G-code
Contents
- 1 Introduction
- 2 RepRap G Code Fields
- 3 Comments
- 4 Individual commands
- 4.1 Checking
- 4.2 Buffered G Commands
- 4.3 Unbuffered G commands
- 4.4 Unbuffered M and T commands
- 4.4.1 M0: Stop
- 4.4.2 M17: Enable/Power all stepper motors
- 4.4.3 M18: Disable all stepper motors
- 4.4.4 M20: List SD card
- 4.4.5 M21: Initialise SD card
- 4.4.6 M22: Release SD card
- 4.4.7 M23: Select SD file
- 4.4.8 M24: Start/resume SD print
- 4.4.9 M25: Pause SD print
- 4.4.10 M26: Set SD position
- 4.4.11 M27: Report SD print status
- 4.4.12 M28: Begin write to SD card
- 4.4.13 M29: Stop writing to SD card
- 4.4.14 M40: Eject
- 4.4.15 M41: Loop
- 4.4.16 M42: Stop on material exhausted / Switch I/O pin
- 4.4.17 M43: Stand by on material exhausted
- 4.4.18 M80: ATX Power On
- 4.4.19 M81: ATX Power Off
- 4.4.20 M82: set extruder to absolute mode
- 4.4.21 M83: set extruder to relative mode
- 4.4.22 M84: Stop idle hold
- 4.4.23 M92: Set axis_steps_per_unit
- 4.4.24 M101 Turn extruder 1 on Forward / Undo Extruder Retraction
- 4.4.25 M102 Turn extruder 1 on Reverse
- 4.4.26 M103 Turn all extruders off / Extruder Retraction
- 4.4.27 M104: Set Extruder Temperature (Fast) DEPRECATED
- 4.4.28 M105: Get Extruder Temperature
- 4.4.29 M106: Fan On
- 4.4.30 M107: Fan Off
- 4.4.31 M108: Set Extruder Speed
- 4.4.32 M109: Set Extruder Temperature DEPRICATED
- 4.4.33 M110: Set Current Line Number
- 4.4.34 M111: Set Debug Level
- 4.4.35 M112: Emergency Stop
- 4.4.36 M113: Set Extruder PWM
- 4.4.37 M114: Get Current Position
- 4.4.38 M115: Get Firmware Version and Capabilities
- 4.4.39 M116: Wait
- 4.4.40 M117: Get Zero Position
- 4.4.41 M118: Negotiate Features
- 4.4.42 M119: Get Endstop Status
- 4.4.43 M126: Open Valve
- 4.4.44 M127: Close Valve
- 4.4.45 M128: Extruder Pressure PWM
- 4.4.46 M129: Extruder pressure off
- 4.4.47 M140: Bed Temperature (Fast)
- 4.4.48 M141: Chamber Temperature (Fast)
- 4.4.49 M142: Holding Pressure
- 4.4.50 M143: Maximum hot-end temperature
- 4.4.51 M160: Number of mixed materials
- 4.4.52 M190: Wait for bed temperature to reach target temp
- 4.4.53 M200 - Set filament diameter
- 4.4.54 M201 - Set max printing acceleration
- 4.4.55 M202 - Set max travel acceleration
- 4.4.56 M203 - Set maximum feedrate
- 4.4.57 M204 - Set default acceleration
- 4.4.58 M205 - advanced settings
- 4.4.59 M206: set home offset
- 4.4.60 M207: calibrate z axis by detecting z max length
- 4.4.61 M226: Gcode Initiated Pause
- 4.4.62 M227: Enable Automatic Reverse and Prime
- 4.4.63 M228: Disable Automatic Reverse and Prime
- 4.4.64 M229: Enable Automatic Reverse and Prime
- 4.4.65 M230: Disable / Enable Wait for Temperature Change
- 4.4.66 M240: Start conveyor belt motor
- 4.4.67 M241: Stop conveyor belt motor
- 4.4.68 M245: Start cooler
- 4.4.69 M246: Stop cooler
- 4.4.70 M300: Play beep sound
- 4.4.71 T: Select Tool
- 5 Proposed EEPROM configuration codes
- 6 Replies from the RepRap machine to the host computer
- 7 Proposal for sending multiple lines of G-code
Introduction
This page describes the G Codes that the RepRap firmware uses and how they work.
The list of what can be done is extensible. But check this page first, and add your extension here first before you implement it.
A typical piece of GCode as sent to a RepRap machine might look like this:
N3 T0*57 N4 G92 E0*67 N5 G28*22 N6 G1 F1500.0*82 N7 G1 X2.0 Y2.0 F3000.0*85 N8 G1 X3.0 Y3.0*33
The meaning of all those symbols and numbers (and more) is explained below.
TO find out which specific gcode/s are implemented in any given firmware, please see the Firmware_features page.
(For the technically minded, the end of line is marked by both a <nl> and a <cr>. If you want to manually enter GCodes in your reprap using the Arduino Serial interface, make sure to select "Both NL & CR" on the bottom of the screen.)
This isn't accurate, firmware accepts single <nl> as well as single <cr>, or combinations thereof. Hosts should accepts all four combinations as well. --Traumflug 09:34, 20 April 2011 (UTC)
RepRap G Code Fields
This section explains the letter-preceded fields. The numbers in the fields are represented by nnn. Numbers can be integers, or can contain a decimal point, depending on context. For example an X coordinate can be integer (X175) or fractional (X17.62), whereas trying to select extruder number 2.76 would make no sense.
Letter | Meaning |
---|---|
Gnnn | Standard GCode command, such as move to a point |
Mnnn | RepRap-defined command, such as turn on a cooling fan |
Tnnn | Select tool nnn. In RepRap, tools are extruders |
Snnn | Command parameter, such as the voltage to send to a motor |
Pnnn | Command parameter, such as a time in milliseconds |
Xnnn | An X coordinate, usually to move to |
Ynnn | A Y coordinate, usually to move to |
Znnn | A Z coordinate, usually to move to |
Innn | Parameter - not currently used |
Jnnn | Parameter - not currently used |
Fnnn | Feedrate in mm per minute. (Speed of print head movement) |
Rnnn | Parameter - used for temperatures |
Qnnn | Parameter - not currently used |
Ennn | Length of extrudate in mm. This is exactly like X, Y and Z, but for the length of filament to extrude. |
Nnnn | Line number. Used to request repeat transmission in the case of communications errors. |
*nnn | Checksum. Used to check for communications errors. |
Comments
G Code comments:
N3 T0*57 ;This is a comment N4 G92 E0*67 ; So is this N5 G28*22
Will be ignored by RepRap, as will blank lines. But it's better to strip these out in the host computer before the lines are sent. This saves bandwidth.
Individual commands
Checking
N and *
Example: N123 [...G Code in here...] *71
These are the line number and the checksum. The RepRap firmware checks the checksum against a locally-computed value and, if they differ, requests a repeat transmission of the line of the given number.
You can leave both of these out - RepRap will still work, but it won't do checking. You have to have both or neither though.
The checksum "cs" for a GCode string "cmd" (including its line number) is computed by exor-ing the bytes in the string up to and not including the * character as follows:
int cs = 0; for(i = 0; cmd[i] != '*' && cmd[i] != NULL; i++) cs = cs ^ cmd[i]; cs &= 0xff; // Defensive programming...
and the value is appended as a decimal integer to the command after the * character.
The RepRap firmware expects line numbers to increase by 1 each line, and if that doesn't happen it is flagged as an error. But you can reset the count using M110 (see below).
Buffered G Commands
The RepRap firmware stores these commands in a ring buffer internally for execution. This means that there is no (appreciable) delay while a command is acknowledged and the next transmitted. In turn, this means that sequences of line segments can be plotted without a dwell between one and the next. As soon as one of these buffered commands is received it is acknowledged and stored locally. If the local buffer is full, then the acknowledgment is delayed until space for storage in the buffer is available. This is how flow control is achieved.
G0: Rapid move
Example: G0 X12
In this case move rapidly to X = 12 mm. In fact, the RepRap firmware uses exactly the same code for rapid as it uses for controlled moves (see G1 below), as - for the RepRap machine - this is just as efficient as not doing so. (The distinction comes from some old machine tools that used to move faster if the axes were not driven in a straight line. For them G0 allowed any movement in space to get to the destination as fast as possible.)
G1: Controlled move
Example: G1 X90.6 Y13.8 E22.4
Go in a straight line from the current (X, Y) point to the point (90.6, 13.8), extruding material as the move happens from the current extruded length to a length of 22.4 mm.
RepRap does subtle things with feedrates. Thus:
G1 F1500 G1 X90.6 Y13.8 E22.4
Will set a feedrate of 1500 mm/minute, then do the move described above at that feedrate. But
G1 F1500 G1 X90.6 Y13.8 E22.4 F3000
Will set a feedrate of 1500 mm/minute, then do the move described above accelerating to a feedrate of 3000 mm/minute as it does so. The extrusion will accelerate along with the X, Y movement so everything stays synchronized.
RepRap thus treats feedrate as simply another variable (like X, Y, Z, and E) to be linearly interpolated. This gives complete control over accelerations and decelerations in a way that ensures that everything moves together and the right volume of material is extruded at all points.
The first example shows how to get a constant-speed movement. The second how to accelerate or decelerate. Thus
G1 F1500 G1 X90.6 Y13.8 E22.4 F3000 G1 X80 Y20 E36 F1500
Will do the first movement accelerating as before, and the second decelerating from 3000 mm/minute back to 1500 mm/minute.
To reverse the extruder by a given amount (for example to reduce its internal pressure while it does an in-air movement so that it doesn't dribble) simply use G1 to send an E value that is less than the currently extruded length.
G28: Move to Origin
Example: G28
This causes the RepRap machine to move back to its X, Y and Z zero endstops, a process known as "homing". It does so accelerating, so as to get there fast. But when it arrives it backs off by 1 mm in each direction slowly, then moves back slowly to the stop. This ensures more accurate positioning.
If you add coordinates, then just the axes with coordinates specified will be zeroed. Thus
G28 X0 Y72.3
will zero the X and Y axes, but not Z. The actual coordinate values are ignored.
Note: this little table is an experiment on how to document G-code, on how to show which firmware supports what. Ignore it for now, please.
FiveD | Teacup | Sprinter | Marlin | Repetier |
---|---|---|---|---|
optional | supported | supported | supported | experimental |
G29-G32: Bed probing
G29 Detailed Z-Probe
probes the bed at 3 points.
G30 Single Z Probe
probes bed at current XY location.
G31 Report Curent Probe status
reports whether Z probe is triggered.
G32 Probe Z and calibrate with FPU
probes the bed at 3 points and updates transformation matrix for bed levelling compensation.
Unbuffered G commands
The following commands are not buffered. When one is received it is stored, but it is not acknowledged to the host until the buffer is exhausted and then the command has been executed. Thus the host will pause at one of these commands until it has been done. Short pauses between these commands and any that might follow them do not affect the performance of the machine.
Teacup Firmware buffers G20, G21, G90 and G91.
G4: Dwell
Example: G4 P200
In this case sit still doing nothing for 200 milliseconds. During delays the state of the machine (for example the temperatures of its extruders) will still be preserved and controlled.
G10: Head Offset
Example: G10 L1 P3 X17.8 Y-19.3 Z0.0 R140 S205
This sets the offset for extrude head 3 (from the P3) to the X and Y values specified. You can put a non-zero Z value in as well, but this is usually a bad idea unless the heads are loaded and unloaded by some sort of head changer. When all the heads are in the machine at once they should all be set to the same Z height.
The R value is the standby temperature in oC that will be used for the tool, and the S value is its operating temperature. If you don't want the head to be at a different temperature when not in use, set both values the same. See the T code (select tool) below.
The L value can be omitted and is ignored. In conventional machine tools it is used to differentiate between, for example, an offset due to tool wear or a real difference of position (called a geometric offset).
G20: Set Units to Inches
Example: G20
Units from now on are in inches.
G21: Set Units to Millimeters
Example: G21
Units from now on are in millimeters. (This is the RepRap default.)
G90: Set to Absolute Positioning
Example: G90
All coordinates from now on are absolute relative to the origin of the machine. (This is the RepRap default.)
G91: Set to Relative Positioning
Example: G91
All coordinates from now on are relative to the last position.
G92: Set Position
Example: G92 X10 E90
Allows programming of absolute zero point, by reseting the current position to the values specified. This would set the machine's X coordinate to 10, and the extrude coordinate to 90. No physical motion will occur.
A G92 without coordinates will reset all axes to zero.
Unbuffered M and T commands
M0: Stop
Example: M0
The RepRap machine finishes any moves left in its buffer, then shuts down. All motors and heaters are turned off. It can be started again by pressing the reset button on the master microcontroller. See also M112.
M17: Enable/Power all stepper motors
Example: M17
M18: Disable all stepper motors
Example: M18
Disables stepper motors and allows axis to move 'freely.'
M20: List SD card
Example: M20
All files in the root folder of the SD card are listed to the serial port. This results in a line like:
ok Files: {SQUARE.G,SQCOM.G,}
The trailing comma is optional. Note that file names are returned in upper case, but - when sent to the M23 command (below) they must be in lower case. This seems to be a function of the SD software. Go figure...
M21: Initialise SD card
Example: M21
The SD card is initialised. If an SD card is loaded when the machine is switched on, this will happen by default. SD card must be initialised for the other SD functions to work.
M22: Release SD card
Example: M22
SD card is released and can be physically removed.
M23: Select SD file
Example: M23 filename.gco
The file specified as filename.gco (8.3 naming convention is supported) is selected ready for printing.
M24: Start/resume SD print
Example: M24
The machine prints from the file selected with the M23 command.
M25: Pause SD print
Example: M25
The machine pause printing at the current position within the file selected with the M23 command.
M26: Set SD position
Example: M26
Set SD position in bytes (M26 S12345).
M27: Report SD print status
Example: M27
Report SD print status.
M28: Begin write to SD card
Example: M28 filename.gco
File specified by filename.gco is created (or overwritten if it exists) on the SD card and all subsequent commands sent to the machine are written to that file.
M29: Stop writing to SD card
Example: M29 filename.gco
File opened by M28 command is closed, and all subsequent commands sent to the machine are executed as normal.
M40: Eject
If your RepRap machine can eject the parts it has built off the bed, this command executes the eject cycle. This usually involves cooling the bed and then performing a sequence of movements that remove the printed parts from it. The X, Y and Z position of the machine at the end of this cycle are undefined (though they can be found out using the M114 command, q.v.).
See also M240 and M241 below.
M41: Loop
Example: M41
If the RepRap machine was building a file from its own memory such as a local SD card (as opposed to a file being transmitted to it from a host computer) this goes back to the beginning of the file and runs it again. So, for example, if your RepRap is capable of ejecting parts from its build bed then you can set it printing in a loop and it will run and run. Use with caution - the only things that will stop it are:
- When you press the reset button,
- When the build material runs out (if your RepRap is set up to detect this), and
- When there's an error (such as a heater failure).
M42: Stop on material exhausted / Switch I/O pin
M42 in ???
Example: M42
If your RepRap can detect when its material runs out, this decides the behaviour when that happens. The X and Y axes are zeroed (but not Z), and then the machine shuts all motors and heaters off. You have to press reset to reactivate the machine. In other words, it parks itself and then executes an M0 command (q.v.).
M42 in Marlin/Sprinter
Example: ???
M42 switches a general purpose I/O pin.
M42 in Teacup
Teacup firmware doesn't implement M42 and switches general purpose devices like a heater, with M104.
M43: Stand by on material exhausted
Example: M43
If your RepRap can detect when its material runs out, this decides the behaviour when that happens. The X and Y axes are zeroed (but not Z), and then the machine shuts all motors and heaters off except the heated bed, the temperature of which is maintained. The machine will still respond to G and M code commands in this state.
M80: ATX Power On
Example: M80
Turns on the ATX power supply from standby mode to fully operational mode. No-op on electronics without standby mode.
Note: some firmwares, like Teacup, handle power on/off automatically, so this is redundant there.
M81: ATX Power Off
Example: M81
Turns off the ATX power supply. Counterpart to M80.
M82: set extruder to absolute mode
Example: M82
makes the extruder interpret extrusion as absolute positions.
This is the default in repetier.
M83: set extruder to relative mode
Example: M83
makes the extruder interpret extrusion values as relative positions.
M84: Stop idle hold
Example: M84
Stop the idle hold on all axis and extruder. In some cases the idle hold causes annoying noises, which can be stopped by disabling the hold. Be aware that by disabling idle hold during printing, you will get quality issues. This is recommended only in between or after printjobs.
M92: Set axis_steps_per_unit
Example: M92 X<newsteps> Sprinter and Marlin
Allows programming of steps per unit of axis till the electronics are reset for the specified axis. Very useful for calibration.
M101 Turn extruder 1 on Forward / Undo Extruder Retraction
M101 in Teacup firmware
If a DC extruder is present, turn that on. Else, undo filament retraction, which means, make the extruder ready for extrusion. Complement to M103.
M101 in other firmwares
Deprecated. Regarding filament retraction, see M227, M228, M229.
M102 Turn extruder 1 on Reverse
Deprecated.
M103 Turn all extruders off / Extruder Retraction
M103 in Teacup firmware
If a DC extruder is present, turn that off. Else, retract the filament in the hope to prevent nozzle drooling. Complement to M101.
M103 in other firmwares
Deprecated. Regarding extruder retraction, see M227, M228, M229.
M104: Set Extruder Temperature (Fast) DEPRECATED
Example: M104 S190
Set the temperature of the current extruder to 190oC and return control to the host immediately (i.e. before that temperature has been reached by the extruder). See also M109.
This is deprecated because temperatures should be set using the G10 and T commands (q.v.).
M105: Get Extruder Temperature
Example: M105
Request the temperature of the current extruder and the build base in degrees Celsius. The temperatures are returned to the host computer. For example, the line sent to the host in response to this command looks like
ok T:201 B:117
M106: Fan On
Example: M106 S127
Turn on the cooling fan at half speed. Optional parameter 'S' declares the PWM value (0-255)
M107: Fan Off
Example: M107
Turn off the cooling fan (if any).
M108: Set Extruder Speed
Sets speed of extruder motor. (Deprecated in current firmware, see M113)
M109: Set Extruder Temperature DEPRICATED
Example: M109 S190
Set the temperature of the current extruder to 190oC and wait for it to reach that value before sending an acknowledgment to the host. In fact the RepRap firmware waits a while after the temperature has been reached for the extruder to stabilise - typically about 40 seconds. This can be changed by a parameter in the firmware configuration file when the firmware is compiled. See also M104 and M116.
This is deprecated because temperatures should be set using the G10 and T commands (q.v.).
M110: Set Current Line Number
Example: M110 N123
Set the current line number to 123. Thus the expected next line after this command will be 124.
M111: Set Debug Level
Example: M111 S6
Set the level of debugging information transmitted back to the host to level 6. The level is the OR of three bits:
#define DEBUG_ECHO (1<<0) #define DEBUG_INFO (1<<1) #define DEBUG_ERRORS (1<<2)
Thus 6 means send information and errors, but don't echo commands. (This is the RepRap default.)
M112: Emergency Stop
Example: M112
Any moves in progress are immediately terminated, then RepRap shuts down. All motors and heaters are turned off. It can be started again by pressing the reset button on the master microcontroller. See also M0.
M113: Set Extruder PWM
Example: M113
Set the PWM for the currently-selected extruder. On its own this command sets RepRap to use the on-board potentiometer on the extruder controller board to set the PWM for the currently-selected extruder's stepper power. With an S field:
M113 S0.7
it causes the PWM to be set to the S value (70% in this instance). M113 S0 turns the extruder off, until an M113 command other than M113 S0 is sent.
M114: Get Current Position
Example: M114
This causes the RepRap machine to report its current X, Y, Z and E coordinates to the host.
For example, the machine returns a string such as:
ok C: X:0.00 Y:0.00 Z:0.00 E:0.00
M115: Get Firmware Version and Capabilities
Example: M115
Request the Firmware Version and Capabilities of the current microcontroller The details are returned to the host computer as key:value pairs separated by spaces and terminated with a linefeed.
sample data from firmware:
ok PROTOCOL_VERSION:0.1 FIRMWARE_NAME:FiveD FIRMWARE_URL:http%3A//reprap.org MACHINE_TYPE:Mendel EXTRUDER_COUNT:1
This M115 code is inconsistently implemented, and should not be relied upon to exist, or output correctly in all cases. An initial implementation was committed to svn for the FiveD Reprap firmware on 11 Oct 2010. Work to more formally define protocol versions is currently (October 2010) being discussed. See M115_Keywords for one draft set of keywords and their meanings.
M116: Wait
Example: M116
Wait for all temperatures and other slowly-changing variables to arrive at their set values. See also M109.
M117: Get Zero Position
Example: M117
This causes the RepRap machine to report the X, Y, Z and E coordinates in steps not mm to the host that it found when it last hit the zero stops for those axes. That is to say, when you zero X, the x coordinate of the machine when it hits the X endstop is recorded. This value should be 0, of course. But if the machine has drifted (for example by dropping steps) then it won't be. This command allows you to measure and to diagnose such problems. (E is included for completeness. It doesn't normally have an endstop.)
M118: Negotiate Features
Example: M118 P42
This M-code is for future proofing. NO firmware or hostware supports this at the moment. It is used in conjunction with M115's FEATURES keyword.
See Protocol_Feature_Negotiation for more info.
M119: Get Endstop Status
Example: M119
Returns the current state of the configured X,Y,Z endstops. Should take into account any 'inverted endstop' settings, so one can confirm that the machine is interpreting the endstops correctly.
M126: Open Valve
Example: M126 P500
Open the extruder's valve (if it has one) and wait 500 milliseconds for it to do so.
M127: Close Valve
Example: M127 P400
Close the extruder's valve (if it has one) and wait 400 milliseconds for it to do so.
M128: Extruder Pressure PWM
Example: M128 S255
PWM value to control internal extruder pressure. S255 is full pressure.
M129: Extruder pressure off
Example: M129 P100
In addition to setting Extruder pressure to 0, you can turn the pressure off entirely. P400 will wait 100ms to do so.
M140: Bed Temperature (Fast)
Example: M140 S55
Set the temperature of the build bed to 55oC and return control to the host immediately (i.e. before that temperature has been reached by the bed).
M141: Chamber Temperature (Fast)
Example: M141 S30
Set the temperature of the chamber to 30oC and return control to the host immediately (i.e. before that temperature has been reached by the chamber).
M142: Holding Pressure
Example: M142 S1
Set the holding pressure of the bed to 1 bar.
The holding pressure is in bar. For hardware which only has on/off holding, when the holding pressure is zero, turn off holding, when the holding pressure is greater than zero, turn on holding.
M143: Maximum hot-end temperature
Example: M143 S275
Set the maximum temperature of the hot-end to 275C
When temperature of the hot-end exceeds this value, take countermeasures, for instance an emergency stop. This is to prevent hot-end damage.
M160: Number of mixed materials
Example: M160 S4
Set the number of materials, N, that the current extruder can handle to the number specified. The default is 1.
When N >= 2, then the E field that controls extrusion requires N+1 values separated by spaces after it like this:
M160 S4 G1 X90.6 Y13.8 E22.4 0.1 0.1 0.1 0.7 G1 X70.6 E42.4 0.0 0.0 0.0 1.0 G1 E42.4 1.0 0.0 0.0 0.0
The second line moves straight to the point (90.6, 13.8) extruding 22.4mm of filament. The mix ratio at the end of the move is 0.1:0.1:0.1:0.7.
The third line moves back 20mm in X extruding 20mm of filament. The mix varies linearly from 0.1:0.1:0.1:0.7 to 0:0:0:1 as the move is made.
The fourth line has no physical effect, but sets the mix proportions for the start of the next move to 1:0:0:0.
M190: Wait for bed temperature to reach target temp
Example: M190 S60
This will wait until the bed temperature reaches 60 degrees, printing out the temperature of the hot end and the bed every second.
M200 - Set filament diameter
M201 - Set max printing acceleration
in units/s^2 for print moves (M201 X1000 Y1000)
M202 - Set max travel acceleration
in units/s^2 for travel moves (M202 X1000 Y1000) Unused in Marlin!!
M203 - Set maximum feedrate
that your machine can sustain (M203 X200 Y200 Z300 E10000) in mm/sec
M204 - Set default acceleration
S normal moves T filament only moves (M204 S3000 T7000) im mm/sec^2 also sets minimum segment time in ms (B20000) to prevent buffer underruns and M20 minimum feedrate
M205 - advanced settings
minimum travel speed S=while printing T=travel only, B=minimum segment time X= maximum xy jerk, Z=maximum Z jerk, E=maximum E jerk
M206: set home offset
Example: M206 X10.0 Y10.0 Z-0.4
The values specified are added to the endstop position when the axes are referenced. The same can be achieved with a G92 right after homing (G28, G161).
With Marlin firmware, this value can be saved to EEPROM using the M500 command.
M207: calibrate z axis by detecting z max length
Example: M207
After placing the tip of the nozzle in the position you expect to be considered Z=0, issue this command to calibrate the Z axis. It will perform a z axis homing routine and calculate the distance traveled in this process. The result is stored in EEPROM as z_max_length. For using this calibration method the machine must be using a Z MAX endstop.
This procedure is usually more reliable than mechanical adjustments of a Z MIN endstop.
M226: Gcode Initiated Pause
Example: M226
Initiates a pause in the same way as if the pause button is pressed. That is, program execution is stopped and the printer waits for user interaction. This matches the behaviour of M1 in the NIST RS274NGC G-code standard and M0 in Marlin firmware.
M227: Enable Automatic Reverse and Prime
Example: M227 P1600 S1600
P and S are steps.
"Reverse and Prime" means, the extruder filament is retracted some distance when not in use and pushed forward the same amount before going into use again. This shall help to prevent drooling of the extruder nozzle. Teacup firmware implements this with M101/M103.
M228: Disable Automatic Reverse and Prime
Example: M228
See also M227.
M229: Enable Automatic Reverse and Prime
Example: M229 P1.0 S1.0
P and S are extruder screw rotations. See also M227.
M230: Disable / Enable Wait for Temperature Change
Example: M230 S1
S1 Disable wait for temperature change S0 Enable wait for temperature change
M240: Start conveyor belt motor
Example: M240
The conveyor belt allows to start mass production of a part with a reprap
M241: Stop conveyor belt motor
Example: M241
M245: Start cooler
Example: M245
used to cool parts/heated-bed down after printing for easy remove of the parts after print
M246: Stop cooler
Example: M246
M300: Play beep sound
Usage: M300 S<frequency Hz> P<duration ms>
Example: M300 S300 P1000
Play beep sound, use to notify important events like the end of printing. See working example on R2C2 electronics.
T: Select Tool
Example: T1
Select extruder number 1 to build with.
The sequence followed is:
- Set the current extruder to its standby temperature specified by G10 (see above),
- Apply any offset for the new extruder specified by G10,
- Set the new tool to its operating temperature specified by G10 and wait till it gets there,
- Use the new extruder.
Note that you may wish to move to some parking position before executing a T command in order to allow the new extruder to reach temperature while not in contact with the print.
After a reset extruders will not start heating until they are selected. You can either put them all at their standby temperature by selecting them in turn, or leave them off so they only come on if/when you first use them. The M0 command turns them all off.
Extruder numbering starts at 0.
Proposed EEPROM configuration codes
BRIEFLY: each RepRap has a number of physical parameters that should be persistent, but easily configurable, such as extrusion steps/mm, various max values, etc. Those parameters are currently hardcoded in the firmware, so that a user has to modify, recompile and re-flash the firmware for any adjustments. These configs can be stored in MCU's EEPROM and modified via some M-codes. Please see the detailed proposal at M-codes for EEPROM config. (This is proposed by --AlexRa on 11-March-2011. There is currently no working implementation of the proposed commands).
Replies from the RepRap machine to the host computer
All communication is in printable ASCII characters. Messages sent back to the host computer are terminated by a newline and look like this:
xx [line number to resend] [T:93.2 B:22.9] [C: X:9.2 Y:125.4 Z:3.7 E:1902.5] [Some debugging or other information may be here]
xx can be one of:
ok
rs
!!
ok means that no error has been detected.
rs means resend, and is followed by the line number to resend.
!! means that a hardware fault has been detected. The RepRap machine will shut down immediately after it has sent this message.
The T: and B: values are the temperature of the currently-selected extruder and the bed respectively, and are only sent in response to M105. If such temperatures don't exist (for example for an extruder that works at room temperature and doesn't have a sensor) then a value below absolute zero (-273oC) is returned.
C: means that coordinates follow. Those are the X: Y: etc values. These are only sent in response to M114 and M117.
The RepRap machine may also send lines that look like this:
// This is some debugging or other information on a line on its own. It may be sent at any time.
Such lines will always be preceded by //.
The most common response is simply:
ok
When the machine boots up it sends the string
start
once to the host before sending anything else. This should not be replaced or augmented by version numbers and the like. M115 (see above) requests those.
All this means that every line sent by RepRap to the host computer except the start line has a two-character prefix (one of ok, rs, !! or //). The machine should never send a line without such a prefix.
Proposal for sending multiple lines of G-code
So far, this is a proposal, open for discussion.
Problem to solve
Each line of G-code sent from the host to the controller is answered with an ok before the next line can be sent without locking communcations up. This makes operations very slow, as the usual USB-TTL converters and probably also the host's operating system drivers come with substantial latency, often 10 milliseconds.
For more details on this proposal, and some suggested solutions, and comments please see GCODE_buffer_multiline_proposal