J_AXIS), enable_axis(K_AXIS),
enable_axis(U_AXIS), enable_axis(V_AXIS), enable_axis(W_AXIS)
);
DIR_WAIT_BEFORE();
const xyz_byte_t old_dir = LINEAR_AXIS_ARRAY(
const xyz_byte_t old_dir = NUM_AXIS_ARRAY(
X_DIR_READ(), Y_DIR_READ(), Z_DIR_READ(),
I_DIR_READ(), J_DIR_READ(), K_DIR_READ()
I_DIR_READ(), J_DIR_READ(), K_DIR_READ(),
U_DIR_READ(), V_DIR_READ(), W_DIR_READ()
);
X_DIR_WRITE(ENABLED(INVERT_X_DIR) ^ z_direction);
@ -3124,6 +3219,15 @@ void Stepper::report_positions() {
#ifdef K_DIR_WRITE
K_DIR_WRITE(ENABLED(INVERT_K_DIR) ^ z_direction);
#endif
#ifdef U_DIR_WRITE
U_DIR_WRITE(ENABLED(INVERT_U_DIR) ^ z_direction);
#endif
#ifdef V_DIR_WRITE
V_DIR_WRITE(ENABLED(INVERT_V_DIR) ^ z_direction);
#endif
#ifdef W_DIR_WRITE
W_DIR_WRITE(ENABLED(INVERT_W_DIR) ^ z_direction);
#endif
DIR_WAIT_AFTER();
@ -3145,6 +3249,15 @@ void Stepper::report_positions() {
#ifdef K_STEP_WRITE
K_STEP_WRITE(!INVERT_K_STEP_PIN);
#endif
#ifdef U_STEP_WRITE
U_STEP_WRITE(!INVERT_U_STEP_PIN);
#endif
#ifdef V_STEP_WRITE
V_STEP_WRITE(!INVERT_V_STEP_PIN);
#endif
#ifdef W_STEP_WRITE
W_STEP_WRITE(!INVERT_W_STEP_PIN);
#endif
_PULSE_WAIT();
@ -3164,6 +3277,15 @@ void Stepper::report_positions() {
#ifdef K_STEP_WRITE
K_STEP_WRITE(INVERT_K_STEP_PIN);
#endif
#ifdef U_STEP_WRITE
U_STEP_WRITE(INVERT_U_STEP_PIN);
#endif
#ifdef V_STEP_WRITE
V_STEP_WRITE(INVERT_V_STEP_PIN);
#endif
#ifdef W_STEP_WRITE
W_STEP_WRITE(INVERT_W_STEP_PIN);
#endif
// Restore direction bits
EXTRA_DIR_WAIT_BEFORE();
@ -3184,6 +3306,15 @@ void Stepper::report_positions() {
#ifdef K_DIR_WRITE
K_DIR_WRITE(old_dir.k);
#endif
#ifdef U_DIR_WRITE
U_DIR_WRITE(old_dir.u);
#endif
#ifdef V_DIR_WRITE
V_DIR_WRITE(old_dir.v);
#endif
#ifdef W_DIR_WRITE
W_DIR_WRITE(old_dir.w);
#endif
EXTRA_DIR_WAIT_AFTER();
@ -3200,6 +3331,15 @@ void Stepper::report_positions() {
#if HAS_K_AXIS
case K_AXIS: BABYSTEP_AXIS(K, 0, direction); break;
#endif
#if HAS_U_AXIS
case U_AXIS: BABYSTEP_AXIS(U, 0, direction); break;
#endif
#if HAS_V_AXIS
case V_AXIS: BABYSTEP_AXIS(V, 0, direction); break;
#endif
#if HAS_W_AXIS
case W_AXIS: BABYSTEP_AXIS(W, 0, direction); break;
#endif
default: break;
}
@ -3428,6 +3568,24 @@ void Stepper::report_positions() {
SET_OUTPUT(K_MS3_PIN);
#endif
#endif
#if HAS_U_MS_PINS
SET_OUTPUT(U_MS1_PIN); SET_OUTPUT(U_MS2_PIN);
#if PIN_EXISTS(U_MS3)
SET_OUTPUT(U_MS3_PIN);
#endif
#endif
#if HAS_V_MS_PINS
SET_OUTPUT(V_MS1_PIN); SET_OUTPUT(V_MS2_PIN);
#if PIN_EXISTS(V_MS3)
SET_OUTPUT(V_MS3_PIN);
#endif
#endif
#if HAS_W_MS_PINS
SET_OUTPUT(W_MS1_PIN); SET_OUTPUT(W_MS2_PIN);
#if PIN_EXISTS(W_MS3)
SET_OUTPUT(W_MS3_PIN);
#endif
#endif
#if HAS_E0_MS_PINS
SET_OUTPUT(E0_MS1_PIN); SET_OUTPUT(E0_MS2_PIN);
#if PIN_EXISTS(E0_MS3)
@ -3553,6 +3711,15 @@ void Stepper::report_positions() {
#if HAS_K_MS_PINS
case 13: WRITE(K_MS1_PIN, ms1); break
#endif
#if HAS_U_MS_PINS
case 14: WRITE(U_MS1_PIN, ms1); break
#endif
#if HAS_V_MS_PINS
case 15: WRITE(V_MS1_PIN, ms1); break
#endif
#if HAS_W_MS_PINS
case 16: WRITE(W_MS1_PIN, ms1); break
#endif
}
if (ms2 >= 0) switch (driver) {
#if HAS_X_MS_PINS || HAS_X2_MS_PINS
@ -3624,6 +3791,15 @@ void Stepper::report_positions() {
#if HAS_K_MS_PINS
case 13: WRITE(K_MS2_PIN, ms2); break
#endif
#if HAS_U_MS_PINS
case 14: WRITE(U_MS2_PIN, ms2); break
#endif
#if HAS_V_MS_PINS
case 15: WRITE(V_MS2_PIN, ms2); break
#endif
#if HAS_W_MS_PINS
case 16: WRITE(W_MS2_PIN, ms2); break
#endif
}
if (ms3 >= 0) switch (driver) {
#if HAS_X_MS_PINS || HAS_X2_MS_PINS
@ -3760,6 +3936,24 @@ void Stepper::report_positions() {
PIN_CHAR(K_MS3);
#endif
#endif
#if HAS_U_MS_PINS
MS_LINE(U);
#if PIN_EXISTS(U_MS3)
PIN_CHAR(U_MS3);
#endif
#endif
#if HAS_V_MS_PINS
MS_LINE(V);
#if PIN_EXISTS(V_MS3)
PIN_CHAR(V_MS3);
#endif
#endif
#if HAS_W_MS_PINS
MS_LINE(W);
#if PIN_EXISTS(W_MS3)
PIN_CHAR(W_MS3);
#endif
#endif
#if HAS_E0_MS_PINS
MS_LINE(E0);
#if PIN_EXISTS(E0_MS3)

View File

@ -159,12 +159,21 @@
#if HAS_K_STEP
#define ISR_K_STEPPER_CYCLES ISR_STEPPER_CYCLES
#endif
#if HAS_U_STEP
#define ISR_U_STEPPER_CYCLES ISR_STEPPER_CYCLES
#endif
#if HAS_V_STEP
#define ISR_V_STEPPER_CYCLES ISR_STEPPER_CYCLES
#endif
#if HAS_W_STEP
#define ISR_W_STEPPER_CYCLES ISR_STEPPER_CYCLES
#endif
#if HAS_EXTRUDERS
#define ISR_E_STEPPER_CYCLES ISR_STEPPER_CYCLES // E is always interpolated, even for mixing extruders
#endif
// And the total minimum loop time, not including the base
#define MIN_ISR_LOOP_CYCLES (ISR_MIXING_STEPPER_CYCLES LOGICAL_AXIS_GANG(+ ISR_E_STEPPER_CYCLES, + ISR_X_STEPPER_CYCLES, + ISR_Y_STEPPER_CYCLES, + ISR_Z_STEPPER_CYCLES, + ISR_I_STEPPER_CYCLES, + ISR_J_STEPPER_CYCLES, + ISR_K_STEPPER_CYCLES))
#define MIN_ISR_LOOP_CYCLES (ISR_MIXING_STEPPER_CYCLES LOGICAL_AXIS_GANG(+ ISR_E_STEPPER_CYCLES, + ISR_X_STEPPER_CYCLES, + ISR_Y_STEPPER_CYCLES, + ISR_Z_STEPPER_CYCLES, + ISR_I_STEPPER_CYCLES, + ISR_J_STEPPER_CYCLES, + ISR_K_STEPPER_CYCLES, + ISR_U_STEPPER_CYCLES, + ISR_V_STEPPER_CYCLES, + ISR_W_STEPPER_CYCLES))
// Calculate the minimum MPU cycles needed per pulse to enforce, limited to the max stepper rate
#define _MIN_STEPPER_PULSE_CYCLES(N) _MAX(uint32_t((F_CPU) / (MAXIMUM_STEPPER_RATE)), ((F_CPU) / 500000UL) * (N))
@ -236,7 +245,7 @@
// Perhaps DISABLE_MULTI_STEPPING should be required with ADAPTIVE_STEP_SMOOTHING.
#define MIN_STEP_ISR_FREQUENCY (MAX_STEP_ISR_FREQUENCY_1X / 2)
#define ENABLE_COUNT (LINEAR_AXES + E_STEPPERS)
#define ENABLE_COUNT (NUM_AXES + E_STEPPERS)
typedef IF<(ENABLE_COUNT > 8), uint16_t, uint8_t>::type ena_mask_t;
// Axis flags type, for enabled state or other simple state
@ -244,25 +253,25 @@ typedef struct {
union {
ena_mask_t bits;
struct {
bool LINEAR_AXIS_LIST(X:1, Y:1, Z:1, I:1, J:1, K:1);
bool NUM_AXIS_LIST(X:1, Y:1, Z:1, I:1, J:1, K:1, U:1, V:1, W:1);
#if HAS_EXTRUDERS
bool LIST_N(EXTRUDERS, E0:1, E1:1, E2:1, E3:1, E4:1, E5:1, E6:1, E7:1);
#endif
};
};
constexpr ena_mask_t linear_bits() { return _BV(LINEAR_AXES) - 1; }
constexpr ena_mask_t e_bits() { return (_BV(EXTRUDERS) - 1) << LINEAR_AXES; }
constexpr ena_mask_t linear_bits() { return _BV(NUM_AXES) - 1; }
constexpr ena_mask_t e_bits() { return (_BV(EXTRUDERS) - 1) << NUM_AXES; }
} stepper_flags_t;
// All the stepper enable pins
constexpr pin_t ena_pins[] = {
LINEAR_AXIS_LIST(X_ENABLE_PIN, Y_ENABLE_PIN, Z_ENABLE_PIN, I_ENABLE_PIN, J_ENABLE_PIN, K_ENABLE_PIN),
NUM_AXIS_LIST(X_ENABLE_PIN, Y_ENABLE_PIN, Z_ENABLE_PIN, I_ENABLE_PIN, J_ENABLE_PIN, K_ENABLE_PIN, U_ENABLE_PIN, V_ENABLE_PIN, W_ENABLE_PIN),
LIST_N(E_STEPPERS, E0_ENABLE_PIN, E1_ENABLE_PIN, E2_ENABLE_PIN, E3_ENABLE_PIN, E4_ENABLE_PIN, E5_ENABLE_PIN, E6_ENABLE_PIN, E7_ENABLE_PIN)
};
// Index of the axis or extruder element in a combined array
constexpr uint8_t index_of_axis(const AxisEnum axis E_OPTARG(const uint8_t eindex=0)) {
return uint8_t(axis) + (E_TERN0(axis < LINEAR_AXES ? 0 : eindex));
return uint8_t(axis) + (E_TERN0(axis < NUM_AXES ? 0 : eindex));
}
//#define __IAX_N(N,V...) _IAX_##N(V)
//#define _IAX_N(N,V...) __IAX_N(N,V)
@ -292,7 +301,7 @@ constexpr bool any_enable_overlap(const uint8_t a=0) {
// (e.g., CoreXY, Dual XYZ, or E with multiple steppers, etc.).
constexpr ena_mask_t enable_overlap[] = {
#define _OVERLAP(N) ena_overlap(INDEX_OF_AXIS(AxisEnum(N))),
REPEAT(LINEAR_AXES, _OVERLAP)
REPEAT(NUM_AXES, _OVERLAP)
#if HAS_EXTRUDERS
#define _E_OVERLAP(N) ena_overlap(INDEX_OF_AXIS(E_AXIS, N)),
REPEAT(E_STEPPERS, _E_OVERLAP)
@ -320,7 +329,7 @@ class Stepper {
#ifndef MOTOR_CURRENT_PWM_FREQUENCY
#define MOTOR_CURRENT_PWM_FREQUENCY 31400
#endif
#define MOTOR_CURRENT_COUNT LINEAR_AXES
#define MOTOR_CURRENT_COUNT NUM_AXES
#elif HAS_MOTOR_CURRENT_SPI
static constexpr uint32_t digipot_count[] = DIGIPOT_MOTOR_CURRENT;
#define MOTOR_CURRENT_COUNT COUNT(Stepper::digipot_count)

View File

@ -64,6 +64,15 @@
#if AXIS_IS_L64XX(K)
L64XX_CLASS(K) stepperK(L6470_CHAIN_SS_PIN);
#endif
#if AXIS_IS_L64XX(U)
L64XX_CLASS(u) stepperU(L6470_CHAIN_SS_PIN);
#endif
#if AXIS_IS_L64XX(V)
L64XX_CLASS(v) stepperV(L6470_CHAIN_SS_PIN);
#endif
#if AXIS_IS_L64XX(W)
L64XX_CLASS(w) stepperW(L6470_CHAIN_SS_PIN);
#endif
#if AXIS_IS_L64XX(E0)
L64XX_CLASS(E0) stepperE0(L6470_CHAIN_SS_PIN);
#endif
@ -217,6 +226,15 @@ void L64XX_Marlin::init_to_defaults() {
#if AXIS_IS_L64XX(K)
L6470_INIT_CHIP(K);
#endif
#if AXIS_IS_L64XX(U)
L6470_INIT_CHIP(U);
#endif
#if AXIS_IS_L64XX(V)
L6470_INIT_CHIP(V);
#endif
#if AXIS_IS_L64XX(W)
L6470_INIT_CHIP(W);
#endif
#if AXIS_IS_L64XX(E0)
L6470_INIT_CHIP(E0);
#endif

View File

@ -266,6 +266,72 @@
#endif
#endif
// U Stepper
#if HAS_U_AXIS
#if AXIS_IS_L64XX(U)
extern L64XX_CLASS(U) stepperU;
#define U_ENABLE_INIT() NOOP
#define U_ENABLE_WRITE(STATE) (STATE ? stepperU.hardStop() : stepperU.free())
#define U_ENABLE_READ() (stepperU.getStatus() & STATUS_HIZ)
#if AXIS_DRIVER_TYPE_U(L6474)
#define U_DIR_INIT() SET_OUTPUT(U_DIR_PIN)
#define U_DIR_WRITE(STATE) L6474_DIR_WRITE(U, STATE)
#define U_DIR_READ() READ(U_DIR_PIN)
#else
#define U_DIR_INIT() NOOP
#define U_DIR_WRITE(STATE) L64XX_DIR_WRITE(U, STATE)
#define U_DIR_READ() (stepper##U.getStatus() & STATUS_DIR);
#if AXIS_DRIVER_TYPE_U(L6470)
#define DISABLE_STEPPER_U() stepperU.free()
#endif
#endif
#endif
#endif
// V Stepper
#if HAS_V_AXIS
#if AXIS_IS_L64XX(V)
extern L64XX_CLASS(V) stepperV;
#define V_ENABLE_INIT() NOOP
#define V_ENABLE_WRITE(STATE) (STATE ? stepperV.hardStop() : stepperV.free())
#define V_ENABLE_READ() (stepperV.getStatus() & STATUS_HIZ)
#if AXIS_DRIVER_TYPE_V(L6474)
#define V_DIR_INIT() SET_OUTPUT(V_DIR_PIN)
#define V_DIR_WRITE(STATE) L6474_DIR_WRITE(V, STATE)
#define V_DIR_READ() READ(V_DIR_PIN)
#else
#define V_DIR_INIT() NOOP
#define V_DIR_WRITE(STATE) L64XX_DIR_WRITE(V, STATE)
#define V_DIR_READ() (stepper##V.getStatus() & STATUS_DIR);
#if AXIS_DRIVER_TYPE_V(L6470)
#define DISABLE_STEPPER_V() stepperV.free()
#endif
#endif
#endif
#endif
// W Stepper
#if HAS_W_AXIS
#if AXIS_IS_L64XX(W)
extern L64XX_CLASS(w) stepperW;
#define W_ENABLE_INIT() NOOP
#define W_ENABLE_WRITE(STATE) (STATE ? stepperW.hardStop() : stepperW.free())
#define W_ENABLE_READ() (stepperW.getStatus() & STATUS_HIZ)
#if AXIS_DRIVER_TYPE_W(L6474)
#define W_DIR_INIT() SET_OUTPUT(W_DIR_PIN)
#define W_DIR_WRITE(STATE) L6474_DIR_WRITE(W, STATE)
#define W_DIR_READ() READ(W_DIR_PIN)
#else
#define W_DIR_INIT() NOOP
#define W_DIR_WRITE(STATE) L64XX_DIR_WRITE(W, STATE)
#define W_DIR_READ() (stepper##W.getStatus() & STATUS_DIR);
#if AXIS_DRIVER_TYPE_W(L6470)
#define DISABLE_STEPPER_W() stepperW.free()
#endif
#endif
#endif
#endif
// E0 Stepper
#if AXIS_IS_L64XX(E0)
extern L64XX_CLASS(E0) stepperE0;

View File

@ -69,6 +69,15 @@
#if AXIS_DRIVER_TYPE_K(TMC26X)
_TMC26X_DEFINE(K);
#endif
#if AXIS_DRIVER_TYPE_U(TMC26X)
_TMC26X_DEFINE(U);
#endif
#if AXIS_DRIVER_TYPE_V(TMC26X)
_TMC26X_DEFINE(V);
#endif
#if AXIS_DRIVER_TYPE_W(TMC26X)
_TMC26X_DEFINE(W);
#endif
#if AXIS_DRIVER_TYPE_E0(TMC26X)
_TMC26X_DEFINE(E0);
#endif
@ -133,6 +142,15 @@ void tmc26x_init_to_defaults() {
#if AXIS_DRIVER_TYPE_K(TMC26X)
_TMC26X_INIT(K);
#endif
#if AXIS_DRIVER_TYPE_U(TMC26X)
_TMC26X_INIT(U);
#endif
#if AXIS_DRIVER_TYPE_V(TMC26X)
_TMC26X_INIT(V);
#endif
#if AXIS_DRIVER_TYPE_W(TMC26X)
_TMC26X_INIT(W);
#endif
#if AXIS_DRIVER_TYPE_E0(TMC26X)
_TMC26X_INIT(E0);
#endif

View File

@ -123,6 +123,30 @@ void tmc26x_init_to_defaults();
#define K_ENABLE_READ() stepperK.isEnabled()
#endif
// U Stepper
#if HAS_U_ENABLE && AXIS_DRIVER_TYPE_U(TMC26X)
extern TMC26XStepper stepperU;
#define U_ENABLE_INIT() NOOP
#define U_ENABLE_WRITE(STATE) stepperU.setEnabled(STATE)
#define U_ENABLE_READ() stepperU.isEnabled()
#endif
// V Stepper
#if HAS_V_ENABLE && AXIS_DRIVER_TYPE_V(TMC26X)
extern TMC26XStepper stepperV;
#define V_ENABLE_INIT() NOOP
#define V_ENABLE_WRITE(STATE) stepperV.setEnabled(STATE)
#define V_ENABLE_READ() stepperV.isEnabled()
#endif
// W Stepper
#if HAS_W_ENABLE && AXIS_DRIVER_TYPE_W(TMC26X)
extern TMC26XStepper stepperW;
#define W_ENABLE_INIT() NOOP
#define W_ENABLE_WRITE(STATE) stepperW.setEnabled(STATE)
#define W_ENABLE_READ() stepperW.isEnabled()
#endif
// E0 Stepper
#if AXIS_DRIVER_TYPE_E0(TMC26X)
extern TMC26XStepper stepperE0;

View File

@ -262,6 +262,63 @@ void reset_stepper_drivers(); // Called by settings.load / settings.reset
#define K_STEP_READ() bool(READ(K_STEP_PIN))
#endif
// U Stepper
#if HAS_U_AXIS
#ifndef U_ENABLE_INIT
#define U_ENABLE_INIT() SET_OUTPUT(U_ENABLE_PIN)
#define U_ENABLE_WRITE(STATE) WRITE(U_ENABLE_PIN,STATE)
#define U_ENABLE_READ() bool(READ(U_ENABLE_PIN))
#endif
#ifndef U_DIR_INIT
#define U_DIR_INIT() SET_OUTPUT(U_DIR_PIN)
#define U_DIR_WRITE(STATE) WRITE(U_DIR_PIN,STATE)
#define U_DIR_READ() bool(READ(U_DIR_PIN))
#endif
#define U_STEP_INIT() SET_OUTPUT(U_STEP_PIN)
#ifndef U_STEP_WRITE
#define U_STEP_WRITE(STATE) WRITE(U_STEP_PIN,STATE)
#endif
#define U_STEP_READ() bool(READ(U_STEP_PIN))
#endif
// V Stepper
#if HAS_V_AXIS
#ifndef V_ENABLE_INIT
#define V_ENABLE_INIT() SET_OUTPUT(V_ENABLE_PIN)
#define V_ENABLE_WRITE(STATE) WRITE(V_ENABLE_PIN,STATE)
#define V_ENABLE_READ() bool(READ(V_ENABLE_PIN))
#endif
#ifndef V_DIR_INIT
#define V_DIR_INIT() SET_OUTPUT(V_DIR_PIN)
#define V_DIR_WRITE(STATE) WRITE(V_DIR_PIN,STATE)
#define V_DIR_READ() bool(READ(V_DIR_PIN))
#endif
#define V_STEP_INIT() SET_OUTPUT(V_STEP_PIN)
#ifndef V_STEP_WRITE
#define V_STEP_WRITE(STATE) WRITE(V_STEP_PIN,STATE)
#endif
#define V_STEP_READ() bool(READ(V_STEP_PIN))
#endif
// W Stepper
#if HAS_W_AXIS
#ifndef W_ENABLE_INIT
#define W_ENABLE_INIT() SET_OUTPUT(W_ENABLE_PIN)
#define W_ENABLE_WRITE(STATE) WRITE(W_ENABLE_PIN,STATE)
#define W_ENABLE_READ() bool(READ(W_ENABLE_PIN))
#endif
#ifndef W_DIR_INIT
#define W_DIR_INIT() SET_OUTPUT(W_DIR_PIN)
#define W_DIR_WRITE(STATE) WRITE(W_DIR_PIN,STATE)
#define W_DIR_READ() bool(READ(W_DIR_PIN))
#endif
#define W_STEP_INIT() SET_OUTPUT(W_STEP_PIN)
#ifndef W_STEP_WRITE
#define W_STEP_WRITE(STATE) WRITE(W_STEP_PIN,STATE)
#endif
#define W_STEP_READ() bool(READ(W_STEP_PIN))
#endif
// E0 Stepper
#ifndef E0_ENABLE_INIT
#define E0_ENABLE_INIT() SET_OUTPUT(E0_ENABLE_PIN)
@ -743,6 +800,51 @@ void reset_stepper_drivers(); // Called by settings.load / settings.reset
#define DISABLE_STEPPER_K() TERN(HAS_K_ENABLE, K_ENABLE_WRITE(!K_ENABLE_ON), NOOP)
#endif
#ifndef ENABLE_STEPPER_U
#if HAS_U_ENABLE
#define ENABLE_STEPPER_U() U_ENABLE_WRITE( U_ENABLE_ON)
#else
#define ENABLE_STEPPER_U() NOOP
#endif
#endif
#ifndef DISABLE_STEPPER_U
#if HAS_U_ENABLE
#define DISABLE_STEPPER_U() U_ENABLE_WRITE(!U_ENABLE_ON)
#else
#define DISABLE_STEPPER_U() NOOP
#endif
#endif
#ifndef ENABLE_STEPPER_V
#if HAS_V_ENABLE
#define ENABLE_STEPPER_V() V_ENABLE_WRITE( V_ENABLE_ON)
#else
#define ENABLE_STEPPER_V() NOOP
#endif
#endif
#ifndef DISABLE_STEPPER_V
#if HAS_V_ENABLE
#define DISABLE_STEPPER_V() V_ENABLE_WRITE(!V_ENABLE_ON)
#else
#define DISABLE_STEPPER_V() NOOP
#endif
#endif
#ifndef ENABLE_STEPPER_W
#if HAS_W_ENABLE
#define ENABLE_STEPPER_W() W_ENABLE_WRITE( W_ENABLE_ON)
#else
#define ENABLE_STEPPER_W() NOOP
#endif
#endif
#ifndef DISABLE_STEPPER_W
#if HAS_W_ENABLE
#define DISABLE_STEPPER_W() W_ENABLE_WRITE(!W_ENABLE_ON)
#else
#define DISABLE_STEPPER_W() NOOP
#endif
#endif
#ifndef ENABLE_STEPPER_E0
#define ENABLE_STEPPER_E0() TERN(HAS_E0_ENABLE, E0_ENABLE_WRITE( E_ENABLE_ON), NOOP)
#endif
@ -917,6 +1019,28 @@ void reset_stepper_drivers(); // Called by settings.load / settings.reset
#define DISABLE_AXIS_K() NOOP
#endif
#if HAS_U_AXIS
#define ENABLE_AXIS_U() if (SHOULD_ENABLE(u)) { ENABLE_STEPPER_U(); AFTER_CHANGE(u, true); }
#define DISABLE_AXIS_U() if (SHOULD_DISABLE(u)) { DISABLE_STEPPER_U(); AFTER_CHANGE(u, false); set_axis_untrusted(U_AXIS); }
#else
#define ENABLE_AXIS_U() NOOP
#define DISABLE_AXIS_U() NOOP
#endif
#if HAS_V_AXIS
#define ENABLE_AXIS_V() if (SHOULD_ENABLE(v)) { ENABLE_STEPPER_V(); AFTER_CHANGE(v, true); }
#define DISABLE_AXIS_V() if (SHOULD_DISABLE(v)) { DISABLE_STEPPER_V(); AFTER_CHANGE(v, false); set_axis_untrusted(V_AXIS); }
#else
#define ENABLE_AXIS_V() NOOP
#define DISABLE_AXIS_V() NOOP
#endif
#if HAS_W_AXIS
#define ENABLE_AXIS_W() if (SHOULD_ENABLE(w)) { ENABLE_STEPPER_W(); AFTER_CHANGE(w, true); }
#define DISABLE_AXIS_W() if (SHOULD_DISABLE(w)) { DISABLE_STEPPER_W(); AFTER_CHANGE(w, false); set_axis_untrusted(W_AXIS); }
#else
#define ENABLE_AXIS_W() NOOP
#define DISABLE_AXIS_W() NOOP
#endif
//
// Extruder steppers enable / disable macros
//

View File

@ -36,7 +36,7 @@
#include <SPI.h>
enum StealthIndex : uint8_t {
LOGICAL_AXIS_LIST(STEALTH_AXIS_E, STEALTH_AXIS_X, STEALTH_AXIS_Y, STEALTH_AXIS_Z, STEALTH_AXIS_I, STEALTH_AXIS_J, STEALTH_AXIS_K)
LOGICAL_AXIS_LIST(STEALTH_AXIS_E, STEALTH_AXIS_X, STEALTH_AXIS_Y, STEALTH_AXIS_Z, STEALTH_AXIS_I, STEALTH_AXIS_J, STEALTH_AXIS_K, STEALTH_AXIS_U, STEALTH_AXIS_V, STEALTH_AXIS_W)
};
#define TMC_INIT(ST, STEALTH_INDEX) tmc_init(stepper##ST, ST##_CURRENT, ST##_MICROSTEPS, ST##_HYBRID_THRESHOLD, stealthchop_by_axis[STEALTH_INDEX], chopper_timing_##ST, ST##_INTERPOLATE, ST##_HOLD_MULTIPLIER)
@ -106,6 +106,15 @@ enum StealthIndex : uint8_t {
#if AXIS_HAS_SPI(K)
TMC_SPI_DEFINE(K, K);
#endif
#if AXIS_HAS_SPI(U)
TMC_SPI_DEFINE(U, U);
#endif
#if AXIS_HAS_SPI(V)
TMC_SPI_DEFINE(V, V);
#endif
#if AXIS_HAS_SPI(W)
TMC_SPI_DEFINE(W, W);
#endif
#if AXIS_HAS_SPI(E0)
TMC_SPI_DEFINE_E(0);
#endif
@ -173,6 +182,15 @@ enum StealthIndex : uint8_t {
#ifndef TMC_K_BAUD_RATE
#define TMC_K_BAUD_RATE TMC_BAUD_RATE
#endif
#ifndef TMC_U_BAUD_RATE
#define TMC_U_BAUD_RATE TMC_BAUD_RATE
#endif
#ifndef TMC_V_BAUD_RATE
#define TMC_V_BAUD_RATE TMC_BAUD_RATE
#endif
#ifndef TMC_W_BAUD_RATE
#define TMC_W_BAUD_RATE TMC_BAUD_RATE
#endif
#ifndef TMC_E0_BAUD_RATE
#define TMC_E0_BAUD_RATE TMC_BAUD_RATE
#endif
@ -374,6 +392,32 @@ enum StealthIndex : uint8_t {
#define K_HAS_SW_SERIAL 1
#endif
#endif
#if AXIS_HAS_UART(U)
#ifdef U_HARDWARE_SERIAL
TMC_UART_DEFINE(HW, U, U);
#define U_HAS_HW_SERIAL 1
#else
TMC_UART_DEFINE(SW, U, U);
#define U_HAS_SW_SERIAL 1
#endif
#endif
#if AXIS_HAS_UART(V)
#ifdef V_HARDWARE_SERIAL
TMC_UART_DEFINE(HW, V, V);
#else
TMC_UART_DEFINE(SW, V, V);
#define V_HAS_SW_SERIAL 1
#endif
#endif
#if AXIS_HAS_UART(W)
#ifdef W_HARDWARE_SERIAL
TMC_UART_DEFINE(HW, W, W);
#define W_HAS_HW_SERIAL 1
#else
TMC_UART_DEFINE(SW, W, W);
#define W_HAS_SW_SERIAL 1
#endif
#endif
#if AXIS_HAS_UART(E0)
#ifdef E0_HARDWARE_SERIAL
@ -449,7 +493,7 @@ enum StealthIndex : uint8_t {
#endif
#define _EN_ITEM(N) , E##N
enum TMCAxis : uint8_t { LINEAR_AXIS_LIST(X, Y, Z, I, J, K), X2, Y2, Z2, Z3, Z4 REPEAT(EXTRUDERS, _EN_ITEM), TOTAL };
enum TMCAxis : uint8_t { NUM_AXIS_LIST(X, Y, Z, I, J, K, U, V, W), X2, Y2, Z2, Z3, Z4 REPEAT(EXTRUDERS, _EN_ITEM), TOTAL };
#undef _EN_ITEM
void tmc_serial_begin() {
@ -543,6 +587,27 @@ enum StealthIndex : uint8_t {
stepperK.beginSerial(TMC_BAUD_RATE);
#endif
#endif
#if AXIS_HAS_UART(U)
#ifdef U_HARDWARE_SERIAL
HW_SERIAL_BEGIN(U);
#else
stepperU.beginSerial(TMC_BAUD_RATE);
#endif
#endif
#if AXIS_HAS_UART(V)
#ifdef V_HARDWARE_SERIAL
HW_SERIAL_BEGIN(V);
#else
stepperV.beginSerial(TMC_BAUD_RATE);
#endif
#endif
#if AXIS_HAS_UART(W)
#ifdef W_HARDWARE_SERIAL
HW_SERIAL_BEGIN(W);
#else
stepperW.beginSerial(TMC_BAUD_RATE);
#endif
#endif
#if AXIS_HAS_UART(E0)
#ifdef E0_HARDWARE_SERIAL
HW_SERIAL_BEGIN(E0);
@ -814,6 +879,15 @@ void restore_trinamic_drivers() {
#if AXIS_IS_TMC(K)
stepperK.push();
#endif
#if AXIS_IS_TMC(U)
stepperU.push();
#endif
#if AXIS_IS_TMC(V)
stepperV.push();
#endif
#if AXIS_IS_TMC(W)
stepperW.push();
#endif
#if AXIS_IS_TMC(E0)
stepperE0.push();
#endif
@ -844,7 +918,8 @@ void reset_trinamic_drivers() {
static constexpr bool stealthchop_by_axis[] = LOGICAL_AXIS_ARRAY(
ENABLED(STEALTHCHOP_E),
ENABLED(STEALTHCHOP_XY), ENABLED(STEALTHCHOP_XY), ENABLED(STEALTHCHOP_Z),
ENABLED(STEALTHCHOP_I), ENABLED(STEALTHCHOP_J), ENABLED(STEALTHCHOP_K)
ENABLED(STEALTHCHOP_I), ENABLED(STEALTHCHOP_J), ENABLED(STEALTHCHOP_K),
ENABLED(STEALTHCHOP_U), ENABLED(STEALTHCHOP_V), ENABLED(STEALTHCHOP_W)
);
#if AXIS_IS_TMC(X)
@ -880,6 +955,15 @@ void reset_trinamic_drivers() {
#if AXIS_IS_TMC(K)
TMC_INIT(K, STEALTH_AXIS_K);
#endif
#if AXIS_IS_TMC(U)
TMC_INIT(U, STEALTH_AXIS_U);
#endif
#if AXIS_IS_TMC(V)
TMC_INIT(V, STEALTH_AXIS_V);
#endif
#if AXIS_IS_TMC(W)
TMC_INIT(W, STEALTH_AXIS_W);
#endif
#if AXIS_IS_TMC(E0)
TMC_INIT(E0, STEALTH_AXIS_E);
#endif
@ -917,6 +1001,9 @@ void reset_trinamic_drivers() {
TERN_(I_SENSORLESS, stepperI.homing_threshold(I_STALL_SENSITIVITY));
TERN_(J_SENSORLESS, stepperJ.homing_threshold(J_STALL_SENSITIVITY));
TERN_(K_SENSORLESS, stepperK.homing_threshold(K_STALL_SENSITIVITY));
TERN_(U_SENSORLESS, stepperU.homing_threshold(U_STALL_SENSITIVITY));
TERN_(V_SENSORLESS, stepperV.homing_threshold(V_STALL_SENSITIVITY));
TERN_(W_SENSORLESS, stepperW.homing_threshold(W_STALL_SENSITIVITY));
#endif
#ifdef TMC_ADV
@ -946,7 +1033,7 @@ void reset_trinamic_drivers() {
TMC_HW_DETAIL(X), TMC_HW_DETAIL(X2),
TMC_HW_DETAIL(Y), TMC_HW_DETAIL(Y2),
TMC_HW_DETAIL(Z), TMC_HW_DETAIL(Z2), TMC_HW_DETAIL(Z3), TMC_HW_DETAIL(Z4),
TMC_HW_DETAIL(I), TMC_HW_DETAIL(J), TMC_HW_DETAIL(K),
TMC_HW_DETAIL(I), TMC_HW_DETAIL(J), TMC_HW_DETAIL(K), TMC_HW_DETAIL(U), TMC_HW_DETAIL(V), TMC_HW_DETAIL(W),
TMC_HW_DETAIL(E0), TMC_HW_DETAIL(E1), TMC_HW_DETAIL(E2), TMC_HW_DETAIL(E3), TMC_HW_DETAIL(E4), TMC_HW_DETAIL(E5), TMC_HW_DETAIL(E6), TMC_HW_DETAIL(E7)
};
@ -969,7 +1056,7 @@ void reset_trinamic_drivers() {
SA_NO_TMC_HW_C(X); SA_NO_TMC_HW_C(X2);
SA_NO_TMC_HW_C(Y); SA_NO_TMC_HW_C(Y2);
SA_NO_TMC_HW_C(Z); SA_NO_TMC_HW_C(Z2); SA_NO_TMC_HW_C(Z3); SA_NO_TMC_HW_C(Z4);
SA_NO_TMC_HW_C(I); SA_NO_TMC_HW_C(J); SA_NO_TMC_HW_C(K);
SA_NO_TMC_HW_C(I); SA_NO_TMC_HW_C(J); SA_NO_TMC_HW_C(K); SA_NO_TMC_HW_C(U); SA_NO_TMC_HW_C(V); SA_NO_TMC_HW_C(W);
SA_NO_TMC_HW_C(E0); SA_NO_TMC_HW_C(E1); SA_NO_TMC_HW_C(E2); SA_NO_TMC_HW_C(E3); SA_NO_TMC_HW_C(E4); SA_NO_TMC_HW_C(E5); SA_NO_TMC_HW_C(E6); SA_NO_TMC_HW_C(E7);
#endif
@ -981,7 +1068,7 @@ void reset_trinamic_drivers() {
TMC_SW_DETAIL(X), TMC_SW_DETAIL(X2),
TMC_SW_DETAIL(Y), TMC_SW_DETAIL(Y2),
TMC_SW_DETAIL(Z), TMC_SW_DETAIL(Z2), TMC_SW_DETAIL(Z3), TMC_SW_DETAIL(Z4),
TMC_SW_DETAIL(I), TMC_SW_DETAIL(J), TMC_SW_DETAIL(K),
TMC_SW_DETAIL(I), TMC_SW_DETAIL(J), TMC_SW_DETAIL(K), TMC_SW_DETAIL(U), TMC_SW_DETAIL(V), TMC_SW_DETAIL(W),
TMC_SW_DETAIL(E0), TMC_SW_DETAIL(E1), TMC_SW_DETAIL(E2), TMC_SW_DETAIL(E3), TMC_SW_DETAIL(E4), TMC_SW_DETAIL(E5), TMC_SW_DETAIL(E6), TMC_SW_DETAIL(E7)
};
@ -999,7 +1086,7 @@ void reset_trinamic_drivers() {
SA_NO_TMC_SW_C(X); SA_NO_TMC_SW_C(X2);
SA_NO_TMC_SW_C(Y); SA_NO_TMC_SW_C(Y2);
SA_NO_TMC_SW_C(Z); SA_NO_TMC_SW_C(Z2); SA_NO_TMC_SW_C(Z3); SA_NO_TMC_SW_C(Z4);
SA_NO_TMC_SW_C(I); SA_NO_TMC_SW_C(J); SA_NO_TMC_SW_C(K);
SA_NO_TMC_SW_C(I); SA_NO_TMC_SW_C(J); SA_NO_TMC_SW_C(K); SA_NO_TMC_SW_C(U); SA_NO_TMC_SW_C(V); SA_NO_TMC_SW_C(W);
SA_NO_TMC_SW_C(E0); SA_NO_TMC_SW_C(E1); SA_NO_TMC_SW_C(E2); SA_NO_TMC_SW_C(E3); SA_NO_TMC_SW_C(E4); SA_NO_TMC_SW_C(E5); SA_NO_TMC_SW_C(E6); SA_NO_TMC_SW_C(E7);
#endif

View File

@ -49,6 +49,9 @@
#define TMC_I_LABEL 'I', '0'
#define TMC_J_LABEL 'J', '0'
#define TMC_K_LABEL 'K', '0'
#define TMC_U_LABEL 'U', '0'
#define TMC_V_LABEL 'V', '0'
#define TMC_W_LABEL 'W', '0'
#define TMC_X2_LABEL 'X', '2'
#define TMC_Y2_LABEL 'Y', '2'
@ -92,6 +95,15 @@
#if HAS_K_AXIS && !defined(CHOPPER_TIMING_K)
#define CHOPPER_TIMING_K CHOPPER_TIMING
#endif
#if HAS_U_AXIS && !defined(CHOPPER_TIMING_U)
#define CHOPPER_TIMING_U CHOPPER_TIMING
#endif
#if HAS_V_AXIS && !defined(CHOPPER_TIMING_V)
#define CHOPPER_TIMING_V CHOPPER_TIMING
#endif
#if HAS_W_AXIS && !defined(CHOPPER_TIMING_W)
#define CHOPPER_TIMING_W CHOPPER_TIMING
#endif
#if HAS_EXTRUDERS && !defined(CHOPPER_TIMING_E)
#define CHOPPER_TIMING_E CHOPPER_TIMING
#endif
@ -274,6 +286,48 @@ void reset_trinamic_drivers();
#endif
#endif
// U Stepper
#if AXIS_IS_TMC(U)
extern TMC_CLASS(U, U) stepperU;
static constexpr chopper_timing_t chopper_timing_U = CHOPPER_TIMING_U;
#if ENABLED(SOFTWARE_DRIVER_ENABLE)
#define U_ENABLE_INIT() NOOP
#define U_ENABLE_WRITE(STATE) stepperU.toff((STATE)==U_ENABLE_ON ? chopper_timing_U.toff : 0)
#define U_ENABLE_READ() stepperU.isEnabled()
#endif
#if AXIS_HAS_SQUARE_WAVE(U)
#define U_STEP_WRITE(STATE) do{ if(STATE) TOGGLE(U_STEP_PIN); }while(0)
#endif
#endif
// V Stepper
#if AXIS_IS_TMC(V)
extern TMC_CLASS(V, V) stepperV;
static constexpr chopper_timing_t chopper_timing_V = CHOPPER_TIMING_V;
#if ENABLED(SOFTWARE_DRIVER_ENABLE)
#define V_ENABLE_INIT() NOOP
#define V_ENABLE_WRITE(STATE) stepperV.toff((STATE)==V_ENABLE_ON ? chopper_timing_V.toff : 0)
#define V_ENABLE_READ() stepperV.isEnabled()
#endif
#if AXIS_HAS_SQUARE_WAVE(V)
#define V_STEP_WRITE(STATE) do{ if(STATE) TOGGLE(V_STEP_PIN); }while(0)
#endif
#endif
// W Stepper
#if AXIS_IS_TMC(W)
extern TMC_CLASS(W, W) stepperW;
static constexpr chopper_timing_t chopper_timing_W = CHOPPER_TIMING_W;
#if ENABLED(SOFTWARE_DRIVER_ENABLE)
#define W_ENABLE_INIT() NOOP
#define W_ENABLE_WRITE(STATE) stepperW.toff((STATE)==W_ENABLE_ON ? chopper_timing_W.toff : 0)
#define W_ENABLE_READ() stepperW.isEnabled()
#endif
#if AXIS_HAS_SQUARE_WAVE(W)
#define W_STEP_WRITE(STATE) do{ if(STATE) TOGGLE(W_STEP_PIN); }while(0)
#endif
#endif
// E0 Stepper
#if AXIS_IS_TMC(E0)
extern TMC_CLASS_E(0) stepperE0;

View File

@ -1052,6 +1052,16 @@ void fast_line_to_current(const AxisEnum fr_axis) { _line_to_current(fr_axis, 0.
if (ok) {
IF_DISABLED(TOOLCHANGE_PARK_Y_ONLY, current_position.x = toolchange_settings.change_point.x);
IF_DISABLED(TOOLCHANGE_PARK_X_ONLY, current_position.y = toolchange_settings.change_point.y);
#if NONE(TOOLCHANGE_PARK_X_ONLY, TOOLCHANGE_PARK_Y_ONLY)
SECONDARY_AXIS_CODE(
current_position.i = toolchange_settings.change_point.i,
current_position.j = toolchange_settings.change_point.j,
current_position.k = toolchange_settings.change_point.k,
current_position.u = toolchange_settings.change_point.u,
current_position.v = toolchange_settings.change_point.v,
current_position.w = toolchange_settings.change_point.w
);
#endif
planner.buffer_line(current_position, MMM_TO_MMS(TOOLCHANGE_PARK_XY_FEEDRATE), active_extruder);
planner.synchronize();
}
@ -1227,6 +1237,16 @@ void tool_change(const uint8_t new_tool, bool no_move/*=false*/) {
if (can_move_away && toolchange_settings.enable_park) {
IF_DISABLED(TOOLCHANGE_PARK_Y_ONLY, current_position.x = toolchange_settings.change_point.x);
IF_DISABLED(TOOLCHANGE_PARK_X_ONLY, current_position.y = toolchange_settings.change_point.y);
#if NONE(TOOLCHANGE_PARK_X_ONLY, TOOLCHANGE_PARK_Y_ONLY)
SECONDARY_AXIS_CODE(
current_position.i = toolchange_settings.change_point.i,
current_position.j = toolchange_settings.change_point.j,
current_position.k = toolchange_settings.change_point.k,
current_position.u = toolchange_settings.change_point.u,
current_position.v = toolchange_settings.change_point.v,
current_position.w = toolchange_settings.change_point.w
);
#endif
planner.buffer_line(current_position, MMM_TO_MMS(TOOLCHANGE_PARK_XY_FEEDRATE), old_tool);
planner.synchronize();
}
@ -1281,7 +1301,7 @@ void tool_change(const uint8_t new_tool, bool no_move/*=false*/) {
sync_plan_position();
#if ENABLED(DELTA)
//LOOP_LINEAR_AXES(i) update_software_endstops(i); // or modify the constrain function
//LOOP_NUM_AXES(i) update_software_endstops(i); // or modify the constrain function
const bool safe_to_move = current_position.z < delta_clip_start_height - 1;
#else
constexpr bool safe_to_move = true;

View File

@ -40,7 +40,7 @@
#endif
#if ENABLED(TOOLCHANGE_PARK)
bool enable_park; // M217 W
xyz_pos_t change_point; // M217 X Y I J K
xyz_pos_t change_point; // M217 X Y I J K C H O
#endif
float z_raise; // M217 Z
} toolchange_settings_t;

Some files were not shown because too many files have changed in this diff Show More