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grbl
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/* | |
config.h - compile time configuration | |
Part of Grbl | |
Copyright (c) 2012-2016 Sungeun K. Jeon for Gnea Research LLC | |
Copyright (c) 2009-2011 Simen Svale Skogsrud | |
Grbl is free software: you can redistribute it and/or modify | |
it under the terms of the GNU General Public License as published by | |
the Free Software Foundation, either version 3 of the License, or | |
(at your option) any later version. | |
Grbl is distributed in the hope that it will be useful, | |
but WITHOUT ANY WARRANTY; without even the implied warranty of | |
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the | |
GNU General Public License for more details. | |
You should have received a copy of the GNU General Public License | |
along with Grbl. If not, see <http://www.gnu.org/licenses/>. | |
*/ | |
// This file contains compile-time configurations for Grbl's internal system. For the most part, | |
// users will not need to directly modify these, but they are here for specific needs, i.e. | |
// performance tuning or adjusting to non-typical machines. | |
// IMPORTANT: Any changes here requires a full re-compiling of the source code to propagate them. | |
#ifndef config_h | |
#define config_h | |
#include "grbl.h" // For Arduino IDE compatibility. | |
// Define CPU pin map and default settings. | |
// 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_ATMEGA328P // Arduino Uno CPU | |
// Serial baud rate | |
// #define BAUD_RATE 230400 | |
#define BAUD_RATE 115200 | |
// Define realtime command special characters. These characters are 'picked-off' directly from the | |
// serial read data stream and are not passed to the grbl line execution parser. Select characters | |
// that do not and must not exist in the streamed g-code program. ASCII control characters may be | |
// used, if they are available per user setup. Also, extended ASCII codes (>127), which are never in | |
// g-code programs, maybe selected for interface programs. | |
// NOTE: If changed, manually update help message in report.c. | |
#define CMD_RESET 0x18 // ctrl-x. | |
#define CMD_STATUS_REPORT '?' | |
#define CMD_CYCLE_START '~' | |
#define CMD_FEED_HOLD '!' | |
// NOTE: All override realtime commands must be in the extended ASCII character set, starting | |
// at character value 128 (0x80) and up to 255 (0xFF). If the normal set of realtime commands, | |
// such as status reports, feed hold, reset, and cycle start, are moved to the extended set | |
// space, serial.c's RX ISR will need to be modified to accomodate the change. | |
// #define CMD_RESET 0x80 | |
// #define CMD_STATUS_REPORT 0x81 | |
// #define CMD_CYCLE_START 0x82 | |
// #define CMD_FEED_HOLD 0x83 | |
#define CMD_SAFETY_DOOR 0x84 | |
#define CMD_JOG_CANCEL 0x85 | |
#define CMD_DEBUG_REPORT 0x86 // Only when DEBUG enabled, sends debug report in '{}' braces. | |
#define CMD_FEED_OVR_RESET 0x90 // Restores feed override value to 100%. | |
#define CMD_FEED_OVR_COARSE_PLUS 0x91 | |
#define CMD_FEED_OVR_COARSE_MINUS 0x92 | |
#define CMD_FEED_OVR_FINE_PLUS 0x93 | |
#define CMD_FEED_OVR_FINE_MINUS 0x94 | |
#define CMD_RAPID_OVR_RESET 0x95 // Restores rapid override value to 100%. | |
#define CMD_RAPID_OVR_MEDIUM 0x96 | |
#define CMD_RAPID_OVR_LOW 0x97 | |
// #define CMD_RAPID_OVR_EXTRA_LOW 0x98 // *NOT SUPPORTED* | |
#define CMD_SPINDLE_OVR_RESET 0x99 // Restores spindle override value to 100%. | |
#define CMD_SPINDLE_OVR_COARSE_PLUS 0x9A | |
#define CMD_SPINDLE_OVR_COARSE_MINUS 0x9B | |
#define CMD_SPINDLE_OVR_FINE_PLUS 0x9C | |
#define CMD_SPINDLE_OVR_FINE_MINUS 0x9D | |
#define CMD_SPINDLE_OVR_STOP 0x9E | |
#define CMD_COOLANT_FLOOD_OVR_TOGGLE 0xA0 | |
#define CMD_COOLANT_MIST_OVR_TOGGLE 0xA1 | |
// If homing is enabled, homing init lock sets Grbl into an alarm state upon power up. This forces | |
// the user to perform the homing cycle (or override the locks) before doing anything else. This is | |
// mainly a safety feature to remind the user to home, since position is unknown to Grbl. | |
#define HOMING_INIT_LOCK // Comment to disable | |
// Define the homing cycle patterns with bitmasks. The homing cycle first performs a search mode | |
// to quickly engage the limit switches, followed by a slower locate mode, and finished by a short | |
// pull-off motion to disengage the limit switches. The following HOMING_CYCLE_x defines are executed | |
// in order starting with suffix 0 and completes the homing routine for the specified-axes only. If | |
// an axis is omitted from the defines, it will not home, nor will the system update its position. | |
// Meaning that this allows for users with non-standard cartesian machines, such as a lathe (x then z, | |
// with no y), to configure the homing cycle behavior to their needs. | |
// NOTE: The homing cycle is designed to allow sharing of limit pins, if the axes are not in the same | |
// cycle, but this requires some pin settings changes in cpu_map.h file. For example, the default homing | |
// cycle can share the Z limit pin with either X or Y limit pins, since they are on different cycles. | |
// By sharing a pin, this frees up a precious IO pin for other purposes. In theory, all axes limit pins | |
// may be reduced to one pin, if all axes are homed with seperate cycles, or vice versa, all three axes | |
// on separate pin, but homed in one cycle. Also, it should be noted that the function of hard limits | |
// will not be affected by pin sharing. | |
// NOTE: Defaults are set for a traditional 3-axis CNC machine. Z-axis first to clear, followed by X & Y. | |
// #define HOMING_CYCLE_0 (1<<Z_AXIS) // REQUIRED: First move Z to clear workspace. | |
// #define HOMING_CYCLE_1 ((1<<X_AXIS)|(1<<Y_AXIS)) // OPTIONAL: Then move X,Y at the same time. | |
// #define HOMING_CYCLE_2 // OPTIONAL: Uncomment and add axes mask to enable | |
// NOTE: The following are two examples to setup homing for 2-axis machines. | |
// #define HOMING_CYCLE_0 ((1<<X_AXIS)|(1<<Y_AXIS)) // NOT COMPATIBLE WITH COREXY: Homes both X-Y in one cycle. | |
#define HOMING_CYCLE_0 (1<<X_AXIS) // COREXY COMPATIBLE: First home X | |
#define HOMING_CYCLE_1 (1<<Y_AXIS) // COREXY COMPATIBLE: Then home Y | |
// Number of homing cycles performed after when the machine initially jogs to limit switches. | |
// This help in preventing overshoot and should improve repeatability. This value should be one or | |
// greater. | |
#define N_HOMING_LOCATE_CYCLE 1 // Integer (1-128) | |
// Enables single axis homing commands. $HX, $HY, and $HZ for X, Y, and Z-axis homing. The full homing | |
// cycle is still invoked by the $H command. This is disabled by default. It's here only to address | |
// users that need to switch between a two-axis and three-axis machine. This is actually very rare. | |
// If you have a two-axis machine, DON'T USE THIS. Instead, just alter the homing cycle for two-axes. | |
// #define HOMING_SINGLE_AXIS_COMMANDS // Default disabled. Uncomment to enable. | |
// After homing, Grbl will set by default the entire machine space into negative space, as is typical | |
// for professional CNC machines, regardless of where the limit switches are located. Uncomment this | |
// define to force Grbl to always set the machine origin at the homed location despite switch orientation. | |
#define HOMING_FORCE_SET_ORIGIN // Uncomment to enable. | |
// Number of blocks Grbl executes upon startup. These blocks are stored in EEPROM, where the size | |
// and addresses are defined in settings.h. With the current settings, up to 2 startup blocks may | |
// be stored and executed in order. These startup blocks would typically be used to set the g-code | |
// parser state depending on user preferences. | |
#define N_STARTUP_LINE 2 // Integer (1-2) | |
// Number of floating decimal points printed by Grbl for certain value types. These settings are | |
// determined by realistic and commonly observed values in CNC machines. For example, position | |
// values cannot be less than 0.001mm or 0.0001in, because machines can not be physically more | |
// precise this. So, there is likely no need to change these, but you can if you need to here. | |
// NOTE: Must be an integer value from 0 to ~4. More than 4 may exhibit round-off errors. | |
#define N_DECIMAL_COORDVALUE_INCH 4 // Coordinate or position value in inches | |
#define N_DECIMAL_COORDVALUE_MM 3 // Coordinate or position value in mm | |
#define N_DECIMAL_RATEVALUE_INCH 1 // Rate or velocity value in in/min | |
#define N_DECIMAL_RATEVALUE_MM 0 // Rate or velocity value in mm/min | |
#define N_DECIMAL_SETTINGVALUE 3 // Decimals for floating point setting values | |
#define N_DECIMAL_RPMVALUE 0 // RPM value in rotations per min. | |
// If your machine has two limits switches wired in parallel to one axis, you will need to enable | |
// this feature. Since the two switches are sharing a single pin, there is no way for Grbl to tell | |
// which one is enabled. This option only effects homing, where if a limit is engaged, Grbl will | |
// alarm out and force the user to manually disengage the limit switch. Otherwise, if you have one | |
// limit switch for each axis, don't enable this option. By keeping it disabled, you can perform a | |
// homing cycle while on the limit switch and not have to move the machine off of it. | |
// #define LIMITS_TWO_SWITCHES_ON_AXES | |
// Allows GRBL to track and report gcode line numbers. Enabling this means that the planning buffer | |
// goes from 16 to 15 to make room for the additional line number data in the plan_block_t struct | |
// #define USE_LINE_NUMBERS // Disabled by default. Uncomment to enable. | |
// Upon a successful probe cycle, this option provides immediately feedback of the probe coordinates | |
// through an automatically generated message. If disabled, users can still access the last probe | |
// coordinates through Grbl '$#' print parameters. | |
#define MESSAGE_PROBE_COORDINATES // Enabled by default. Comment to disable. | |
// Enables a second coolant control pin via the mist coolant g-code command M7 on the Arduino Uno | |
// analog pin 4. Only use this option if you require a second coolant control pin. | |
// NOTE: The M8 flood coolant control pin on analog pin 3 will still be functional regardless. | |
// #define ENABLE_M7 // Disabled by default. Uncomment to enable. | |
// This option causes the feed hold input to act as a safety door switch. A safety door, when triggered, | |
// immediately forces a feed hold and then safely de-energizes the machine. Resuming is blocked until | |
// the safety door is re-engaged. When it is, Grbl will re-energize the machine and then resume on the | |
// previous tool path, as if nothing happened. | |
// #define ENABLE_SAFETY_DOOR_INPUT_PIN // Default disabled. Uncomment to enable. | |
// After the safety door switch has been toggled and restored, this setting sets the power-up delay | |
// between restoring the spindle and coolant and resuming the cycle. | |
#define SAFETY_DOOR_SPINDLE_DELAY 4.0 // Float (seconds) | |
#define SAFETY_DOOR_COOLANT_DELAY 1.0 // Float (seconds) | |
// Enable CoreXY kinematics. Use ONLY with CoreXY machines. | |
// IMPORTANT: If homing is enabled, you must reconfigure the homing cycle #defines above to | |
// #define HOMING_CYCLE_0 (1<<X_AXIS) and #define HOMING_CYCLE_1 (1<<Y_AXIS) | |
// NOTE: This configuration option alters the motion of the X and Y axes to principle of operation | |
// defined at (http://corexy.com/theory.html). Motors are assumed to positioned and wired exactly as | |
// described, if not, motions may move in strange directions. Grbl requires the CoreXY A and B motors | |
// have the same steps per mm internally. | |
// #define COREXY // Default disabled. Uncomment to enable. | |
// Inverts pin logic of the control command pins based on a mask. This essentially means you can use | |
// normally-closed switches on the specified pins, rather than the default normally-open switches. | |
// NOTE: The top option will mask and invert all control pins. The bottom option is an example of | |
// inverting only two control pins, the safety door and reset. See cpu_map.h for other bit definitions. | |
// #define INVERT_CONTROL_PIN_MASK CONTROL_MASK // Default disabled. Uncomment to disable. | |
// #define INVERT_CONTROL_PIN_MASK ((1<<CONTROL_SAFETY_DOOR_BIT)|(CONTROL_RESET_BIT)) // Default disabled. | |
// Inverts select limit pin states based on the following mask. This effects all limit pin functions, | |
// such as hard limits and homing. However, this is different from overall invert limits setting. | |
// This build option will invert only the limit pins defined here, and then the invert limits setting | |
// will be applied to all of them. This is useful when a user has a mixed set of limit pins with both | |
// normally-open(NO) and normally-closed(NC) switches installed on their machine. | |
// NOTE: PLEASE DO NOT USE THIS, unless you have a situation that needs it. | |
// #define INVERT_LIMIT_PIN_MASK ((1<<X_LIMIT_BIT)|(1<<Y_LIMIT_BIT)) // Default disabled. Uncomment to enable. | |
// Inverts the spindle enable pin from low-disabled/high-enabled to low-enabled/high-disabled. Useful | |
// for some pre-built electronic boards. | |
// NOTE: If VARIABLE_SPINDLE is enabled(default), this option has no effect as the PWM output and | |
// spindle enable are combined to one pin. If you need both this option and spindle speed PWM, | |
// uncomment the config option USE_SPINDLE_DIR_AS_ENABLE_PIN below. | |
// #define INVERT_SPINDLE_ENABLE_PIN // Default disabled. Uncomment to enable. | |
// Inverts the selected coolant pin from low-disabled/high-enabled to low-enabled/high-disabled. Useful | |
// for some pre-built electronic boards. | |
// #define INVERT_COOLANT_FLOOD_PIN // Default disabled. Uncomment to enable. | |
// #define INVERT_COOLANT_MIST_PIN // Default disabled. Note: Enable M7 mist coolant in config.h | |
// When Grbl powers-cycles or is hard reset with the Arduino reset button, Grbl boots up with no ALARM | |
// by default. This is to make it as simple as possible for new users to start using Grbl. When homing | |
// is enabled and a user has installed limit switches, Grbl will boot up in an ALARM state to indicate | |
// Grbl doesn't know its position and to force the user to home before proceeding. This option forces | |
// Grbl to always initialize into an ALARM state regardless of homing or not. This option is more for | |
// OEMs and LinuxCNC users that would like this power-cycle behavior. | |
// #define FORCE_INITIALIZATION_ALARM // Default disabled. Uncomment to enable. | |
// At power-up or a reset, Grbl will check the limit switch states to ensure they are not active | |
// before initialization. If it detects a problem and the hard limits setting is enabled, Grbl will | |
// simply message the user to check the limits and enter an alarm state, rather than idle. Grbl will | |
// not throw an alarm message. | |
#define CHECK_LIMITS_AT_INIT | |
// --------------------------------------------------------------------------------------- | |
// ADVANCED CONFIGURATION OPTIONS: | |
// Enables code for debugging purposes. Not for general use and always in constant flux. | |
// #define DEBUG // Uncomment to enable. Default disabled. | |
// Configure rapid, feed, and spindle override settings. These values define the max and min | |
// allowable override values and the coarse and fine increments per command received. Please | |
// note the allowable values in the descriptions following each define. | |
#define DEFAULT_FEED_OVERRIDE 100 // 100%. Don't change this value. | |
#define MAX_FEED_RATE_OVERRIDE 200 // Percent of programmed feed rate (100-255). Usually 120% or 200% | |
#define MIN_FEED_RATE_OVERRIDE 10 // Percent of programmed feed rate (1-100). Usually 50% or 1% | |
#define FEED_OVERRIDE_COARSE_INCREMENT 10 // (1-99). Usually 10%. | |
#define FEED_OVERRIDE_FINE_INCREMENT 1 // (1-99). Usually 1%. | |
#define DEFAULT_RAPID_OVERRIDE 100 // 100%. Don't change this value. | |
#define RAPID_OVERRIDE_MEDIUM 50 // Percent of rapid (1-99). Usually 50%. | |
#define RAPID_OVERRIDE_LOW 25 // Percent of rapid (1-99). Usually 25%. | |
// #define RAPID_OVERRIDE_EXTRA_LOW 5 // *NOT SUPPORTED* Percent of rapid (1-99). Usually 5%. | |
#define DEFAULT_SPINDLE_SPEED_OVERRIDE 100 // 100%. Don't change this value. | |
#define MAX_SPINDLE_SPEED_OVERRIDE 200 // Percent of programmed spindle speed (100-255). Usually 200%. | |
#define MIN_SPINDLE_SPEED_OVERRIDE 10 // Percent of programmed spindle speed (1-100). Usually 10%. | |
#define SPINDLE_OVERRIDE_COARSE_INCREMENT 10 // (1-99). Usually 10%. | |
#define SPINDLE_OVERRIDE_FINE_INCREMENT 1 // (1-99). Usually 1%. | |
// When a M2 or M30 program end command is executed, most g-code states are restored to their defaults. | |
// This compile-time option includes the restoring of the feed, rapid, and spindle speed override values | |
// to their default values at program end. | |
#define RESTORE_OVERRIDES_AFTER_PROGRAM_END // Default enabled. Comment to disable. | |
// The status report change for Grbl v1.1 and after also removed the ability to disable/enable most data | |
// fields from the report. This caused issues for GUI developers, who've had to manage several scenarios | |
// and configurations. The increased efficiency of the new reporting style allows for all data fields to | |
// be sent without potential performance issues. | |
// NOTE: The options below are here only provide a way to disable certain data fields if a unique | |
// situation demands it, but be aware GUIs may depend on this data. If disabled, it may not be compatible. | |
#define REPORT_FIELD_BUFFER_STATE // Default enabled. Comment to disable. | |
#define REPORT_FIELD_PIN_STATE // Default enabled. Comment to disable. | |
#define REPORT_FIELD_CURRENT_FEED_SPEED // Default enabled. Comment to disable. | |
#define REPORT_FIELD_WORK_COORD_OFFSET // Default enabled. Comment to disable. | |
#define REPORT_FIELD_OVERRIDES // Default enabled. Comment to disable. | |
#define REPORT_FIELD_LINE_NUMBERS // Default enabled. Comment to disable. | |
// Some status report data isn't necessary for realtime, only intermittently, because the values don't | |
// change often. The following macros configures how many times a status report needs to be called before | |
// the associated data is refreshed and included in the status report. However, if one of these value | |
// changes, Grbl will automatically include this data in the next status report, regardless of what the | |
// count is at the time. This helps reduce the communication overhead involved with high frequency reporting | |
// and agressive streaming. There is also a busy and an idle refresh count, which sets up Grbl to send | |
// refreshes more often when its not doing anything important. With a good GUI, this data doesn't need | |
// to be refreshed very often, on the order of a several seconds. | |
// NOTE: WCO refresh must be 2 or greater. OVR refresh must be 1 or greater. | |
#define REPORT_OVR_REFRESH_BUSY_COUNT 20 // (1-255) | |
#define REPORT_OVR_REFRESH_IDLE_COUNT 10 // (1-255) Must be less than or equal to the busy count | |
#define REPORT_WCO_REFRESH_BUSY_COUNT 30 // (2-255) | |
#define REPORT_WCO_REFRESH_IDLE_COUNT 10 // (2-255) Must be less than or equal to the busy count | |
// The temporal resolution of the acceleration management subsystem. A higher number gives smoother | |
// acceleration, particularly noticeable on machines that run at very high feedrates, but may negatively | |
// impact performance. The correct value for this parameter is machine dependent, so it's advised to | |
// set this only as high as needed. Approximate successful values can widely range from 50 to 200 or more. | |
// NOTE: Changing this value also changes the execution time of a segment in the step segment buffer. | |
// When increasing this value, this stores less overall time in the segment buffer and vice versa. Make | |
// certain the step segment buffer is increased/decreased to account for these changes. | |
#define ACCELERATION_TICKS_PER_SECOND 100 | |
// Adaptive Multi-Axis Step Smoothing (AMASS) is an advanced feature that does what its name implies, | |
// smoothing the stepping of multi-axis motions. This feature smooths motion particularly at low step | |
// frequencies below 10kHz, where the aliasing between axes of multi-axis motions can cause audible | |
// noise and shake your machine. At even lower step frequencies, AMASS adapts and provides even better | |
// step smoothing. See stepper.c for more details on the AMASS system works. | |
#define ADAPTIVE_MULTI_AXIS_STEP_SMOOTHING // Default enabled. Comment to disable. | |
// Sets the maximum step rate allowed to be written as a Grbl setting. This option enables an error | |
// check in the settings module to prevent settings values that will exceed this limitation. The maximum | |
// step rate is strictly limited by the CPU speed and will change if something other than an AVR running | |
// at 16MHz is used. | |
// NOTE: For now disabled, will enable if flash space permits. | |
// #define MAX_STEP_RATE_HZ 30000 // Hz | |
// By default, Grbl sets all input pins to normal-high operation with their internal pull-up resistors | |
// enabled. This simplifies the wiring for users by requiring only a switch connected to ground, | |
// although its recommended that users take the extra step of wiring in low-pass filter to reduce | |
// electrical noise detected by the pin. If the user inverts the pin in Grbl settings, this just flips | |
// which high or low reading indicates an active signal. In normal operation, this means the user | |
// needs to connect a normal-open switch, but if inverted, this means the user should connect a | |
// normal-closed switch. | |
// The following options disable the internal pull-up resistors, sets the pins to a normal-low | |
// operation, and switches must be now connect to Vcc instead of ground. This also flips the meaning | |
// of the invert pin Grbl setting, where an inverted setting now means the user should connect a | |
// normal-open switch and vice versa. | |
// NOTE: All pins associated with the feature are disabled, i.e. XYZ limit pins, not individual axes. | |
// WARNING: When the pull-ups are disabled, this requires additional wiring with pull-down resistors! | |
//#define DISABLE_LIMIT_PIN_PULL_UP | |
//#define DISABLE_PROBE_PIN_PULL_UP | |
//#define DISABLE_CONTROL_PIN_PULL_UP | |
// Sets which axis the tool length offset is applied. Assumes the spindle is always parallel with | |
// the selected axis with the tool oriented toward the negative direction. In other words, a positive | |
// tool length offset value is subtracted from the current location. | |
#define TOOL_LENGTH_OFFSET_AXIS Z_AXIS // Default z-axis. Valid values are X_AXIS, Y_AXIS, or Z_AXIS. | |
// Enables variable spindle output voltage for different RPM values. On the Arduino Uno, the spindle | |
// enable pin will output 5V for maximum RPM with 256 intermediate levels and 0V when disabled. | |
// NOTE: IMPORTANT for Arduino Unos! When enabled, the Z-limit pin D11 and spindle enable pin D12 switch! | |
// The hardware PWM output on pin D11 is required for variable spindle output voltages. | |
#define VARIABLE_SPINDLE // Default enabled. Comment to disable. | |
// Used by variable spindle output only. This forces the PWM output to a minimum duty cycle when enabled. | |
// The PWM pin will still read 0V when the spindle is disabled. Most users will not need this option, but | |
// it may be useful in certain scenarios. This minimum PWM settings coincides with the spindle rpm minimum | |
// setting, like rpm max to max PWM. This is handy if you need a larger voltage difference between 0V disabled | |
// and the voltage set by the minimum PWM for minimum rpm. This difference is 0.02V per PWM value. So, when | |
// minimum PWM is at 1, only 0.02 volts separate enabled and disabled. At PWM 5, this would be 0.1V. Keep | |
// in mind that you will begin to lose PWM resolution with increased minimum PWM values, since you have less | |
// and less range over the total 255 PWM levels to signal different spindle speeds. | |
// NOTE: Compute duty cycle at the minimum PWM by this equation: (% duty cycle)=(SPINDLE_PWM_MIN_VALUE/255)*100 | |
// #define SPINDLE_PWM_MIN_VALUE 5 // Default disabled. Uncomment to enable. Must be greater than zero. Integer (1-255). | |
// By default on a 328p(Uno), Grbl combines the variable spindle PWM and the enable into one pin to help | |
// preserve I/O pins. For certain setups, these may need to be separate pins. This configure option uses | |
// the spindle direction pin(D13) as a separate spindle enable pin along with spindle speed PWM on pin D11. | |
// NOTE: This configure option only works with VARIABLE_SPINDLE enabled and a 328p processor (Uno). | |
// NOTE: Without a direction pin, M4 will not have a pin output to indicate a difference with M3. | |
// NOTE: BEWARE! The Arduino bootloader toggles the D13 pin when it powers up. If you flash Grbl with | |
// a programmer (you can use a spare Arduino as "Arduino as ISP". Search the web on how to wire this.), | |
// this D13 LED toggling should go away. We haven't tested this though. Please report how it goes! | |
// #define USE_SPINDLE_DIR_AS_ENABLE_PIN // Default disabled. Uncomment to enable. | |
// Alters the behavior of the spindle enable pin with the USE_SPINDLE_DIR_AS_ENABLE_PIN option . By default, | |
// Grbl will not disable the enable pin if spindle speed is zero and M3/4 is active, but still sets the PWM | |
// output to zero. This allows the users to know if the spindle is active and use it as an additional control | |
// input. However, in some use cases, user may want the enable pin to disable with a zero spindle speed and | |
// re-enable when spindle speed is greater than zero. This option does that. | |
// NOTE: Requires USE_SPINDLE_DIR_AS_ENABLE_PIN to be enabled. | |
// #define SPINDLE_ENABLE_OFF_WITH_ZERO_SPEED // Default disabled. Uncomment to enable. | |
// With this enabled, Grbl sends back an echo of the line it has received, which has been pre-parsed (spaces | |
// removed, capitalized letters, no comments) and is to be immediately executed by Grbl. Echoes will not be | |
// sent upon a line buffer overflow, but should for all normal lines sent to Grbl. For example, if a user | |
// sendss the line 'g1 x1.032 y2.45 (test comment)', Grbl will echo back in the form '[echo: G1X1.032Y2.45]'. | |
// NOTE: Only use this for debugging purposes!! When echoing, this takes up valuable resources and can effect | |
// performance. If absolutely needed for normal operation, the serial write buffer should be greatly increased | |
// to help minimize transmission waiting within the serial write protocol. | |
// #define REPORT_ECHO_LINE_RECEIVED // Default disabled. Uncomment to enable. | |
// Minimum planner junction speed. Sets the default minimum junction speed the planner plans to at | |
// every buffer block junction, except for starting from rest and end of the buffer, which are always | |
// zero. This value controls how fast the machine moves through junctions with no regard for acceleration | |
// limits or angle between neighboring block line move directions. This is useful for machines that can't | |
// tolerate the tool dwelling for a split second, i.e. 3d printers or laser cutters. If used, this value | |
// should not be much greater than zero or to the minimum value necessary for the machine to work. | |
#define MINIMUM_JUNCTION_SPEED 0.0 // (mm/min) | |
// Sets the minimum feed rate the planner will allow. Any value below it will be set to this minimum | |
// value. This also ensures that a planned motion always completes and accounts for any floating-point | |
// round-off errors. Although not recommended, a lower value than 1.0 mm/min will likely work in smaller | |
// machines, perhaps to 0.1mm/min, but your success may vary based on multiple factors. | |
#define MINIMUM_FEED_RATE 1.0 // (mm/min) | |
// Number of arc generation iterations by small angle approximation before exact arc trajectory | |
// correction with expensive sin() and cos() calcualtions. This parameter maybe decreased if there | |
// are issues with the accuracy of the arc generations, or increased if arc execution is getting | |
// bogged down by too many trig calculations. | |
#define N_ARC_CORRECTION 12 // Integer (1-255) | |
// The arc G2/3 g-code standard is problematic by definition. Radius-based arcs have horrible numerical | |
// errors when arc at semi-circles(pi) or full-circles(2*pi). Offset-based arcs are much more accurate | |
// but still have a problem when arcs are full-circles (2*pi). This define accounts for the floating | |
// point issues when offset-based arcs are commanded as full circles, but get interpreted as extremely | |
// small arcs with around machine epsilon (1.2e-7rad) due to numerical round-off and precision issues. | |
// This define value sets the machine epsilon cutoff to determine if the arc is a full-circle or not. | |
// NOTE: Be very careful when adjusting this value. It should always be greater than 1.2e-7 but not too | |
// much greater than this. The default setting should capture most, if not all, full arc error situations. | |
#define ARC_ANGULAR_TRAVEL_EPSILON 5E-7 // Float (radians) | |
// Time delay increments performed during a dwell. The default value is set at 50ms, which provides | |
// a maximum time delay of roughly 55 minutes, more than enough for most any application. Increasing | |
// this delay will increase the maximum dwell time linearly, but also reduces the responsiveness of | |
// run-time command executions, like status reports, since these are performed between each dwell | |
// time step. Also, keep in mind that the Arduino delay timer is not very accurate for long delays. | |
#define DWELL_TIME_STEP 50 // Integer (1-255) (milliseconds) | |
// Creates a delay between the direction pin setting and corresponding step pulse by creating | |
// another interrupt (Timer2 compare) to manage it. The main Grbl interrupt (Timer1 compare) | |
// sets the direction pins, and does not immediately set the stepper pins, as it would in | |
// normal operation. The Timer2 compare fires next to set the stepper pins after the step | |
// pulse delay time, and Timer2 overflow will complete the step pulse, except now delayed | |
// by the step pulse time plus the step pulse delay. (Thanks langwadt for the idea!) | |
// NOTE: Uncomment to enable. The recommended delay must be > 3us, and, when added with the | |
// user-supplied step pulse time, the total time must not exceed 127us. Reported successful | |
// values for certain setups have ranged from 5 to 20us. | |
// #define STEP_PULSE_DELAY 10 // Step pulse delay in microseconds. Default disabled. | |
// The number of linear motions in the planner buffer to be planned at any give time. The vast | |
// majority of RAM that Grbl uses is based on this buffer size. Only increase if there is extra | |
// available RAM, like when re-compiling for a Mega2560. Or decrease if the Arduino begins to | |
// crash due to the lack of available RAM or if the CPU is having trouble keeping up with planning | |
// new incoming motions as they are executed. | |
// #define BLOCK_BUFFER_SIZE 16 // Uncomment to override default in planner.h. | |
// Governs the size of the intermediary step segment buffer between the step execution algorithm | |
// and the planner blocks. Each segment is set of steps executed at a constant velocity over a | |
// fixed time defined by ACCELERATION_TICKS_PER_SECOND. They are computed such that the planner | |
// block velocity profile is traced exactly. The size of this buffer governs how much step | |
// execution lead time there is for other Grbl processes have to compute and do their thing | |
// before having to come back and refill this buffer, currently at ~50msec of step moves. | |
// #define SEGMENT_BUFFER_SIZE 6 // Uncomment to override default in stepper.h. | |
// Line buffer size from the serial input stream to be executed. Also, governs the size of | |
// each of the startup blocks, as they are each stored as a string of this size. Make sure | |
// to account for the available EEPROM at the defined memory address in settings.h and for | |
// the number of desired startup blocks. | |
// NOTE: 80 characters is not a problem except for extreme cases, but the line buffer size | |
// can be too small and g-code blocks can get truncated. Officially, the g-code standards | |
// support up to 256 characters. In future versions, this default will be increased, when | |
// we know how much extra memory space we can re-invest into this. | |
// #define LINE_BUFFER_SIZE 80 // Uncomment to override default in protocol.h | |
// Serial send and receive buffer size. The receive buffer is often used as another streaming | |
// buffer to store incoming blocks to be processed by Grbl when its ready. Most streaming | |
// interfaces will character count and track each block send to each block response. So, | |
// increase the receive buffer if a deeper receive buffer is needed for streaming and avaiable | |
// memory allows. The send buffer primarily handles messages in Grbl. Only increase if large | |
// messages are sent and Grbl begins to stall, waiting to send the rest of the message. | |
// NOTE: Grbl generates an average status report in about 0.5msec, but the serial TX stream at | |
// 115200 baud will take 5 msec to transmit a typical 55 character report. Worst case reports are | |
// around 90-100 characters. As long as the serial TX buffer doesn't get continually maxed, Grbl | |
// will continue operating efficiently. Size the TX buffer around the size of a worst-case report. | |
// #define RX_BUFFER_SIZE 128 // (1-254) Uncomment to override defaults in serial.h | |
// #define TX_BUFFER_SIZE 100 // (1-254) | |
// A simple software debouncing feature for hard limit switches. When enabled, the interrupt | |
// monitoring the hard limit switch pins will enable the Arduino's watchdog timer to re-check | |
// the limit pin state after a delay of about 32msec. This can help with CNC machines with | |
// problematic false triggering of their hard limit switches, but it WILL NOT fix issues with | |
// electrical interference on the signal cables from external sources. It's recommended to first | |
// use shielded signal cables with their shielding connected to ground (old USB/computer cables | |
// work well and are cheap to find) and wire in a low-pass circuit into each limit pin. | |
// #define ENABLE_SOFTWARE_DEBOUNCE // Default disabled. Uncomment to enable. | |
// Configures the position after a probing cycle during Grbl's check mode. Disabled sets | |
// the position to the probe target, when enabled sets the position to the start position. | |
// #define SET_CHECK_MODE_PROBE_TO_START // Default disabled. Uncomment to enable. | |
// Force Grbl to check the state of the hard limit switches when the processor detects a pin | |
// change inside the hard limit ISR routine. By default, Grbl will trigger the hard limits | |
// alarm upon any pin change, since bouncing switches can cause a state check like this to | |
// misread the pin. When hard limits are triggered, they should be 100% reliable, which is the | |
// reason that this option is disabled by default. Only if your system/electronics can guarantee | |
// that the switches don't bounce, we recommend enabling this option. This will help prevent | |
// triggering a hard limit when the machine disengages from the switch. | |
// NOTE: This option has no effect if SOFTWARE_DEBOUNCE is enabled. | |
// #define HARD_LIMIT_FORCE_STATE_CHECK // Default disabled. Uncomment to enable. | |
// Adjusts homing cycle search and locate scalars. These are the multipliers used by Grbl's | |
// homing cycle to ensure the limit switches are engaged and cleared through each phase of | |
// the cycle. The search phase uses the axes max-travel setting times the SEARCH_SCALAR to | |
// determine distance to look for the limit switch. Once found, the locate phase begins and | |
// uses the homing pull-off distance setting times the LOCATE_SCALAR to pull-off and re-engage | |
// the limit switch. | |
// NOTE: Both of these values must be greater than 1.0 to ensure proper function. | |
// #define HOMING_AXIS_SEARCH_SCALAR 1.5 // Uncomment to override defaults in limits.c. | |
// #define HOMING_AXIS_LOCATE_SCALAR 10.0 // Uncomment to override defaults in limits.c. | |
// Enable the '$RST=*', '$RST=$', and '$RST=#' eeprom restore commands. There are cases where | |
// these commands may be undesirable. Simply comment the desired macro to disable it. | |
// NOTE: See SETTINGS_RESTORE_ALL macro for customizing the `$RST=*` command. | |
#define ENABLE_RESTORE_EEPROM_WIPE_ALL // '$RST=*' Default enabled. Comment to disable. | |
#define ENABLE_RESTORE_EEPROM_DEFAULT_SETTINGS // '$RST=$' Default enabled. Comment to disable. | |
#define ENABLE_RESTORE_EEPROM_CLEAR_PARAMETERS // '$RST=#' Default enabled. Comment to disable. | |
// Defines the EEPROM data restored upon a settings version change and `$RST=*` command. Whenever the | |
// the settings or other EEPROM data structure changes between Grbl versions, Grbl will automatically | |
// wipe and restore the EEPROM. This macro controls what data is wiped and restored. This is useful | |
// particularily for OEMs that need to retain certain data. For example, the BUILD_INFO string can be | |
// written into the Arduino EEPROM via a seperate .INO sketch to contain product data. Altering this | |
// macro to not restore the build info EEPROM will ensure this data is retained after firmware upgrades. | |
// NOTE: Uncomment to override defaults in settings.h | |
// #define SETTINGS_RESTORE_ALL (SETTINGS_RESTORE_DEFAULTS | SETTINGS_RESTORE_PARAMETERS | SETTINGS_RESTORE_STARTUP_LINES | SETTINGS_RESTORE_BUILD_INFO) | |
// Enable the '$I=(string)' build info write command. If disabled, any existing build info data must | |
// be placed into EEPROM via external means with a valid checksum value. This macro option is useful | |
// to prevent this data from being over-written by a user, when used to store OEM product data. | |
// NOTE: If disabled and to ensure Grbl can never alter the build info line, you'll also need to enable | |
// the SETTING_RESTORE_ALL macro above and remove SETTINGS_RESTORE_BUILD_INFO from the mask. | |
// NOTE: See the included grblWrite_BuildInfo.ino example file to write this string seperately. | |
#define ENABLE_BUILD_INFO_WRITE_COMMAND // '$I=' Default enabled. Comment to disable. | |
// AVR processors require all interrupts to be disabled during an EEPROM write. This includes both | |
// the stepper ISRs and serial comm ISRs. In the event of a long EEPROM write, this ISR pause can | |
// cause active stepping to lose position and serial receive data to be lost. This configuration | |
// option forces the planner buffer to completely empty whenever the EEPROM is written to prevent | |
// any chance of lost steps. | |
// However, this doesn't prevent issues with lost serial RX data during an EEPROM write, especially | |
// if a GUI is premptively filling up the serial RX buffer simultaneously. It's highly advised for | |
// GUIs to flag these gcodes (G10,G28.1,G30.1) to always wait for an 'ok' after a block containing | |
// one of these commands before sending more data to eliminate this issue. | |
// NOTE: Most EEPROM write commands are implicitly blocked during a job (all '$' commands). However, | |
// coordinate set g-code commands (G10,G28/30.1) are not, since they are part of an active streaming | |
// job. At this time, this option only forces a planner buffer sync with these g-code commands. | |
#define FORCE_BUFFER_SYNC_DURING_EEPROM_WRITE // Default enabled. Comment to disable. | |
// In Grbl v0.9 and prior, there is an old outstanding bug where the `WPos:` work position reported | |
// may not correlate to what is executing, because `WPos:` is based on the g-code parser state, which | |
// can be several motions behind. This option forces the planner buffer to empty, sync, and stop | |
// motion whenever there is a command that alters the work coordinate offsets `G10,G43.1,G92,G54-59`. | |
// This is the simplest way to ensure `WPos:` is always correct. Fortunately, it's exceedingly rare | |
// that any of these commands are used need continuous motions through them. | |
#define FORCE_BUFFER_SYNC_DURING_WCO_CHANGE // Default enabled. Comment to disable. | |
// By default, Grbl disables feed rate overrides for all G38.x probe cycle commands. Although this | |
// may be different than some pro-class machine control, it's arguable that it should be this way. | |
// Most probe sensors produce different levels of error that is dependent on rate of speed. By | |
// keeping probing cycles to their programmed feed rates, the probe sensor should be a lot more | |
// repeatable. If needed, you can disable this behavior by uncommenting the define below. | |
// #define ALLOW_FEED_OVERRIDE_DURING_PROBE_CYCLES // Default disabled. Uncomment to enable. | |
// Enables and configures parking motion methods upon a safety door state. Primarily for OEMs | |
// that desire this feature for their integrated machines. At the moment, Grbl assumes that | |
// the parking motion only involves one axis, although the parking implementation was written | |
// to be easily refactored for any number of motions on different axes by altering the parking | |
// source code. At this time, Grbl only supports parking one axis (typically the Z-axis) that | |
// moves in the positive direction upon retracting and negative direction upon restoring position. | |
// The motion executes with a slow pull-out retraction motion, power-down, and a fast park. | |
// Restoring to the resume position follows these set motions in reverse: fast restore to | |
// pull-out position, power-up with a time-out, and plunge back to the original position at the | |
// slower pull-out rate. | |
// NOTE: Still a work-in-progress. Machine coordinates must be in all negative space and | |
// does not work with HOMING_FORCE_SET_ORIGIN enabled. Parking motion also moves only in | |
// positive direction. | |
// #define PARKING_ENABLE // Default disabled. Uncomment to enable | |
// Configure options for the parking motion, if enabled. | |
#define PARKING_AXIS Z_AXIS // Define which axis that performs the parking motion | |
#define PARKING_TARGET -5.0 // Parking axis target. In mm, as machine coordinate [-max_travel,0]. | |
#define PARKING_RATE 500.0 // Parking fast rate after pull-out in mm/min. | |
#define PARKING_PULLOUT_RATE 100.0 // Pull-out/plunge slow feed rate in mm/min. | |
#define PARKING_PULLOUT_INCREMENT 5.0 // Spindle pull-out and plunge distance in mm. Incremental distance. | |
// Must be positive value or equal to zero. | |
// Enables a special set of M-code commands that enables and disables the parking motion. | |
// These are controlled by `M56`, `M56 P1`, or `M56 Px` to enable and `M56 P0` to disable. | |
// The command is modal and will be set after a planner sync. Since it is g-code, it is | |
// executed in sync with g-code commands. It is not a real-time command. | |
// NOTE: PARKING_ENABLE is required. By default, M56 is active upon initialization. Use | |
// DEACTIVATE_PARKING_UPON_INIT to set M56 P0 as the power-up default. | |
// #define ENABLE_PARKING_OVERRIDE_CONTROL // Default disabled. Uncomment to enable | |
// #define DEACTIVATE_PARKING_UPON_INIT // Default disabled. Uncomment to enable. | |
// This option will automatically disable the laser during a feed hold by invoking a spindle stop | |
// override immediately after coming to a stop. However, this also means that the laser still may | |
// be reenabled by disabling the spindle stop override, if needed. This is purely a safety feature | |
// to ensure the laser doesn't inadvertently remain powered while at a stop and cause a fire. | |
#define DISABLE_LASER_DURING_HOLD // Default enabled. Comment to disable. | |
// Enables a piecewise linear model of the spindle PWM/speed output. Requires a solution by the | |
// 'fit_nonlinear_spindle.py' script in the /doc/script folder of the repo. See file comments | |
// on how to gather spindle data and run the script to generate a solution. | |
// #define ENABLE_PIECEWISE_LINEAR_SPINDLE // Default disabled. Uncomment to enable. | |
// N_PIECES, RPM_MAX, RPM_MIN, RPM_POINTxx, and RPM_LINE_XX constants are all set and given by | |
// the 'fit_nonlinear_spindle.py' script solution. Used only when ENABLE_PIECEWISE_LINEAR_SPINDLE | |
// is enabled. Make sure the constant values are exactly the same as the script solution. | |
// NOTE: When N_PIECES < 4, unused RPM_LINE and RPM_POINT defines are not required and omitted. | |
#define N_PIECES 4 // Integer (1-4). Number of piecewise lines used in script solution. | |
#define RPM_MAX 11686.4 // Max RPM of model. $30 > RPM_MAX will be limited to RPM_MAX. | |
#define RPM_MIN 202.5 // Min RPM of model. $31 < RPM_MIN will be limited to RPM_MIN. | |
#define RPM_POINT12 6145.4 // Used N_PIECES >=2. Junction point between lines 1 and 2. | |
#define RPM_POINT23 9627.8 // Used N_PIECES >=3. Junction point between lines 2 and 3. | |
#define RPM_POINT34 10813.9 // Used N_PIECES = 4. Junction point between lines 3 and 4. | |
#define RPM_LINE_A1 3.197101e-03 // Used N_PIECES >=1. A and B constants of line 1. | |
#define RPM_LINE_B1 -3.526076e-1 | |
#define RPM_LINE_A2 1.722950e-2 // Used N_PIECES >=2. A and B constants of line 2. | |
#define RPM_LINE_B2 8.588176e+01 | |
#define RPM_LINE_A3 5.901518e-02 // Used N_PIECES >=3. A and B constants of line 3. | |
#define RPM_LINE_B3 4.881851e+02 | |
#define RPM_LINE_A4 1.203413e-01 // Used N_PIECES = 4. A and B constants of line 4. | |
#define RPM_LINE_B4 1.151360e+03 | |
/* --------------------------------------------------------------------------------------- | |
OEM Single File Configuration Option | |
Instructions: Paste the cpu_map and default setting definitions below without an enclosing | |
#ifdef. Comment out the CPU_MAP_xxx and DEFAULT_xxx defines at the top of this file, and | |
the compiler will ignore the contents of defaults.h and cpu_map.h and use the definitions | |
below. | |
*/ | |
// Paste CPU_MAP definitions here. | |
// Paste default settings definitions here. | |
#endif |
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