2019-05-28 22:16:50 +03:00
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This document provides information on implementing G-Code command
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sequences in gcode_macro (and similar) config sections.
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### Formatting of G-Code in the config
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Indentation is important when defining a macro in the config file. To
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specify a multi-line G-Code sequence it is important for each line to
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have proper indentation. For example:
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```
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[gcode_macro blink_led]
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gcode:
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SET_PIN PIN=my_led VALUE=1
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G4 P2000
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SET_PIN PIN=my_led VALUE=0
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```
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Note how the `gcode:` config option always starts at the beginning of
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the line and subsequent lines in the G-Code macro never start at the
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beginning.
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### Save/Restore state for G-Code moves
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Unfortunately, the G-Code command language can be challenging to use.
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The standard mechanism to move the toolhead is via the `G1` command
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(the `G0` command is an alias for `G1` and it can be used
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interchangeably with it). However, this command relies on the "G-Code
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parsing state" setup by `M82`, `M83`, `G90`, `G91`, `G92`, and
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previous `G1` commands. When creating a G-Code macro it is a good
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idea to always explicitly set the G-Code parsing state prior to
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issuing a `G1` command. (Otherwise, there is a risk the `G1` command
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will make an undesirable request.)
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A common way to accomplish that is to wrap the `G1` moves in
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`SAVE_GCODE_STATE`, `G91`, and `RESTORE_GCODE_STATE`. For example:
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```
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[gcode_macro MOVE_UP]
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gcode:
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SAVE_GCODE_STATE NAME=my_move_up_state
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G91
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G1 Z10 F300
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RESTORE_GCODE_STATE NAME=my_move_up_state
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```
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The `G91` command places the G-Code parsing state into "relative move
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mode" and the `RESTORE_GCODE_STATE` command restores the state to what
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it was prior to entering the macro. Be sure to specify an explicit
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speed (via the `F` parameter) on the first `G1` command.
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### Template expansion
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2019-06-04 17:31:03 +03:00
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<!-- {% raw %} -->
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2019-05-28 22:16:50 +03:00
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The gcode_macro `gcode:` config section is evaluated using the Jinja2
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template language. One can evaluate expressions at run-time by
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wrapping them in `{ }` characters or use conditional statements
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wrapped in `{% %}`. See the
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[Jinja2 documentation](http://jinja.pocoo.org/docs/2.10/templates/)
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for further information on the syntax.
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This is most often used to inspect parameters passed to the macro when
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it is called. These parameters are available via the `params`
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pseudo-variable. For example, if the macro:
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```
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[gcode_macro SET_PERCENT]
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gcode:
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M117 Now at { params.VALUE|float * 100 }%
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```
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were invoked as `SET_PERCENT VALUE=.2` it would evaluate to `M117 Now
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at 20%`. Note that parameter names are always in upper-case when
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evaluated in the macro and are always passed as strings. If performing
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math then they must be explicitly converted to integers or floats.
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An example of a complex macro:
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```
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[gcode_macro clean_nozzle]
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gcode:
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SAVE_GCODE_STATE NAME=clean_nozzle_state
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G90
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G0 Z15 F300
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{% for wipe in range(8) %}
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{% for coordinate in [(275,4),(235,4)] %}
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G0 X{coordinate[0]} Y{coordinate[1] + 0.25 * wipe} Z9.7 F12000
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{% endfor %}
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{% endfor %}
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RESTORE_GCODE_STATE NAME=clean_nozzle_state
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```
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2019-06-04 17:31:03 +03:00
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<!-- {% endraw %} -->
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2019-05-28 22:16:50 +03:00
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#### The "printer" Variable
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It is possible to inspect (and alter) the current state of the printer
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via the `printer` pseudo-variable. For example:
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```
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[gcode_macro slow_fan]
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gcode:
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M106 S{ printer.fan.speed * 0.9 * 255}
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```
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Important! Macros are first evaluated in entirety and only then are
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the resulting commands executed. If a macro issues a command that
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alters the state of the printer, the results of that state change will
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not be visible during the evaluation of the macro. This can also
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result in subtle behavior when a macro generates commands that call
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other macros, as the called macro is evaluated when it is invoked
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(which is after the entire evaluation of the calling macro).
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By convention, the name immediately following `printer` is the name of
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a config section. So, for example, `printer.fan` refers to the fan
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object created by the `[fan]` config section. There are some
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exceptions to this rule - notably the `gcode` and `toolhead` objects.
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If the config section contains spaces in it, then one can access it
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via the `[ ]` accessor - for example:
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`printer["generic_heater my_chamber_heater"].temperature`.
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Some printer objects allow one to alter the state of the printer. By
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convention, these objects use an `action_` prefix. For example,
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`printer.gcode.action_emergency_stop()` would cause the printer to go
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into a shutdown state. These actions are taken at the time that the
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macro is evaluated, which may be a significant amount of time before
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the generated commands are executed.
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The following are common printer attributes:
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- `printer.fan.speed`: The fan speed as a float between 0.0 and 1.0.
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- `printer.gcode.action_respond_info(msg)`: Write the given `msg` to
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the /tmp/printer pseudo-terminal. Each line of `msg` will be sent
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with a "// " prefix.
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- `printer.gcode.action_respond_error(msg)`: Write the given `msg` to
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the /tmp/printer pseudo-terminal. The first line of `msg` will be
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sent with a "!! " prefix and subsequent lines will have a "// "
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prefix.
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- `printer.gcode.action_emergency_stop(msg)`: Transition the printer
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to a shutdown state. The `msg` parameter is optional, it may be
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useful to describe the reason for the shutdown.
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- `printer.gcode.gcode_position`: The current position of the toolhead
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relative to the current G-Code origin. It is possible to access the
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x, y, z, and e components of this position (eg,
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`printer.gcode.gcode_position.x`).
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- `printer["gcode_macro <macro_name>"].<variable>`: The current value
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of a gcode_macro variable.
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- `printer.<heater>.temperature`: The last reported temperature (in
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2019-11-25 03:02:49 +03:00
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Celsius as a float) for the given heater. Example heaters are:
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`extruder`, `extruder1`, `heater_bed`, `heater_generic
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<config_name>`.
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2019-05-28 22:16:50 +03:00
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- `printer.<heater>.target`: The current target temperature (in
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Celsius as a float) for the given heater.
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- `printer.pause_resume.is_paused`: Returns true if a PAUSE command
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has been executed without a corresponding RESUME.
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- `printer.toolhead.position`: The last commanded position of the
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toolhead relative to the coordinate system specified in the config
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file. It is possible to access the x, y, z, and e components of this
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position (eg, `printer.toolhead.position.x`).
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2019-11-25 03:02:49 +03:00
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- `printer.toolhead.extruder`: The name of the currently active
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extruder. For example, one could use
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`printer[printer.toolhead.extruder].target` to get the target
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temperature of the current extruder.
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2019-11-25 03:16:21 +03:00
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- `printer.toolhead.homed_axes`: The current cartesian axes considered
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to be in a "homed" state. This is a string containing one or more of
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"x", "y", "z".
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2019-05-28 22:16:50 +03:00
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The above list is subject to change - if using an attribute be sure to
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2019-06-04 17:39:43 +03:00
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review the [Config Changes document](Config_Changes.md) when upgrading
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the Klipper software. The above list is not exhaustive. Other
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attributes may be available (via `get_status()` methods defined in the
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2019-05-28 22:16:50 +03:00
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software). However, undocumented attributes may change without notice
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in future Klipper releases.
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### Variables
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The SET_GCODE_VARIABLE command may be useful for saving state between
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macro calls. For example:
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```
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[gcode_macro start_probe]
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variable_bed_temp: 0
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gcode:
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# Save target temperature to bed_temp variable
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SET_GCODE_VARIABLE MACRO=start_probe VARIABLE=bed_temp VALUE={printer.heater_bed.target}
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# Disable bed heater
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M140
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# Perform probe
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PROBE
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# Call finish_probe macro at completion of probe
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finish_probe
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[gcode_macro finish_probe]
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gcode:
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# Restore temperature
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M140 S{printer["gcode_macro start_probe"].bed_temp}
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```
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Be sure to take the timing of macro evaluation and command execution
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into account when using SET_GCODE_VARIABLE.
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2019-06-30 00:13:35 +03:00
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### Delayed Gcodes
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The [delayed_gcode] configuration option can be used to execute a delayed
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gcode sequence:
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```
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[delayed_gcode clear_display]
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gcode:
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M117
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[gcode_macro load_filament]
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gcode:
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G91
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G1 E50
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G90
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M400
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M117 Load Complete!
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UPDATE_DELAYED_GCODE ID=clear_display DURATION=10
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```
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When the `load_filament` macro above executes, it will display a
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"Load Complete!" message after the extrusion is finished. The
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last line of gcode enables the "clear_display" delayed_gcode, set
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to execute in 10 seconds.
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The `initial_duration` config option can be set to execute the
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delayed_gcode on printer startup. The countdown begins when the
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printer enters the "ready" state. For example, the below delayed_gcode
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will execute 5 seconds after the printer is ready, initializing
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the display with a "Welcome!" message:
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```
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[delayed_gcode welcome]
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initial_duration: 5.
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gcode:
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M117 Welcome!
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```
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Its possible for a delayed gcode to repeat by updating itself in
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the gcode option:
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```
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[delayed_gcode report_temp]
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initial_duration: 2.
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gcode:
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{printer.gcode.action_respond_info(
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"Extruder Temp: %.1f" %
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(printer.extruder0.temperature))}
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UPDATE_DELAYED_GCODE ID=report_temp DURATION=2
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```
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The above delayed_gcode will send "// Extruder Temp: [ex0_temp]" to
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Octoprint every 2 seconds. This can be canceled with the following
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gcode:
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```
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UPDATE_DELAYED_GCODE ID=report_temp DURATION=0
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```
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