b237ad566a
- Re-organized source code files into a ‘grbl’ directory to lessen one step in compiling Grbl through the Arduino IDE. - Added an ‘examples’ directory with an upload .INO sketch to further simplify compiling and uploading Grbl via the Arduino IDE. - Updated the Makefile with regard to the source code no longer being in the root directory. All files generated by compiling is placed in a separate ‘build’ directory to keep things tidy. The makefile should operate in the same way as it did before.
326 lines
22 KiB
C
326 lines
22 KiB
C
/*
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config.h - compile time configuration
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Part of Grbl v0.9
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Copyright (c) 2013-2015 Sungeun K. Jeon
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Grbl is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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Grbl is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with Grbl. If not, see <http://www.gnu.org/licenses/>.
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*/
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/*
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This file is based on work from Grbl v0.8, distributed under the
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terms of the MIT-license. See COPYING for more details.
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Copyright (c) 2009-2011 Simen Svale Skogsrud
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Copyright (c) 2011-2013 Sungeun K. Jeon
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*/
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// This file contains compile-time configurations for Grbl's internal system. For the most part,
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// users will not need to directly modify these, but they are here for specific needs, i.e.
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// performance tuning or adjusting to non-typical machines.
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// IMPORTANT: Any changes here requires a full re-compiling of the source code to propagate them.
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#ifndef config_h
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#define config_h
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// Default settings. Used when resetting EEPROM. Change to desired name in defaults.h
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#define DEFAULTS_GENERIC
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// Serial baud rate
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#define BAUD_RATE 115200
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// Default cpu mappings. Grbl officially supports the Arduino Uno only. Other processor types
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// may exist from user-supplied templates or directly user-defined in cpu_map.h
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#define CPU_MAP_ATMEGA328P // Arduino Uno CPU
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// Define realtime command special characters. These characters are 'picked-off' directly from the
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// serial read data stream and are not passed to the grbl line execution parser. Select characters
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// that do not and must not exist in the streamed g-code program. ASCII control characters may be
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// used, if they are available per user setup. Also, extended ASCII codes (>127), which are never in
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// g-code programs, maybe selected for interface programs.
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// NOTE: If changed, manually update help message in report.c.
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#define CMD_STATUS_REPORT '?'
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#define CMD_FEED_HOLD '!'
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#define CMD_CYCLE_START '~'
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#define CMD_RESET 0x18 // ctrl-x.
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// If homing is enabled, homing init lock sets Grbl into an alarm state upon power up. This forces
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// the user to perform the homing cycle (or override the locks) before doing anything else. This is
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// mainly a safety feature to remind the user to home, since position is unknown to Grbl.
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#define HOMING_INIT_LOCK // Comment to disable
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// Define the homing cycle patterns with bitmasks. The homing cycle first performs a search mode
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// to quickly engage the limit switches, followed by a slower locate mode, and finished by a short
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// pull-off motion to disengage the limit switches. The following HOMING_CYCLE_x defines are executed
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// in order starting with suffix 0 and completes the homing routine for the specified-axes only. If
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// an axis is omitted from the defines, it will not home, nor will the system update its position.
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// Meaning that this allows for users with non-standard cartesian machines, such as a lathe (x then z,
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// with no y), to configure the homing cycle behavior to their needs.
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// NOTE: The homing cycle is designed to allow sharing of limit pins, if the axes are not in the same
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// cycle, but this requires some pin settings changes in cpu_map.h file. For example, the default homing
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// cycle can share the Z limit pin with either X or Y limit pins, since they are on different cycles.
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// By sharing a pin, this frees up a precious IO pin for other purposes. In theory, all axes limit pins
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// may be reduced to one pin, if all axes are homed with seperate cycles, or vice versa, all three axes
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// on separate pin, but homed in one cycle. Also, it should be noted that the function of hard limits
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// will not be affected by pin sharing.
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// NOTE: Defaults are set for a traditional 3-axis CNC machine. Z-axis first to clear, followed by X & Y.
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#define HOMING_CYCLE_0 (1<<Z_AXIS) // REQUIRED: First move Z to clear workspace.
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#define HOMING_CYCLE_1 ((1<<X_AXIS)|(1<<Y_AXIS)) // OPTIONAL: Then move X,Y at the same time.
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// #define HOMING_CYCLE_2 // OPTIONAL: Uncomment and add axes mask to enable
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// Number of homing cycles performed after when the machine initially jogs to limit switches.
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// This help in preventing overshoot and should improve repeatability. This value should be one or
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// greater.
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#define N_HOMING_LOCATE_CYCLE 2 // Integer (1-128)
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// After homing, Grbl will set by default the entire machine space into negative space, as is typical
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// for professional CNC machines, regardless of where the limit switches are located. Uncomment this
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// define to force Grbl to always set the machine origin at the homed location despite switch orientation.
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// #define HOMING_FORCE_SET_ORIGIN // Uncomment to enable.
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// Number of blocks Grbl executes upon startup. These blocks are stored in EEPROM, where the size
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// and addresses are defined in settings.h. With the current settings, up to 2 startup blocks may
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// be stored and executed in order. These startup blocks would typically be used to set the g-code
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// parser state depending on user preferences.
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#define N_STARTUP_LINE 2 // Integer (1-2)
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// Number of floating decimal points printed by Grbl for certain value types. These settings are
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// determined by realistic and commonly observed values in CNC machines. For example, position
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// values cannot be less than 0.001mm or 0.0001in, because machines can not be physically more
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// precise this. So, there is likely no need to change these, but you can if you need to here.
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// NOTE: Must be an integer value from 0 to ~4. More than 4 may exhibit round-off errors.
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#define N_DECIMAL_COORDVALUE_INCH 4 // Coordinate or position value in inches
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#define N_DECIMAL_COORDVALUE_MM 3 // Coordinate or position value in mm
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#define N_DECIMAL_RATEVALUE_INCH 1 // Rate or velocity value in in/min
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#define N_DECIMAL_RATEVALUE_MM 0 // Rate or velocity value in mm/min
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#define N_DECIMAL_SETTINGVALUE 3 // Decimals for floating point setting values
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// If your machine has two limits switches wired in parallel to one axis, you will need to enable
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// this feature. Since the two switches are sharing a single pin, there is no way for Grbl to tell
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// which one is enabled. This option only effects homing, where if a limit is engaged, Grbl will
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// alarm out and force the user to manually disengage the limit switch. Otherwise, if you have one
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// limit switch for each axis, don't enable this option. By keeping it disabled, you can homing while
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// on the limit switch and not have to move the machine off of it.
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// #define LIMITS_TWO_SWITCHES_ON_AXES
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// Allows GRBL to track and report gcode line numbers. Enabling this means that the planning buffer
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// goes from 18 or 16 to make room for the additional line number data in the plan_block_t struct
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// #define USE_LINE_NUMBERS // Disabled by default. Uncomment to enable.
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// Allows GRBL to report the real-time feed rate. Enabling this means that GRBL will be reporting more
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// data with each status update.
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// NOTE: This is experimental and doesn't quite work 100%. Maybe fixed or refactored later.
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// #define REPORT_REALTIME_RATE // Disabled by default. Uncomment to enable.
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// Upon a successful probe cycle, this option provides immediately feedback of the probe coordinates
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// through an automatically generated message. If disabled, users can still access the last probe
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// coordinates through Grbl '$#' print parameters.
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#define MESSAGE_PROBE_COORDINATES // Enabled by default. Comment to disable.
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// Enables a second coolant control pin via the mist coolant g-code command M7 on the Arduino Uno
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// analog pin 5. Only use this option if you require a second coolant control pin.
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// NOTE: The M8 flood coolant control pin on analog pin 4 will still be functional regardless.
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// #define ENABLE_M7 // Disabled by default. Uncomment to enable.
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// Enable CoreXY kinematics. Use ONLY with CoreXY machines.
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// IMPORTANT: If homing is enabled, you must reconfigure the homing cycle #defines above to
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// #define HOMING_CYCLE_0 (1<<X_AXIS) and #define HOMING_CYCLE_1 (1<<Y_AXIS)
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// NOTE: This configuration option alters the motion of the X and Y axes to principle of operation
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// defined at (http://corexy.com/theory.html). Motors are assumed to positioned and wired exactly as
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// described, if not, motions may move in strange directions. Grbl assumes the CoreXY A and B motors
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// have the same steps per mm internally.
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// #define COREXY // Default disabled. Uncomment to enable.
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// Inverts pin logic of the control command pins. This essentially means when this option is enabled
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// you can use normally-closed switches, rather than the default normally-open switches.
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// NOTE: Will eventually be added to Grbl settings in v1.0.
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// #define INVERT_CONTROL_PIN // Default disabled. Uncomment to enable.
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// Enable input pin states feedback in status reports. The data is presented as a binary value with
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// the bits in the appropriate input pin ports being 0(low) or 1(high). Useful for setting up a new
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// CNC machine, but do not recommend keeping this option by default, as it will consume CPU resources
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// with little to no benefit during normal operation.
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// #define REPORT_INPUT_PIN_STATES // Default disabled. Uncomment to enable.
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// ---------------------------------------------------------------------------------------
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// ADVANCED CONFIGURATION OPTIONS:
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// The temporal resolution of the acceleration management subsystem. A higher number gives smoother
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// acceleration, particularly noticeable on machines that run at very high feedrates, but may negatively
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// impact performance. The correct value for this parameter is machine dependent, so it's advised to
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// set this only as high as needed. Approximate successful values can widely range from 50 to 200 or more.
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// NOTE: Changing this value also changes the execution time of a segment in the step segment buffer.
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// When increasing this value, this stores less overall time in the segment buffer and vice versa. Make
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// certain the step segment buffer is increased/decreased to account for these changes.
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#define ACCELERATION_TICKS_PER_SECOND 100
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// Adaptive Multi-Axis Step Smoothing (AMASS) is an advanced feature that does what its name implies,
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// smoothing the stepping of multi-axis motions. This feature smooths motion particularly at low step
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// frequencies below 10kHz, where the aliasing between axes of multi-axis motions can cause audible
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// noise and shake your machine. At even lower step frequencies, AMASS adapts and provides even better
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// step smoothing. See stepper.c for more details on the AMASS system works.
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#define ADAPTIVE_MULTI_AXIS_STEP_SMOOTHING // Default enabled. Comment to disable.
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// Sets the maximum step rate allowed to be written as a Grbl setting. This value is strictly limited
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// by the CPU speed and will change if something other than an AVR running at 16MHz is used.
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// NOTE: For now disabled, will enable if flash space permits.
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// #define MAX_STEP_RATE_HZ 30000 // Hz
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// By default, Grbl sets all input pins to normal-high operation with their internal pull-up resistors
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// enabled. This simplifies the wiring for users by requiring only a switch connected to ground,
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// although its recommended that users take the extra step of wiring in low-pass filter to reduce
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// electrical noise detected by the pin. If the user inverts the pin in Grbl settings, this just flips
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// which high or low reading indicates an active signal. In normal operation, this means the user
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// needs to connect a normal-open switch, but if inverted, this means the user should connect a
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// normal-closed switch.
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// The following options disable the internal pull-up resistors, sets the pins to a normal-low
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// operation, and switches must be now connect to Vcc instead of ground. This also flips the meaning
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// of the invert pin Grbl setting, where an inverted setting now means the user should connect a
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// normal-open switch and vice versa.
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// NOTE: All pins associated with the feature are disabled, i.e. XYZ limit pins, not individual axes.
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// WARNING: When the pull-ups are disabled, this requires additional wiring with pull-down resistors!
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//#define DISABLE_LIMIT_PIN_PULL_UP
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//#define DISABLE_PROBE_PIN_PULL_UP
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//#define DISABLE_CONTROL_PIN_PULL_UP
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// Sets which axis the tool length offset is applied. Assumes the spindle is always parallel with
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// the selected axis with the tool oriented toward the negative direction. In other words, a positive
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// tool length offset value is subtracted from the current location.
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#define TOOL_LENGTH_OFFSET_AXIS Z_AXIS // Default z-axis. Valid values are X_AXIS, Y_AXIS, or Z_AXIS.
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// Enables variable spindle output voltage for different RPM values. On the Arduino Uno, the spindle
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// enable pin will output 5V for maximum RPM with 256 intermediate levels and 0V when disabled.
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// NOTE: IMPORTANT for Arduino Unos! When enabled, the Z-limit pin D11 and spindle enable pin D12 switch!
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// The hardware PWM output on pin D11 is required for variable spindle output voltages.
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#define VARIABLE_SPINDLE // Default disabled. Uncomment to enable.
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// Used by the variable spindle output only. These parameters set the maximum and minimum spindle speed
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// "S" g-code values to correspond to the maximum and minimum pin voltages. There are 256 discrete and
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// equally divided voltage bins between the maximum and minimum spindle speeds. So for a 5V pin, 1000
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// max rpm, and 250 min rpm, the spindle output voltage would be set for the following "S" commands:
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// "S1000" @ 5V, "S250" @ 0.02V, and "S625" @ 2.5V (mid-range). The pin outputs 0V when disabled.
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#define SPINDLE_MAX_RPM 1000.0 // Max spindle RPM. This value is equal to 100% duty cycle on the PWM.
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#define SPINDLE_MIN_RPM 0.0 // Min spindle RPM. This value is equal to (1/256) duty cycle on the PWM.
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// Used by variable spindle output only. This forces the PWM output to a minimum duty cycle when enabled.
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// When disabled, the PWM pin will still read 0V. Most users will not need this option, but it may be
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// useful in certain scenarios. This setting does not update the minimum spindle RPM calculations. Any
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// spindle RPM output lower than this value will be set to this value.
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// #define MINIMUM_SPINDLE_PWM 5 // Default disabled. Uncomment to enable. Integer (0-255)
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// Minimum planner junction speed. Sets the default minimum junction speed the planner plans to at
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// every buffer block junction, except for starting from rest and end of the buffer, which are always
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// zero. This value controls how fast the machine moves through junctions with no regard for acceleration
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// limits or angle between neighboring block line move directions. This is useful for machines that can't
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// tolerate the tool dwelling for a split second, i.e. 3d printers or laser cutters. If used, this value
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// should not be much greater than zero or to the minimum value necessary for the machine to work.
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#define MINIMUM_JUNCTION_SPEED 0.0 // (mm/min)
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// Sets the minimum feed rate the planner will allow. Any value below it will be set to this minimum
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// value. This also ensures that a planned motion always completes and accounts for any floating-point
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// round-off errors. A lower value than 1.0 mm/min may work in some cases, but we don't recommend it.
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#define MINIMUM_FEED_RATE 1.0 // (mm/min)
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// Number of arc generation iterations by small angle approximation before exact arc trajectory
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// correction with expensive sin() and cos() calcualtions. This parameter maybe decreased if there
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// are issues with the accuracy of the arc generations, or increased if arc execution is getting
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// bogged down by too many trig calculations.
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#define N_ARC_CORRECTION 12 // Integer (1-255)
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// Time delay increments performed during a dwell. The default value is set at 50ms, which provides
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// a maximum time delay of roughly 55 minutes, more than enough for most any application. Increasing
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// this delay will increase the maximum dwell time linearly, but also reduces the responsiveness of
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// run-time command executions, like status reports, since these are performed between each dwell
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// time step. Also, keep in mind that the Arduino delay timer is not very accurate for long delays.
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#define DWELL_TIME_STEP 50 // Integer (1-255) (milliseconds)
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// Creates a delay between the direction pin setting and corresponding step pulse by creating
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// another interrupt (Timer2 compare) to manage it. The main Grbl interrupt (Timer1 compare)
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// sets the direction pins, and does not immediately set the stepper pins, as it would in
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// normal operation. The Timer2 compare fires next to set the stepper pins after the step
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// pulse delay time, and Timer2 overflow will complete the step pulse, except now delayed
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// by the step pulse time plus the step pulse delay. (Thanks langwadt for the idea!)
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// NOTE: Uncomment to enable. The recommended delay must be > 3us, and, when added with the
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// user-supplied step pulse time, the total time must not exceed 127us. Reported successful
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// values for certain setups have ranged from 5 to 20us.
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// #define STEP_PULSE_DELAY 10 // Step pulse delay in microseconds. Default disabled.
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// The number of linear motions in the planner buffer to be planned at any give time. The vast
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// majority of RAM that Grbl uses is based on this buffer size. Only increase if there is extra
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// available RAM, like when re-compiling for a Mega or Sanguino. Or decrease if the Arduino
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// begins to crash due to the lack of available RAM or if the CPU is having trouble keeping
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// up with planning new incoming motions as they are executed.
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// #define BLOCK_BUFFER_SIZE 18 // Uncomment to override default in planner.h.
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// Governs the size of the intermediary step segment buffer between the step execution algorithm
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// and the planner blocks. Each segment is set of steps executed at a constant velocity over a
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// fixed time defined by ACCELERATION_TICKS_PER_SECOND. They are computed such that the planner
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// block velocity profile is traced exactly. The size of this buffer governs how much step
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// execution lead time there is for other Grbl processes have to compute and do their thing
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// before having to come back and refill this buffer, currently at ~50msec of step moves.
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// #define SEGMENT_BUFFER_SIZE 6 // Uncomment to override default in stepper.h.
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// Line buffer size from the serial input stream to be executed. Also, governs the size of
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// each of the startup blocks, as they are each stored as a string of this size. Make sure
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// to account for the available EEPROM at the defined memory address in settings.h and for
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// the number of desired startup blocks.
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// NOTE: 80 characters is not a problem except for extreme cases, but the line buffer size
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// can be too small and g-code blocks can get truncated. Officially, the g-code standards
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// support up to 256 characters. In future versions, this default will be increased, when
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// we know how much extra memory space we can re-invest into this.
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// #define LINE_BUFFER_SIZE 80 // Uncomment to override default in protocol.h
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// Serial send and receive buffer size. The receive buffer is often used as another streaming
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// buffer to store incoming blocks to be processed by Grbl when its ready. Most streaming
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// interfaces will character count and track each block send to each block response. So,
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// increase the receive buffer if a deeper receive buffer is needed for streaming and avaiable
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// memory allows. The send buffer primarily handles messages in Grbl. Only increase if large
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// messages are sent and Grbl begins to stall, waiting to send the rest of the message.
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// NOTE: Buffer size values must be greater than zero and less than 256.
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// #define RX_BUFFER_SIZE 128 // Uncomment to override defaults in serial.h
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// #define TX_BUFFER_SIZE 64
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// Toggles XON/XOFF software flow control for serial communications. Not officially supported
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// due to problems involving the Atmega8U2 USB-to-serial chips on current Arduinos. The firmware
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// on these chips do not support XON/XOFF flow control characters and the intermediate buffer
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// in the chips cause latency and overflow problems with standard terminal programs. However,
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// using specifically-programmed UI's to manage this latency problem has been confirmed to work.
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// As well as, older FTDI FT232RL-based Arduinos(Duemilanove) are known to work with standard
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// terminal programs since their firmware correctly manage these XON/XOFF characters. In any
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// case, please report any successes to grbl administrators!
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// #define ENABLE_XONXOFF // Default disabled. Uncomment to enable.
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// A simple software debouncing feature for hard limit switches. When enabled, the interrupt
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// monitoring the hard limit switch pins will enable the Arduino's watchdog timer to re-check
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// the limit pin state after a delay of about 32msec. This can help with CNC machines with
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// problematic false triggering of their hard limit switches, but it WILL NOT fix issues with
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// electrical interference on the signal cables from external sources. It's recommended to first
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// use shielded signal cables with their shielding connected to ground (old USB/computer cables
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// work well and are cheap to find) and wire in a low-pass circuit into each limit pin.
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// #define ENABLE_SOFTWARE_DEBOUNCE // Default disabled. Uncomment to enable.
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// ---------------------------------------------------------------------------------------
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// TODO: Install compile-time option to send numeric status codes rather than strings.
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// ---------------------------------------------------------------------------------------
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// COMPILE-TIME ERROR CHECKING OF DEFINE VALUES:
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// ---------------------------------------------------------------------------------------
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#endif
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