klipper-dgus/docs/Todo.md

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Klipper is currently in an experimental state. There are several
features still to be implemented. In no particular order:
Host user interaction
=====================
* See if there is a better way to report errors. Octoprint sometimes
doesn't highlight an error (one has to look in the terminal tab to
find the error) and errors written to the log can be non-obvious to
a user.
* Improve startup:
* Provide startup scripts so that Klippy can startup at system
bootup.
* Improve gcode interface:
* Provide a better way to handle print nozzle z offsets. The M206
command is cryptic to use and it is too easy to set the value
incorrectly or to forget to set it.
* Provide a way to temporarily disable endstop checks so that a user
can issue commands that potentially move the head past
position_min/position_max.
* Improve logging:
* Automatically roll Klippy log files. The default log file should
have the current date in the log file name.
* Possibly collate and report the statistics messages in the log in a
more friendly way.
* Possibly support a mechanism for the host to limit maximum velocity
so that the mcu is never requested to step at a higher rate than it
can support.
Safety features
===============
* Support loading a valid step range into the firmware after
homing. This would provide a sanity check in the firmware that would
reduce the risk of the host commanding a stepper motor past its
valid step range. To maintain high efficiency in the firmware, the
firmware would only need to check periodically (eg, every 100ms)
that the stepper is in range.
* Possibly support periodically querying the endstop switches and use
multiple step ranges depending on the switch state. This would
enable runtime endstop detection. (However, it's unclear if runtime
endstop detection is a good idea because of spurious signals caused
by electrical noise.)
* Support validating that heaters are heating at expected rates. This
can be useful to detect a sensor failure (eg, thermistor short) that
could otherwise cause the PID to command excessive heating.
Testing features
================
* Complete the host based simulator. It's possible to compile the
firmware for a "host simulator", but that simulator doesn't do
anything currently. It would be useful to expand the code to support
more error checks, kinematic simulations, and improved logging.
Documentation
=============
* Document and test running the host software on a Beagle Bone Black.
* Add documentation describing how to perform bed-leveling accurately
in Klipper. Improve description of stepper phase based bed leveling.
* Document the kinematic formulas in Klippy. Document how acceleration
and jerk limits are enforced.
* Document how one can tune the pressure advance setting.
Hardware features
=================
* Port firmware to more architectures:
* Beagle Bone Black PRU
* Smoothieboard / NXP LPC1769 (ARM cortex-M3)
* Unix based scheduling; Unix based real-time scheduling
* Support for additional kinematics: scara, corexy, etc.
* Support shared motor enable GPIO lines.
* Support for multiple extruders.
* Support for bed-level probes.
* Possible support for touch panels attached to the micro-controller.
(In general, it would be preferable to attach touch panels to the
host system and have octoprint interact with the panel directly, but
it would also be useful to handle panels already hardwired to the
micro-controller.)
* The raspberry pi has the ability to cut power to its USB ports. This
feature is useful for resetting micro-controllers that are powered
over USB. It would be useful to have a high-level command interface
in Klippy to request a micro-controller reset via this mechanism.
* Possibly support printers using multiple micro-controllers.
Misc features
=============
* Possibly use cubic functions instead of quadratic functions in step
compression code.
* Possibly support a "feed forward PID" that takes into account the
amount of plastic being extruded. If the extrude rate changes
significantly during a print it can cause heating bumps that the PID
overcompensates for. The temperature change due to the extrusion
rate could be modeled to eliminate these bumps and make the
extrusion temperature more consistent.