I love my ERCF and building it was the most fun I've had in many years of the 3D-printing hobby. Whilst the design is brilliant I found a few problems with the software and wanted to add some features and improve user friendliness. This became especially true after the separation of functionality with the introduction of the "sensorless filament homing" branch. I liked the new python implementation as a Klipper plug-in but wanted to leverage my (very reliable) toolhead sensor. So I rewrote the software behind ERCF - it still has the structure and much of the code of the original but, more significantly, it has many new features, integrates the toolhead sensor and sensorless options. I'm calling it the "Happy Hare" release or v3.

Also, some folks have asked about making a donation to cover the cost of the all the coffee I'm drinking. I'm not doing this for any financial reward but it you feel inclined a donation to PayPal https://www.paypal.me/moggieuk will certainly be spent making your life with ERCF more enjoyable.

Thank you!

• Support all options for both toolhead sensor based loading/unloading and the newer sensorless filament homing (no toolhead sensor)
• Supports sync load and unloading steps moving the extruder and gear motor together, including a config with toolhead sensor that can work with FLEX materials!
• Fully implements “EndlessSpool” with new concept of Tool --> Gate mapping. This allows empty gates to be identified and tool changes subsequent to runout to use the correct filament spool. It has the added advantage for being able to map gates to tools in case of slicing to spool loading mismatch.
• Vastly improved logging including a new log to file functionality. You can keep the console log to a minimum and send debugging information to `ercf.log` located in the same directory as Klipper logs
• Optional fun visual representation of loading and unloading sequence
• Ability to specify empty or disabled tools (gates) and to discover availability autmatically
• Formal support for the filament bypass block with associated new commands and state if using it.
• Ability to reduce gear current (currently TMC2209 only) during “collision” homing procedure to prevent grinding, etc.
• Convenience filament "autoload" function and check gate feature to ensure filaments are all ready before print
• No need to do anything custom in your existing macros
• Moonraker update-manager support
• Complete persitance of state and statistics across restarts!
• Reliable servo operation - no more "kickback" problems
• Integrated encoder driver that implements filament measurement and automatic clog detection!
• Supports my sister project...

Now with customized KlipperScreen for ERCF touchscreen control

• Reworks calibration routine to average measurements, add compensation based on spring in filament (related to ID and length of bowden), and considers configuration options.
• Runtime configuration via new command (ERCF_TEST_CONFIG) for most options which avoids constantly restarting klipper or recalibrating during setup
• Workaround to some of the ways to provoke Klipper “Timer too close” errors (although there are definitely bugs in the Klipper firmware)
• Measures “spring” in filament after extruder homing for more accurate calibration reference
• Adds servo_up delay making the gear to extruder transition of filament more reliable (maintains pressure)
• New "TEST_TRACKING" commands to help diagnose issues with encoder
• Experimental logic to use stallguard filament homing (Caveat: not easy to setup using EASY-BRD and not compatible with sensorless selector homing option)

• Vastly increased error detection/checking of supplied parameters and configurations
• Consistent handling of errors. E.g. use exceptions to avoid multiple calls to "pause"
• Wrapping of all stepper movements to facilitate “DEVELOPER” logging level and easier debugging
• New load and unload sequences (to support all build configurations) and effectively combine the sensor and sensorless logic

The module can be installed into an existing Klipper installation with the install script. Once installed it will be added to Moonraker update-manager to easy updates like other Klipper plugins:

cd ~
git clone https://github.com/moggieuk/ERCF-Software-V3.git
cd ERCF-Software-V3

./install.sh -i

The -i option will bring up some interactive prompts to aid setting some confusing parameters (like sensorless selector homing setup). For EASY-BRD and Fysetc ERB installations it will also configure all the pins for you. If not run with the -i flag the new template ercf*.cfg files will not be installed. Note that if existing ercf*.cfg files are found the old versions will be moved to numbered backups like <file>.00 extension instead so as not to overwrite an existing configuration. If you still choose not to install the new ercf*.cfg files automatically be sure to examine them closely and compare to the supplied templates (this is completely different software from the original)

Note that the installer will look for Klipper install and config in standard locations. If you have customized locations or the installer fails to find Klipper you can use the -k and -c flags to override the klipper home directory and klipper config directory respectively. Also, the install assumes a single instance of Klipper running per device. If you have many you may need to install and configure the ercf*.cfg files by hand.

REMEMBER that ercf_hardware.cfg, ercf_software.cfg & ercf_parameters.cfg must all be referenced by your printer.cfg master config file. client_macros.cfg should also be referenced if you don't already have working PAUSE/RESUME/CANCEL_PRINT macros (but be sure to read the section before on macro expectations). These includes can be added automatically for you with the install script.

Pro tip: If you are concerned about running install.sh -i then run like this: install.sh -i -c /tmp -k /tmp This will build the *.cfg files for you but put then in /tmp. You can then read them, pull out the bits your want to augment existing install or simply see what the answers to the various questions will do...

Also be sure to read my notes on Encoder problems - the better the encoder the better this software will work.

The configuration and setup of your ERCF using Happy Hare is 95% the same as documented in the newer V2 Manual. Be sure to read this README and the installed 'ercf_*.cfg' files to understand any difference. Read a SUMMARY OF DIFFERENCES here.

• v1.0.0 - Initial Beta Release
• v1.0.3 - Bug fixes from community: Better logging on toolchange (for manual recovery); Advanced config parameters for adjust tolerance used in 'apply_bowden_correction' move; Fixed a couple of silly (non serious) bugs
• v1.1.0 - New commands: ERCF_PRELOAD & ERCF_CHECK_GATES ; Automatic setting of clog detection distance in calibration routine ; New interactive install script to help EASY-BRD setup; Bug fixes
• v1.1.1 - Fixes for over zealous tolerance checks on bowden loading; Fix for unloading to far if apply_bowden_correction is active; new test command: ERCF_TEST_TRACKING; Fixed slicer based tool load issue
• v1.1.2 - Improved install.sh -i to include servo and calib bowden length; Better detection of malfunctioning toolhead sensor
• v1.1.3 - Added ERCF_RECOVER command to re-establish filament position after manual intervention and filament movement. Not necessary if you use ERCF commands to correct problem but useful to call prior to RESUME; Much improved install.sh to cover toolhead sensor and auto restart moonraker on first time install
• v1.1.4 - Change to automatic clog detection length based on community feedback
• v1.1.5 - Further install.sh improvements - no longer need filament_sensor defined or duplicate pin override if not using clog detection; Cleaned up documentation in template config file; Stallguard filament homing should now be possible (have to configure by hand); Additional configuration checks on startup; minor useability improvements based on community feedback
• v1.1.6 - New feature to log to file independently to console (allows for clean console and debug to logfile); New gate statistics (like slippage) are recorded and available with an augmented ERCF_DUMP_STATS command; Several minor improvements and fixes suggested by community
• v1.1.7 - Automatic setting of encoder state - no need to put anything ERCF related into existing macros (START/PAUSE/RESUME/STOP/CANCEL) anymore!; Improvements to install script for non EASY-BRD config; Exposed all built-in gear/extruder feed speeds; Tweaks to tolerance checks to prevent false pauses; No annoying pause/unlock sequence while you are playing out of a print. UPDATE TO CONFIG FILES RECOMMENDED
• v1.1.8 - Enhanced ERCF_CHECK_GATES command; better configuraton of tip forming; Workarounds to Timer Too Close errors on selector; Fined grained current reduction control; less conservative restting of filament state; servo remains up on failed load; fixes typos and spelling mistakes. Full details here: https://discord.com/channels/460117602945990666/909743915475816458/1058586768791838791
• v1.1.9 - Installer support for the Fytsec ERB Burrows board; Inclusion of display setup for 12864 mini displays; Bug fixes
• v1.2.0 - Major new feature for being able to persist all ERCF state between restarts - now you can just turn on an print!; Various bug fixes, error message and status display improvements. SOME ADDITIONS TO `ercf_parameters.cfg` CONFIG FILE
• v1.2.1 - MAJOR: Bundled servo driver with careful PWM synchronization to avoid servo kickback!!! (Requires re-running ./install.sh)
• v1.2.2 - Automatic clog length setting. No more [filament_runout_sensor] or [duplicate_pin] setup (Required re-running ./install.sh)
• v1.2.3 - Update to support KlipperScreen; Additional printer variables exposed; Cleanup of bypass commands; Bug fixes
• v1.2.4 - Improvement of clog detection during wipetower movements generated by slicer; Enhanced ERCF_ENDLESS_SPOOL command; Restore users "idle_timeout" when print ends; Updated ercf_software for stand-alone tip formation

Because this is a complete rewrite some existing commands have been modifed and enhanced. See the command reference at the end of this page for full details.

Note that if a toolhead sensor is configured it will become the default filament homing method and home to extruder an optional but unnecessary step. Also note the home to extruder step will always be performed during calibration of tool 0 (to accurately set ercf_calib_ref). For accurate homing and to avoid grinding, tune the gear stepper current reduction extruder_homing_current as a % of the default run current.

1. ERCF [T1] >.... [encoder] .............. [extruder] .... [sensor] .... [nozzle] UNLOADED (@0.0 mm)
2. ERCF [T1] >>>>> [encoder] >>>........... [extruder] .... [sensor] .... [nozzle] (@48.2 mm)
3. ERCF [T1] >>>>> [encoder] >>>>>>>>...... [extruder] .... [sensor] .... [nozzle] (@696.4 mm)
4. ERCF [T1] >>>>> [encoder] >>>>>>>>>>>>>> [extruder] .... [sensor] .... [nozzle] (@696.4 mm)
5. ERCF [T1] >>>>> [encoder] >>>>>>>>>>>>>> [extruder] >>>| [sensor] .... [nozzle] (@707.8 mm)
6. ERCF [T1] >>>>> [encoder] >>>>>>>>>>>>>> [extruder] >>>> [sensor] >>>> [nozzle] LOADED (@758.7 mm)

The "visual log" above shows individual steps of the loading process:

1. Starting with filament unloaded and sitting in the gate for tool 1
2. Firstly ERCF clamps the servo down and pulls a short length of filament through the encoder. It it doesn't see filament it will try 'load_encoder_retries' times (default 2). If still no filament it will report the error. The speed of this initial movement is controlled by 'short_moves_speed', the acceleration is as defined on the gear stepper motor config in 'ercf_hardware.cfg'
3. ERCF will then load the filament through the bowden in a fast movement. The speed is controlled by 'long_moves_speed'. This movement can be broken up into multiple movements with 'num_moves' as one workaround to overcome "Timer too close" errors from Klipper. If you keep your step size to 8 for the gear motor you are likely to be able to operate with a single fast movement. The length of this movement is set when you calibrate ERCF and stored in 'ercf_vars.cfg'. There is an advanced option to allow for correction of this move if slippage is detected controlled by 'apply_bowden_correction' and 'load_bowden_tolerance' (see comments in 'ercf_parameters.cfg' for more details)
4. The example shown uses a toolhead sensor, but if you configure sensorless filament homing then ERCF will now creep towards your extruder gears to detect this point as its homing position. This homing move is controlled by 'extruder_homing_max' (maximum distance to advance in order to attempt to home the extruder), 'extruder_homing_step' (step size to use when homing to the extruder with collision detection), 'extruder_homing_current' (tunable to control how much % to temporarily reduce the gear stepper current to prevent grinding of filament)
5. This is the move into the toolhead and is the most critical transition point. ERCF will advance the extruder looking to see that the filament was successfully picked up. In the case of a toolhead sensor this is deterministic because it will advance to the sensor and use this as a new homing point. For sensorless ERCF will look for encoder movement implying that filament has been picked up. Optionally this move can be made to run gear and extruder motors synchronously for greater reliability. 'sync_load_length' (mm of synchronized extruder loading at entry to extruder). As a further aid to reliability ERCF will use the "spring" in the filament by delaying the servo release by 'delay_servo_release' mm. When using synchronous load this will relax the compression in the filament leading to quieter loading, for extruder only load this will keep pressure on the gear to aid grabbing the filament.
   With toolhead sensor enabled there is a little more to this step: ERCF will home the end of the filament to the toolhead sensor controlled by 'toolhead_homing_max' (maximum distance to advance in order to attempt to home to toolhead sensor) and 'toolhead_homing_step (step size to use when homing to the toolhead sensor. If 'sync_load_length' is greater than 0 this homing step will be synchronised.
   The speed of all movements in this step is controlled by 'sync_load_speed'
6. Now the filament is under exclusive control of the extruder. Filament is moved the remaining distance to the meltzone. This distance is defined by 'home_position_to_nozzle' and is either the distance from the toolhead sensor to the nozzle or the distance from the extruder gears to the nozzle depending on your setup. This move speed is controlled by 'nozzle_load_speed'. We are now loaded and ready to print.

1. ERCF [T1] <<<<< [encoder] <<<<<<<<<<<<<< [extruder] <<<< [sensor] <... [nozzle] (@34.8 mm)
2. ERCF [T1] <<<<< [encoder] <<<<<<<<<<<<<< [extruder] <<<| [sensor] .... [nozzle] (@87.7 mm)
3. ERCF [T1] <<<<< [encoder] <<<<<<<<<<<<<< [extruder] .... [sensor] .... [nozzle] (@91.7 mm)
4. ERCF [T1] <<<<< [encoder] <<<<<<<<...... [extruder] .... [sensor] .... [nozzle] (@729.9 mm)
5. ERCF [T1] <<<<< [encoder] <<<........... [extruder] .... [sensor] .... [nozzle] (@729.9 mm)
6. ERCF [T1] <<<.. [encoder] .............. [extruder] .... [sensor] .... [nozzle] (@795.5 mm)
7. ERCF [T1] <.... [encoder] .............. [extruder] .... [sensor] .... [nozzle] UNLOADED (@795.5 mm)

The "visual log" above shows individual steps of the loading process:

1. Starting with filament loaded in tool 1. This example is taken from an unload that is not under control of the slicer, so the first thing that happens is that a tip is formed on the end of the filament which ends with filament in the cooling zone of the extruder. This operation is controlled but the user edited '_ERCF_FORM_TIP_STANDALONE' macro in 'ercf_software.cfg'
2. This step only occurs with toolhead sensor. The filament is withdrawn until it no longer detected by toolhead sensor. This is done at the 'nozzle_unload_speed' and provides a more accurate determination of how much further to retract and a safety check that the filament is not stuck in the nozzle
3. ERCF then moves the filament out of the extruder at 'nozzle_unload_speed'. This is approximate for sensorless but the distance moved can be optimized if using a toolhead sensor by the setting of 'extruder_to_nozzle' and 'sensor_to_nozzle' (the difference represents the distance moved)
4. Once at where it believes is the gear entrance to the extruder an optional short synchronized (gear and extruder) move can be configured. This is controlled by 'sync_unload_speed' and 'sync_unload_length'. This is a great safely step and "hair pull" operation but also serves to ensure that the ERCF gear has a grip on the filament. If synchronized unload is not configured ERCF will still perform the bowden unload with an initial short move with gear motor only, again to ensure filament is gripped
5. The filament is now extracted quickly through the bowden. The speed is controlled by 'long_moves_speed' and the movement can be broken up with 'num_moves' similar to when loading
6. Completion of the the fast bowden move
7. At this point ERCF performs a series of short moves looking for when the filament exits the encoder. The speed is controlled by 'short_moves_speed'
8. When the filament is released from the encoder, the remainder of the distance to the park position is moved at 'short_moves_speed'. The filament is now unloaded

When the state of ERCF is unknown, ERCF will perform other movements and look at its sensors to try to ascertain filament location. This may modify the above sequence and result in the omission of the fast bowden move for unloads.

 If you have a toolhead sensor for filament homing:
    toolhead_homing_max: 35            # Maximum distance to advance in order to attempt to home to toolhead sensor (default 20)
    toolhead_homing_step: 1.0          # Step size to use when homing to the toolhead sensor (default 1)

Options without toolhead sensor (but still needed for calibration with toolhead sensor)

    extruder_homing_max: 50            # Maximum distance to advance in order to attempt to home the extruder
    extruder_homing_step: 2.0          # Step size to use when homing to the extruder with collision detection (default 2)

For accurate homing and to avoid grinding, tune the gear stepper current reduction

    extruder_homing_current: 40        # Percentage of gear stepper current to use when extruder homing (TMC2209 only, 100 to disable)

How far (mm) to run gear_stepper and extruder together in sync on load and unload. This will make loading and unloading
more reliable and will act as a "hair pulling" step on unload.  These settings are optional - use 0 to disable
Non zero value for 'sync_load_length' will synchronize the whole homing distance if toolhead sensor is installed

    sync_load_length: 10               # mm of synchronized extruder loading at entry to extruder
    sync_unload_length: 10             # mm of synchronized movement at start of bowden unloading

This is the distance of the final filament load from the homing point to the nozzle
If homing to toolhead sensor this will be the distance from the toolhead sensor to the nozzle
If extruder homing it will be the distance from the extruder gears (end of bowden) to the nozzle

This value can be determined by manually inserting filament to your homing point (extruder gears or toolhead sensor)
and advancing it 1-2mm at a time until it starts to extrude from the nozzle.  Subtract 1-2mm from that distance distance
to get this value.  If you have large gaps in your purge tower, increase this value.  If you have blobs, reduce this value.
This value will depend on your extruder, hotend and nozzle setup.

    home_position_to_nozzle: 72        # E.g. Revo Voron with CW2 extruder using extruder homing

Advanced and optional. If you regularly switch between sensorless and toolhead sensor or you want to optimize extruder
unload when using toolhead sensor you can override 'home_position_to_nozzle' with these more specific values
(Note that the difference between these two represents the extruder to sensor distance and is used as the final
unload distance from extruder. An accurate setting can reduce tip noise/grinding on exit from extruder)

    extruder_to_nozzle: 72		# E.g. Revo Voron with CW2 extruder using extruder homing
    sensor_to_nozzle: 62		# E.g. Revo Voron with CW2 extruder using toolhead sensor homing

Again, these last two settings are optional and can be omitted

Obviously the actual distances shown above may be customized

Advanced options When not using synchronous load move the spring tension in the filament held by servo will be leverage to help feed the filament into the extruder. This is controlled with the delay_servo_release setting. It defaults to 2mm and is unlikely that it will need to be altered.
An option to home to the extruder using stallguard homing_method=1 is available but not recommended: (i) it is not necessary with current reduction, (ii) it is not readily compatible with EASY-BRD and (iii) is currently incompatible with sensorless selector homing which hijacks the gear endstop configuration.
The 'apply_bowden_correction' setting, if enabled, will make the driver "believe" the encoder reading and make correction moves to bring the filament to the desired end of bowden position. This is useful is you suspect slippage on high speed loading, perhaps when yanking on spool (requires accurate encoder). If disabled, the gear stepper will be solely responsible for filament positioning in bowden (requires minimal friction in feeder tubes). The associated (advanced) 'load_bowden_tolerance' defines the point at which to apply to correction moves. See 'ercf_parameters.cfg' for more details.

Note about post homing distance Regardless of loading settings above it is important to accurately set home_to_nozzle distance. If you are not homing to the toolhead sensor this will be from the extruder entrance to nozzle. If you are homing to toolhead sensor, this will be the (smaller) distance from sensor to nozzle. For example in my setup of Revo & Clockwork 2, the distance is 72mm or 62mm respectively.

This is much simplier than loading. The toolhead sensor, if installed, will automatically be leveraged as a checkpoint when extracting from the extruder. sync_unload_length controls the mm of synchronized movement at start of bowden unloading. This can make unloading more reliable if the tip is caught in the gears and will act as what Ette refers to as a "hair pulling" step on unload. This is an optional step, set to 0 to disable.

ERCF can use its encoder to detect filament runout or clog conditions. This functionality is enabled with the enable_clog_detection in ercf_parameters.cfg. It works by monitoring how much filament the extruder is pushing and comparing it that measured by the encoder. If the extruder ever gets ahead by more that the calibrated clog_detection_length the runout/clog detection logic is triggered. If it is determined to be a clog, the printer will pause in the usual manner and require ERCF_UNLOCK & RESUME to continue. If a runout and endless spool is enabled the tool with be remaped and printing will automatically continue.

Setting this value to 1 enables clog detection employing the static clog detection length. Setting it to 2 will enable automatic adjustment of the detection length. Whilst this doesn't guarantee you won't get a false trigger it will contiually tune until false triggers not longer occur. The automatic algorithm is controlled by two variables in the [ercf_encoder] section:

desired_headroom: 5.0		# The runout headroom that ERCF will attempt to maintain (closest ERCF comes to triggering runout)
average_samples: 4		# The "damping" effect of last measurement. Higher value means clog_length will be reduced more slowly

When changing a tool with the Tx command the ERCF will by default select the filament at the gate (spool) of the same number. The mapping built into this Happy Hare driver allows you to modify that. There are 3 primary use cases for this feature:

1. You have loaded your filaments differently than you sliced gcode file... No problem, just issue the appropriate remapping commands prior to printing
2. Some of "tools" don't have filament and you want to mark them as empty to avoid selection.
3. Most importantly, for EndlessSpool - when a filament runs out on one gate (spool) then next in the sequence is automatically mapped to the original tool. It will therefore continue to print on subsequent tool changes. You can also replace the spool and update the map to indicate availability mid print

*Note that the initial availability of filament at each gate can also be specified in the ercf_parameters.cfg file by updating the gate_status list. E.g.

gate_status = 1, 1, 0, 0, 1, 0, 0, 0, 1

on a 9-gate ERCF would mark gates 2, 3, 5, 6 & 7 as empty

To view the current mapping you can use either ERCF_STATUS or ERCF_DISPLAY_TTG_MAP

Since EndlessSpool is not something that triggers very often you can use the following to simulate the action:

ERCF_ENCODER_RUNOUT FORCE_RUNOUT=1

This will emulate a filament runout and force ERCF to interpret it as a true runout and not a possible clog. ERCF will then run the following sequence:

• Move the toolhead up a little (defined by 'z_hop_distance & z_hop_speed') to avoid blobs
• Call '_ERCF_ENDLESS_SPOOL_PRE_UNLOAD' macro. Typically this where you would quickly move the toolhead to your parking area
• Perform the toolchange and map the new gate in the sequence
• Call '_ERCF_ENDLESS_SPOOL_POST_LOAD' macro. Typically this is where you would clean the nozzle and quickly move your toolhead back to the position where you picked it up in the PRE_UNLOAD macro
• Move the toolhead back down the final amount and resume the print

The default supplied _PRE and _POST macros call PAUSE/RESUME which is typically a similar operation and may be already sufficient. Note: A common problem is that a custom _POST macro does not return the toolhead to previous position. ERCF will still handle this case but it will move very slowly because it is not expecting large horizontal movement.

The log_visual setting turns on an off the addition of a filament tracking visualization in either long form or abbreviated KlipperScreen form. This is a nice with log_level of 0 or 1 on a tuned and functioning setup.

If you have installed the optional filament bypass block your can configure its selector position by setting bypass_selector in ercf_parameters.cfg. Once this is done you can use the following command to unload any ERCF controlled filament and select the bypass:

ERCF_SELECT_BYPASS`

Once you have filament loaded up to the extruder you can load the filament to nozzle with:

ERCF_LOAD

Finally, you can unload just the extruder using the usual eject.

ERCF_EJECT

All the essential configuration and tuning parameters can be modified at runtime without restarting Klipper. Use the ERCF_TEST_CONFIG command to do this:

Any of the displayed config settings can be modified. E.g.

ERCF_TEST_CONFIG home_position_to_nozzle=45

Will update the distance from homing position to nozzle. The change is designed for testing was will not be persistent. Once you find your tuned settings be sure to update ercf_parameters.cfg

Setting the ercf_calib_ref is slightly different in that it will, by default, average 3 runs and compensate for spring tension in filament held by servo. It might be worth limiting to a single pass until you have tuned the gear motor current. Here is an example:

The ERCF_PRELOAD is an aid to loading filament into the ERCF. The command works a bit like the Prusa MMU and spins gear with servo depressed until filament is fed in. Then parks the filament nicely. This is the recommended way to load filament into ERCF and ensures that filament is not under/over inserted blocking the gate.

Similarly the ERCF_CHECK_GATES command will run through all the gates (or those specified), checks that filament is loaded, correctly parks and updates the "gate status" map of empty gates. Could be a really useful pre-print check...

Per-gate statistics that aggregate servo/load/unload failures and slippage are recorded throughout a session and can be logged at each toolchange. An augmented ERCF_DUMP_STATS command will display these stats and will give a rating on the "quality assessment" of functionality of the gate (more info is sent to debug level typically found in the ercf.log). The per-gate statistics will record important data about possible problems with individual gates. Since the software will try to recover for many of these conditions you might not know you have a problem. One particularly useful feature is being able to spot gates that are prone to slippage. If slippage occurs on all gates equally, it is likely an encoder problem. If on one gate if might be incorrect calibration of that gate or friction in the filament path. Note that ERCF_DUMP_STATS will display this data but the details are sent to the DEBUG log level so you will only see it in the ercf.log file if you setup as I suggest.

There are four configuration options that control logging:

log_level & logfile_level can be set to one of (0 = essential, 1 = info, 2 = debug, 3 = trace, 4 = developer)
Generally you can keep console logging to a minimal whilst still sending debug output to the ercf.log file
Increasing the console log level is only really useful during initial setup to save having to constantly open the log file
  log_level: 1
  logfile_level: 3            # Can also be set to -1 to disable log file completely
  log_statistics: 1           # 1 to log statistics on every toolchange, 0 to disable (still recorded)
  log_visual: 1               # 1 to log a fun visual representation of ERCF state showing filament position, 0 disable

The logfile will be placed in the same directory as other log files and is called ercf.log. It will rotate and keep the last 5 versions (just like klipper). The default log level for ercf.log is "3" but can be set by adding logfile_level in you ercf_parameters.cfg. With this available my suggestion is to reset the console logging level log_level: 1 for an uncluttered experience knowing that you can always access ercf.log for debugging at a later time. Oh, and if you don't want the logfile, no problem, just set logfile_level: -1

It is no longer necessary to added anything to these macros -- ERCF will automatically wrap anything defined. If you have used other versions of the software then you should remove these customizations. To understand the philosophy and expectations here is the sequence:

During a print, if ERCF detects a problem, it will record the print position, safely lift the nozzle up to z_hop_height at z_hop_speed (to prevent a blob). It will then call the user's PAUSE macro (which can be the example one supplied in ercf_software.cfg). It is expected that pause will save it's starting position (GCODE_SAVE_STATE) and move the toolhead to a park area, often above a purge bucket, at fast speed.

The user then calls ERCF_UNLOCK, addresses the issue and calls RESUME to continue with the print.

The user's RESUME macro may do some purging or nozzle cleaning, but is expected to return the toolhead at higher speed to where it was left when the pause macro was called. At this point the ERCF wrapper takes over and is responsible for dropping the toolhead back down to the print and resumes printing.

ERCF will always return the toolhead to the correct position, but if you leave it in your park area will will move it back very slowly. You can to follow the above sequence to make this operation fast to prevent oozing from leaking on your print.

At some point when a project occurs during a multi-color print ERCF will go into a pause/locked state. Generally the user would then call ERCF_UNLOCK, fix the issue and then resume print with RESUME. While fixing the problem you may find it useful to issue ERCF commands to move the filament around or change gate. If you do this the ERCF will "know" the correct state when resuming a print and everything will be copacetic. However, if you manually move the filament you are able to tell ERCF the correct state with the ERCF_RECOVER command. This command is also useful when first turning on an ERCF with filament already loaded. Instead of ERCF having to unload and reload to figure out the state you can simple tell it! Here are some examples:

ERCF_RECOVER - attempt to automatically recover the filament state.  The tool or gate selection will not be changed.
ERCF_RECOVER TOOL=0 - tell ERCF that T0 is selected but automatically look at filament location
ERCF_RECOVER TOOL=5 LOADED=1 - tell ERCF that T5 is loaded and ready to print
ERCF_RECOVER TOOL=1 GATE=2 LOADED=0 - tell ERCF that T1 is being serviced by gate #2 and the filament is Unloaded

This is considered advanced functionality but it is incredibly useful once you are familar with the basic operation of ERCF. Essentially the state of everything from the EndlessSpool groups to the filament position and gate selection can be persisted accross restarts (homing is not even necessary)! The implication of using this big time saver is that you must be aware that if you modify ERCF whilst it is off-line you will need to correct the appropriate state prior to printing. Here is an example startup state:

(note this was accomplished by setting startup_status: 1 in ercf_parameters.cfg and can be generated anytime with the ERCF_DISPLAY_TTG_MAP SUMMARY=1 command) This graphic indicates how I left ERCF the day prior... Filaments are loaded in gates 0,1 & 6; Gate/Tool #1 is selected; and the filament is fully loaded. If you are astute you can see I have remapped T2 to be on gate #3 and T3 to be on gate #2 because previously I had loaded these spools backward and this saved me from regenerating g-code.

In addition to basic operational state the print statistics and gate health statistics are persisted and so occasionally you might want to explicitly reset them with ERCF_RESET_STATS. There are 5 levels of operation for this feature that you can set based on your personal preference/habbits. The level is controlled by a single variable persistence_level in ercf_parameters.cfg:

Advanced: ERCF can auto-initialize based on previous persisted state. There are 5 levels with each level bringing in
additional state information requiring progressively less inital setup. The higher level assume that you don't touch
ERCF while it is offline and it can come back to life exactly where it left off.  If you do touch it or get confused
then issue an appropriate reset command (E.g. ERCF_RESET) to get state back to the defaults.
Enabling `startup_status` is recommended if you use persisted state at level 2 and above
Levels: 0 = start fresh every time (the former default behavior)
        1 = restore persisted endless spool groups
        2 = additionally restore persisted tool-to-gate mapping
        3 = additionally restore persisted gate status (filament availability)
        4 = additionally restore persisted tool, gate and filament position!

Generally there is no downside of setting the level to 2 and so that is the suggested default. Really, so long as you are aware that persistence is happening and know how to adjust/reset you can set the level to 4 and enjoy immediate ERCF availability. So what options are there for resetting state? Here is the complete list:

• `ERCF_RESET` - Reset all persisted state back to defaults / unknown except for print stats and per-gate health stats
• `ERCF_RESET_STATS` - Reset print stats and per-gate health stats back to 0
• `ERCF_REMAP_TTG RESET=1` - Reset just the tool-to-gate mapping
• `ERCF_ENDLESS_SPOOL_GROUPS RESET=1` - Reset just the endless spool groups back to default
• `ERCF_SET_GATE_MAP RESET=1` - Reset information about the filament type, color and availability
• `ERCF_RECOVER` - Automatically discover or manually reset filament position, selected gate, selected tool, filament availability (lots of options)
• Needless to say, other operations can also be used to update state

Couple of miscellaneous notes:

• Closely relevant to the usefulness of this functionality is the `ERCF_CHECK_GATES` command that will examine all or selection of gates for presence of filament
• In the graphic depictions of filament state the '*' indicates presence, '?' unknown and ' ' or '.' the lack of filament
• With tool-to-gate mapping it is entirely possible to have multiple tools mapped to the same gate (for example to force a multi-color print to be monotone) and therefore some gates can be made inaccessable until map is reset
• The default value for `gate_status`, `tool_to_gate_map` and `endless_spool_groups` can be set in `ercf_parameters.cfg`. If not set the default will be, Tx maps to Gate#x, the status of each gate is unknown and each tool is in its own endless spool group (i.e. not part of a group)

Happy Hare exposes the following 'printer' variables:

printer.ercf.enabled : {bool}
printer.ercf.is_locked : {bool}
printer.ercf.is_homed : {bool}
printer.ercf.tool : {int} 0..n | -1 for unknown | -2 for bypass
printer.ercf.gate : {int} 0..n | -1 for unknown
printer.ercf.material : {string} Material type for current gate (useful for print_start macro)
printer.ercf.next_tool : {int} 0..n | -1 for unknown | -2 for bypass (during a tool change)
printer.ercf.last_tool : {int} 0..n | -1 for unknown | -2 for bypass (during a tool change after unload)
printer.ercf.last_toolchange : {string} description of last change similar to M117 display
printer.ercf.clog_detection : {int} 0 (off) | 1 (manual) | 2 (auto)
printer.ercf.endless_spool : {int} 0 (disabled) | 1 (enabled)
printer.ercf.filament : {string} Loaded | Unloaded | Unknown
printer.ercf.loaded_status : {int} state machine - exact location of filament
printer.ercf.filament_direction : {int} 1 (load) | -1 (unload)
printer.ercf.servo : {string} Up | Down | Unknown
printer.ercf.ttg_map : {list} defined gate for each tool
printer.ercf.gate_status : {list} per gate: 0 empty | 1 available | -1 unknown
printer.ercf.gate_material : {list} of material names, one per gate
printer.ercf.gate_color : {list} of color names, one per gate
printer.ercf.endless_spool_groups : {list} group membership for each tool
printer.ercf.action : {string} Idle | Loading | Unloading | Forming Tip | Heating | Loading Ext | Exiting Ext | Checking | Homing | Selecting

Even if not a KlipperScreen user you might be interested in my brand new KlipperScreen version. Be sure to follow the install directions carefully and read the panel-by-panel documentation. It will make you even happier!!

This software is largely rewritten as well as being extended and so, despite best efforts, has probably introduced some bugs that may not exist in the official driver. It also lacks extensive testing on different configurations that will stress the corner cases. I have been using successfully on Voron 2.4 / ERCF with EASY-BRD. I use a self-modified CW2 extruder with foolproof microswitch toolhead sensor. My day-to-day configuration is to load the filament to the extruder in a single movement (num_moves=1) at 200mm/s, then home to toolhead sensor with synchronous gear/extruder movement (option #1 explained above). I use the sensorless selector and have runout and EndlessSpool enabled.

Firstly the importance of a reliable and fairly accurate encoder should not be under estimated. If you cannot get very reliable results from ERCF_CALIBRATE_ENCODER then don't proceed with setup - address the encoder problem first. Because the encoder is the HEART of ERCF I created a how-to on fixing many possible problems with encoder.

• If using a toolhead sensor, that must be reliable too. The hall effect based switch is very awkward to get right because of so many variables: strength of magnet, amount of iron in washer, even temperature, therefore I strongly recommend a simple microswitch based detection. They work first time, every time.
• The longer the bowden length the more important it is to calibrate correctly (do a couple of times to check for consistency). Small errors multiply with longer moves!
• Eliminate all points of friction in the filament path. There is lots written about this already but I found some unusual places where filament was rubbing on plastic and drilling out the path improved things a good deal.
• This version of the driver software both, compensates for, and exploits the spring that is inherently built when homing to the extruder. The `ERCF_CALIBRATE_SINGLE TOOL=0` (which calibrates the *ercf_calib_ref* length) averages the measurement of multiple passes, measures the spring rebound and considers the configuration options when recommending and setting the ercf_calib_ref length. If you change basic configuration options it is advisable to rerun this calibration step again.
• The dreaded "Timer too close" can occur but I believe I have worked around most of these cases. The problem is not always an overloaded mcu as often cited -- there are a couple of bugs in Klipper that will delay messages between mcu and host and thus provoke this problem. To minimize you hitting these, I recommend you use a step size of 8 for the gear motor. You don't need high fidelity and this greatly reduces the chance of this error. Also, increasing 'num_moves' also is a workaround. I'm not experiencing this and have a high speed (200 mm/s) single move load with a step size of 8.
• The servo problem where a servo with move to end position and then jump back can occur due to bug in Klipper just like the original software but also because of power supply problems. The workaround for the former is increase the same servo "dwell" config options in small increments until the servo works reliably. Note that this driver will retry the initial servo down movement if it detects slippage thus working around this issue to some extent.
• I also added a 'apply_bowden_correction' config option that dictates whether the driver "believes" the encoder or not for long moves. If enabled, the driver will make correction moves to get the encoder reading correct. If disabled the gear stepper movement will be applied without slippage detection. Details on when this is useful is documented in 'ercf_parameters'. If enabled, the options 'load_bowden_tolerance' and 'unload_bowden_tolerance' will set the threshold at which correction is applied.
• I can recommend the "sensorless selector" option -- it works well once tuned and provides for additional recovery abilities if filament gets stuck in encoder preventing selection of a different gate. However there are some important things to note:
  • The selector cart must home against something solid. You need to make sure there are no wires or zip tie getting in the way.
  • If the motor audibly vibrates but doesn't appear to reliably detect home you selector belt might be too loose.
  • It is likely necessary to change the square head homing screw for a lower profile button head one -- the reason is that you will get inaccurate homing position if you are forceable stopping on the microswitch. You just want to make sure the microswitch is triggered when the selector cart comes to a stop.
  • You can also add a small spacer to the slider mechanism make the selector cart physically stops before fully pressing the microswitch fully. Just be sure that the homing point is before gate #0. (I use a 1mm thick printed washer on the 8mm rods. See my repro for ERCF hacks).
  • Finally it is important to experiement and tune the `driver_SGTHRS` value which is the point at which the TMC driver detects the stepper has stalled. Lower values are less sensitive (selector can ram too hard) and too high a value can mean a bit of friction on the selector is detected as a stall and interpreted as a blocked selector.
• Speeds.... starting in v1.1.7 the speed setting for all the various moves made by ERCF can be tuned. These are all configurable in the 'ercf_parameters.cfg' file or can be tested without restarting Klipper with the 'ERCF_TEST_CONFIG' command. If you want to optimise performance you might want to tuning these faster. If you do, watch for the gear stepper missing steps which will often be reported as slippage.

Good luck and hopefully a little less enraged printing. You can find me on discord as moggieuk#6538

Note that some of these commands have been enhanced from the original

Working reference PAUSE / RESUME / CANCEL_PRINT macros are defined in client_macros.cfg

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( *,*)
(")_(") ERCF Ready