Added 4.axes (A) and moved default settings to defaults.h and cpu-map.h

2017-05-11 19:58:41 +02:00 · 2017-05-11 19:58:41 +02:00 · f7083b9491
commit f7083b9491
parent 17121a2652
19 changed files with 385 additions and 200 deletions
--- a/doc/markdown/settings.md
+++ b/doc/markdown/settings.md
@ -51,6 +51,7 @@ $27=1.000
 $30=1000.
 $31=0.
 $32=0
 $33=5000
 $100=250.000
 $101=250.000
 $102=250.000
@ -63,6 +64,9 @@ $122=10.000
 $130=200.000
 $131=200.000
 $132=200.000
 $140=0.000
 $141=0.000
 $142=0.000
 ```
 #### $x=val - Save Grbl setting
@ -227,6 +231,10 @@ When enabled, Grbl will move continuously through consecutive `G1`, `G2`, or `G3
 When disabled, Grbl will operate as it always has, stopping motion with every `S` spindle speed command. This is the default operation of a milling machine to allow a pause to let the spindle change speeds.
 #### $33 - Spindle/Laser PWM frequency
 This sets the PWM frequency.
 #### $100, $101 and $102 – [X,Y,Z] steps/mm
 Grbl needs to know how far each step will take the tool in reality. To calculate steps/mm for an axis of your machine you need to know:
--- a/doc/media/Thumbs.db
+++ b/doc/media/Thumbs.db
--- a/grbl-lpc/current_control.cpp
+++ b/grbl-lpc/current_control.cpp
@ -55,7 +55,7 @@ void current_init()
    set_current(0, settings.current[0]);
    set_current(1, settings.current[1]);
    set_current(2, settings.current[2]);
-    set_current(3, DEFAULT_A_CURRENT);
+    set_current(3, settings.current[3]);
 #endif
 }
--- a/grbl/config.h
+++ b/grbl/config.h
@ -35,8 +35,11 @@
 // NOTE: OEMs can avoid the need to maintain/update the defaults.h and cpu_map.h files and use only
 // one configuration file by placing their specific defaults and pin map at the bottom of this file.
 // If doing so, simply comment out these two defines and see instructions below.
-// #define DEFAULTS_GENERIC
+#define CPU_MAP_LPC1769 // NXP LPC1769 boards (like Smoothieboard, Cohesion3D, MKS SBase)
-// #define CPU_MAP_ATMEGA328P // Arduino Uno CPU
+#define BOARD_C3D       // For boards without i2c stepper current chip (like Cohesion3D).
 //#define DEFAULTS_GENERIC
 #define DEFAULTS_K40
 //#define DEFAULTS_FABKIT
 // Serial baud rate
 // #define BAUD_RATE 230400
@ -359,6 +362,7 @@
 //      pwm = scaled value. settings.rpm_min scales to SPINDLE_PWM_MIN_VALUE. settings.rpm_max
 //            scales to SPINDLE_PWM_MAX_VALUE.
 // Not needed anymore, as spindle PWM frequency is set by $33 param
 //#define SPINDLE_PWM_PERIOD        (SystemCoreClock / 40000)         // SystemCoreClock / frequency
 #define SPINDLE_PWM_OFF_VALUE     0.0    // SPINDLE_PWM_PERIOD * fraction
 //#define SPINDLE_PWM_MIN_VALUE     (SPINDLE_PWM_PERIOD * 0.0)    // SPINDLE_PWM_PERIOD * fraction
@ -629,154 +633,5 @@
   below.
 */
 // Paste CPU_MAP definitions here.
 // Define serial port pins and interrupt vectors.
 #define SERIAL_RX     USART_RX_vect
 #define SERIAL_UDRE   USART_UDRE_vect
 // Define step pulse output pins. NOTE: All step bit pins must be on the same port.
 #define STEP_DDR        LPC_GPIO2->FIODIR
 #define STEP_PORT       LPC_GPIO2->FIOPIN
 #define X_STEP_BIT      0
 #define Y_STEP_BIT      1
 #define Z_STEP_BIT      2
 #define STEP_MASK       ((1<<X_STEP_BIT)|(1<<Y_STEP_BIT)|(1<<Z_STEP_BIT)) // All step bits
 // Define step direction output pins. NOTE: All direction pins must be on the same port.
 #define DIRECTION_DDR     LPC_GPIO0->FIODIR
 #define DIRECTION_PORT    LPC_GPIO0->FIOPIN
 #define X_DIRECTION_BIT   5
 #define Y_DIRECTION_BIT   11
 #define Z_DIRECTION_BIT   20
 #define DIRECTION_MASK    ((1<<X_DIRECTION_BIT)|(1<<Y_DIRECTION_BIT)|(1<<Z_DIRECTION_BIT)) // All direction bits
 // Define stepper driver enable/disable output pin.
 #define STEPPERS_DISABLE_DDR    LPC_GPIO0->FIODIR
 #define STEPPERS_DISABLE_PORT   LPC_GPIO0->FIOPIN
 #define X_DISABLE_BIT           4
 #define Y_DISABLE_BIT           10
 #define Z_DISABLE_BIT           19
 #define STEPPERS_DISABLE_MASK   ((1<<X_DISABLE_BIT)|(1<<Y_DISABLE_BIT)|(1<<Z_DISABLE_BIT))
 // Define homing/hard limit switch input pins and limit interrupt vectors.
 // NOTE: All limit bit pins must be on the same port, but not on a port with other input pins (CONTROL).
 #define LIMIT_DDR         LPC_GPIO1->FIODIR
 #define LIMIT_PIN         LPC_GPIO1->FIOPIN
 #define LIMIT_PORT        LPC_GPIO1->FIOPIN
 #define X_LIMIT_BIT       24  // X-MIN=24, X-MAX=25
 #define Y_LIMIT_BIT       27  // Y-MIN=26, Y-MAX=27
 #define Z_LIMIT_BIT	      29  // Z-MIN=28, Z-MAX=29
 #define LIMIT_MASK       ((1<<X_LIMIT_BIT)|(1<<Y_LIMIT_BIT)) //|(1<<Z_LIMIT_BIT)) // All limit bits
 // hard limits not ported    #define LIMIT_INT        PCIE0  // Pin change interrupt enable pin
 // hard limits not ported    #define LIMIT_INT_vect   PCINT0_vect
 // hard limits not ported    #define LIMIT_PCMSK      PCMSK0 // Pin change interrupt register
 // Define spindle enable and spindle direction output pins.
 /* not ported
 #define SPINDLE_ENABLE_DDR    DDRB
 #define SPINDLE_ENABLE_PORT   PORTB
 // Z Limit pin and spindle PWM/enable pin swapped to access hardware PWM on Pin 11.
 #ifdef VARIABLE_SPINDLE
  #ifdef USE_SPINDLE_DIR_AS_ENABLE_PIN
    // If enabled, spindle direction pin now used as spindle enable, while PWM remains on D11.
    #define SPINDLE_ENABLE_BIT    5  // Uno Digital Pin 13 (NOTE: D13 can't be pulled-high input due to LED.)
  #else
    #define SPINDLE_ENABLE_BIT    3  // Uno Digital Pin 11
  #endif
 #else
  #define SPINDLE_ENABLE_BIT    4  // Uno Digital Pin 12
 #endif
 #ifndef USE_SPINDLE_DIR_AS_ENABLE_PIN
  #define SPINDLE_DIRECTION_DDR   DDRB
  #define SPINDLE_DIRECTION_PORT  PORTB
  #define SPINDLE_DIRECTION_BIT   5  // Uno Digital Pin 13 (NOTE: D13 can't be pulled-high input due to LED.)
 #endif
 */
 // Define flood and mist coolant enable output pins.
 #define COOLANT_FLOOD_DDR   NotUsed
 #define COOLANT_FLOOD_PORT  NotUsed
 #define COOLANT_FLOOD_BIT   3  // Uno Analog Pin 3
 #define COOLANT_MIST_DDR   NotUsed
 #define COOLANT_MIST_PORT  NotUsed
 #define COOLANT_MIST_BIT   4  // Uno Analog Pin 3
 // Define user-control controls (cycle start, reset, feed hold) input pins.
 // NOTE: All CONTROLs pins must be on the same port and not on a port with other input pins (limits).
 #define CONTROL_DDR       NotUsed
 #define CONTROL_PIN       NotUsed
 #define CONTROL_PORT      NotUsed
 #define CONTROL_RESET_BIT         0  // Uno Analog Pin 0
 #define CONTROL_FEED_HOLD_BIT     1  // Uno Analog Pin 1
 #define CONTROL_CYCLE_START_BIT   2  // Uno Analog Pin 2
 #define CONTROL_SAFETY_DOOR_BIT   1  // Uno Analog Pin 1 NOTE: Safety door is shared with feed hold. Enabled by config define.
 #define CONTROL_INT       PCIE1  // Pin change interrupt enable pin
 #define CONTROL_INT_vect  PCINT1_vect
 #define CONTROL_PCMSK     NotUsed // Pin change interrupt register
 #define CONTROL_MASK      ((1<<CONTROL_RESET_BIT)|(1<<CONTROL_FEED_HOLD_BIT)|(1<<CONTROL_CYCLE_START_BIT)|(1<<CONTROL_SAFETY_DOOR_BIT))
 #define CONTROL_INVERT_MASK   CONTROL_MASK // May be re-defined to only invert certain control pins.
 // Define probe switch input pin.
 #define PROBE_DDR       NotUsed
 #define PROBE_PIN       NotUsed
 #define PROBE_PORT      NotUsed
 #define PROBE_BIT       5  // Uno Analog Pin 5
 #define PROBE_MASK      (1<<PROBE_BIT)
 // The LPC17xx has 6 PWM channels. Each channel has 2 pins. It can drive both pins simultaneously to the same value.
 //
 // PWM Channel      PWM1_CH1  PWM1_CH2  PWM1_CH3  PWM1_CH4  PWM1_CH5  PWM1_CH6
 // Primary pin      P1.18     P1.20     P1.21     P1.23     P1.24     P1.26
 // Secondary pin    P2.0      P2.1      P2.2      P2.3      P2.4      P2.5
 #define SPINDLE_PWM_CHANNEL           PWM1_CH6
 #define SPINDLE_PWM_USE_PRIMARY_PIN   false
 #define SPINDLE_PWM_USE_SECONDARY_PIN true
 // Stepper current control
 //#define CURRENT_I2C Driver_I2C1         // I2C driver for current control. Comment out to disable.
 #define CURRENT_MCP44XX_ADDR 0b0101100  // Address of MCP44XX
 #define CURRENT_WIPERS {0, 1, 6, 7};    // Wiper registers (X, Y, Z, A)
 #define CURRENT_FACTOR 113.33           // Convert amps to digipot value
 // Paste default settings definitions here.
 #define DEFAULT_X_STEPS_PER_MM 160.0
 #define DEFAULT_Y_STEPS_PER_MM 160.0
 #define DEFAULT_Z_STEPS_PER_MM 160.0
 #define DEFAULT_X_MAX_RATE 24000 // mm/min
 #define DEFAULT_Y_MAX_RATE 24000 // mm/min
 #define DEFAULT_Z_MAX_RATE 24000 // mm/min
 #define DEFAULT_X_ACCELERATION (2500.0*60*60) // 5000*60*60 mm/min^2 = 5000 mm/sec^2
 #define DEFAULT_Y_ACCELERATION (2500.0*60*60) // 5000*60*60 mm/min^2 = 5000 mm/sec^2
 #define DEFAULT_Z_ACCELERATION (2500.0*60*60) // 5000*60*60 mm/min^2 = 5000 mm/sec^2
 #define DEFAULT_X_CURRENT 0.0 // amps
 #define DEFAULT_Y_CURRENT 0.0 // amps
 #define DEFAULT_Z_CURRENT 0.0 // amps
 #define DEFAULT_A_CURRENT 0.0  // amps
 #define DEFAULT_X_MAX_TRAVEL 300.0 // mm
 #define DEFAULT_Y_MAX_TRAVEL 200.0 // mm
 #define DEFAULT_Z_MAX_TRAVEL 50.0 // mm
 #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
 #define DEFAULT_SPINDLE_RPM_MAX 1000.0 // rpm
 #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
 #define DEFAULT_STEP_PULSE_MICROSECONDS 10
 #define DEFAULT_STEPPING_INVERT_MASK 0
 #define DEFAULT_DIRECTION_INVERT_MASK 0
 #define DEFAULT_STEPPER_IDLE_LOCK_TIME 25 // msec (0-254, 255 keeps steppers enabled)
 #define DEFAULT_STATUS_REPORT_MASK 0 // WPos enabled
 #define DEFAULT_JUNCTION_DEVIATION 0.01 // mm
 #define DEFAULT_ARC_TOLERANCE 0.002 // mm
 #define DEFAULT_REPORT_INCHES 0 // false
 #define DEFAULT_INVERT_ST_ENABLE 0 // false
 #define DEFAULT_INVERT_LIMIT_PINS 1 // false
 #define DEFAULT_SOFT_LIMIT_ENABLE 0 // false
 #define DEFAULT_HARD_LIMIT_ENABLE 0  // false
 #define DEFAULT_INVERT_PROBE_PIN 0 // false
 #define DEFAULT_LASER_MODE 1 // true
 #define DEFAULT_HOMING_ENABLE 0  // false
 #define DEFAULT_HOMING_DIR_MASK 0 // move positive dir
 #define DEFAULT_HOMING_FEED_RATE 50.0 // mm/min
 #define DEFAULT_HOMING_SEEK_RATE 6000.0 // mm/min
 #define DEFAULT_HOMING_DEBOUNCE_DELAY 250 // msec (0-65k)
 #define DEFAULT_HOMING_PULLOFF 1.0 // mm
 #endif
--- a/grbl/cpu_map.h
+++ b/grbl/cpu_map.h
@ -144,11 +144,165 @@
  // NOTE: On the 328p, these must be the same as the SPINDLE_ENABLE settings.
  #define SPINDLE_PWM_DDR	  DDRB
-  #define SPINDLE_PWM_PORT  PORTB
+  #define SPINDLE_PWM_PORT    PORTB
  #define SPINDLE_PWM_BIT	  3    // Uno Digital Pin 11
 #endif
 #ifdef CPU_MAP_LPC1769 // (Boards with NXP-LPC1769 MCU, like Smoothieboard, Cohesion3D, MKS SBase) Only supported by grbl_LPC
  // Define serial port pins and interrupt vectors.
  #define SERIAL_RX     USART_RX_vect
  #define SERIAL_UDRE   USART_UDRE_vect
  // Define step pulse output pins. NOTE: All step bit pins must be on the same port.
  #define STEP_DDR        LPC_GPIO2->FIODIR
  #define STEP_PORT       LPC_GPIO2->FIOPIN
  #define X_STEP_BIT      0
  #define Y_STEP_BIT      1
  #define Z_STEP_BIT      2
  #define A_STEP_BIT      3
  //#define B_STEP_BIT      8
  //#define C_STEP_BIT      9
  #define STEP_MASK       ((1<<X_STEP_BIT)|(1<<Y_STEP_BIT)|(1<<Z_STEP_BIT)|(1<<A_STEP_BIT)) // All step bits
  // Define step direction output pins. NOTE: All direction pins must be on the same port.
  #define DIRECTION_DDR     LPC_GPIO0->FIODIR
  #define DIRECTION_PORT    LPC_GPIO0->FIOPIN
  #define X_DIRECTION_BIT   5
  #define Y_DIRECTION_BIT   11
  #define Z_DIRECTION_BIT   20
  #define A_DIRECTION_BIT   22
  //#define B_DIRECTION_BIT   13
  //#define C_DIRECTION_BIT   NotUsed
  #define DIRECTION_MASK    ((1<<X_DIRECTION_BIT)|(1<<Y_DIRECTION_BIT)|(1<<Z_DIRECTION_BIT)|(1<<A_DIRECTION_BIT)) // All direction bits
  // Define stepper driver enable/disable output pin.
  #define STEPPERS_DISABLE_DDR    LPC_GPIO0->FIODIR
  #define STEPPERS_DISABLE_PORT   LPC_GPIO0->FIOPIN
  #define X_DISABLE_BIT           4
  #define Y_DISABLE_BIT           10
  #define Z_DISABLE_BIT           19
  #define A_DISABLE_BIT           21
  //#define B_DISABLE_BIT           29
  //#define C_DISABLE_BIT           NotUsed
  #define STEPPERS_DISABLE_MASK   ((1<<X_DISABLE_BIT)|(1<<Y_DISABLE_BIT)|(1<<Z_DISABLE_BIT)|(1<<A_DISABLE_BIT))
  // Define homing/hard limit switch input pins and limit interrupt vectors.
  // NOTE: All limit bit pins must be on the same port, but not on a port with other input pins (CONTROL).
  #define LIMIT_DDR         LPC_GPIO1->FIODIR
  #define LIMIT_PIN         LPC_GPIO1->FIOPIN
  #define LIMIT_PORT        LPC_GPIO1->FIOPIN
  #define X_LIMIT_BIT       24  // X-MIN=24, X-MAX=25
  #define Y_LIMIT_BIT       27  // Y-MIN=26, Y-MAX=27
  #define Z_LIMIT_BIT	    29  // Z-MIN=28, Z-MAX=29
  #define A_LIMIT_BIT       28  // reuse p1.28, as z-min is not often used
  //#define B_LIMIT_BIT       NotUsed
  //#define C_LIMIT_BIT 	  NotUsed
  #define LIMIT_MASK       ((1<<X_LIMIT_BIT)|(1<<Y_LIMIT_BIT)|(1<<Z_LIMIT_BIT)|(1<<A_LIMIT_BIT)) // All limit bits
  // hard limits not ported    #define LIMIT_INT        PCIE0  // Pin change interrupt enable pin
  // hard limits not ported    #define LIMIT_INT_vect   PCINT0_vect
  // hard limits not ported    #define LIMIT_PCMSK      PCMSK0 // Pin change interrupt register
  // Define spindle enable and spindle direction output pins.
  /* not ported
  #define SPINDLE_ENABLE_DDR    DDRB
  #define SPINDLE_ENABLE_PORT   PORTB
  // Z Limit pin and spindle PWM/enable pin swapped to access hardware PWM on Pin 11.
  #ifdef VARIABLE_SPINDLE
    #ifdef USE_SPINDLE_DIR_AS_ENABLE_PIN
      // If enabled, spindle direction pin now used as spindle enable, while PWM remains on D11.
      #define SPINDLE_ENABLE_BIT    5  // Uno Digital Pin 13 (NOTE: D13 can't be pulled-high input due to LED.)
    #else
      #define SPINDLE_ENABLE_BIT    3  // Uno Digital Pin 11
    #endif
  #else
    #define SPINDLE_ENABLE_BIT    4  // Uno Digital Pin 12
  #endif
  #ifndef USE_SPINDLE_DIR_AS_ENABLE_PIN
    #define SPINDLE_DIRECTION_DDR   DDRB
    #define SPINDLE_DIRECTION_PORT  PORTB
    #define SPINDLE_DIRECTION_BIT   5  // Uno Digital Pin 13 (NOTE: D13 can't be pulled-high input due to LED.)
  #endif
  */
  // Define flood and mist coolant enable output pins.
  #define COOLANT_FLOOD_DDR   NotUsed
  #define COOLANT_FLOOD_PORT  NotUsed
  #define COOLANT_FLOOD_BIT   3  // Uno Analog Pin 3
  #define COOLANT_MIST_DDR   NotUsed
  #define COOLANT_MIST_PORT  NotUsed
  #define COOLANT_MIST_BIT   4  // Uno Analog Pin 3
  // Define user-control controls (cycle start, reset, feed hold) input pins.
  // NOTE: All CONTROLs pins must be on the same port and not on a port with other input pins (limits).
  #define CONTROL_DDR       NotUsed
  #define CONTROL_PIN       NotUsed
  #define CONTROL_PORT      NotUsed
  #define CONTROL_RESET_BIT         0  // Uno Analog Pin 0
  #define CONTROL_FEED_HOLD_BIT     1  // Uno Analog Pin 1
  #define CONTROL_CYCLE_START_BIT   2  // Uno Analog Pin 2
  #define CONTROL_SAFETY_DOOR_BIT   1  // Uno Analog Pin 1 NOTE: Safety door is shared with feed hold. Enabled by config define.
  #define CONTROL_INT       PCIE1  // Pin change interrupt enable pin
  #define CONTROL_INT_vect  PCINT1_vect
  #define CONTROL_PCMSK     NotUsed // Pin change interrupt register
  #define CONTROL_MASK      ((1<<CONTROL_RESET_BIT)|(1<<CONTROL_FEED_HOLD_BIT)|(1<<CONTROL_CYCLE_START_BIT)|(1<<CONTROL_SAFETY_DOOR_BIT))
  #define CONTROL_INVERT_MASK   CONTROL_MASK // May be re-defined to only invert certain control pins.
  // Define probe switch input pin.
  #define PROBE_DDR       NotUsed
  #define PROBE_PIN       NotUsed
  #define PROBE_PORT      NotUsed
  #define PROBE_BIT       5  // Uno Analog Pin 5
  #define PROBE_MASK      (1<<PROBE_BIT)
  // The LPC17xx has 6 PWM channels. Each channel has 2 pins. It can drive both pins simultaneously to the same value.
  //
  // PWM Channel      PWM1_CH1  PWM1_CH2  PWM1_CH3  PWM1_CH4  PWM1_CH5  PWM1_CH6
  // Primary pin      P1.18     P1.20     P1.21     P1.23     P1.24     P1.26
  // Secondary pin    P2.0      P2.1      P2.2      P2.3      P2.4      P2.5
  #define SPINDLE_PWM_CHANNEL           PWM1_CH6
  #define SPINDLE_PWM_USE_PRIMARY_PIN   false
  #define SPINDLE_PWM_USE_SECONDARY_PIN true
  // Stepper current control
  #ifndef BOARD_C3D
    #define CURRENT_I2C Driver_I2C1       // I2C driver for current control. Comment out to disable (for C3d boards!)
  #endif
  #define CURRENT_MCP44XX_ADDR 0b0101100  // Address of MCP44XX
  #define CURRENT_WIPERS {0, 1, 6, 7};    // Wiper registers (X, Y, Z, A)
  #define CURRENT_FACTOR 113.33           // Convert amps to digipot value
  // Variable spindle configuration below. Do not change unless you know what you are doing.
  // NOTE: Only used when variable spindle is enabled.
  #define SPINDLE_PWM_MAX_VALUE     255 // Don't change. 328p fast PWM mode fixes top value as 255.
  #ifndef SPINDLE_PWM_MIN_VALUE
    #define SPINDLE_PWM_MIN_VALUE   1   // Must be greater than zero.
  #endif
  //#define SPINDLE_PWM_OFF_VALUE     0 // Defined in config.h
  #define SPINDLE_PWM_RANGE         (SPINDLE_PWM_MAX_VALUE-SPINDLE_PWM_MIN_VALUE)
  #define SPINDLE_TCCRA_REGISTER	TCCR2A
  #define SPINDLE_TCCRB_REGISTER	TCCR2B
  #define SPINDLE_OCR_REGISTER      OCR2A
  #define SPINDLE_COMB_BIT	        COM2A1
  // Prescaled, 8-bit Fast PWM mode.
  /* not used
  #define SPINDLE_TCCRA_INIT_MASK   ((1<<WGM20) | (1<<WGM21))  // Configures fast PWM mode.
  // #define SPINDLE_TCCRB_INIT_MASK   (1<<CS20)               // Disable prescaler -> 62.5kHz
  // #define SPINDLE_TCCRB_INIT_MASK   (1<<CS21)               // 1/8 prescaler -> 7.8kHz (Used in v0.9)
  // #define SPINDLE_TCCRB_INIT_MASK   ((1<<CS21) | (1<<CS20)) // 1/32 prescaler -> 1.96kHz
  #define SPINDLE_TCCRB_INIT_MASK      (1<<CS22)               // 1/64 prescaler -> 0.98kHz (J-tech laser)
  // NOTE: On the 328p, these must be the same as the SPINDLE_ENABLE settings.
  #define SPINDLE_PWM_DDR	  DDRB
  #define SPINDLE_PWM_PORT    PORTB
  #define SPINDLE_PWM_BIT	  3    // Uno Digital Pin 11
  */
 #endif
 /*
 #ifdef CPU_MAP_CUSTOM_PROC
  // For a custom pin map or different processor, copy and edit one of the available cpu
--- a/grbl/defaults.h
+++ b/grbl/defaults.h
@ -32,15 +32,33 @@
  #define DEFAULT_X_STEPS_PER_MM 250.0
  #define DEFAULT_Y_STEPS_PER_MM 250.0
  #define DEFAULT_Z_STEPS_PER_MM 250.0
  #define DEFAULT_A_STEPS_PER_MM 160.0
  //#define DEFAULT_B_STEPS_PER_MM 160.0
  //#define DEFAULT_C_STEPS_PER_MM 160.0
  #define DEFAULT_X_MAX_RATE 500.0 // mm/min
  #define DEFAULT_Y_MAX_RATE 500.0 // mm/min
  #define DEFAULT_Z_MAX_RATE 500.0 // mm/min
  #define DEFAULT_A_MAX_RATE 500.0 // mm/min
  //#define DEFAULT_B_MAX_RATE 500.0 // mm/min
  //#define DEFAULT_C_MAX_RATE 500.0 // mm/min
  #define DEFAULT_X_ACCELERATION (10.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  #define DEFAULT_Y_ACCELERATION (10.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  #define DEFAULT_Z_ACCELERATION (10.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  #define DEFAULT_A_ACCELERATION (10.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  //#define DEFAULT_B_ACCELERATION (10.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  //#define DEFAULT_C_ACCELERATION (10.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  #define DEFAULT_X_CURRENT 0.6 // amps
  #define DEFAULT_Y_CURRENT 0.6 // amps
  #define DEFAULT_Z_CURRENT 0.0 // amps
  #define DEFAULT_A_CURRENT 0.0 // amps
  //#define DEFAULT_B_CURRENT 0.0 // amps
  //#define DEFAULT_C_CURRENT 0.0 // amps
  #define DEFAULT_X_MAX_TRAVEL 200.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 200.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 200.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_A_MAX_TRAVEL 1.0 // mm NOTE: Must be a positive value.
  //#define DEFAULT_B_MAX_TRAVEL 1.0 // mm NOTE: Must be a positive value.
  //#define DEFAULT_C_MAX_TRAVEL 1.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 1000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
@ -71,19 +89,33 @@
  #define DEFAULT_X_STEPS_PER_MM 160.0
  #define DEFAULT_Y_STEPS_PER_MM 160.0
  #define DEFAULT_Z_STEPS_PER_MM 160.0
  #define DEFAULT_A_STEPS_PER_MM 160.0
  //#define DEFAULT_B_STEPS_PER_MM 160.0
  //#define DEFAULT_C_STEPS_PER_MM 160.0
  #define DEFAULT_X_MAX_RATE 24000.0 // mm/min
  #define DEFAULT_Y_MAX_RATE 24000.0 // mm/min
  #define DEFAULT_Z_MAX_RATE 24000.0 // mm/min
  #define DEFAULT_A_MAX_RATE 24000.0 // mm/min
  //#define DEFAULT_B_MAX_RATE 24000.0 // mm/min
  //#define DEFAULT_C_MAX_RATE 24000.0 // mm/min
  #define DEFAULT_X_ACCELERATION (2500.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  #define DEFAULT_Y_ACCELERATION (2500.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  #define DEFAULT_Z_ACCELERATION (2500.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
-  #define DEFAULT_X_CURRENT 0.0 // amps
+  #define DEFAULT_A_ACCELERATION (2500.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
-  #define DEFAULT_Y_CURRENT 0.0 // amps
+  //#define DEFAULT_B_ACCELERATION (2500.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  //#define DEFAULT_C_ACCELERATION (2500.0*60*60) // 10*60*60 mm/min^2 = 10 mm/sec^2
  #define DEFAULT_X_CURRENT 0.6 // amps
  #define DEFAULT_Y_CURRENT 0.6 // amps
  #define DEFAULT_Z_CURRENT 0.0 // amps
-  #define DEFAULT_A_CURRENT 0.0  // amps
+  #define DEFAULT_A_CURRENT 0.0 // amps
  //#define DEFAULT_B_CURRENT 0.0 // amps
  //#define DEFAULT_C_CURRENT 0.0 // amps
  #define DEFAULT_X_MAX_TRAVEL 300.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 200.0 // mm NOTE: Must be a positive value.
-  #define DEFAULT_Z_MAX_TRAVEL 50.0 // mm NOTE: Must be a positive value.
+  #define DEFAULT_Z_MAX_TRAVEL 1.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_A_MAX_TRAVEL 1.0 // mm NOTE: Must be a positive value.
  //#define DEFAULT_B_MAX_TRAVEL 1.0 // mm NOTE: Must be a positive value.
  //#define DEFAULT_C_MAX_TRAVEL 1.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 1000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
@ -109,6 +141,49 @@
  #define DEFAULT_HOMING_PULLOFF 1.0 // mm
 #endif
 #ifdef DEFAULTS_FABKIT
  // Paste default settings definitions here.
  #define DEFAULT_X_STEPS_PER_MM 80.0
  #define DEFAULT_Y_STEPS_PER_MM 80.0
  #define DEFAULT_Z_STEPS_PER_MM 640.0
  #define DEFAULT_X_MAX_RATE 30000 // mm/min
  #define DEFAULT_Y_MAX_RATE 4500 // mm/min
  #define DEFAULT_Z_MAX_RATE 1200 // mm/min
  #define DEFAULT_X_ACCELERATION (4000.0*60*60) // 5000*60*60 mm/min^2 = 5000 mm/sec^2
  #define DEFAULT_Y_ACCELERATION (250.0*60*60) // 5000*60*60 mm/min^2 = 5000 mm/sec^2
  #define DEFAULT_Z_ACCELERATION (150.0*60*60) // 5000*60*60 mm/min^2 = 5000 mm/sec^2
  #define DEFAULT_X_CURRENT 1.5 // amps
  #define DEFAULT_Y_CURRENT 1.5 // amps
  #define DEFAULT_Z_CURRENT 1.5 // amps
  #define DEFAULT_A_CURRENT 0.0  // amps
  #define DEFAULT_X_MAX_TRAVEL 680.0 // mm
  #define DEFAULT_Y_MAX_TRAVEL 460.0 // mm
  #define DEFAULT_Z_MAX_TRAVEL 150.0 // mm
  #define DEFAULT_SPINDLE_PWM_FREQ 50000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 0.7 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.08 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 1
  #define DEFAULT_STEPPING_INVERT_MASK 0
  #define DEFAULT_DIRECTION_INVERT_MASK 2
  #define DEFAULT_STEPPER_IDLE_LOCK_TIME 255 // msec (0-254, 255 keeps steppers enabled)
  #define DEFAULT_STATUS_REPORT_MASK 0 // WPos enabled
  #define DEFAULT_JUNCTION_DEVIATION 0.01 // mm
  #define DEFAULT_ARC_TOLERANCE 0.002 // mm
  #define DEFAULT_REPORT_INCHES 0 // false
  #define DEFAULT_INVERT_ST_ENABLE 0 // false
  #define DEFAULT_INVERT_LIMIT_PINS 1 // false
  #define DEFAULT_SOFT_LIMIT_ENABLE 0 // false
  #define DEFAULT_HARD_LIMIT_ENABLE 0  // false
  #define DEFAULT_INVERT_PROBE_PIN 0 // false
  #define DEFAULT_LASER_MODE 1 // true
  #define DEFAULT_HOMING_ENABLE 1  // false
  #define DEFAULT_HOMING_DIR_MASK 1 // move positive dir
  #define DEFAULT_HOMING_FEED_RATE 60.0 // mm/min
  #define DEFAULT_HOMING_SEEK_RATE 6000.0 // mm/min
  #define DEFAULT_HOMING_DEBOUNCE_DELAY 250 // msec (0-65k)
  #define DEFAULT_HOMING_PULLOFF 1.0 // mm
 #endif
 #ifdef DEFAULTS_SHERLINE_5400
  // Description: Sherline 5400 mill with three NEMA 23 Keling  KL23H256-21-8B 185 oz-in stepper motors,
  // driven by three Pololu A4988 stepper drivers with a 30V, 6A power supply at 1.5A per winding.
@ -127,6 +202,7 @@
  #define DEFAULT_X_MAX_TRAVEL 225.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 125.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 170.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 2800.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
@ -172,6 +248,7 @@
  #define DEFAULT_X_MAX_TRAVEL 200.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 200.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 200.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 10000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
@ -217,6 +294,7 @@
  #define DEFAULT_X_MAX_TRAVEL 290.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 290.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 100.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 10000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
@ -261,6 +339,7 @@
  #define DEFAULT_X_MAX_TRAVEL 425.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 465.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 80.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 10000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
@ -306,6 +385,7 @@
  #define DEFAULT_X_MAX_TRAVEL 290.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 290.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 100.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 10000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
@ -351,6 +431,7 @@
  #define DEFAULT_X_MAX_TRAVEL 740.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 790.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 100.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 10000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
@ -394,6 +475,7 @@
  #define DEFAULT_X_MAX_TRAVEL 190.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 180.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 150.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 10000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
@ -433,6 +515,7 @@
  #define DEFAULT_X_MAX_TRAVEL 500.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 750.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 80.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 1000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
@ -472,6 +555,7 @@
  #define DEFAULT_X_MAX_TRAVEL 1000.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Y_MAX_TRAVEL 1000.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_Z_MAX_TRAVEL 1000.0 // mm NOTE: Must be a positive value.
  #define DEFAULT_SPINDLE_PWM_FREQ 5000 // Hz
  #define DEFAULT_SPINDLE_RPM_MAX 1000.0 // rpm
  #define DEFAULT_SPINDLE_RPM_MIN 0.0 // rpm
  #define DEFAULT_STEP_PULSE_MICROSECONDS 10
--- a/grbl/gcode.c
+++ b/grbl/gcode.c
@ -80,7 +80,7 @@ uint8_t gc_execute_line(char *line)
  uint8_t coord_select = 0; // Tracks G10 P coordinate selection for execution
  // Initialize bitflag tracking variables for axis indices compatible operations.
-  uint8_t axis_words = 0; // XYZ tracking
+  uint8_t axis_words = 0; // XYZA tracking
  uint8_t ijk_words = 0; // IJK tracking
  // Initialize command and value words and parser flags variables.
@ -296,7 +296,7 @@ uint8_t gc_execute_line(char *line)
           legal g-code words and stores their value. Error-checking is performed later since some
           words (I,J,K,L,P,R) have multiple connotations and/or depend on the issued commands. */
        switch(letter){
-          // case 'A': // Not supported
+          case 'A': word_bit = WORD_A; gc_block.values.xyza[A_AXIS] = value; axis_words |= (1<<A_AXIS); break;
          // case 'B': // Not supported
          // case 'C': // Not supported
          // case 'D': // Not supported
@ -316,9 +316,9 @@ uint8_t gc_execute_line(char *line)
 					  if (value > MAX_TOOL_NUMBER) { FAIL(STATUS_GCODE_MAX_VALUE_EXCEEDED); }
            gc_block.values.t = int_value;
 						break;
-          case 'X': word_bit = WORD_X; gc_block.values.xyz[X_AXIS] = value; axis_words |= (1<<X_AXIS); break;
+          case 'X': word_bit = WORD_X; gc_block.values.xyza[X_AXIS] = value; axis_words |= (1<<X_AXIS); break;
-          case 'Y': word_bit = WORD_Y; gc_block.values.xyz[Y_AXIS] = value; axis_words |= (1<<Y_AXIS); break;
+          case 'Y': word_bit = WORD_Y; gc_block.values.xyza[Y_AXIS] = value; axis_words |= (1<<Y_AXIS); break;
-          case 'Z': word_bit = WORD_Z; gc_block.values.xyz[Z_AXIS] = value; axis_words |= (1<<Z_AXIS); break;
+          case 'Z': word_bit = WORD_Z; gc_block.values.xyza[Z_AXIS] = value; axis_words |= (1<<Z_AXIS); break;
          default: FAIL(STATUS_GCODE_UNSUPPORTED_COMMAND);
        }
@ -475,7 +475,7 @@ uint8_t gc_execute_line(char *line)
  if (gc_block.modal.units == UNITS_MODE_INCHES) {
    for (idx=0; idx<N_AXIS; idx++) { // Axes indices are consistent, so loop may be used.
      if (bit_istrue(axis_words,bit(idx)) ) {
-        gc_block.values.xyz[idx] *= MM_PER_INCH;
+        gc_block.values.xyza[idx] *= MM_PER_INCH;
      }
    }
  }
@ -549,11 +549,11 @@ uint8_t gc_execute_line(char *line)
          if (gc_block.values.l == 20) {
            // L20: Update coordinate system axis at current position (with modifiers) with programmed value
            // WPos = MPos - WCS - G92 - TLO  ->  WCS = MPos - G92 - TLO - WPos
-            gc_block.values.ijk[idx] = gc_state.position[idx]-gc_state.coord_offset[idx]-gc_block.values.xyz[idx];
+            gc_block.values.ijk[idx] = gc_state.position[idx]-gc_state.coord_offset[idx]-gc_block.values.xyza[idx];
            if (idx == TOOL_LENGTH_OFFSET_AXIS) { gc_block.values.ijk[idx] -= gc_state.tool_length_offset; }
          } else {
            // L2: Update coordinate system axis to programmed value.
-            gc_block.values.ijk[idx] = gc_block.values.xyz[idx];
+            gc_block.values.ijk[idx] = gc_block.values.xyza[idx];
          }
        } // Else, keep current stored value.
      }
@ -567,10 +567,10 @@ uint8_t gc_execute_line(char *line)
      for (idx=0; idx<N_AXIS; idx++) { // Axes indices are consistent, so loop may be used.
        if (bit_istrue(axis_words,bit(idx)) ) {
          // WPos = MPos - WCS - G92 - TLO  ->  G92 = MPos - WCS - TLO - WPos
-          gc_block.values.xyz[idx] = gc_state.position[idx]-block_coord_system[idx]-gc_block.values.xyz[idx];
+          gc_block.values.xyza[idx] = gc_state.position[idx]-block_coord_system[idx]-gc_block.values.xyza[idx];
-          if (idx == TOOL_LENGTH_OFFSET_AXIS) { gc_block.values.xyz[idx] -= gc_state.tool_length_offset; }
+          if (idx == TOOL_LENGTH_OFFSET_AXIS) { gc_block.values.xyza[idx] -= gc_state.tool_length_offset; }
        } else {
-          gc_block.values.xyz[idx] = gc_state.coord_offset[idx];
+          gc_block.values.xyza[idx] = gc_state.coord_offset[idx];
        }
      }
      break;
@ -585,17 +585,17 @@ uint8_t gc_execute_line(char *line)
        if (axis_words) {
          for (idx=0; idx<N_AXIS; idx++) { // Axes indices are consistent, so loop may be used to save flash space.
            if ( bit_isfalse(axis_words,bit(idx)) ) {
-              gc_block.values.xyz[idx] = gc_state.position[idx]; // No axis word in block. Keep same axis position.
+              gc_block.values.xyza[idx] = gc_state.position[idx]; // No axis word in block. Keep same axis position.
            } else {
              // Update specified value according to distance mode or ignore if absolute override is active.
              // NOTE: G53 is never active with G28/30 since they are in the same modal group.
              if (gc_block.non_modal_command != NON_MODAL_ABSOLUTE_OVERRIDE) {
                // Apply coordinate offsets based on distance mode.
                if (gc_block.modal.distance == DISTANCE_MODE_ABSOLUTE) {
-                  gc_block.values.xyz[idx] += block_coord_system[idx] + gc_state.coord_offset[idx];
+                  gc_block.values.xyza[idx] += block_coord_system[idx] + gc_state.coord_offset[idx];
-                  if (idx == TOOL_LENGTH_OFFSET_AXIS) { gc_block.values.xyz[idx] += gc_state.tool_length_offset; }
+                  if (idx == TOOL_LENGTH_OFFSET_AXIS) { gc_block.values.xyza[idx] += gc_state.tool_length_offset; }
                } else {  // Incremental mode
-                  gc_block.values.xyz[idx] += gc_state.position[idx];
+                  gc_block.values.xyza[idx] += gc_state.position[idx];
                }
              }
            }
@ -684,12 +684,12 @@ uint8_t gc_execute_line(char *line)
          // Calculate the change in position along each selected axis
          float x,y;
-          x = gc_block.values.xyz[axis_0]-gc_state.position[axis_0]; // Delta x between current position and target
+          x = gc_block.values.xyza[axis_0]-gc_state.position[axis_0]; // Delta x between current position and target
-          y = gc_block.values.xyz[axis_1]-gc_state.position[axis_1]; // Delta y between current position and target
+          y = gc_block.values.xyza[axis_1]-gc_state.position[axis_1]; // Delta y between current position and target
          if (value_words & bit(WORD_R)) { // Arc Radius Mode
            bit_false(value_words,bit(WORD_R));
-            if (isequal_position_vector(gc_state.position, gc_block.values.xyz)) { FAIL(STATUS_GCODE_INVALID_TARGET); } // [Invalid target]
+            if (isequal_position_vector(gc_state.position, gc_block.values.xyza)) { FAIL(STATUS_GCODE_INVALID_TARGET); } // [Invalid target]
            // Convert radius value to proper units.
            if (gc_block.modal.units == UNITS_MODE_INCHES) { gc_block.values.r *= MM_PER_INCH; }
@ -816,7 +816,7 @@ uint8_t gc_execute_line(char *line)
          //   an error, it issues an alarm to prevent further motion to the probe. It's also done there to
          //   allow the planner buffer to empty and move off the probe trigger before another probing cycle.
          if (!axis_words) { FAIL(STATUS_GCODE_NO_AXIS_WORDS); } // [No axis words]
-          if (isequal_position_vector(gc_state.position, gc_block.values.xyz)) { FAIL(STATUS_GCODE_INVALID_TARGET); } // [Invalid target]
+          if (isequal_position_vector(gc_state.position, gc_block.values.xyza)) { FAIL(STATUS_GCODE_INVALID_TARGET); } // [Invalid target]
          break;
      }
    }
@ -832,7 +832,7 @@ uint8_t gc_execute_line(char *line)
  } else {
    bit_false(value_words,(bit(WORD_N)|bit(WORD_F)|bit(WORD_S)|bit(WORD_T))); // Remove single-meaning value words.
  }
-  if (axis_command) { bit_false(value_words,(bit(WORD_X)|bit(WORD_Y)|bit(WORD_Z))); } // Remove axis words.
+  if (axis_command) { bit_false(value_words,(bit(WORD_X)|bit(WORD_Y)|bit(WORD_Z)|bit(WORD_A))); } // Remove axis words.
  if (value_words) { FAIL(STATUS_GCODE_UNUSED_WORDS); } // [Unused words]
  /* -------------------------------------------------------------------------------------
@ -861,7 +861,7 @@ uint8_t gc_execute_line(char *line)
    plan_data.condition = (gc_state.modal.spindle | gc_state.modal.coolant);
    uint8_t status = jog_execute(&plan_data, &gc_block);
-    if (status == STATUS_OK) { memcpy(gc_state.position, gc_block.values.xyz, sizeof(gc_block.values.xyz)); }
+    if (status == STATUS_OK) { memcpy(gc_state.position, gc_block.values.xyza, sizeof(gc_block.values.xyza)); }
    return(status);
  }
@ -985,10 +985,10 @@ uint8_t gc_execute_line(char *line)
  if (axis_command == AXIS_COMMAND_TOOL_LENGTH_OFFSET ) { // Indicates a change.
    gc_state.modal.tool_length = gc_block.modal.tool_length;
    if (gc_state.modal.tool_length == TOOL_LENGTH_OFFSET_CANCEL) { // G49
-      gc_block.values.xyz[TOOL_LENGTH_OFFSET_AXIS] = 0.0;
+      gc_block.values.xyza[TOOL_LENGTH_OFFSET_AXIS] = 0.0;
    } // else G43.1
-    if ( gc_state.tool_length_offset != gc_block.values.xyz[TOOL_LENGTH_OFFSET_AXIS] ) {
+    if ( gc_state.tool_length_offset != gc_block.values.xyza[TOOL_LENGTH_OFFSET_AXIS] ) {
-      gc_state.tool_length_offset = gc_block.values.xyz[TOOL_LENGTH_OFFSET_AXIS];
+      gc_state.tool_length_offset = gc_block.values.xyza[TOOL_LENGTH_OFFSET_AXIS];
      system_flag_wco_change();
    }
  }
@ -1022,7 +1022,7 @@ uint8_t gc_execute_line(char *line)
      // Move to intermediate position before going home. Obeys current coordinate system and offsets
      // and absolute and incremental modes.
      pl_data->condition |= PL_COND_FLAG_RAPID_MOTION; // Set rapid motion condition flag.
-      if (axis_command) { mc_line(gc_block.values.xyz, pl_data); }
+      if (axis_command) { mc_line(gc_block.values.xyza, pl_data); }
      mc_line(gc_block.values.ijk, pl_data);
      memcpy(gc_state.position, gc_block.values.ijk, N_AXIS*sizeof(float));
      break;
@ -1033,7 +1033,7 @@ uint8_t gc_execute_line(char *line)
      settings_write_coord_data(SETTING_INDEX_G30,gc_state.position,false,true);
      break;
    case NON_MODAL_SET_COORDINATE_OFFSET:
-      memcpy(gc_state.coord_offset,gc_block.values.xyz,sizeof(gc_block.values.xyz));
+      memcpy(gc_state.coord_offset,gc_block.values.xyza,sizeof(gc_block.values.xyza));
      system_flag_wco_change();
      break;
    case NON_MODAL_RESET_COORDINATE_OFFSET:
@ -1051,27 +1051,27 @@ uint8_t gc_execute_line(char *line)
    if (axis_command == AXIS_COMMAND_MOTION_MODE) {
      uint8_t gc_update_pos = GC_UPDATE_POS_TARGET;
      if (gc_state.modal.motion == MOTION_MODE_LINEAR) {
-        mc_line(gc_block.values.xyz, pl_data);
+        mc_line(gc_block.values.xyza, pl_data);
      } else if (gc_state.modal.motion == MOTION_MODE_SEEK) {
        pl_data->condition |= PL_COND_FLAG_RAPID_MOTION; // Set rapid motion condition flag.
-        mc_line(gc_block.values.xyz, pl_data);
+        mc_line(gc_block.values.xyza, pl_data);
      } else if ((gc_state.modal.motion == MOTION_MODE_CW_ARC) || (gc_state.modal.motion == MOTION_MODE_CCW_ARC)) {
-        mc_arc(gc_block.values.xyz, pl_data, gc_state.position, gc_block.values.ijk, gc_block.values.r,
+        mc_arc(gc_block.values.xyza, pl_data, gc_state.position, gc_block.values.ijk, gc_block.values.r,
            axis_0, axis_1, axis_linear, bit_istrue(gc_parser_flags,GC_PARSER_ARC_IS_CLOCKWISE));
      } else {
-        // NOTE: gc_block.values.xyz is returned from mc_probe_cycle with the updated position value. So
+        // NOTE: gc_block.values.xyza is returned from mc_probe_cycle with the updated position value. So
        // upon a successful probing cycle, the machine position and the returned value should be the same.
        #ifndef ALLOW_FEED_OVERRIDE_DURING_PROBE_CYCLES
          pl_data->condition |= PL_COND_FLAG_NO_FEED_OVERRIDE;
        #endif
-        gc_update_pos = mc_probe_cycle(gc_block.values.xyz, pl_data, gc_parser_flags);
+        gc_update_pos = mc_probe_cycle(gc_block.values.xyza, pl_data, gc_parser_flags);
      }  
      // As far as the parser is concerned, the position is now == target. In reality the
      // motion control system might still be processing the action and the real tool position
      // in any intermediate location.
      if (gc_update_pos == GC_UPDATE_POS_TARGET) {
-        memcpy(gc_state.position, gc_block.values.xyz, sizeof(gc_block.values.xyz)); // gc_state.position[] = gc_block.values.xyz[]
+        memcpy(gc_state.position, gc_block.values.xyza, sizeof(gc_block.values.xyza)); // gc_state.position[] = gc_block.values.xyza[]
      } else if (gc_update_pos == GC_UPDATE_POS_SYSTEM) {
        gc_sync_position(); // gc_state.position[] = sys_position
      } // == GC_UPDATE_POS_NONE
--- a/grbl/gcode.h
+++ b/grbl/gcode.h
@ -149,6 +149,7 @@
 #define WORD_X  10
 #define WORD_Y  11
 #define WORD_Z  12
 #define WORD_A  13
 // Define g-code parser position updating flags
 #define GC_UPDATE_POS_TARGET   0 // Must be zero
@ -206,7 +207,7 @@ typedef struct {
  float r;         // Arc radius
  float s;         // Spindle speed
  uint8_t t;       // Tool selection
-  float xyz[3];    // X,Y,Z Translational axes
+  float xyza[N_AXIS];   // X,Y,Z,A Translational axes
 } gc_values_t;
--- a/grbl/grbl.h
+++ b/grbl/grbl.h
@ -23,7 +23,7 @@
 // Grbl versioning system
 #define GRBL_VERSION "1.1f"
-#define GRBL_VERSION_BUILD "20170131"
+#define GRBL_VERSION_BUILD "20170511"
 // Define standard libraries used by Grbl.
 #include <avr/io.h>
--- a/grbl/jog.c
+++ b/grbl/jog.c
@ -33,11 +33,11 @@ uint8_t jog_execute(plan_line_data_t *pl_data, parser_block_t *gc_block)
  #endif
  if (bit_istrue(settings.flags,BITFLAG_SOFT_LIMIT_ENABLE)) {
-    if (system_check_travel_limits(gc_block->values.xyz)) { return(STATUS_TRAVEL_EXCEEDED); }
+    if (system_check_travel_limits(gc_block->values.xyza)) { return(STATUS_TRAVEL_EXCEEDED); }
  }
  // Valid jog command. Plan, set state, and execute.
-  mc_line(gc_block->values.xyz,pl_data);
+  mc_line(gc_block->values.xyza,pl_data);
  if (sys.state == STATE_IDLE) {
    if (plan_get_current_block() != NULL) { // Check if there is a block to execute.
      sys.state = STATE_JOG;
--- a/grbl/motion_control.c
+++ b/grbl/motion_control.c
@ -227,6 +227,9 @@ void mc_homing_cycle(uint8_t cycle_mask)
    #ifdef HOMING_CYCLE_2
      limits_go_home(HOMING_CYCLE_2);  // Homing cycle 2
    #endif
    #ifdef HOMING_CYCLE_3
      limits_go_home(HOMING_CYCLE_3);  // Homing cycle 3
    #endif
  }
  protocol_execute_realtime(); // Check for reset and set system abort.
--- a/grbl/motion_control.h
+++ b/grbl/motion_control.h
@ -31,6 +31,9 @@
 #define HOMING_CYCLE_X    bit(X_AXIS)
 #define HOMING_CYCLE_Y    bit(Y_AXIS)
 #define HOMING_CYCLE_Z    bit(Z_AXIS)
 #define HOMING_CYCLE_A    bit(A_AXIS)
 //#define HOMING_CYCLE_B    bit(B_AXIS)
 //#define HOMING_CYCLE_C    bit(C_AXIS)
 // Execute linear motion in absolute millimeter coordinates. Feed rate given in millimeters/second
--- a/grbl/nuts_bolts.h
+++ b/grbl/nuts_bolts.h
@ -30,11 +30,13 @@
 #define SOME_LARGE_VALUE 1.0E+38
 // Axis array index values. Must start with 0 and be continuous.
-#define N_AXIS 3 // Number of axes
+#define N_AXIS 4 // Number of axes
 #define X_AXIS 0 // Axis indexing value.
 #define Y_AXIS 1
 #define Z_AXIS 2
-// #define A_AXIS 3
+#define A_AXIS 3
 //#define B_AXIS 4
 //#define C_AXIS 5
 // CoreXY motor assignments. DO NOT ALTER.
 // NOTE: If the A and B motor axis bindings are changed, this effects the CoreXY equations.
--- a/grbl/planner.c
+++ b/grbl/planner.c
@ -336,6 +336,7 @@ uint8_t plan_buffer_line(float *target, plan_line_data_t *pl_data)
      position_steps[X_AXIS] = system_convert_corexy_to_x_axis_steps(sys_position);
      position_steps[Y_AXIS] = system_convert_corexy_to_y_axis_steps(sys_position);
      position_steps[Z_AXIS] = sys_position[Z_AXIS];
      position_steps[A_AXIS] = sys_position[A_AXIS];
    #else
      memcpy(position_steps, sys_position, sizeof(sys_position)); 
    #endif
--- a/grbl/report.c
+++ b/grbl/report.c
@ -578,6 +578,9 @@ void report_realtime_status()
        if (bit_istrue(lim_pin_state,bit(X_AXIS))) { serial_write('X'); }
        if (bit_istrue(lim_pin_state,bit(Y_AXIS))) { serial_write('Y'); }
        if (bit_istrue(lim_pin_state,bit(Z_AXIS))) { serial_write('Z'); }
        if (bit_istrue(lim_pin_state,bit(A_AXIS))) { serial_write('A'); }
        //if (bit_istrue(lim_pin_state,bit(B_AXIS))) { serial_write('B'); }
        //if (bit_istrue(lim_pin_state,bit(C_AXIS))) { serial_write('C'); }
      }
      if (ctrl_pin_state) {
        #ifdef ENABLE_SAFETY_DOOR_INPUT_PIN
--- a/grbl/settings.c
+++ b/grbl/settings.c
@ -109,18 +109,33 @@ void settings_restore(uint8_t restore_flag) {
    settings.steps_per_mm[X_AXIS] = DEFAULT_X_STEPS_PER_MM;
    settings.steps_per_mm[Y_AXIS] = DEFAULT_Y_STEPS_PER_MM;
    settings.steps_per_mm[Z_AXIS] = DEFAULT_Z_STEPS_PER_MM;
    settings.steps_per_mm[A_AXIS] = DEFAULT_A_STEPS_PER_MM;
    //settings.steps_per_mm[B_AXIS] = DEFAULT_B_STEPS_PER_MM;
    //settings.steps_per_mm[C_AXIS] = DEFAULT_C_STEPS_PER_MM;
    settings.max_rate[X_AXIS] = DEFAULT_X_MAX_RATE;
    settings.max_rate[Y_AXIS] = DEFAULT_Y_MAX_RATE;
    settings.max_rate[Z_AXIS] = DEFAULT_Z_MAX_RATE;
    settings.max_rate[A_AXIS] = DEFAULT_A_MAX_RATE;
    //settings.max_rate[B_AXIS] = DEFAULT_B_MAX_RATE;
    //settings.max_rate[C_AXIS] = DEFAULT_C_MAX_RATE;
    settings.acceleration[X_AXIS] = DEFAULT_X_ACCELERATION;
    settings.acceleration[Y_AXIS] = DEFAULT_Y_ACCELERATION;
    settings.acceleration[Z_AXIS] = DEFAULT_Z_ACCELERATION;
    settings.acceleration[A_AXIS] = DEFAULT_A_ACCELERATION;
    //settings.acceleration[B_AXIS] = DEFAULT_B_ACCELERATION;
    //settings.acceleration[C_AXIS] = DEFAULT_C_ACCELERATION;
    settings.max_travel[X_AXIS] = (-DEFAULT_X_MAX_TRAVEL);
    settings.max_travel[Y_AXIS] = (-DEFAULT_Y_MAX_TRAVEL);
    settings.max_travel[Z_AXIS] = (-DEFAULT_Z_MAX_TRAVEL);
    settings.max_travel[A_AXIS] = (-DEFAULT_A_MAX_TRAVEL);
    //settings.max_travel[B_AXIS] = (-DEFAULT_B_MAX_TRAVEL);
    //settings.max_travel[C_AXIS] = (-DEFAULT_C_MAX_TRAVEL);
    settings.current[X_AXIS] = DEFAULT_X_CURRENT;
    settings.current[Y_AXIS] = DEFAULT_Y_CURRENT;
    settings.current[Z_AXIS] = DEFAULT_Z_CURRENT;
    settings.current[A_AXIS] = DEFAULT_A_CURRENT;
    //settings.current[B_AXIS] = DEFAULT_B_CURRENT;
    //settings.current[C_AXIS] = DEFAULT_C_CURRENT;
    write_global_settings(false);
  }
@ -343,7 +358,11 @@ uint32_t get_step_pin_mask(uint8_t axis_idx)
 {
  if ( axis_idx == X_AXIS ) { return((1<<X_STEP_BIT)); }
  if ( axis_idx == Y_AXIS ) { return((1<<Y_STEP_BIT)); }
-  return((1<<Z_STEP_BIT));
+  if ( axis_idx == Z_AXIS ) { return((1<<Z_STEP_BIT)); }
  return((1<<A_STEP_BIT));
  //if ( axis_idx == A_AXIS ) { return((1<<A_STEP_BIT)); }
  //if ( axis_idx == B_AXIS ) { return((1<<B_STEP_BIT)); }
  //return((1<<C_STEP_BIT));
 }
@ -352,7 +371,11 @@ uint32_t get_direction_pin_mask(uint8_t axis_idx)
 {
  if ( axis_idx == X_AXIS ) { return((1<<X_DIRECTION_BIT)); }
  if ( axis_idx == Y_AXIS ) { return((1<<Y_DIRECTION_BIT)); }
-  return((1<<Z_DIRECTION_BIT));
+  if ( axis_idx == Z_AXIS ) { return((1<<Z_DIRECTION_BIT)); }
  return((1<<A_DIRECTION_BIT));
  //if ( axis_idx == A_AXIS ) { return((1<<A_DIRECTION_BIT)); }
  //if ( axis_idx == B_AXIS ) { return((1<<B_DIRECTION_BIT)); }
  //return((1<<C_DIRECTION_BIT));
 }
@ -361,5 +384,9 @@ uint32_t get_limit_pin_mask(uint8_t axis_idx)
 {
  if ( axis_idx == X_AXIS ) { return((1<<X_LIMIT_BIT)); }
  if ( axis_idx == Y_AXIS ) { return((1<<Y_LIMIT_BIT)); }
-  return((1<<Z_LIMIT_BIT));
+  if ( axis_idx == Z_AXIS ) { return((1<<Z_LIMIT_BIT)); }
  return((1<<A_LIMIT_BIT));
  //if ( axis_idx == A_AXIS ) { return((1<<A_LIMIT_BIT)); }
  //if ( axis_idx == B_AXIS ) { return((1<<B_LIMIT_BIT)); }
  //return((1<<C_LIMIT_BIT));
 }
--- a/grbl/settings.h
+++ b/grbl/settings.h
@ -27,7 +27,7 @@
 // Version of the EEPROM data. Will be used to migrate existing data from older versions of Grbl
 // when firmware is upgraded. Always stored in byte 0 of eeprom
-#define SETTINGS_VERSION 10  // NOTE: Check settings_reset() when moving to next version.
+#define SETTINGS_VERSION 11  // NOTE: Check settings_reset() when moving to next version.
 // Define bit flag masks for the boolean settings in settings.flag.
 #define BITFLAG_REPORT_INCHES      bit(0)
--- a/grbl/stepper.c
+++ b/grbl/stepper.c
@ -97,7 +97,10 @@ typedef struct {
  // Used by the bresenham line algorithm
  uint32_t counter_x,        // Counter variables for the bresenham line tracer
           counter_y,
-           counter_z;
+           counter_z,
           counter_a;
           //counter_b,
           //counter_c;
  #ifdef STEP_PULSE_DELAY
    uint32_t step_bits;  // Stores out_bits output to complete the step pulse delay
  #endif
@ -370,6 +373,9 @@ extern "C" void TIMER1_IRQHandler()
        st.steps[X_AXIS] = st.exec_block->steps[X_AXIS] >> st.exec_segment->amass_level;
        st.steps[Y_AXIS] = st.exec_block->steps[Y_AXIS] >> st.exec_segment->amass_level;
        st.steps[Z_AXIS] = st.exec_block->steps[Z_AXIS] >> st.exec_segment->amass_level;
        st.steps[A_AXIS] = st.exec_block->steps[A_AXIS] >> st.exec_segment->amass_level;
        //st.steps[B_AXIS] = st.exec_block->steps[B_AXIS] >> st.exec_segment->amass_level;
        //st.steps[C_AXIS] = st.exec_block->steps[C_AXIS] >> st.exec_segment->amass_level;
      #endif
      #ifdef VARIABLE_SPINDLE
@ -433,6 +439,41 @@ extern "C" void TIMER1_IRQHandler()
    if (st.exec_block->direction_bits & (1<<Z_DIRECTION_BIT)) { sys_position[Z_AXIS]--; }
    else { sys_position[Z_AXIS]++; }
  }
  #ifdef ADAPTIVE_MULTI_AXIS_STEP_SMOOTHING
    st.counter_a += st.steps[A_AXIS];
  #else
    st.counter_a += st.exec_block->steps[A_AXIS];
  #endif
  if (st.counter_a > st.exec_block->step_event_count) {
    st.step_outbits |= (1<<A_STEP_BIT);
    st.counter_a -= st.exec_block->step_event_count;
    if (st.exec_block->direction_bits & (1<<A_DIRECTION_BIT)) { sys_position[A_AXIS]--; }
    else { sys_position[A_AXIS]++; }
  }
 /*
  #ifdef ADAPTIVE_MULTI_AXIS_STEP_SMOOTHING
    st.counter_b += st.steps[B_AXIS];
  #else
    st.counter_b += st.exec_block->steps[B_AXIS];
  #endif
  if (st.counter_b > st.exec_block->step_event_count) {
    st.step_outbits |= (1<<B_STEP_BIT);
    st.counter_b -= st.exec_block->step_event_count;
    if (st.exec_block->direction_bits & (1<<B_DIRECTION_BIT)) { sys_position[B_AXIS]--; }
    else { sys_position[B_AXIS]++; }
  }
  #ifdef ADAPTIVE_MULTI_AXIS_STEP_SMOOTHING
    st.counter_c += st.steps[C_AXIS];
  #else
    st.counter_c += st.exec_block->steps[C_AXIS];
  #endif
  if (st.counter_c > st.exec_block->step_event_count) {
    st.step_outbits |= (1<<C_STEP_BIT);
    st.counter_c -= st.exec_block->step_event_count;
    if (st.exec_block->direction_bits & (1<<C_DIRECTION_BIT)) { sys_position[C_AXIS]--; }
    else { sys_position[C_AXIS]++; }
  }
 */
  // During a homing cycle, lock out and prevent desired axes from moving.
  if (sys.state == STATE_HOMING) { st.step_outbits &= sys.homing_axis_lock; }
--- a/grbl/system.c
+++ b/grbl/system.c
@ -185,6 +185,9 @@ uint8_t system_execute_line(char *line)
                case 'X': mc_homing_cycle(HOMING_CYCLE_X); break;
                case 'Y': mc_homing_cycle(HOMING_CYCLE_Y); break;
                case 'Z': mc_homing_cycle(HOMING_CYCLE_Z); break;
                case 'A': mc_homing_cycle(HOMING_CYCLE_A); break;
                //case 'B': mc_homing_cycle(HOMING_CYCLE_B); break;
                //case 'C': mc_homing_cycle(HOMING_CYCLE_C); break;
                default: return(STATUS_INVALID_STATEMENT);
              }
          #endif