github: Add a stale ticket tracker for github PRs

Signed-off-by: Kevin O'Connor <kevin@koconnor.net>
2025-02-02 18:18:36 -05:00
252 changed files with 2442 additions and 9574 deletions
--- a/.github/workflows/build-test.yaml
+++ b/.github/workflows/build-test.yaml
@@ -4,7 +4,7 @@ on: [push, pull_request]
 jobs:
  build:
-    runs-on: ubuntu-22.04
+    runs-on: ubuntu-20.04
    steps:
    - uses: actions/checkout@v3
--- a/.github/workflows/stale-issue-bot.yaml
+++ b/.github/workflows/stale-issue-bot.yaml
@@ -11,16 +11,14 @@ jobs:
    steps:
    - uses: actions/stale@v8
      with:
-        repo-token: ${{ secrets.GITHUB_TOKEN }}
+        stale-pr-message: |
        stale-issue-message: |
          Hello,
          It looks like there hasn't been any recent updates on this
-          Klipper github issue.  If you created this issue and no
+          github ticket.  We prefer to only list tickets as "open" if
-          longer consider it open, then please login to github and
+          they are actively being worked on.  Feel free to provide an
-          close the issue.  Otherwise, if there is no further activity
+          update on this ticket.  Otherwise the ticket will be
-          on this thread then it will be automatically closed in a few
+          automatically closed in a few days.
          days.
          Best regards,
@@ -29,10 +27,10 @@ jobs:
          PS: I'm just an automated script, not a human being.
        exempt-issue-labels: 'enhancement,bug'
-        days-before-stale: 35
+        days-before-stale: 60
        days-before-close: 7
-        days-before-pr-stale: -1
+        days-before-issue-stale: -1
-        days-before-pr-close: -1
+        days-before-issue-close: -1
  # Close tickets marked with "not on github" label
  close_not_on_github:
    if: github.repository == 'Klipper3d/klipper'
@@ -330,7 +328,7 @@ jobs:
            }
  # Lock closed issues after 6 months of inactivity and PRs after 1 year.
  lock:
-    name: Lock Closed Issues
+    name: Lock Closed Tickets
    if: github.repository == 'Klipper3d/klipper'
    runs-on: ubuntu-latest
    steps:
--- a/config/example-generic-caretesian.cfg
+++ b/config/example-generic-caretesian.cfg
@@ -1,138 +0,0 @@
 # This file is an example config file for cartesian style printers.
 # One may copy and edit this file to configure a new printer with
 # a generic cartesian kinematics.
 # DO NOT COPY THIS FILE WITHOUT CAREFULLY READING AND UPDATING IT
 # FIRST. Incorrectly configured parameters may cause damage.
 # See docs/Config_Reference.md for a description of parameters.
 [carriage x]
 position_endstop: 0
 position_max: 300
 homing_speed: 50
 endstop_pin: ^PE5
 [carriage y]
 position_endstop: 0
 position_max: 200
 homing_speed: 50
 endstop_pin: ^PJ1
 [extra_carriage y1]
 primary_carriage: y
 endstop_pin: ^PB6
 [carriage z]
 position_endstop: 0.5
 position_max: 100
 endstop_pin: ^PD3
 [dual_carriage u]
 primary_carriage: x
 position_endstop: 300
 position_max: 300
 homing_speed: 50
 endstop_pin: ^PE4
 [stepper my_stepper_x]
 carriages: x+y
 step_pin: PF0
 dir_pin: PF1
 enable_pin: !PD7
 microsteps: 16
 rotation_distance: 40
 [stepper my_stepper_u]
 carriages: u-y1
 step_pin: PH1
 dir_pin: PH0
 enable_pin: !PA1
 microsteps: 16
 rotation_distance: 40
 [stepper my_stepper_y0]
 carriages: y
 step_pin: PF6
 dir_pin: !PF7
 enable_pin: !PF2
 microsteps: 16
 rotation_distance: 40
 [stepper my_stepper_y1]
 carriages: y1
 step_pin: PE3
 dir_pin: !PH6
 enable_pin: !PG5
 microsteps: 16
 rotation_distance: 40
 [stepper my_stepper_z0]
 carriages: z
 step_pin: PL3
 dir_pin: PL1
 enable_pin: !PK0
 microsteps: 16
 rotation_distance: 8
 [stepper my_stepper_z1]
 carriages: z
 step_pin: PG1
 dir_pin: PG0
 enable_pin: !PH3
 microsteps: 16
 rotation_distance: 8
 [extruder]
 step_pin: PA4
 dir_pin: PA6
 enable_pin: !PA2
 microsteps: 16
 rotation_distance: 33.5
 nozzle_diameter: 0.400
 filament_diameter: 1.750
 heater_pin: PB4
 sensor_type: EPCOS 100K B57560G104F
 sensor_pin: PK5
 control: pid
 pid_Kp: 22.2
 pid_Ki: 1.08
 pid_Kd: 114
 min_temp: 0
 max_temp: 250
 [extruder1]
 step_pin: PC1
 dir_pin: PC3
 enable_pin: !PC7
 microsteps: 16
 rotation_distance: 33.5
 nozzle_diameter: 0.400
 filament_diameter: 1.750
 heater_pin: PB5
 sensor_type: EPCOS 100K B57560G104F
 sensor_pin: PK7
 control: pid
 pid_Kp: 22.2
 pid_Ki: 1.08
 pid_Kd: 114
 min_temp: 0
 max_temp: 250
 [heater_bed]
 heater_pin: PH5
 sensor_type: EPCOS 100K B57560G104F
 sensor_pin: PK6
 control: watermark
 min_temp: 0
 max_temp: 110
 [mcu]
 serial: /dev/ttyACM0
 [printer]
 kinematics: generic_cartesian
 max_velocity: 500
 max_accel: 3000
 max_z_velocity: 20
 max_z_accel: 100
--- a/config/generic-bigtreetech-manta-m8p-v1.0.cfg
+++ b/config/generic-bigtreetech-manta-m8p-v1.0.cfg
@@ -39,7 +39,7 @@ position_max: 270
 # Motor4
 # The M8P only has 4 heater outputs which leaves an extra stepper
 # This can be used for a second Z stepper, dual_carriage, extruder co-stepper,
-# or other accessory such as an MMU
+# or other accesory such as an MMU
 #[stepper_]
 #step_pin: PD3
 #dir_pin: PD2
--- a/config/generic-bigtreetech-manta-m8p-v1.1.cfg
+++ b/config/generic-bigtreetech-manta-m8p-v1.1.cfg
@@ -40,7 +40,7 @@ position_max: 270
 # Motor4
 # The M8P only has 4 heater outputs which leaves an extra stepper
 # This can be used for a second Z stepper, dual_carriage, extruder co-stepper,
-# or other accessory such as an MMU
+# or other accesory such as an MMU
 #[stepper_]
 #step_pin: PD3
 #dir_pin: PD2
--- a/config/generic-bigtreetech-octopus-max-ez.cfg
+++ b/config/generic-bigtreetech-octopus-max-ez.cfg
@@ -43,7 +43,7 @@ position_max: 200
 # Motor-4
 # The Octopus only has 4 heater outputs which leaves an extra stepper
 # This can be used for a second Z stepper, dual_carriage, extruder co-stepper,
-# or other accessory such as an MMU
+# or other accesory such as an MMU
 #[stepper_]
 #step_pin: PB8
 #dir_pin: PB9
--- a/config/generic-bigtreetech-octopus-v1.1.cfg
+++ b/config/generic-bigtreetech-octopus-v1.1.cfg
@@ -52,7 +52,7 @@ position_max: 200
 # Driver3
 # The Octopus only has 4 heater outputs which leaves an extra stepper
 # This can be used for a second Z stepper, dual_carriage, extruder co-stepper,
-# or other accessory such as an MMU
+# or other accesory such as an MMU
 #[stepper_]
 #step_pin: PG4
 #dir_pin: PC1
--- a/config/generic-bigtreetech-skr-2.cfg
+++ b/config/generic-bigtreetech-skr-2.cfg
@@ -153,48 +153,3 @@ aliases:
 #uart_pin: PD12
 #run_current: 0.600
 #diag_pin:
 ########################################
 # TMC2130 configuration
 ########################################
 #[tmc2130 stepper_x]
 #cs_pin: PE0
 #spi_software_miso_pin: PA14
 #spi_software_mosi_pin: PE14
 #spi_software_sclk_pin: PE15
 #run_current: 0.800
 #diag1_pin: PC1
 #[tmc2130 stepper_y]
 #cs_pin: PD3
 #spi_software_miso_pin: PA14
 #spi_software_mosi_pin: PE14
 #spi_software_sclk_pin: PE15
 #run_current: 0.800
 #diag1_pin: PC3
 #[tmc2130 stepper_z]
 #cs_pin: PD0
 #spi_software_miso_pin: PA14
 #spi_software_mosi_pin: PE14
 #spi_software_sclk_pin: PE15
 #run_current: 0.800
 #diag1_pin: PC0
 #[tmc2130 extruder]
 #cs_pin: PC6
 #spi_software_miso_pin: PA14
 #spi_software_mosi_pin: PE14
 #spi_software_sclk_pin: PE15
 #run_current: 0.600
 #diag1_pin: PC2
 #[tmc2130 extruder1]
 #cs_pin: PD12
 #spi_software_miso_pin: PA14
 #spi_software_mosi_pin: PE14
 #spi_software_sclk_pin: PE15
 #run_current: 0.600
 #stealthchop_threshold: 999999
 #diag1_pin: PA0
--- a/config/generic-bigtreetech-skr-mini-mz.cfg
+++ b/config/generic-bigtreetech-skr-mini-mz.cfg
@@ -122,12 +122,6 @@ max_z_accel: 100
 [static_digital_output usb_pullup_enable]
 pins: !PA14
 #[neopixel my_neopixel]
 #pin: PA8
 [output_pin red_led]
 pin: PA13
 [board_pins]
 aliases:
    # EXP1 header
--- a/config/generic-mightyboard.cfg
+++ b/config/generic-mightyboard.cfg
@@ -89,32 +89,32 @@ max_z_velocity: 5
 max_z_accel: 100
 [mcp4018 x_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PF3
+sda_pin: PF3
 wiper: 0.50
 scale: 0.773
 [mcp4018 y_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PF7
+sda_pin: PF7
 wiper: 0.50
 scale: 0.773
 [mcp4018 z_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PK3
+sda_pin: PK3
 wiper: 0.50
 scale: 0.773
 [mcp4018 a_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PA5
+sda_pin: PA5
 wiper: 0.50
 scale: 0.773
 [mcp4018 b_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PJ6
+sda_pin: PJ6
 wiper: 0.50
 scale: 0.773
--- a/config/kit-voron2-250mm.cfg
+++ b/config/kit-voron2-250mm.cfg
@@ -19,7 +19,7 @@
 # FSR switch (z endstop) location       [homing_override] section
 # FSR switch (z endstop) offset for Z0  [stepper_z] section
 # Probe points                          [quad_gantry_level] section
-# Min & Max gantry corner positions     [quad_gantry_level] section
+# Min & Max gantry corner postions      [quad_gantry_level] section
 # PID tune                              [extruder] and [heater_bed] sections
 # Fine tune E steps                     [extruder] section
--- a/config/kit-zav3d-2019.cfg
+++ b/config/kit-zav3d-2019.cfg
@@ -20,7 +20,7 @@
 # FSR switch (z endstop) location       [homing_override] section
 # FSR switch (z endstop) offset for Z0  [stepper_z] section
 # Probe points                          [quad_gantry_level] section
-# Min & Max gantry corner positions     [quad_gantry_level] section
+# Min & Max gantry corner postions      [quad_gantry_level] section
 # PID tune                              [extruder] and [heater_bed] sections
 # Fine tune E steps                     [extruder] section
--- a/config/printer-anycubic-kossel-2016.cfg
+++ b/config/printer-anycubic-kossel-2016.cfg
@@ -17,7 +17,7 @@ endstop_pin: ^PE4
 homing_speed: 60
 # The next parameter needs to be adjusted for
 # your printer. You may want to start with 280
-# and measure the distance from nozzle to bed.
+# and meassure the distance from nozzle to bed.
 # This value then needs to be added.
 position_endstop: 273.0
 arm_length: 229.4
--- a/config/printer-creality-cr10-v3-2020.cfg
+++ b/config/printer-creality-cr10-v3-2020.cfg
@@ -43,7 +43,7 @@ position_max: 400
 #Uncomment if you have a BL-Touch:
 #position_min: -4
 #endstop_pin: probe:z_virtual_endstop
-#and comment the following lines:
+#and comment the follwing lines:
 position_endstop: 0.0
 endstop_pin: ^PD3 #ar18
--- a/config/printer-creality-cr6se-2020.cfg
+++ b/config/printer-creality-cr6se-2020.cfg
@@ -1,5 +1,4 @@
-# This file contains pin mappings for the stock 2020 Creality CR6-SE
+# This file contains pin mappings for the stock 2020 Creality CR6-SE.
 # with the early 4.5.2 board only.
 # To use this config, during "make menuconfig" select the STM32F103
 # with a "28KiB bootloader" and serial (on USART1 PA10/PA9)
 # communication.
--- a/config/printer-creality-cr6se-2021.cfg
+++ b/config/printer-creality-cr6se-2021.cfg
@@ -1,6 +1,4 @@
-# This file contains pin mappings for the Creality CR6-SE
+# This file contains pin mappings for the Creality CR6-SE with Rev. 4.5.3 Motherboard (Late 2020/2021) as the heater pins changed.
 # with Rev. 4.5.3 Motherboard (Late 2020/2021) as the heater pins changed.
 # This config also works for the CR-ERA_V1.1.0.3
 # To use this config, during "make menuconfig" select the STM32F103
 # with a "28KiB bootloader" and serial (on USART1 PA10/PA9)
 # communication.
--- a/config/printer-creality-ender5-s1-2023.cfg
+++ b/config/printer-creality-ender5-s1-2023.cfg
@@ -81,7 +81,7 @@ pin: PA0
 kick_start_time: 0.5
 # Hotend fan
-# set fan running when extruder temperature is over 60
+# set fan runnig when extruder temperature is over 60
 [heater_fan heatbreak_fan]
 pin: PC0
 heater:extruder
--- a/config/printer-flashforge-creator-pro-2018.cfg
+++ b/config/printer-flashforge-creator-pro-2018.cfg
@@ -127,32 +127,32 @@ max_z_velocity: 5
 max_z_accel: 100
 [mcp4018 x_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PF3
+sda_pin: PF3
 wiper: 118
 scale: 127
 [mcp4018 y_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PF7
+sda_pin: PF7
 wiper: 118
 scale: 127
 [mcp4018 z_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PK3
+sda_pin: PK3
 wiper: 40
 scale: 127
 [mcp4018 a_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PA5
+sda_pin: PA5
 wiper: 118
 scale: 127
 [mcp4018 b_axis_pot]
-i2c_software_scl_pin: PJ5
+scl_pin: PJ5
-i2c_software_sda_pin: PJ6
+sda_pin: PJ6
 wiper: 118
 scale: 127
--- a/config/printer-lulzbot-mini1-2016.cfg
+++ b/config/printer-lulzbot-mini1-2016.cfg
@@ -195,7 +195,7 @@ samples_tolerance: 0.200
 samples_tolerance_retries: 2
 [bed_tilt]
-# Enable bed tilt measurements using the probe we defined above
+# Enable bed tilt measurments using the probe we defined above
 # Probe points using X0 Y0 offsets @ 0.01mm/step
 points: -2, -6
        156, -6
--- a/config/printer-lulzbot-taz6-dual-v3-2017.cfg
+++ b/config/printer-lulzbot-taz6-dual-v3-2017.cfg
@@ -183,7 +183,7 @@ samples: 2
 samples_tolerance: 0.100
 [bed_tilt]
-#Enable bed tilt measurements using the probe we defined above
+#Enable bed tilt measurments using the probe we defined above
 #Probe points using X0 Y0 offsets @ 0.01mm/step
 points: -3, -6
        282, -6
--- a/config/printer-robo3d-r2-2017.cfg
+++ b/config/printer-robo3d-r2-2017.cfg
@@ -37,7 +37,7 @@ microsteps: 16
 rotation_distance: 4
 # Required if not using probe for the virtual endstop
 # endstop_pin: ^PD3
-# position_endstop: 250 # Will need adjustment
+# position_endstop: 250 # Will need ajustment
 endstop_pin: probe:z_virtual_endstop
 homing_speed: 10.0
 position_max: 250
--- a/config/printer-seemecnc-rostock-max-v2-2015.cfg
+++ b/config/printer-seemecnc-rostock-max-v2-2015.cfg
@@ -1,4 +1,4 @@
-# This file contains the pin mappings for the SeeMeCNC Rostock Max
+# This file constains the pin mappings for the SeeMeCNC Rostock Max
 # (version 2) delta printer from 2015. To use this config, the
 # firmware should be compiled for the AVR atmega2560.
--- a/config/sample-corexyuv.cfg
+++ b/config/sample-corexyuv.cfg
@@ -1,177 +0,0 @@
 # This file contains a configuration snippet for a CoreXYUV
 # printer with an independent dual extruder moving over X and Y axes.
 # See docs/Config_Reference.md for a description of parameters.
 [carriage x]
 position_endstop: 0
 position_max: 300
 homing_speed: 50
 endstop_pin: ^PE5
 [carriage y]
 position_endstop: 0
 position_max: 200
 homing_speed: 50
 endstop_pin: ^PJ1
 [dual_carriage u]
 primary_carriage: x
 safe_distance: 70
 position_endstop: 300
 position_max: 300
 homing_speed: 50
 endstop_pin: ^PE4
 [dual_carriage v]
 primary_carriage: y
 safe_distance: 50
 position_endstop: 200
 position_max: 200
 homing_speed: 50
 endstop_pin: ^PD4
 [stepper a]
 carriages: x+y
 step_pin: PF0
 dir_pin: PF1
 enable_pin: !PD7
 microsteps: 16
 rotation_distance: 40
 [stepper b]
 carriages: u-v
 step_pin: PH1
 dir_pin: PH0
 enable_pin: !PA1
 microsteps: 16
 rotation_distance: 40
 [stepper c]
 carriages: x-y
 step_pin: PF6
 dir_pin: !PF7
 enable_pin: !PF2
 microsteps: 16
 rotation_distance: 40
 [stepper d]
 carriages: u+v
 step_pin: PE3
 dir_pin: !PH6
 enable_pin: !PG5
 microsteps: 16
 rotation_distance: 40
 [extruder]
 step_pin: PA4
 dir_pin: PA6
 enable_pin: !PA2
 microsteps: 16
 rotation_distance: 33.5
 nozzle_diameter: 0.400
 filament_diameter: 1.750
 heater_pin: PB4
 sensor_type: EPCOS 100K B57560G104F
 sensor_pin: PK5
 control: pid
 pid_Kp: 22.2
 pid_Ki: 1.08
 pid_Kd: 114
 min_temp: 0
 max_temp: 250
 [gcode_macro PARK_extruder]
 gcode:
    SET_DUAL_CARRIAGE CARRIAGE=x
    SET_DUAL_CARRIAGE CARRIAGE=y
    G90
    G1 X0 Y0
 [gcode_macro T0]
 gcode:
    PARK_{printer.toolhead.extruder}
    ACTIVATE_EXTRUDER EXTRUDER=extruder
    SET_DUAL_CARRIAGE CARRIAGE=x
    SET_DUAL_CARRIAGE CARRIAGE=y
 [extruder1]
 step_pin: PC1
 dir_pin: PC3
 enable_pin: !PC7
 microsteps: 16
 rotation_distance: 33.5
 nozzle_diameter: 0.400
 filament_diameter: 1.750
 heater_pin: PB5
 sensor_type: EPCOS 100K B57560G104F
 sensor_pin: PK7
 control: pid
 pid_Kp: 22.2
 pid_Ki: 1.08
 pid_Kd: 114
 min_temp: 0
 max_temp: 250
 [gcode_macro PARK_extruder1]
 gcode:
    SET_DUAL_CARRIAGE CARRIAGE=u
    SET_DUAL_CARRIAGE CARRIAGE=v
    G90
    G1 X300 Y200
 [gcode_macro T1]
 gcode:
    PARK_{printer.toolhead.extruder}
    ACTIVATE_EXTRUDER EXTRUDER=extruder1
    SET_DUAL_CARRIAGE CARRIAGE=u
    SET_DUAL_CARRIAGE CARRIAGE=v
 # A helper script to activate copy mode
 [gcode_macro ACTIVATE_COPY_MODE]
 gcode:
    SET_DUAL_CARRIAGE CARRIAGE=x MODE=PRIMARY
    SET_DUAL_CARRIAGE CARRIAGE=y MODE=PRIMARY
    G1 X0 Y0
    ACTIVATE_EXTRUDER EXTRUDER=extruder
    SET_DUAL_CARRIAGE CARRIAGE=u MODE=PRIMARY
    SET_DUAL_CARRIAGE CARRIAGE=v MODE=PRIMARY
    G1 X150 Y100
    SET_DUAL_CARRIAGE CARRIAGE=u MODE=COPY
    SET_DUAL_CARRIAGE CARRIAGE=v MODE=COPY
    SYNC_EXTRUDER_MOTION EXTRUDER=extruder1 MOTION_QUEUE=extruder
 # A helper script to activate mirror mode
 [gcode_macro ACTIVATE_MIRROR_MODE]
 gcode:
    SET_DUAL_CARRIAGE CARRIAGE=x MODE=PRIMARY
    SET_DUAL_CARRIAGE CARRIAGE=y MODE=PRIMARY
    G1 X0 Y0
    ACTIVATE_EXTRUDER EXTRUDER=extruder
    SET_DUAL_CARRIAGE CARRIAGE=u MODE=PRIMARY
    SET_DUAL_CARRIAGE CARRIAGE=v MODE=PRIMARY
    G1 X300 Y100
    SET_DUAL_CARRIAGE CARRIAGE=u MODE=MIRROR
    SET_DUAL_CARRIAGE CARRIAGE=v MODE=COPY
    SYNC_EXTRUDER_MOTION EXTRUDER=extruder1 MOTION_QUEUE=extruder
 [printer]
 kinematics: generic_cartesian
 max_velocity: 300
 max_accel: 3000
 max_z_velocity: 5
 max_z_accel: 100
 ## An optional input shaper support
 #[input_shaper]
 ## The section is intentionally empty
 #
 #[delayed_gcode init_shaper]
 #initial_duration: 0.1
 #gcode:
 #    SET_DUAL_CARRIAGE CARRIAGE=u
 #    SET_DUAL_CARRIAGE CARRIAGE=v
 #    SET_INPUT_SHAPER SHAPER_TYPE_X=<dual_carriage_x_shaper> SHAPER_FREQ_X=<dual_carriage_x_freq> SHAPER_TYPE_Y=<dual_carriage_y_shaper> SHAPER_FREQ_Y=<dual_carriage_y_freq>
 #    SET_DUAL_CARRIAGE CARRIAGE=x MODE=PRIMARY
 #    SET_DUAL_CARRIAGE CARRIAGE=y MODE=PRIMARY
 #    SET_INPUT_SHAPER SHAPER_TYPE_X=<primary_carriage_x_shaper> SHAPER_FREQ_X=<primary_carriage_x_freq> SHAPER_TYPE_Y=<primary_carriage_y_shaper> SHAPER_FREQ_Y=<primary_carriage_y_freq>
--- a/config/sample-duet3-1lc.cfg
+++ b/config/sample-duet3-1lc.cfg
@@ -6,7 +6,7 @@
 # Communication interface of "CAN bus (on PA25/PA24)"
 # To flash the board use a debugger, or use a raspberry pi and follow
-# the instructions at docs/Bootloaders.md for the SAMC21. You may
+# the instructions at docs/Bootloaders.md fot the SAMC21. You may
 # supply power to the 1LC by connecting the 3.3v rail on the Pi to the
 # 5v input of the SWD header on the 1LC.
--- a/config/sample-mmu2s-diy.cfg
+++ b/config/sample-mmu2s-diy.cfg
@@ -96,7 +96,7 @@ switch_pin: !P1.28 # P1.28 for X-max
 # variable_pause_z               : z lift when MMU2S need intervention and the printer is paused
 # variable_min_temp_extruder     : minimal required heater temperature to load/unload filament from the extruder gear to the nozzle
 # variable_extruder_eject_temp   : heater temperature used to eject filament during home if the filament is already loaded
-# variable_enable_5in1           : pass from MMU2S standard (0) to MMU2S-5in1 mode with splitter
+# variable_enable_5in1           : pass from MMU2S standart (0) to MMU2S-5in1 mode with splitter
 #
 ################################
 [gcode_macro VAR_MMU2S]
@@ -394,7 +394,7 @@ gcode:
    {% endif %}
    {% endif %}
-# Retry unload, try correct misalignment of bondtech gear
+# Retry unload, try correct misalignement of bondtech gear
 [gcode_macro RETRY_UNLOAD_FILAMENT_IN_EXTRUDER]
 gcode:
    {% if printer["filament_switch_sensor ir_sensor"].filament_detected == True %}
@@ -444,7 +444,7 @@ gcode:
    {% endif %}
    {% endif %}
-# Ramming process for standard PLA, code extracted from slic3r gcode
+# Ramming process for standart PLA, code extracted from slic3r gcode
 [gcode_macro RAMMING_SLICER]
 gcode:
    G91
--- a/docs/API_Server.md
+++ b/docs/API_Server.md
@@ -364,42 +364,37 @@ and might later produce asynchronous messages such as:
 The "header" field in the initial query response is used to describe
 the fields found in later "data" responses.
-### load_cell/dump_force
+### hx71x/dump_hx71x
-This endpoint is used to subscribe to force data produced by a load_cell.
+This endpoint is used to subscribe to raw HX711 and HX717 ADC data.
-Using this endpoint may increase Klipper's system load.
+Obtaining these low-level ADC updates may be useful for diagnostic
 and debugging purposes. Using this endpoint may increase Klipper's
 system load.
 A request may look like:
-`{"id": 123, "method":"load_cell/dump_force",
+`{"id": 123, "method":"hx71x/dump_hx71x",
 "params": {"sensor": "load_cell", "response_template": {}}}`
 and might return:
-`{"id": 123,"result":{"header":["time", "force (g)", "counts", "tare_counts"]}}`
+`{"id": 123,"result":{"header":["time","counts","value"]}}`
 and might later produce asynchronous messages such as:
-`{"params":{"data":[[3292.432935, 40.65, 562534, -234467]]}}`
+`{"params":{"data":[[3292.432935, 562534, 0.067059278],
 [3292.4394937, 5625322, 0.670590639]]}}`
-The "header" field in the initial query response is used to describe
+### ads1220/dump_ads1220
 the fields found in later "data" responses.
-### load_cell_probe/dump_taps
+This endpoint is used to subscribe to raw ADS1220 ADC data.
-
+Obtaining these low-level ADC updates may be useful for diagnostic
-This endpoint is used to subscribe to details of probing "tap" events.
+and debugging purposes. Using this endpoint may increase Klipper's
-Using this endpoint may increase Klipper's system load.
+system load.
 A request may look like:
-`{"id": 123, "method":"load_cell/dump_force",
+`{"id": 123, "method":"ads1220/dump_ads1220",
 "params": {"sensor": "load_cell", "response_template": {}}}`
 and might return:
-`{"id": 123,"result":{"header":["probe_tap_event"]}}`
+`{"id": 123,"result":{"header":["time","counts","value"]}}`
 and might later produce asynchronous messages such as:
-```
+`{"params":{"data":[[3292.432935, 562534, 0.067059278],
-{"params":{"tap":'{
+[3292.4394937, 5625322, 0.670590639]]}}`
   "time": [118032.28039, 118032.2834, ...],
   "force": [-459.4213119680034, -458.1640702543264, ...],
 }}}
 ```
 This data can be used to render:
 * The time/force graph
 ### pause_resume/cancel
--- a/docs/Axis_Twist_Compensation.md
+++ b/docs/Axis_Twist_Compensation.md
@@ -1,6 +1,6 @@
 # Axis Twist Compensation
-This document describes the `[axis_twist_compensation]` module.
+This document describes the [axis_twist_compensation] module.
 Some printers may have a small twist in their X rail which can skew the results
 of a probe attached to the X carriage.
@@ -25,7 +25,7 @@ try to probe the bed without attaching the probe if you use it.
 > correctly set as they greatly influence calibration.
 ### Basic Usage: X-Axis Calibration
-1. After setting up the `[axis_twist_compensation]` module, run:
+1. After setting up the ```[axis_twist_compensation]``` module, run:
 ```
 AXIS_TWIST_COMPENSATION_CALIBRATE
 ```
@@ -39,8 +39,8 @@ SAMPLE_COUNT=<value>
 ``
 2. **Adjust Your Z Offset:**
-After completing the calibration, be sure to
+After completing the calibration, be sure to [adjust your Z offset]
-[adjust your Z offset](Probe_Calibrate.md#calibrating-probe-z-offset).
+(Probe_Calibrate.md#calibrating-probe-z-offset).
 3. **Perform Bed Leveling Operations:**
 Use probe-based operations as needed, such as:
@@ -61,13 +61,22 @@ AXIS_TWIST_COMPENSATION_CALIBRATE AXIS=Y
 ```
 This will guide you through the same measuring process as for the X-axis.
 ### Automatic Calibration for Both Axes
 To perform automatic calibration for both the X and Y axes without manual
 intervention, use:
 ```
 AXIS_TWIST_COMPENSATION_CALIBRATE AUTO=True
 ```
 In this mode, the calibration process will run for both axes automatically.
 > **Tip:** Bed temperature and nozzle temperature and size do not seem to have
 > an influence to the calibration process.
 ## [axis_twist_compensation] setup and commands
-Configuration options for `[axis_twist_compensation]` can be found in the
+Configuration options for [axis_twist_compensation] can be found in the
 [Configuration Reference](Config_Reference.md#axis_twist_compensation).
-Commands for `[axis_twist_compensation]` can be found in the
+Commands for [axis_twist_compensation] can be found in the
 [G-Codes Reference](G-Codes.md#axis_twist_compensation)
--- a/docs/Bed_Mesh.md
+++ b/docs/Bed_Mesh.md
@@ -267,7 +267,7 @@ by heat or interference.  This can make calculating the probe's z-offset
 challenging, particularly at different bed temperatures.  As such, some
 printers use an endstop for homing the Z axis and a probe for calibrating the
 mesh. In this configuration it is possible offset the mesh so that the (X, Y)
-`reference position` applies zero adjustment.  The `reference position` should
+`reference position` applies zero adjustment.  The `reference postion` should
 be the location on the bed where a
 [Z_ENDSTOP_CALIBRATE](./Manual_Level.md#calibrating-a-z-endstop)
 paper test is performed.  The bed_mesh module provides the
@@ -292,6 +292,33 @@ probe_count: 5, 3
  z-offset.  Note that this coordinate must NOT be in a location specified as
  a `faulty_region` if a probe is necessary.
 #### The deprecated relative_reference_index
 Existing configurations using the `relative_reference_index` option must be
 updated to use the `zero_reference_position`.  The response to the
 [BED_MESH_OUTPUT PGP=1](#output) gcode command will include the (X, Y)
 coordinate associated with the index;  this position may be used as the value for
 the `zero_reference_position`. The output will look similar to the following:
 ```
 // bed_mesh: generated points
 // Index | Tool Adjusted | Probe
 // 0 | (1.0, 1.0) | (24.0, 6.0)
 // 1 | (36.7, 1.0) | (59.7, 6.0)
 // 2 | (72.3, 1.0) | (95.3, 6.0)
 // 3 | (108.0, 1.0) | (131.0, 6.0)
 ... (additional generated points)
 // bed_mesh: relative_reference_index 24 is (131.5, 108.0)
 ```
 _Note:  The above output is also printed in `klippy.log` during initialization._
 Using the example above we see that the `relative_reference_index` is
 printed along with its coordinate.  Thus the `zero_reference_position`
 is `131.5, 108`.
 ### Faulty Regions
 It is possible for some areas of a bed to report inaccurate results when
@@ -470,8 +497,7 @@ _Default Adaptive Margin: 0_
 Initiates the probing procedure for Bed Mesh Calibration.
-The mesh will be immediately ready to use when the command completes and saved
+The mesh will be saved into a profile specified by the `PROFILE` parameter,
 into a profile specified by the `PROFILE` parameter,
 or `default` if unspecified. The `METHOD` parameter takes one of the following
 values:
@@ -535,10 +561,6 @@ load the `default` profile it is recommended to add
 `BED_MESH_PROFILE LOAD=default` to either their `START_PRINT` macro or their
 slicer's "Start G-Code" configuration, whichever is applicable.
 Note that this is not required if a new mesh is generated with
 `BED_MESH_CALIBRATE` in the `START_PRINT` macro or the slicer's "Start G-Code"
 and may produce unexpected results, especially with adaptive meshing.
 Alternatively the old behavior of loading a profile at startup can be
 restored with a `[delayed_gcode]`:
--- a/docs/Benchmarks.md
+++ b/docs/Benchmarks.md
@@ -250,22 +250,23 @@ results were obtained by running an STM32F407 binary on an STM32F446
 ### STM32H7 step rate benchmark
-The following configuration sequence is used on STM32H723:
+The following configuration sequence is used on a STM32H743VIT6:
 ```
 allocate_oids count=3
-config_stepper oid=0 step_pin=PA13 dir_pin=PB5 invert_step=-1 step_pulse_ticks=52
+config_stepper oid=0 step_pin=PD4 dir_pin=PD3 invert_step=-1 step_pulse_ticks=0
-config_stepper oid=1 step_pin=PB2 dir_pin=PB6 invert_step=-1 step_pulse_ticks=52
+config_stepper oid=1 step_pin=PA15 dir_pin=PA8 invert_step=-1 step_pulse_ticks=0
-config_stepper oid=2 step_pin=PB3 dir_pin=PB7 invert_step=-1 step_pulse_ticks=52
+config_stepper oid=2 step_pin=PE2 dir_pin=PE3 invert_step=-1 step_pulse_ticks=0
 finalize_config crc=0
 ```
-The test was last run on commit `554ae78d` with gcc version
+The test was last run on commit `00191b5c` with gcc version
-`arm-none-eabi-gcc (Fedora 14.1.0-1.fc40) 14.1.0`.
+`arm-none-eabi-gcc (15:8-2019-q3-1+b1) 8.3.1 20190703 (release)
 [gcc-8-branch revision 273027]`.
-| stm32h723            | ticks |
+| stm32h7              | ticks |
 | -------------------- | ----- |
-| 1 stepper            | 70    |
+| 1 stepper            | 44    |
-| 3 stepper            | 181   |
+| 3 stepper            | 198   |
 ### STM32G0B1 step rate benchmark
@@ -286,25 +287,6 @@ The test was last run on commit `247cd753` with gcc version
 | 1 stepper        | 58    |
 | 3 stepper        | 243   |
 ### STM32G4 step rate benchmark
 The following configuration sequence is used on the STM32G431:
 ```
 allocate_oids count=3
 config_stepper oid=0 step_pin=PA0 dir_pin=PB5 invert_step=-1 step_pulse_ticks=17
 config_stepper oid=1 step_pin=PB2 dir_pin=PB6 invert_step=-1 step_pulse_ticks=17
 config_stepper oid=2 step_pin=PB3 dir_pin=PB7 invert_step=-1 step_pulse_ticks=17
 finalize_config crc=0
 ```
 The test was last run on commit `cfa48fe3` with gcc version
 `arm-none-eabi-gcc (Fedora 14.1.0-1.fc40) 14.1.0`.
 | stm32g431        | ticks |
 | ---------------- | ----- |
 | 1 stepper        | 47    |
 | 3 stepper        | 208   |
 ### LPC176x step rate benchmark
 The following configuration sequence is used on the LPC176x:
@@ -425,14 +407,14 @@ config_stepper oid=2 step_pin=gpio27 dir_pin=gpio5 invert_step=-1 step_pulse_tic
 finalize_config crc=0
 ```
-The test was last run on commit `14c105b8` with gcc version
+The test was last run on commit `f6718291` with gcc version
 `arm-none-eabi-gcc (Fedora 14.1.0-1.fc40) 14.1.0` on Raspberry Pi
 Pico and Pico 2 boards.
 | rp2040 (*)           | ticks |
 | -------------------- | ----- |
-| 1 stepper            | 3     |
+| 1 stepper            | 5     |
-| 3 stepper            | 14    |
+| 3 stepper            | 22    |
 | rp2350               | ticks |
 | -------------------- | ----- |
@@ -440,9 +422,9 @@ Pico and Pico 2 boards.
 | 3 stepper            | 169   |
 (*) Note that the reported rp2040 ticks are relative to a 12Mhz
-scheduling timer and do not correspond to its 200Mhz internal ARM
+scheduling timer and do not correspond to its 125Mhz internal ARM
-processing rate. It is expected that 3 scheduling ticks corresponds to
+processing rate. It is expected that 5 scheduling ticks corresponds to
-~42 ARM core cycles and 14 scheduling ticks corresponds to ~225 ARM
+~47 ARM core cycles and 22 scheduling ticks corresponds to ~224 ARM
 core cycles.
 ### Linux MCU step rate benchmark
@@ -482,23 +464,18 @@ When the test completes, determine the difference between the clocks
 reported in the two "uptime" response messages. The total number of
 commands per second is then `100000 * mcu_frequency / clock_diff`.
-The USB tests may exceed the CPU capacity of a Raspberry Pi. If
+Note that this test may saturate the USB/CPU capacity of a Raspberry
-running on a Raspberry Pi, Beaglebone, or similar host computer then
+Pi. If running on a Raspberry Pi, Beaglebone, or similar host computer
-increase the delay (eg, `DELAY {clock + 20*freq} get_uptime`). Where
+then increase the delay (eg, `DELAY {clock + 20*freq} get_uptime`).
-applicable, the benchmarks below are with console.py running on a
+Where applicable, the benchmarks below are with console.py running on
-desktop class machine with the device connected via a super-speed hub.
+a desktop class machine with the device connected via a high-speed
-
+hub.
 The CAN bus tests may saturate the USB host controller of a Raspberry
 Pi (when testing via a standard gs_usb USB to CAN bus adapter). Where
 applicable, the CAN bus benchmarks below are with console.py running
 on a desktop class machine with a USB to CAN bus adapter connected via
 a super-speed USB hub.
 | MCU                 | Rate | Build    | Build compiler      |
 | ------------------- | ---- | -------- | ------------------- |
 | stm32f042 (CAN)     |  18K | c105adc8 | arm-none-eabi-gcc (GNU Tools 7-2018-q3-update) 7.3.1 |
 | atmega2560 (serial) |  23K | b161a69e | avr-gcc (GCC) 4.8.1 |
 | sam3x8e (serial)    |  23K | b161a69e | arm-none-eabi-gcc (Fedora 7.1.0-5.fc27) 7.1.0 |
 | rp2350 (CAN)        |  59K | 17b8ce4c | arm-none-eabi-gcc (Fedora 14.1.0-1.fc40) 14.1.0 |
 | at90usb1286 (USB)   |  75K | 01d2183f | avr-gcc (GCC) 5.4.0 |
 | ar100 (serial)      | 138K | 08d037c6 | or1k-linux-musl-gcc 9.3.0 |
 | samd21 (USB)        | 223K | 01d2183f | arm-none-eabi-gcc (Fedora 7.4.0-1.fc30) 7.4.0 |
--- a/docs/Bootloaders.md
+++ b/docs/Bootloaders.md
@@ -194,7 +194,7 @@ Alternatively, one can use a
 When using OpenOCD with the SAMC21, extra steps must be taken to first
 put the chip into Cold Plugging mode if the board makes use of the
-SWD pins for other purposes. If using OpenOCD on a Raspberry Pi, this
+SWD pins for other purposes. If using OpenOCD on a Rasberry Pi, this
 can be done by running the following commands before invoking OpenOCD.
 ```
 SWCLK=25
--- a/docs/CANBUS.md
+++ b/docs/CANBUS.md
@@ -125,14 +125,10 @@ iface can0 can static
  frequency. As a result, it is recommended to use a CAN bus frequency
  of 1000000 when using "USB to CAN bus bridge mode".
-* It is only valid to use USB to CAN bridge mode if there is a
+  Even at a CAN bus frequency of 1000000, there may not be sufficient
-  functioning CAN bus with at least one other node available (in
+  bandwidth to run a `SHAPER_CALIBRATE` test if both the XY steppers
-  addition to the bridge node itself). Use a standard USB
+  and the accelerometer all communicate via a single "USB to CAN bus"
-  configuration if the goal is to communicate only with the single USB
+  interface.
  device. Using USB to CAN bridge mode without a fully functioning CAN
  bus (including terminating resistors and an additional node) may
  result in sporadic errors even when communicating with the bridge
  node.
 * A USB to CAN bridge board will not appear as a USB serial device, it
  will not show up when running `ls /dev/serial/by-id`, and it can not
--- a/docs/CANBUS_Troubleshooting.md
+++ b/docs/CANBUS_Troubleshooting.md
@@ -37,36 +37,20 @@ hours or more frequently) then it is an indication of a severe
 problem.
 Incrementing `bytes_invalid` on a CAN bus connection is a symptom of
-reordered messages on the CAN bus. If seen, make sure to:
+reordered messages on the CAN bus. There are two known causes of
-* Use a Linux kernel version 6.6.0 or later.
+reordered messages:
-* If using a USB-to-CANBUS adapter running candlelight firmware, use
+1. Old versions of the popular candlight_firmware for USB CAN adapters
-  v2.0 or later of candleLight_fw.
+   had a bug that could cause reordered messages. If using a USB CAN
-* If using Klipper's USB-to-CANBUS bridge mode, make sure the bridge
+   adapter running this firmware then make sure to update to the
-  node is flashed with Klipper v0.12.0 or later.
+   latest firmware if incrementing `bytes_invalid` is observed.
 2. Some Linux kernel builds for embedded devices have been known to
   reorder CAN bus messages. It may be necessary to use an alternative
   Linux kernel or to use alternative hardware that supports
   mainstream Linux kernels that do not exhibit this problem.
 Reordered messages is a severe problem that must be fixed. It will
 result in unstable behavior and can lead to confusing errors at any
-part of a print. An incrementing `bytes_invalid` is not caused by
+part of a print.
 wiring or similar hardware issues and can only be fixed by identifying
 and updating the faulty software.
 Older versions of the Linux kernel had a bug in the gs_usb canbus
 driver code that could cause reordered canbus packets.  The issue is
 thought to be fixed in
 [Linux commit 24bc41b4](https://github.com/torvalds/linux/commit/24bc41b4558347672a3db61009c339b1f5692169)
 which was released in v6.6.0. In some cases, older Linux versions may
 not show the problem (due to how hardware interrupts are configured),
 however if problems are seen the recommended solution is to upgrade to
 a newer kernel.
 Older versions of candlelight firmware could reorder canbus packets,
 and the issue is thought to be fixed in
 [candlelight_fw commit 8b3a7b45](https://github.com/candle-usb/candleLight_fw/commit/8b3a7b4565a3c9521b762b154c94c72c5acb2bcf).
 Older versions of Klipper's USB-to-CANBUS bridge code could
 incorrectly drop canbus messages. This is not as severe as reordering
 messages, but it should still be fixed. It is thought to be fixed with
 [Klipper PR #6175](https://github.com/Klipper3d/klipper/pull/6175).
 ## Use an appropriate txqueuelen setting
@@ -118,23 +102,6 @@ necessary to increase the `txqueuelen` above the recommended value
 of 128. However, as above, care should be taken when selecting a new
 value to avoid excessive round-trip-time latency.
 ## Use `canbus_query.py` only to identify nodes never previously seen
 It is only valid to use the
 [`canbus_query.py` tool](CANBUS.md#finding-the-canbus_uuid-for-new-micro-controllers)
 to identify micro-controllers that have never been previously
 identified. Once all nodes on a bus are identified, record the
 resulting uuids in the printer.cfg, and avoid running the tool
 unnecessarily.
 The tool is implemented using a low-level mechanism that can cause
 nodes to internally observe bus errors. These internal errors may
 result in communication interruptions and may result is some nodes
 disconnecting from the bus.
 It is not valid to use the tool to "ping" if a node is connected. Do
 not run the tool during an active print.
 ## Obtaining candump logs
 The CAN bus messages sent to and from the micro-controller are handled
--- a/docs/CONTRIBUTING.md
+++ b/docs/CONTRIBUTING.md
@@ -323,7 +323,7 @@ a month without updates.
 Once the requirements are met, you need to:
-1. update klipper-translations repository
+1. update klipper-tranlations repository
 [active_translations](https://github.com/Klipper3d/klipper-translations/blob/translations/active_translations)
 2. Optional: add a manual-index.md file in klipper-translations repository's
 `docs\locals\<lang>` folder to replace the language specific index.md (generated
--- a/docs/Code_Overview.md
+++ b/docs/Code_Overview.md
@@ -286,11 +286,6 @@ The following may also be useful:
  during the `load_config()` or "connect event" phases. Use either
  `raise config.error("my error")` or `raise printer.config_error("my
  error")` to report the error.
 * Do not store a reference to the `config` object in a class member
  variable (nor in any similar location that may persist past initial
  module loading). The `config` object is a reference to a "config
  loading phase" class and it is not valid to invoke its methods after
  the "config loading phase" has completed.
 * Use the "pins" module to configure a pin on a micro-controller. This
  is typically done with something similar to
  `printer.lookup_object("pins").setup_pin("pwm",
--- a/docs/Config_Changes.md
+++ b/docs/Config_Changes.md
@@ -8,41 +8,6 @@ All dates in this document are approximate.
 ## Changes
 20250811: Support for the `max_accel_to_decel` parameter in the
 `[printer]` config section has been removed and support for the
 `ACCEL_TO_DECEL` parameter in the `SET_VELOCITY_LIMIT` command has
 been removed. These capabilities were deprecated on 20240313.
 20250721: The `[pca9632]` and `[mcp4018]` modules no longer accept the
 `scl_pin` and `sda_pin` options. Use `i2c_software_scl_pin` and
 `i2c_software_sda_pin` instead.
 20250428: The maximum `cycle_time` for pwm `[output_pin]`,
 `[pwm_cycle_time]`, `[pwm_tool]`, and similar config sections is now 3
 seconds (reduced from 5 seconds). The `maximum_mcu_duration` in
 `[pwm_tool]` is now also 3 seconds.
 20250418: The manual_stepper `STOP_ON_ENDSTOP` feature may now take
 less time to complete. Previously, the command would wait the entire
 time the move could possibly take even if the endstop triggered
 earlier. Now, the command finishes shortly after the endstop trigger.
 20250417: SPI devices using "software SPI" are now rate limited.
 Previously, the `spi_speed` in the config was ignored and the
 transmission speed was only limited by the processing speed of the
 micro-controller. Now, speeds are limited by the `spi_speed` config
 parameter (actual hardware speeds are likely to be lower than the
 configured value due to software overhead).
 20250411: Klipper v0.13.0 released.
 20250308: The `AUTO` parameter of the
 `AXIS_TWIST_COMPENSATION_CALIBRATE` command has been removed.
 20250131: Option `VARIABLE=<name>` in `SAVE_VARIABLE` requires lowercase
 value. For example, `extruder` instead of mixedcase `Extruder` or
 uppercase `EXTRUDER`. Using any uppercase letter will raise an error.
 20241203: The resonance test has been changed to include slow sweeping
 moves. This change requires that testing point(s) have some clearance
 in X/Y plane (+/- 30 mm from the test point should suffice when using
@@ -67,7 +32,7 @@ object were issued faster than the minimum scheduling time (typically
 100ms) then actual updates could be queued far into the future. Now if
 many updates are issued in rapid succession then it is possible that
 only the latest request will be applied. If the previous behavior is
-required then consider adding explicit `G4` delay commands between
+requried then consider adding explicit `G4` delay commands between
 updates.
 20240912: Support for `maximum_mcu_duration` and `static_value`
@@ -140,7 +105,7 @@ carriage are exported as `printer.dual_carriage.carriage_0` and
 `printer.dual_carriage.carriage_1`.
 20230619: The `relative_reference_index` option has been deprecated
-and superseded by the `zero_reference_position` option.  Refer to the
+and superceded by the `zero_reference_position` option.  Refer to the
 [Bed Mesh Documentation](./Bed_Mesh.md#the-deprecated-relative_reference_index)
 for details on how to update the configuration.  With this deprecation
 the `RELATIVE_REFERENCE_INDEX` is no longer available as a parameter
@@ -374,7 +339,7 @@ endstop phases by running the ENDSTOP_PHASE_CALIBRATE command.
 `gear_ratio` for their rotary steppers, and they may no longer specify
 a `step_distance` parameter.  See the
 [config reference](Config_Reference.md#stepper) for the format of the
-new gear_ratio parameter.
+new gear_ratio paramter.
 20201213: It is not valid to specify a Z "position_endstop" when using
 "probe:z_virtual_endstop".  An error will now be raised if a Z
--- a/docs/Config_Reference.md
+++ b/docs/Config_Reference.md
@@ -84,9 +84,8 @@ The printer section controls high level printer settings.
 [printer]
 kinematics:
 #   The type of printer in use. This option may be one of: cartesian,
-#   corexy, corexz, hybrid_corexy, hybrid_corexz, generic_cartesian,
+#   corexy, corexz, hybrid_corexy, hybrid_corexz, rotary_delta, delta,
-#   rotary_delta, delta, deltesian, polar, winch, or none.
+#   deltesian, polar, winch, or none. This parameter must be specified.
 #   This parameter must be specified.
 max_velocity:
 #   Maximum velocity (in mm/s) of the toolhead (relative to the
 #   print). This value may be changed at runtime using the
@@ -126,6 +125,8 @@ max_accel:
 #   decelerate to zero at each corner. The value specified here may be
 #   changed at runtime using the SET_VELOCITY_LIMIT command. The
 #   default is 5mm/s.
 #max_accel_to_decel:
 #   This parameter is deprecated and should no longer be used.
 ```
 ### [stepper]
@@ -711,171 +712,6 @@ anchor_z:
 #   These parameters must be provided.
 ```
 ### Generic Cartesian Kinematics
 See [example-generic-cartesian.cfg](../config/example-generic-caretesian.cfg)
 for an example generic Cartesian kinematics config file.
 This printer kinematic class allows a user to define in a pretty flexible
 manner an arbitrary Cartesian-style kinematics. In principle, the regular
 cartesian, corexy, hybrid_corexy can be defined this way too. However,
 more importantly, various otherwise unsupported kinematics such as
 inverted hybrid_corexy or corexyuv can be defined using this kinematic.
 Notably, the definition of a generic Cartesian kinematic deviates
 significantly from the other kinematic types. It follows the following
 convention: a user defines a set of carriages with certain range of motion
 that can move independently from each other (they should move over the
 Cartesian axes X, Y, and Z, hence the name of the kinematic) and
 corresponding endstops that allow the firmware to determine the position
 of carriages during homing, as well as a set of steppers that move those
 carriages. The `[printer]` section must specify the kinematic and
 other printer-level settings same as the regular Cartesian kinematic:
 ```
 [printer]
 kinematics: generic_cartesian
 max_velocity:
 max_accel:
 #minimum_cruise_ratio:
 #square_corner_velocity:
 #max_z_velocity:
 #max_z_accel:
 ```
 Then a user must define the following three carriages: `[carriage x]`,
 `[carriage y]`, and `[carriage z]`, e.g.
 ```
 [carriage x]
 endstop_pin:
 #   Endstop switch detection pin. If this endstop pin is on a
 #   different mcu than the stepper motor(s) moving this carriage,
 #   then it enables "multi-mcu homing". This parameter must be provided.
 #position_min: 0
 #   Minimum valid distance (in mm) the user may command the carriage to
 #   move to.  The default is 0mm.
 position_endstop:
 #   Location of the endstop (in mm). This parameter must be provided.
 position_max:
 #   Maximum valid distance (in mm) the user may command the stepper to
 #   move to. This parameter must be provided.
 #homing_speed: 5.0
 #   Maximum velocity (in mm/s) of the carriage when homing. The default
 #   is 5mm/s.
 #homing_retract_dist: 5.0
 #   Distance to backoff (in mm) before homing a second time during
 #   homing. Set this to zero to disable the second home. The default
 #   is 5mm.
 #homing_retract_speed:
 #   Speed to use on the retract move after homing in case this should
 #   be different from the homing speed, which is the default for this
 #   parameter
 #second_homing_speed:
 #   Velocity (in mm/s) of the carriage when performing the second home.
 #   The default is homing_speed/2.
 #homing_positive_dir:
 #   If true, homing will cause the carriage to move in a positive
 #   direction (away from zero); if false, home towards zero. It is
 #   better to use the default than to specify this parameter. The
 #   default is true if position_endstop is near position_max and false
 #   if near position_min.
 ```
 Afterwards, a user specifies the stepper motors that move these carriages,
 for instance
 ```
 [stepper my_stepper]
 carriages:
 #   A string describing the carriages the stepper moves. All defined
 #   carriages can be specified here, as well as their linear combinations,
 #   e.g. x, x+y, y-0.5*z, x-z, etc. This parameter must be provided.
 step_pin:
 dir_pin:
 enable_pin:
 rotation_distance:
 microsteps:
 #full_steps_per_rotation: 200
 #gear_ratio:
 #step_pulse_duration:
 ```
 See [stepper](#stepper) section for more information on the regular
 stepper parameters. The `carriages` parameter defines how the stepper
 affects the motion of the carriages. For example, `x+y` indicates that
 the motion of the stepper in the positive direction by the distance `d`
 moves the carriages `x` and `y` by the same distance `d` in the positive
 direction, while `x-0.5*y` means the motion of the stepper in the positive
 direction by the distance `d` moves the carriage `x` by the distance `d`
 in the positive direction, but the carriage `y` will travel distance `d/2`
 in the negative direction.
 More than a single stepper motor can be defined to drive the same axis
 or belt. For example, on a CoreXY AWD setups two motors driving the same
 belt can be defined as
 ```
 [carriage x]
 endstop_pin: ...
 ...
 [carriage y]
 endstop_pin: ...
 ...
 [stepper a0]
 carriages: x-y
 step_pin: ...
 dir_pin: ...
 enable_pin: ...
 rotation_distance: ...
 ...
 [stepper a1]
 carriages: x-y
 step_pin: ...
 dir_pin: ...
 enable_pin: ...
 rotation_distance: ...
 ...
 ```
 with `a0` and `a1` steppers having their own control pins, but
 sharing the same `carriages` and corresponding endstops.
 There are situations when a user wants to have more than one endstop
 per axis. Examples of such configurations include Y axis driven by
 two independent stepper motors with belts attached to both ends of the
 X beam, with effectively two carriages on Y axis each having an
 independent endstop, and multi-stepper Z axis with each stepper having
 its own endstop (not to be confused with the configurations with
 multiple Z motors but only a single endstop). These configurations
 can be declared by specifying additional carriage(s) with their endstops:
 ```
 [extra_carriage my_carriage]
 primary_carriage:
 #   The name of the primary carriage this carriage corresponds to.
 #   It also effectively defines the axis the carriage moves over.
 #   This parameter must be provided.
 endstop_pin:
 #   Endstop switch detection pin. This parameter must be provided.
 ```
 and the corresponding stepper motors, for example:
 ```
 [extra_carriage y1]
 primary_carriage: y
 endstop_pin: ...
 [stepper sy1]
 carriages: y1
 ...
 ```
 Notably, an `[extra_carriage]` does not define parameters such as
 `position_min`, `position_max`, and `position_endstop`, but instead
 inherits them from the specified `primary_carriage`, thus sharing
 the same range of motion with the primary carriage.
 For the references on how to configure IDEX setups, see the
 [dual carriage](#dual-carriage) section.
 ### None Kinematics
 It is possible to define a special "none" kinematics to disable
@@ -1833,25 +1669,6 @@ cs_pin:
 #   measurements.
 ```
 ### [icm20948]
 Support for icm20948 accelerometers.
 ```
 [icm20948]
 #i2c_address:
 #   Default is 104 (0x68). If AD0 is high, it would be 0x69 instead.
 #i2c_mcu:
 #i2c_bus:
 #i2c_software_scl_pin:
 #i2c_software_sda_pin:
 #i2c_speed: 400000
 #   See the "common I2C settings" section for a description of the
 #   above parameters. The default "i2c_speed" is 400000.
 #axes_map: x, y, z
 #   See the "adxl345" section for information on this parameter.
 ```
 ### [lis2dw]
 Support for LIS2DW accelerometers.
@@ -2248,9 +2065,6 @@ Support for eddy current inductive probes. One may define this section
 sensor_type: ldc1612
 #   The sensor chip used to perform eddy current measurements. This
 #   parameter must be provided and must be set to ldc1612.
 #frequency:
 #   The external crystal frequency (in Hz) of the LDC1612 chip.
 #   The default is 12000000.
 #intb_pin:
 #   MCU gpio pin connected to the ldc1612 sensor's INTB pin (if
 #   available). The default is to not use the INTB pin.
@@ -2371,8 +2185,8 @@ for an example configuration.
 ### [dual_carriage]
-Support for cartesian, generic_cartesian and hybrid_corexy/z printers with
+Support for cartesian and hybrid_corexy/z printers with dual carriages
-dual carriages on a single axis. The carriage mode can be set via the
+on a single axis. The carriage mode can be set via the
 SET_DUAL_CARRIAGE extended g-code command. For example,
 "SET_DUAL_CARRIAGE CARRIAGE=1" command will activate the carriage defined
 in this section (CARRIAGE=0 will return activation to the primary carriage).
@@ -2399,7 +2213,7 @@ typically be achieved with
 or a similar command.
 See [sample-idex.cfg](../config/sample-idex.cfg) for an example
-configuration with a regular Cartesian kinematic.
+configuration.
 ```
 [dual_carriage]
@@ -2413,7 +2227,7 @@ axis:
 #   error. If safe_distance is not provided, it will be inferred from
 #   position_min and position_max for the dual and primary carriages. If set
 #   to 0 (or safe_distance is unset and position_min and position_max are
-#   identical for the primary and dual carriages), the carriages proximity
+#   identical for the primary and dual carraiges), the carriages proximity
 #   checks will be disabled.
 #step_pin:
 #dir_pin:
@@ -2427,83 +2241,6 @@ axis:
 #   See the "stepper" section for the definition of the above parameters.
 ```
 For an example of dual carriage configuration with `generic_cartesian`
 kinematic, see the following configuration
 [sample](../config/example-generic-caretesian.cfg).
 Please note that in this case the `[dual_carriage]` configuration deviates
 from the configuration described above:
 ```
 [dual_carriage my_dc_carriage]
 primary_carriage:
 #   Defines the matching primary carriage of this dual carriage and
 #   the corresponding IDEX axis. Valid choices are x, y, z.
 #   This parameter must be provided.
 #safe_distance:
 #   The minimum distance (in mm) to enforce between the dual and the primary
 #   carriages. If a G-Code command is executed that will bring the carriages
 #   closer than the specified limit, such a command will be rejected with an
 #   error. If safe_distance is not provided, it will be inferred from
 #   position_min and position_max for the dual and primary carriages. If set
 #   to 0 (or safe_distance is unset and position_min and position_max are
 #   identical for the primary and dual carriages), the carriages proximity
 #   checks will be disabled.
 endstop_pin:
 #position_min:
 position_endstop:
 position_max:
 #homing_speed:
 #homing_retract_dist:
 #homing_retract_speed:
 #second_homing_speed:
 #homing_positive_dir:
 ...
 ```
 Refer to [generic cartesian](#generic-cartesian) section for more information
 on the regular `carriage` parameters.
 Then a user must define one or more stepper motors moving the dual carriage
 (and other carriages as appropriate), for instance
 ```
 [carriage x]
 ...
 [carriage y]
 ...
 [dual_carriage u]
 primary_carriage: x
 ...
 [stepper dc_stepper]
 carriages: u-y
 ...
 ```
 `[dual_carriage]` requires special configuration for the input shaper.
 In general, it is necessary to run input shaper calibration twice -
 for the `dual_carriage` and its `primary_carriage` for the axis they
 share. Then the input shaper can be configured as follows, assuming the
 example above:
 ```
 [input_shaper]
 # Intentionally empty
 [delayed_gcode init_shaper]
 initial_duration: 0.1
 gcode:
  SET_DUAL_CARRIAGE CARRIAGE=u
  SET_INPUT_SHAPER SHAPER_TYPE_X=<dual_carriage_x_shaper> SHAPER_FREQ_X=<dual_carriage_x_freq> SHAPER_TYPE_Y=<y_shaper> SHAPER_FREQ_Y=<y_freq>
  SET_DUAL_CARRIAGE CARRIAGE=x
  SET_INPUT_SHAPER SHAPER_TYPE_X=<primary_carriage_x_shaper> SHAPER_FREQ_X=<primary_carriage_x_freq> SHAPER_TYPE_Y=<y_shaper> SHAPER_FREQ_Y=<y_freq>
 ```
 Note that `SHAPER_TYPE_Y` and `SHAPER_FREQ_Y` must be the same in both
 commands in this case, since the same motors drive Y axis when either
 of the `x` and `u` carriages are active.
 It is worth noting that `generic_cartesian` kinematic can support two
 dual carriages for X and Y axes. For reference, see for instance a
 [sample](../config/sample-corexyuv.cfg) of CoreXYUV configuration.
 ### [extruder_stepper]
 Support for additional steppers synchronized to the movement of an
@@ -2558,13 +2295,6 @@ printer kinematics.
 #   Endstop switch detection pin. If specified, then one may perform
 #   "homing moves" by adding a STOP_ON_ENDSTOP parameter to
 #   MANUAL_STEPPER movement commands.
 #position_min:
 #position_max:
 #   The minimum and maximum position the stepper can be commanded to
 #   move to. If specified then one may not command the stepper to move
 #   past the given position. Note that these limits do not prevent
 #   setting an arbitrary position with the `MANUAL_STEPPER
 #   SET_POSITION=x` command. The default is to not enforce a limit.
 ```
 ## Custom heaters and sensors
@@ -3474,6 +3204,11 @@ PCA9632 LED support. The PCA9632 is used on the FlashForge Dreamer.
 #i2c_speed:
 #   See the "common I2C settings" section for a description of the
 #   above parameters.
 #scl_pin:
 #sda_pin:
 #   Alternatively, if the pca9632 is not connected to a hardware I2C
 #   bus, then one may specify the "clock" (scl_pin) and "data"
 #   (sda_pin) pins. The default is to use hardware I2C.
 #color_order: RGBW
 #   Set the pixel order of the LED (using a string containing the
 #   letters R, G, B, W). The default is RGBW.
@@ -3543,10 +3278,6 @@ pin:
 #   A list of G-Code commands to execute when the button is released.
 #   G-Code templates are supported. The default is to not run any
 #   commands on a button release.
 #debounce_delay:
 #   A period of time in seconds to debounce events prior to running the
 #   button gcode. If the button is pressed and released during this
 #   delay, the entire button press is ignored. Default is 0.
 ```
 ### [output_pin]
@@ -3725,9 +3456,8 @@ run_current:
 #stealthchop_threshold: 0
 #   The velocity (in mm/s) to set the "stealthChop" threshold to. When
 #   set, "stealthChop" mode will be enabled if the stepper motor
-#   velocity is below this value. Note that the "sensorless homing"
+#   velocity is below this value. The default is 0, which disables
-#   code may temporarily override this setting during homing
+#   "stealthChop" mode.
 #   operations. The default is 0, which disables "stealthChop" mode.
 #coolstep_threshold:
 #   The velocity (in mm/s) to set the TMC driver internal "CoolStep"
 #   threshold to. If set, the coolstep feature will be enabled when
@@ -3776,7 +3506,6 @@ run_current:
 #driver_PWM_FREQ: 1
 #driver_PWM_GRAD: 4
 #driver_PWM_AMPL: 128
 #driver_FREEWHEEL: 0
 #driver_SGT: 0
 #driver_SEMIN: 0
 #driver_SEUP: 0
@@ -3840,9 +3569,8 @@ run_current:
 #stealthchop_threshold: 0
 #   The velocity (in mm/s) to set the "stealthChop" threshold to. When
 #   set, "stealthChop" mode will be enabled if the stepper motor
-#   velocity is below this value. Note that the "sensorless homing"
+#   velocity is below this value. The default is 0, which disables
-#   code may temporarily override this setting during homing
+#   "stealthChop" mode.
 #   operations. The default is 0, which disables "stealthChop" mode.
 #driver_MULTISTEP_FILT: True
 #driver_IHOLDDELAY: 8
 #driver_TPOWERDOWN: 20
@@ -3857,7 +3585,6 @@ run_current:
 #driver_PWM_FREQ: 1
 #driver_PWM_GRAD: 14
 #driver_PWM_OFS: 36
 #driver_FREEWHEEL: 0
 #   Set the given register during the configuration of the TMC2208
 #   chip. This may be used to set custom motor parameters. The
 #   defaults for each parameter are next to the parameter name in the
@@ -3907,7 +3634,6 @@ run_current:
 #driver_PWM_FREQ: 1
 #driver_PWM_GRAD: 14
 #driver_PWM_OFS: 36
 #driver_FREEWHEEL: 0
 #driver_SGTHRS: 0
 #driver_SEMIN: 0
 #driver_SEUP: 0
@@ -4046,9 +3772,8 @@ run_current:
 #stealthchop_threshold: 0
 #   The velocity (in mm/s) to set the "stealthChop" threshold to. When
 #   set, "stealthChop" mode will be enabled if the stepper motor
-#   velocity is below this value. Note that the "sensorless homing"
+#   velocity is below this value. The default is 0, which disables
-#   code may temporarily override this setting during homing
+#   "stealthChop" mode.
 #   operations. The default is 0, which disables "stealthChop" mode.
 #coolstep_threshold:
 #   The velocity (in mm/s) to set the TMC driver internal "CoolStep"
 #   threshold to. If set, the coolstep feature will be enabled when
@@ -4181,9 +3906,8 @@ run_current:
 #stealthchop_threshold: 0
 #   The velocity (in mm/s) to set the "stealthChop" threshold to. When
 #   set, "stealthChop" mode will be enabled if the stepper motor
-#   velocity is below this value. Note that the "sensorless homing"
+#   velocity is below this value. The default is 0, which disables
-#   code may temporarily override this setting during homing
+#   "stealthChop" mode.
 #   operations. The default is 0, which disables "stealthChop" mode.
 #coolstep_threshold:
 #   The velocity (in mm/s) to set the TMC driver internal "CoolStep"
 #   threshold to. If set, the coolstep feature will be enabled when
@@ -4389,21 +4113,16 @@ prefix).
 ### [mcp4018]
-Statically configured MCP4018 digipot connected via i2c (one may
+Statically configured MCP4018 digipot connected via two gpio "bit
-define any number of sections with an "mcp4018" prefix).
+banging" pins (one may define any number of sections with an "mcp4018"
 prefix).
 ```
 [mcp4018 my_digipot]
-#i2c_address: 47
+scl_pin:
-#   The i2c address that the chip is using on the i2c bus. The default
+#   The SCL "clock" pin. This parameter must be provided.
-#   is 47.
+sda_pin:
-#i2c_mcu:
+#   The SDA "data" pin. This parameter must be provided.
 #i2c_bus:
 #i2c_software_scl_pin:
 #i2c_software_sda_pin:
 #i2c_speed:
 #   See the "common I2C settings" section for a description of the
 #   above parameters.
 wiper:
 #   The value to statically set the given MCP4018 "wiper" to. This is
 #   typically set to a number between 0.0 and 1.0 with 1.0 being the
@@ -4918,11 +4637,6 @@ more information.
 #   dispatch and execution of the runout_gcode. It may be useful to
 #   increase this delay if OctoPrint exhibits strange pause behavior.
 #   Default is 0.5 seconds.
 #debounce_delay:
 #   A period of time in seconds to debounce events prior to running the
 #   switch gcode. The switch must he held in a single state for at least
 #   this long to activate. If the switch is toggled on/off during this delay,
 #   the event is ignored. Default is 0.
 #switch_pin:
 #   The pin on which the switch is connected. This parameter must be
 #   provided.
@@ -5040,16 +4754,6 @@ scale.
 [load_cell]
 sensor_type:
 #   This must be one of the supported sensor types, see below.
 #counts_per_gram:
 #   The floating point number of sensor counts that indicates 1 gram of force.
 #   This value is calculated by the LOAD_CELL_CALIBRATE command.
 #reference_tare_counts:
 #   The integer tare value, in raw sensor counts, taken when LOAD_CELL_CALIBRATE
 #   is run. This is the default tare value when klipper starts up.
 #sensor_orientation:
 #   Change the sensor's orientation. Can be either 'normal' or 'inverted'.
 #   The default is 'normal'. Use 'inverted' if the sensor reports a
 #   decreasing force value when placed under load.
 ```
 #### HX711
@@ -5146,65 +4850,6 @@ data_ready_pin:
 #   and 'analog_supply'. Default is 'internal'.
 ```
 ### [load_cell_probe]
 Load Cell Probe. This combines the functionality of a [probe] and a [load_cell].
 ```
 [load_cell_probe]
 sensor_type:
 #   This must be one of the supported bulk ADC sensor types and support
 #   load cell endstops on the mcu.
 #counts_per_gram:
 #reference_tare_counts:
 #sensor_orientation:
 #   These parameters must be configured before the probe will operate.
 #   See the [load_cell] section for further details.
 #force_safety_limit: 2000
 #   The safe limit for probing force relative to the reference_tare_counts on
 #   the load_cell. The default is +/-2Kg.
 #trigger_force: 75.0
 #   The force that the probe will trigger at. 75g is the default.
 #drift_filter_cutoff_frequency: 0.8
 #   Enable optional continuous taring while homing & probing to reject drift.
 #   The value is a frequency, in Hz, below which drift will be ignored. This
 #   option requires the SciPy library. Default: None
 #drift_filter_delay: 2
 #   The delay, or 'order', of the drift filter. This controls the number of
 #   samples required to make a trigger detection. Can be 1 or 2, the default
 #   is 2.
 #buzz_filter_cutoff_frequency: 100.0
 #   The value is a frequency, in Hz, above which high frequency noise in the
 #   load cell will be igfiltered outnored. This option requires the SciPy
 #   library. Default: None
 #buzz_filter_delay: 2
 #   The delay, or 'order', of the buzz filter. This controls the number of
 #   samples required to make a trigger detection. Can be 1 or 2, the default
 #   is 2.
 #notch_filter_frequencies: 50, 60
 #   1 or 2 frequencies, in Hz, to filter out of the load cell data. This is
 #   intended to reject power line noise. This option requires the SciPy
 #   library.  Default: None
 #notch_filter_quality: 2.0
 #   Controls how narrow the range of frequencies are that the notch filter
 #   removes. Larger numbers produce a narrower filter. Minimum value is 0.5 and
 #   maximum is 3.0. Default: 2.0
 #tare_time:
 #   The rime in seconds used for taring the load_cell before each probe. The
 #   default value is: 4 / 60 = 0.066. This collects samples from 4 cycles of
 #   60Hz mains power to cancel power line noise.
 #z_offset:
 #speed:
 #samples:
 #sample_retract_dist:
 #lift_speed:
 #samples_result:
 #samples_tolerance:
 #samples_tolerance_retries:
 #activate_gcode:
 #deactivate_gcode:
 #   See the "[probe]" section for a description of the above parameters.
 ```
 ## Board specific hardware support
 ### [sx1509]
@@ -5311,7 +4956,7 @@ chip: ADS1115
 #   scales all values read from the ADC. Options are: 6.144V, 4.096V, 2.048V,
 #   1.024V, 0.512V, 0.256V
 #adc_voltage: 3.3
-#   The supply voltage for the device. This allows additional software scaling
+#   The suppy voltage for the device. This allows additional software scaling
 #   for all values read from the ADC.
 i2c_mcu: host
 i2c_bus: i2c.1
@@ -5330,7 +4975,7 @@ sensor_pin: my_ads1x1x:AIN0
 #   A combination of the name of the ads1x1x chip and the pin. Possible
 #   pin values are AIN0, AIN1, AIN2 and AIN3 for single ended lines and
 #   DIFF01, DIFF03, DIFF13 and DIFF23 for differential between their
-#   corresponding lines. For example
+#   correspoding lines. For example
 #   DIFF03 measures the differential between line 0 and 3. Only specific
 #   combinations for the differentials are allowed.
 ```
@@ -5416,7 +5061,7 @@ Octoprint as they will conflict, and 1 will fail to initialize
 properly likely aborting your print.
 If you use Octoprint and stream gcode over the serial port instead of
-printing from virtual_sd, then remove **M1** and **M0** from *Pausing commands*
+printing from virtual_sd, then remo **M1** and **M0** from *Pausing commands*
 in *Settings > Serial Connection > Firmware & protocol* will prevent
 the need to start print on the Palette 2 and unpausing in Octoprint
 for your print to begin.
--- a/docs/Features.md
+++ b/docs/Features.md
@@ -102,13 +102,11 @@ Klipper supports many standard 3d printer features:
  printers.
 * Automatic bed leveling support. Klipper can be configured for basic
-  bed tilt detection or full mesh bed leveling. The bed mesh can be
+  bed tilt detection or full mesh bed leveling. If the bed uses
  customized to the print size (adaptive bed mesh). If the bed uses
  multiple Z steppers then Klipper can also level by independently
  manipulating the Z steppers. Most Z height probes are supported,
  including BL-Touch probes and servo activated probes. Probes may be
-  calibrated for axis twist compensation. If using an "eddy current
+  calibrated for axis twist compensation.
  probe" then one can utilize fast bed mesh scanning,
 * Automatic delta calibration support. The calibration tool can
  perform basic height calibration as well as an enhanced X and Y
@@ -120,7 +118,7 @@ Klipper supports many standard 3d printer features:
 * Support for common temperature sensors (eg, common thermistors,
  AD595, AD597, AD849x, PT100, PT1000, MAX6675, MAX31855, MAX31856,
-  MAX31865, BME280, HTU21D, DS18B20, AHT10, SHT3x, and LM75). Custom
+  MAX31865, BME280, HTU21D, DS18B20, AHT10, and LM75). Custom
  thermistors and custom analog temperature sensors can also be
  configured. One can monitor the internal micro-controller
  temperature sensor and the internal temperature sensor of a
@@ -130,8 +128,7 @@ Klipper supports many standard 3d printer features:
 * Support for standard fans, nozzle fans, and temperature controlled
  fans. No need to keep fans running when the printer is idle. Fan
-  speed can be monitored on fans that have a tachometer. One can
+  speed can be monitored on fans that have a tachometer.
  assign a "math formula" to a fan for automatic fan speed updating.
 * Support for run-time configuration of TMC2130, TMC2208/TMC2224,
  TMC2209, TMC2240, TMC2660, and TMC5160 stepper motor drivers. There
@@ -157,7 +154,7 @@ Klipper supports many standard 3d printer features:
  filament width sensors.
 * Support for measuring and recording acceleration using adxl345,
-  mpu9250, mpu6050, lis2dw12, lis3dh, and icm20948 accelerometers.
+  mpu9250, mpu6050, and lis2dw12 accelerometers.
 * Support for limiting the top speed of short "zigzag" moves to reduce
  printer vibration and noise. See the [kinematics](Kinematics.md)
@@ -187,16 +184,15 @@ represent total number of steps per second on the micro-controller.
 | SAM4S8C                         | 1690K             | 1385K             |
 | LPC1768                         | 1923K             | 1351K             |
 | LPC1769                         | 2353K             | 1622K             |
 | RP2040                          | 2400K             | 1636K             |
 | SAM4E8E                         | 2500K             | 1674K             |
 | SAMD51                          | 3077K             | 1885K             |
 | AR100                           | 3529K             | 2507K             |
 | STM32G431                       | 3617K             | 2452K             |
 | STM32F407                       | 3652K             | 2459K             |
 | STM32F446                       | 3913K             | 2634K             |
 | RP2040                          | 4000K             | 2571K             |
 | RP2350                          | 4167K             | 2663K             |
 | SAME70                          | 6667K             | 4737K             |
-| STM32H723                       | 7429K             | 8619K             |
+| STM32H743                       | 9091K             | 6061K             |
 If unsure of the micro-controller on a particular board, find the
 appropriate [config file](../config/), and look for the
--- a/docs/G-Codes.md
+++ b/docs/G-Codes.md
@@ -154,7 +154,8 @@ The following commands are available when the
 section](Config_Reference.md#axis_twist_compensation) is enabled.
 #### AXIS_TWIST_COMPENSATION_CALIBRATE
-`AXIS_TWIST_COMPENSATION_CALIBRATE [AXIS=<X|Y>] [SAMPLE_COUNT=<value>]`
+`AXIS_TWIST_COMPENSATION_CALIBRATE [AXIS=<X|Y>] [AUTO=<True|False>]
 [SAMPLE_COUNT=<value>]`
 Calibrates axis twist compensation by specifying the target axis or
 enabling automatic calibration.
@@ -162,6 +163,11 @@ enabling automatic calibration.
 - **AXIS:** Define the axis (`X` or `Y`) for which the twist compensation
 will be calibrated. If not specified, the axis defaults to `'X'`.
 - **AUTO:** Enables automatic calibration mode. When `AUTO=True`, the
 calibration will run for both the X and Y axes. In this mode, `AXIS`
 cannot be specified. If both `AXIS` and `AUTO` are provided, an error
 will be raised.
 ### [bed_mesh]
 The following commands are available when the
@@ -174,10 +180,8 @@ The following commands are available when the
 [ADAPTIVE_MARGIN=<value>]`: This command probes the bed using generated points
 specified by the parameters in the config. After probing, a mesh is generated
 and z-movement is adjusted according to the mesh.
 The mesh is immediately active after successful completion of `BED_MESH_CALIBRATE`.
 The mesh will be saved into a profile specified by the `PROFILE` parameter,
-or `default` if unspecified. If ADAPTIVE=1 is specified then the profile
+or `default` if unspecified.
 name will begin with `adaptive-` and should not be saved for reuse.
 See the PROBE command for details on the optional probe parameters. If
 METHOD=manual is specified then the manual probing tool is activated - see the
 MANUAL_PROBE command above for details on the additional commands available
@@ -343,18 +347,15 @@ The following command is available when the
 enabled.
 #### SET_DUAL_CARRIAGE
-`SET_DUAL_CARRIAGE CARRIAGE=<carriage> [MODE=[PRIMARY|COPY|MIRROR]]`:
+`SET_DUAL_CARRIAGE CARRIAGE=[0|1] [MODE=[PRIMARY|COPY|MIRROR]]`:
 This command will change the mode of the specified carriage.
-If no `MODE` is provided it defaults to `PRIMARY`. `<carriage>` must
+If no `MODE` is provided it defaults to `PRIMARY`. Setting the mode
-reference a defined primary or dual carriage for `generic_cartesian`
+to `PRIMARY` deactivates the other carriage and makes the specified
-kinematics or be 0 (for primary carriage) or 1 (for dual carriage)
+carriage execute subsequent G-Code commands as-is. `COPY` and `MIRROR`
-for all other kinematics supporting IDEX. Setting the mode to `PRIMARY`
+modes are supported only for `CARRIAGE=1`. When set to either of these
-deactivates the other carriage and makes the specified carriage execute
+modes, carriage 1 will then track the subsequent moves of the carriage 0
-subsequent G-Code commands as-is. `COPY` and `MIRROR` modes are supported
+and either copy relative movements of it (in `COPY` mode) or execute them
-only for dual carriages. When set to either of these modes, dual carriage
+in the opposite (mirror) direction (in `MIRROR` mode).
 will then track the subsequent moves of its primary carriage and either
 copy relative movements of it (in `COPY` mode) or execute them in the
 opposite (mirror) direction (in `MIRROR` mode).
 #### SAVE_DUAL_CARRIAGE_STATE
 `SAVE_DUAL_CARRIAGE_STATE [NAME=<state_name>]`: Save the current positions
@@ -372,7 +373,7 @@ restored and "MOVE_SPEED" is specified, then the toolhead moves will be
 performed with the given speed (in mm/s); otherwise the toolhead move will
 use the rail homing speed. Note that the carriages restore their positions
 only over their own axis, which may be necessary to correctly restore COPY
-and MIRROR mode of the dual carriage.
+and MIRROR mode of the dual carraige.
 ### [endstop_phase]
@@ -584,51 +585,18 @@ state; issue a G28 afterwards to reset the kinematics. This command is
 intended for low-level diagnostics and debugging.
 #### SET_KINEMATIC_POSITION
 `SET_KINEMATIC_POSITION [X=<value>] [Y=<value>] [Z=<value>]
-[SET_HOMED=<[X][Y][Z]>] [CLEAR_HOMED=<[X][Y][Z]>]`: Force the
+[CLEAR=<[X][Y][Z]>]`: Force the low-level kinematic code to believe the
-low-level kinematic code to believe the toolhead is at the given
+toolhead is at the given cartesian position. This is a diagnostic and
-cartesian position and set/clear homed status. This is a diagnostic
+debugging command; use SET_GCODE_OFFSET and/or G92 for regular axis
-and debugging command; use SET_GCODE_OFFSET and/or G92 for regular
+transformations. If an axis is not specified then it will default to the
-axis transformations. Setting an incorrect or invalid position may
+position that the head was last commanded to. Setting an incorrect or
-lead to internal software errors.
+invalid position may lead to internal software errors. Use the CLEAR
-
+parameter to forget the homing state for the given axes. Note that CLEAR
-The `X`, `Y`, and `Z` parameters are used to alter the low-level
+will not override the previous functionality; if an axis is not specified
-kinematic position tracking. If any of these parameters are not set
+to CLEAR it will have its kinematic position set as per above. This
-then the position is not changed - for example `SET_KINEMATIC_POSITION
+command may invalidate future boundary checks; issue a G28 afterwards to
-Z=10` would set all axes as homed, set the internal Z position to 10,
+reset the kinematics.
 and leave the X and Y positions unchanged. Changing the internal
 position tracking is not dependent on the internal homing state - one
 may alter the position for both homed and not homed axes, and
 similarly one may set or clear the homing state of an axis without
 altering its internal position.
 The `SET_HOMED` parameter defaults to `XYZ` which instructs the
 kinematics to consider all axes as homed. A bare
 `SET_KINEMATIC_POSITION` command will result in all axes being
 considered homed (and not change its current position). If it is not
 desired to change the state of homed axes then assign `SET_HOMED` to
 an empty string - for example:
 `SET_KINEMATIC_POSITION SET_HOMED= X=10`. It is also possible to
 request an individual axis be considered homed (eg, `SET_HOMED=X`),
 but note that non-cartesian style kinematics (such as delta
 kinematics) may not support setting an individual axis as homed.
 The `CLEAR_HOMED` parameter instructs the kinematics to consider the
 given axes as not homed. For example, `CLEAR_HOMED=XYZ` would request
 all axes to be considered not homed (and thus require homing prior to
 movement on those axes). The default is `SET_HOMED=XYZ` even if
 `CLEAR_HOMED` is present, so the command `SET_KINEMATIC_POSITION
 CLEAR_HOMED=Z` will set X and Y as homed and clear the homing state
 for Z.  Use `SET_KINEMATIC_POSITION SET_HOMED= CLEAR_HOMED=Z` if the
 goal is to clear only the Z homing state. If an axis is specified in
 neither `SET_HOMED` nor `CLEAR_HOMED` then its homing state is not
 changed and if it is specified in both then `CLEAR_HOMED` has
 precedence. It is possible to request clearing of an individual axis,
 but on non-cartesian style kinematics (such as delta kinematics) doing
 so may result in clearing the homing state of additional axes. Note
 the `CLEAR` parameter is currently an alias for the `CLEAR_HOMED`
 parameter, but this alias will be removed in the future.
 ### [gcode]
@@ -720,46 +688,6 @@ is specified then the toolhead move will be performed with the given
 speed (in mm/s); otherwise the toolhead move will use the restored
 g-code speed.
 ### [generic_cartesian]
 The commands in this section become automatically available when
 `kinematics: generic_cartesian` is specified as the printer kinematics.
 #### SET_STEPPER_CARRIAGES
 `SET_STEPPER_CARRIAGES STEPPER=<stepper_name> CARRIAGES=<carriages>
 [DISABLE_CHECKS=[0|1]]`: Set or update the stepper carriages.
 `<stepper_name>` must reference an existing stepper defined in `printer.cfg`,
 and `<carriages>` describes the carriages the stepper moves. See
 [Generic Cartesian Kinematics](Config_Reference.md#generic-cartesian-kinematics)
 for a more detailed overview of the `carriages` parameter in the
 stepper configuration section. Note that it is only possible
 to change the coefficients or signs of the carriages with this
 command, but a user cannot add or remove the carriages that the stepper
 controls.
 `SET_STEPPER_CARRIAGES` is an advanced tool, and the user is advised
 to exercise an extreme caution using it, since specifying incorrect
 configuration may physically damage the printer.
 Note that `SET_STEPPER_CARRIAGES` performs certain internal validations
 of the new printer kinematics after the change. Keep in mind that if it
 detects an issue, it may leave printer kinematics in an invalid state.
 This means that if `SET_STEPPER_CARRIAGES` reports an error, it is unsafe
 to issue other GCode commands, and the user must inspect the error message
 and either fix the problem, or manually restore the previous stepper(s)
 configuration.
 Since `SET_STEPPER_CARRIAGES` can update a configuration of a single
 stepper at a time, some sequences of changes can lead to invalid
 intermediate kinematic configurations, even if the final configuration
 is valid. In such cases a user can pass `DISABLE_CHECKS=1` parameters to
 all but the last command to disable intermediate checks. For example,
 if `stepper a` and `stepper b` initially have `x-y` and `x+y` carriages
 correspondingly, then the following sequence of commands will let a user
 effectively swap the carriage controls:
 `SET_STEPPER_CARRIAGES STEPPER=a CARRIAGES=x+y DISABLE_CHECKS=1`
 and `SET_STEPPER_CARRIAGES STEPPER=b CARRIAGES=x-y`, while
 still validating the final kinematics state.
 ### [hall_filament_width_sensor]
 The following commands are available when the
@@ -838,116 +766,6 @@ together with either of SHAPER_TYPE_X and SHAPER_TYPE_Y parameters.
 See [config reference](Config_Reference.md#input_shaper) for more
 details on each of these parameters.
 ### [led]
 The following command is available when any of the
 [led config sections](Config_Reference.md#leds) are enabled.
 #### SET_LED
 `SET_LED LED=<config_name> RED=<value> GREEN=<value> BLUE=<value>
 WHITE=<value> [INDEX=<index>] [TRANSMIT=0] [SYNC=1]`: This sets the
 LED output. Each color `<value>` must be between 0.0 and 1.0. The
 WHITE option is only valid on RGBW LEDs. If the LED supports multiple
 chips in a daisy-chain then one may specify INDEX to alter the color
 of just the given chip (1 for the first chip, 2 for the second,
 etc.). If INDEX is not provided then all LEDs in the daisy-chain will
 be set to the provided color. If TRANSMIT=0 is specified then the
 color change will only be made on the next SET_LED command that does
 not specify TRANSMIT=0; this may be useful in combination with the
 INDEX parameter to batch multiple updates in a daisy-chain. By
 default, the SET_LED command will sync it's changes with other ongoing
 gcode commands.  This can lead to undesirable behavior if LEDs are
 being set while the printer is not printing as it will reset the idle
 timeout. If careful timing is not needed, the optional SYNC=0
 parameter can be specified to apply the changes without resetting the
 idle timeout.
 #### SET_LED_TEMPLATE
 `SET_LED_TEMPLATE LED=<led_name> TEMPLATE=<template_name>
 [<param_x>=<literal>] [INDEX=<index>]`: Assign a
 [display_template](Config_Reference.md#display_template) to a given
 [LED](Config_Reference.md#leds). For example, if one defined a
 `[display_template my_led_template]` config section then one could
 assign `TEMPLATE=my_led_template` here. The display_template should
 produce a comma separated string containing four floating point
 numbers corresponding to red, green, blue, and white color settings.
 The template will be continuously evaluated and the LED will be
 automatically set to the resulting colors. One may set
 display_template parameters to use during template evaluation
 (parameters will be parsed as Python literals). If INDEX is not
 specified then all chips in the LED's daisy-chain will be set to the
 template, otherwise only the chip with the given index will be
 updated. If TEMPLATE is an empty string then this command will clear
 any previous template assigned to the LED (one can then use `SET_LED`
 commands to manage the LED's color settings).
 ### [load_cell]
 The following commands are enabled if a
 [load_cell config section](Config_Reference.md#load_cell) has been enabled.
 ### LOAD_CELL_DIAGNOSTIC
 `LOAD_CELL_DIAGNOSTIC [LOAD_CELL=<config_name>]`: This command collects 10
 seconds of load cell data and reports statistics that can help you verify proper
 operation of the load cell. This command can be run on both calibrated and
 uncalibrated load cells.
 ### LOAD_CELL_CALIBRATE
 `LOAD_CELL_CALIBRATE [LOAD_CELL=<config_name>]`: Start the guided calibration
 utility. Calibration is a 3 step process:
 1. First you remove all load from the load cell and run the `TARE` command
 2. Next you apply a known load to the load cell and run the
 `CALIBRATE GRAMS=nnn` command
 3. Finally use the `ACCEPT` command to save the results
 You can cancel the calibration process at any time with `ABORT`.
 ### LOAD_CELL_TARE
 `LOAD_CELL_TARE [LOAD_CELL=<config_name>]`: This works just like the tare button
 on digital scale. It sets the current raw reading of the load cell to be the
 zero point reference value. The response is the percentage of the sensors range
 that was read and the raw value in counts. If the load cell is calibrated a
 force in grams is also reported.
 ### LOAD_CELL_READ load_cell="name"
 `LOAD_CELL_READ [LOAD_CELL=<config_name>]`:
 This command takes a reading from the load cell. The response is the percentage
 of the sensors range that was read and the raw value in counts. If the load cell
 is calibrated a force in grams is also reported.
 ### [load_cell_probe]
 The following commands are enabled if a
 [load_cell config section](Config_Reference.md#load_cell_probe) has been
 enabled.
 ### LOAD_CELL_TEST_TAP
 `LOAD_CELL_TEST_TAP [TAPS=<taps>] [TIMEOUT=<timeout>]`: Run a testing routine
 that reports taps on the load cell. The toolhead will not move but the load cell
 probe will sense taps just as if it was probing. This can be used as a
 sanity check to make sure that the probe works. This tool replaces
 QUERY_ENDSTOPS and QUERY_PROBE for load cell probes.
 - `TAPS`: the number of taps the tool expects
 - `TIMEOOUT`: the time, in seconds, that the tool waits for each tab before
  aborting.
 ### Load Cell Command Extensions
 Commands that perform probes, such as [`PROBE`](#probe),
 [`PROBE_ACCURACY`](#probe_accuracy),
 [`BED_MESH_CALIBRATE`](#bed_mesh_calibrate) etc. will accept additional
 parameters if a `[load_cell_probe]` is defined. The parameters override the
 corresponding settings from the
 [`[load_cell_probe]`](./Config_Reference.md#load_cell_probe) configuration:
 - `FORCE_SAFETY_LIMIT=<grams>`
 - `TRIGGER_FORCE=<grams>`
 - `DRIFT_FILTER_CUTOFF_FREQUENCY=<frequency_hz>`
 - `DRIFT_FILTER_DELAY=<1|2>`
 - `BUZZ_FILTER_CUTOFF_FREQUENCY=<frequency_hz>`
 - `BUZZ_FILTER_DELAY=<1|2>`
 - `NOTCH_FILTER_FREQUENCIES=<list of frequency_hz>`
 - `NOTCH_FILTER_QUALITY=<quality>`
 - `TARE_TIME=<seconds>`
 ### [manual_probe]
 The manual_probe module is automatically loaded.
@@ -1004,25 +822,6 @@ scheduled to run after the stepper move completes, however if a manual
 stepper move uses SYNC=0 then future G-Code movement commands may run
 in parallel with the stepper movement.
 `MANUAL_STEPPER STEPPER=config_name GCODE_AXIS=[A-Z]
 [LIMIT_VELOCITY=<velocity>] [LIMIT_ACCEL=<accel>]
 [INSTANTANEOUS_CORNER_VELOCITY=<velocity>]`: If the `GCODE_AXIS`
 parameter is specified then it configures the stepper motor as an
 extra axis on `G1` move commands.  For example, if one were to issue a
 `MANUAL_STEPPER ... GCODE_AXIS=R` command then one could issue
 commands like `G1 X10 Y20 R30` to move the stepper motor.  The
 resulting moves will occur synchronously with the associated toolhead
 xyz movements.  If the motor is associated with a `GCODE_AXIS` then
 one may no longer issue movements using the above `MANUAL_STEPPER`
 command - one may unregister the stepper with a `MANUAL_STEPPER
 ... GCODE_AXIS=` command to resume manual control of the motor. The
 `LIMIT_VELOCITY` and `LIMIT_ACCEL` parameters allow one to reduce the
 speed of `G1` moves if those moves would result in a velocity or
 acceleration above the specified limits. The
 `INSTANTANEOUS_CORNER_VELOCITY` specifies the maximum instantaneous
 velocity change (in mm/s) of the motor during the junction of two
 moves (the default is 1mm/s).
 ### [mcp4018]
 The following command is available when a
@@ -1037,6 +836,49 @@ be between 0.0 and 1.0, unless a 'scale' is defined in the config.
 When 'scale' is defined, then this value should be  between 0.0 and
 'scale'.
 ### [led]
 The following command is available when any of the
 [led config sections](Config_Reference.md#leds) are enabled.
 #### SET_LED
 `SET_LED LED=<config_name> RED=<value> GREEN=<value> BLUE=<value>
 WHITE=<value> [INDEX=<index>] [TRANSMIT=0] [SYNC=1]`: This sets the
 LED output. Each color `<value>` must be between 0.0 and 1.0. The
 WHITE option is only valid on RGBW LEDs. If the LED supports multiple
 chips in a daisy-chain then one may specify INDEX to alter the color
 of just the given chip (1 for the first chip, 2 for the second,
 etc.). If INDEX is not provided then all LEDs in the daisy-chain will
 be set to the provided color. If TRANSMIT=0 is specified then the
 color change will only be made on the next SET_LED command that does
 not specify TRANSMIT=0; this may be useful in combination with the
 INDEX parameter to batch multiple updates in a daisy-chain. By
 default, the SET_LED command will sync it's changes with other ongoing
 gcode commands.  This can lead to undesirable behavior if LEDs are
 being set while the printer is not printing as it will reset the idle
 timeout. If careful timing is not needed, the optional SYNC=0
 parameter can be specified to apply the changes without resetting the
 idle timeout.
 #### SET_LED_TEMPLATE
 `SET_LED_TEMPLATE LED=<led_name> TEMPLATE=<template_name>
 [<param_x>=<literal>] [INDEX=<index>]`: Assign a
 [display_template](Config_Reference.md#display_template) to a given
 [LED](Config_Reference.md#leds). For example, if one defined a
 `[display_template my_led_template]` config section then one could
 assign `TEMPLATE=my_led_template` here. The display_template should
 produce a comma separated string containing four floating point
 numbers corresponding to red, green, blue, and white color settings.
 The template will be continuously evaluated and the LED will be
 automatically set to the resulting colors. One may set
 display_template parameters to use during template evaluation
 (parameters will be parsed as Python literals). If INDEX is not
 specified then all chips in the LED's daisy-chain will be set to the
 template, otherwise only the chip with the given index will be
 updated. If TEMPLATE is an empty string then this command will clear
 any previous template assigned to the LED (one can then use `SET_LED`
 commands to manage the LED's color settings).
 ### [output_pin]
 The following command is available when an
@@ -1099,6 +941,20 @@ Palette 2 once the loading has been completed. This command is the
 same as pressing **Smart Load** directly on the Palette 2 screen after
 the filament load is complete.
 ### [pid_calibrate]
 The pid_calibrate module is automatically loaded if a heater is defined
 in the config file.
 #### PID_CALIBRATE
 `PID_CALIBRATE HEATER=<config_name> TARGET=<temperature>
 [WRITE_FILE=1]`: Perform a PID calibration test. The specified heater
 will be enabled until the specified target temperature is reached, and
 then the heater will be turned off and on for several cycles. If the
 WRITE_FILE parameter is enabled, then the file /tmp/heattest.txt will
 be created with a log of all temperature samples taken during the
 test.
 ### [pause_resume]
 The following commands are available when the
@@ -1124,20 +980,6 @@ the paused state is fresh for each print.
 #### CANCEL_PRINT
 `CANCEL_PRINT`: Cancels the current print.
 ### [pid_calibrate]
 The pid_calibrate module is automatically loaded if a heater is defined
 in the config file.
 #### PID_CALIBRATE
 `PID_CALIBRATE HEATER=<config_name> TARGET=<temperature>
 [WRITE_FILE=1]`: Perform a PID calibration test. The specified heater
 will be enabled until the specified target temperature is reached, and
 then the heater will be turned off and on for several cycles. If the
 WRITE_FILE parameter is enabled, then the file /tmp/heattest.txt will
 be created with a log of all temperature samples taken during the
 test.
 ### [print_stats]
 The print_stats module is automatically loaded.
@@ -1359,9 +1201,8 @@ has been enabled.
 #### SAVE_VARIABLE
 `SAVE_VARIABLE VARIABLE=<name> VALUE=<value>`: Saves the variable to
-disk so that it can be used across restarts. The VARIABLE must be lowercase.
+disk so that it can be used across restarts. All stored variables are
-All stored variables are loaded into the
+loaded into the `printer.save_variables.variables` dict at startup and
 `printer.save_variables.variables` dict at startup and
 can be used in gcode macros. The provided VALUE is parsed as a Python
 literal.
@@ -1505,42 +1346,6 @@ temperature_fan. If a target is not supplied, it is set to the
 specified temperature in the config file. If speeds are not supplied,
 no change is applied.
 ### [temperature_probe]
 The following commands are available when a
 [temperature_probe config section](Config_Reference.md#temperature_probe)
 is enabled.
 #### TEMPERATURE_PROBE_CALIBRATE
 `TEMPERATURE_PROBE_CALIBRATE [PROBE=<probe name>] [TARGET=<value>] [STEP=<value>]`:
 Initiates probe drift calibration for eddy current based probes.  The `TARGET`
 is a target temperature for the last sample.  When the temperature recorded
 during a sample exceeds the `TARGET` calibration will complete.  The `STEP`
 parameter sets temperature delta (in C) between samples. After a sample has
 been taken, this delta is used to schedule a call to `TEMPERATURE_PROBE_NEXT`.
 The default `STEP` is 2.
 #### TEMPERATURE_PROBE_NEXT
 `TEMPERATURE_PROBE_NEXT`: After calibration has started this command is run to
 take the next sample.  It is automatically scheduled to run when the delta
 specified by `STEP` has been reached, however its also possible to manually run
 this command to force a new sample.  This command is only available during
 calibration.
 #### TEMPERATURE_PROBE_COMPLETE:
 `TEMPERATURE_PROBE_COMPLETE`:  Can be used to end calibration and save the
 current result before the `TARGET` temperature is reached.  This command
 is only available during calibration.
 #### ABORT
 `ABORT`:  Aborts the calibration process, discarding the current results.
 This command is only available during drift calibration.
 ### TEMPERATURE_PROBE_ENABLE
 `TEMPERATURE_PROBE_ENABLE ENABLE=[0|1]`: Sets temperature drift
 compensation on or off. If ENABLE is set to 0, drift compensation
 will be disabled, if set to 1 it is enabled.
 ### [tmcXXXX]
 The following commands are available when any of the
@@ -1676,3 +1481,39 @@ independent adjustments to each Z stepper to compensate for tilt. See
 the PROBE command for details on the optional probe parameters. The
 optional `RETRIES`, `RETRY_TOLERANCE`, and `HORIZONTAL_MOVE_Z` values
 override those options specified in the config file.
 ### [temperature_probe]
 The following commands are available when a
 [temperature_probe config section](Config_Reference.md#temperature_probe)
 is enabled.
 #### TEMPERATURE_PROBE_CALIBRATE
 `TEMPERATURE_PROBE_CALIBRATE [PROBE=<probe name>] [TARGET=<value>] [STEP=<value>]`:
 Initiates probe drift calibration for eddy current based probes.  The `TARGET`
 is a target temperature for the last sample.  When the temperature recorded
 during a sample exceeds the `TARGET` calibration will complete.  The `STEP`
 parameter sets temperature delta (in C) between samples. After a sample has
 been taken, this delta is used to schedule a call to `TEMPERATURE_PROBE_NEXT`.
 The default `STEP` is 2.
 #### TEMPERATURE_PROBE_NEXT
 `TEMPERATURE_PROBE_NEXT`: After calibration has started this command is run to
 take the next sample.  It is automatically scheduled to run when the delta
 specified by `STEP` has been reached, however its also possible to manually run
 this command to force a new sample.  This command is only available during
 calibration.
 #### TEMPERATURE_PROBE_COMPLETE:
 `TEMPERATURE_PROBE_COMPLETE`:  Can be used to end calibration and save the
 current result before the `TARGET` temperature is reached.  This command
 is only available during calibration.
 #### ABORT
 `ABORT`:  Aborts the calibration process, discarding the current results.
 This command is only available during drift calibration.
 ### TEMPERATURE_PROBE_ENABLE
 `TEMPERATURE_PROBE_ENABLE ENABLE=[0|1]`: Sets temperature drift
 compensation on or off. If ENABLE is set to 0, drift compensation
 will be disabled, if set to 1 it is enabled.
--- a/docs/Installation.md
+++ b/docs/Installation.md
@@ -1,14 +1,14 @@
 # Installation
-These instructions assume the software will run on a Linux-based host
+These instructions assume the software will run on a linux based host
-running a Klipper-compatible front end. It is recommended that a
+running a Klipper compatible front end. It is recommended that a
-SBC(Small Board Computer) such as a Raspberry Pi or Debian-based Linux
+SBC(Small Board Computer) such as a Raspberry Pi or Debian based Linux
 device be used as the host machine (see the
 [FAQ](FAQ.md#can-i-run-klipper-on-something-other-than-a-raspberry-pi-3)
 for other options).
-For the purposes of these instructions, host relates to the Linux device and
+For the purposes of these instructions host relates to the Linux device and
-mcu relates to the printer board. SBC relates to the term Small Board Computer
+mcu relates to the printboard. SBC relates to the term Small Board Computer
 such as the Raspberry Pi.
 ## Obtain a Klipper Configuration File
@@ -56,13 +56,13 @@ make an informed decision.
 ## Obtaining an OS image for SBC's
 There are many ways to obtain an OS image for Klipper for SBC use, most depend on
-what front end you wish to use. Some manufacturers of these SBC boards also provide
+what front end you wish to use. Some manafactures of these SBC boards also provide
 their own Klipper-centric images.
-The two main Moonraker-based front ends are [Fluidd](https://docs.fluidd.xyz/)
+The two main Moonraker based front ends are [Fluidd](https://docs.fluidd.xyz/)
 and [Mainsail](https://docs.mainsail.xyz/), the latter of which has a premade install
-image ["MainsailOS"](https://docs-os.mainsail.xyz/), this has the option for Raspberry Pi
+image ["MainsailOS"](http://docs.mainsailOS.xyz), this has the option for Raspberry Pi
-and some OrangePi variants.
+and some OrangePi varianta.
 Fluidd can be installed via KIAUH(Klipper Install And Update Helper), which
 is explained below and is a 3rd party installer for all things Klipper.
@@ -73,12 +73,12 @@ process is explained in [OctoPrint.md](OctoPrint.md)
 ## Installing via KIAUH
 Normally you would start with a base image for your SBC, RPiOS Lite for example,
-or in the case of an x86 Linux device, Ubuntu Server. Please note that Desktop
+or in the case of a x86 Linux device, Ubuntu Server. Please note that Desktop
 variants are not recommended due to certain helper programs that can stop some
-Klipper functions from working and even mask access to some printer boards.
+Klipper functions working and even mask access to some print boards.
 KIAUH can be used to install Klipper and its associated programs on a variety
-of Linux-based systems that run a form of Debian. More information can be found
+of Linux based systems that run a form of Debian. More information can be found
 at https://github.com/dw-0/kiauh
 ## Building and flashing the micro-controller
@@ -106,7 +106,7 @@ make
 If the comments at the top of the
 [printer configuration file](#obtain-a-klipper-configuration-file)
 describe custom steps for "flashing" the final image to the printer
-control board, then follow those steps and then proceed to
+control board then follow those steps and then proceed to
 [configuring OctoPrint](#configuring-octoprint-to-use-klipper).
 Otherwise, the following steps are often used to "flash" the printer
@@ -132,31 +132,12 @@ run the command again, the missing item will be your print board(see the
 [FAQ](FAQ.md#wheres-my-serial-port) for more information).
 For common micro-controllers with STM32 or clone chips, LPC chips and
-others, it is usual that these need an initial Klipper flash via SD card.
+others it is usual that these need an initial Klipper flash via SD card.
 When flashing with this method, it is important to make sure that the
 print board is not connected with USB to the host, due to some boards
 being able to feed power back to the board and stopping a flash from
-occurring.
+occuring.
 Please note, that most print boards that use SD cards for flash will
 implement some kind of flash loop protection for when the sd card is left
 in place. There are two common methods:
 Filename Change Required (usually "stock" print boards):
 These boards require the firmware file to have a different name each
 time you flash (for example, firmware1.bin, firmware2.bin, etc.).
 If you reuse the same filename, the board may ignore it and not update.
 Automatic File Renaming (usually aftermarket print boards:
 Other boards allow using the same filename, commonly firmware.bin,
 but after flashing, the board renames the file to firmware.cur.
 This helps indicate the firmware was successfully flashed and prevents
 it from flashing again on the next startup.
 Before flashing, make sure to check which behavior your board follows.
 For common micro-controllers using Atmega chips, for example the 2560,
 the code can be flashed with something
@@ -191,7 +172,7 @@ The next step is to copy the
 the host.
 Arguably the easiest way to set the Klipper configuration file is using the
-built-in editors in Mainsail or Fluidd. These will allow the user to open
+built in editors in Mainsail or Fluidd. These will allow the user to open
 the configuration examples and save them to be printer.cfg.
 Another option is to use a desktop editor that supports editing files
@@ -202,7 +183,7 @@ named "printer.cfg" in the home directory of the pi user
 (ie, /home/pi/printer.cfg).
 Alternatively, one can also copy and edit the file directly on the
-host via SSH. That may look something like the following (be
+host via ssh. That may look something like the following (be
 sure to update the command to use the appropriate printer config
 filename):
@@ -233,9 +214,9 @@ the `[mcu]` section to look something similar to:
 serial: /dev/serial/by-id/usb-1a86_USB2.0-Serial-if00-port0
 ```
-After creating and editing the file, it will be necessary to issue a
+After creating and editing the file it will be necessary to issue a
 "restart" command in the command console to load the config. A
-"status" command will report that the printer is ready if the Klipper
+"status" command will report the printer is ready if the Klipper
 config file is successfully read and the micro-controller is
 successfully found and configured.
@@ -244,10 +225,10 @@ Klipper to report a configuration error. If an error occurs, make any
 necessary corrections to the printer config file and issue "restart"
 until "status" reports the printer is ready.
-Klipper reports error messages via the command console and pop-ups in
+Klipper reports error messages via the command console and via pop up in
 Fluidd and Mainsail. The "status" command can be used to re-report error
-messages. A log is available and usually located at
+messages. A log is available and usually located in ~/printer_data/logs
-`~/printer_data/logs/klippy.log`.
+this is named klippy.log
 After Klipper reports that the printer is ready, proceed to the
 [config check document](Config_checks.md) to perform some basic checks
--- a/docs/Load_Cell.md
+++ b/docs/Load_Cell.md
@@ -1,489 +0,0 @@
 # Load Cells
 This document describes Klipper's support for load cells. Basic load cell
 functionality can be used to read force data and to weigh things like filament.
 A calibrated force sensor is an important part of a load cell based probe.
 ## Related Documentation
 * [load_cell Config Reference](Config_Reference.md#load_cell)
 * [load_cell G-Code Commands](G-Codes.md#load_cell)
 * [load_cell Status Reference](Status_Reference.md#load_cell)
 ## Using `LOAD_CELL_DIAGNOSTIC`
 When you first connect a load cell its good practice to check for issues by
 running `LOAD_CELL_DIAGNOSTIC`. This tool collects 10 seconds of data from the
 load cell and resport statistics:
 ```
 $ LOAD_CELL_DIAGNOSTIC
 // Collecting load cell data for 10 seconds...
 // Samples Collected: 3211
 // Measured samples per second: 332.0
 // Good samples: 3211, Saturated samples: 0, Unique values: 900
 // Sample range: [4.01% to 4.02%]
 // Sample range / sensor capacity: 0.00524%
 ```
 Things you can check with this data:
 * The configured sample rate of the sensor should be close to the 'Measured
  samples per second' value. If it is not you may have a configuration or wiring
  issue.
 * 'Saturated samples' should be 0. If you have saturated samples it means the
  load sell is seeing more force than it can measure.
 * 'Unique values' should be a large percentage of the 'Samples
  Collected' value. If 'Unique values' is 1 it is very likely a wiring issue.
 * Tap or push on the sensor while `LOAD_CELL_DIAGNOSTIC` runs. If
  things are working correctly this should increase the 'Sample range'.
 ## Calibrating a Load Cell
 Load cells are calibrated using the `LOAD_CELL_CALIBRATE` command. This is an
 interactive calibration utility that walks you though a 3 step process:
 1. First use the `TARE` command to establish the zero force value. This is the
   `reference_tare_counts` config value.
 2. Next you apply a known load or force to the load cell and run the
   `CALIBRATE GRAMS=nnn` command. From this the `counts_per_gram` value is
   calculated. See [the next section](#applying-a-known-force-or-load) for some
   suggestions on how to do this.
 3. Finally, use the `ACCEPT` command to save the results.
 You can cancel the calibration process at any time with `ABORT`.
 ### Applying a Known Force or Load
 The `CALIBRATE GRAMS=nnn` step can be accomplished in a number of ways. If your
 load cell is under a platform like a bed or filament holder it might be easiest
 to put a known mass on the platform. E.g. you could use a couple of 1KG filament
 spools.
 If your load cell is in the printer's toolhead a different approach is easier.
 Put a digital scale on the printers bed and gently lower the toolhead onto the
 scale (or raise the bed into the toolhead if your bed moves). You may be able to
 do this using the `FORCE_MOVE` command. But more likely you will have to
 manually moving the z axis with the motors off until the toolhead presses on the
 scale.
 A good calibration force would ideally be a large percentage of the load cell's
 rated capacity. E.g. if you have a 5Kg load cell you would ideally calibrate it
 with a 5kg mass. This might work well with under-bed sensors that have to
 support a lot of weight. For toolhead probes this may not be a load that your
 printer bed or toolhead can tolerate without damage. Do try to use at least 1Kg
 of force, most printers should tolerate this without issue.
 When calibrating make careful note of the values reported:
 ```
 $ CALIBRATE GRAMS=555
 // Calibration value: -2.78% (-59803108), Counts/gram: 73039.78739,
 Total capacity: +/- 29.14Kg
 ```
 The `Total capacity` should be close to the theoretical rating of the load cell
 based on the sensor's capacity. If it is much larger you could have used a
 higher gain setting in the sensor or a more sensitive load cell. This isn't as
 critical for 32bit and 24bit sensors but is much more critical for low bit width
 sensors.
 ## Reading Force Data
 Force data can be read with a GCode command:
 ```
 LOAD_CELL_READ
 // 10.6g (1.94%)
 ```
 Data is also continuously read and can be consumed from the load_cell printer
 object in a macro:
 ```
 {% set grams = printer.load_cell.force_g %}
 ```
 This provides an average force over the last 1 second, similar to how
 temperature sensors work.
 ## Taring a Load Cell
 Taring, sometimes called zeroing, sets the current weight reported by the
 load_cell to 0. This is useful for measuring relative to a known weight. e.g.
 when measuring a filament spool, using `LOAD_CELL_TARE` sets the weight to 0.
 Then as filament is printed the load_cell will report the weight of the
 filament used.
 ```
 LOAD_CELL_TARE
 // Load cell tare value: 5.32% (445903)
 ```
 The current tare value is reported in the printers status and can be read in
 a macro:
 ```
 {% set tare_counts = printer.load_cell.tare_counts %}
 ```
 # Load Cell Probes
 ## Related Documentation
 * [load_cell_probe Config Reference](Config_Reference.md#load_cell_probe)
 * [load_cell_probe G-Code Commands](G-Codes.md#load_cell_probe)
 * [load_cell_probe Statuc Reference](Status_Reference.md#load_cell_probe)
 ## Load Cell Probe Safety
 Because load cells are a direct nozzle contact probe there is a risk of
 damage to your printer if too much force is used. The load cell probing system
 includes a number of safety checks that try to keep your machine safe from
 excessive force to the toolhead. It's important to understand what they are
 and how they work as you can defeat most of them with poorly chosen config
 values.
 #### Calibration Check
 Every time a homing move starts, load_cell_probe checks
 that the load_cell is calibrated. If not it will stop the move with an error:
 `!! Load Cell not calibrated`.
 #### `counts_per_gram`
 This setting is used to convert raw sensor counts into grams. All the safety
 limits are in gram units for your convenience. If the `counts_per_gram`
 setting is not accurate you can easily exceed the safe force on the toolhead.
 You should never guess this value. Use `LOAD_CELL_CALIBRATE` to find your load
 cells actual `counts_per_gram`.
 #### `trigger_force`
 This is the force in grams that triggers the endstop to halt the homing move.
 When a homing move starts the endstop tares itself with the current reading
 from the load cell. `trigger_force` is measured from that tare value. There is
 always some overshoot of this value when the probe collides with the bed,
 so be conservative. e.g. a setting of 100g could result in 350g of peak force
 before the toolhead stops. This overshoot will increase with faster probing
 `speed`, a low ADC sample rate or [multi MCU homing](Multi_MCU_Homing.md).
 #### `reference_tare_counts`
 This is the baseline tare value that is set by `LOAD_CELL_CALIBRATE`.
 This value works with `force_safety_limit` to limit the maximum force on the
 toolhead.
 #### `force_safety_limit`
 This is the maximum absolute force, relative to `reference_tare_counts`,
 that the probe will allow while homing or probing. If the MCU sees this
 force exceeded it will shut down the printer with the error `!! Load cell
 endstop: too much force!`. There are a number of ways this can be triggered:
 The first risk this protects against is picking too large of a value for
 `drift_filter_cutoff_frequency`. This can cause the drift filter to filter out
 a probe event and continue the homing move. If this happens the
 `force_safety_limit` acts as a backup protection.
 The second problem is probing repeatedly in one place. Klipper does not retract
 the probe when doing a single `PROBE` command. This can result
 in force applied to the toolhead at the end of a probing cycle. Because
 external forces can vary greatly between probing locations,
 `load_cell_probe` performs a tare before beginning each probe. If you repeat
 the `PROBE` command, load_cell_probe will tare the endstop at the current force.
 Multiple cycles of this will result in ever-increasing force on the toolhead.
 `force_safety_limit` stops this cycle from running out of control.
 Another way this run-away can happen is damage to a strain gauge. If the metal
 part is permanently bent it will change the `reference_tare_counts` of the
 device. This puts the starting tare value much closer to the limit making it
 more likely to be violated. You want to be notified if this is happening
 because your hardware has been permanently damaged.
 The final way this can be triggered is due to temperature changes. If your
 strain gauges are heated their `reference_tare_counts` may be very different
 at ambient temperature vs operating temperature. In this case you may need
 to increase the `force_safety_limit` to allow for thermal changes.
 #### Load Cell Endstop Watchdog Task
 When homing the load_cell_endstop starts a task on the MCU to trac
 measurements arriving from the sensor. If the sensor fails to send
 measurements for 2 sample periods the watchdog will shut down the printer
 with an error `!! LoadCell Endstop timed out waiting on ADC data`.
 If this happens, the most likely cause is a fault from the ADC. Inadequate
 grounding of your printer can be the root cause. The frame, power supply
 case and pint bed should all be connected to ground. You may need to ground
 the frame in multiple places. Anodized aluminum extrusions do not conduct
 electricity well. You might need to sand the area where the grounding wire
 is attached to make good electrical contact.
 ## Load Cell Probe Setup
 This section covers the process for commissioning a load cell probe.
 ### Verify the Load Cell First
 A `[load_cell_probe]` is also a `[load_cell]` and G-code commands related to
 `[load_cell]` work with `[load_cell_probe]`. Before attempting to use a load
 cell probe, follow the directions for
 [calibrating the load cell](Load_Cell.md#calibrating-a-load-cell) with
 `CALIBRATE_LOAD_CELL` and checking its operation with `LOAD_CELL_DIAGNOSTIC`.
 ### Verify Probe Operation With LOAD_CELL_TEST_TAP
 Use the command `LOAD_CELL_TEST_TAP` to test the operation of the load cell
 probe before actually trying to probe with it. This command detects taps,
 just like the PROBE command, but it does not move the z axis. By default, it
 listens for 3 taps before ending the test. You have 30 seconds to do each
 tap, if no taps are detected the command will time out.
 If this test fails, check your configuration and `LOAD_CELL_DIAGNOSTIC`
 carefully to look for issues.
 Load cell probes don't support the `QUERY_ENDSTOPS` or `QUERY_PROBE`
 commands. Use `LOAD_CELL_TEST_TAP` for testing functionality before probing.
 ### Homing Macros
 Load cell probe is not an endstop and doesn't support `endstop:
 prove:z_virtual_endstop`. For the time being you'll need to configure your z
 axis with an MCU pin as its endstop. You won't actually be using the pin but
 for the time being you have to configure something.
 To home the axis with just the probe you need to set up a custom homing
 macro. This requires setting up
 [homing_override](Config_Reference.md#homing_override).
 Here is a simple macro that can accomplish this. Note that the
 `_HOME_Z_FROM_LAST_PROBE` macro has to be separate because of the way macros
 work. The sub-call is needed so that the `_HOME_Z_FROM_LAST_PROBE` macro can
 see the result of the probe in `printer.probe.last_z_result`.
 ```gcode
 [gcode_macro _HOME_Z_FROM_LAST_PROBE]
 gcode:
    {% set z_probed = printer.probe.last_z_result %}
    {% set z_position = printer.toolhead.position[2] %}
    {% set z_actual = z_position - z_probed %}
    SET_KINEMATIC_POSITION Z={z_actual}
 [gcode_macro _HOME_Z]
 gcode:
    SET_GCODE_OFFSET Z=0  # load cell probes dont need a Z offset
    # position toolhead for homing Z, edit for your printers size
    #G90  # absolute move
    #G1 Y50 X50 F{5 * 60}  # move to X/Y position for homing
    # soft home the z axis to its limit so it can be moved:
    SET_KINEMATIC_POSITION Z={printer.toolhead.axis_maximum[2]}
    # Fast approach and tap
    PROBE PROBE_SPEED={5 * 60}  # override the speed for faster homing
    _HOME_Z_FROM_LAST_PROBE
    # lift z to 2mm
    G91  # relative move
    G1 Z2 F{5 * 60}
    # probe at standard speed
    PROBE
    _HOME_Z_FROM_LAST_PROBE
    # lift z to 10mm for clearance
    G91  # relative move
    G1 Z10 F{5 * 60}
 ```
 ### Suggested Probing Temperature
 Currently, we suggest keeping the nozzle temperature below the level that causes
 the filament to ooze while homing and probing. 140C is a good starting
 point. This temperature is also low enough not to scar PEI build surfaces.
 Fouling of the nozzle and the print bed due to oozing filament is the #1 source
 of probing error with the load cell probe. Klipper does not yet have a universal
 way to detect poor quality taps due to filament ooze. The existing code may
 decide that a tap is valid when it is of poor quality. Classifying these poor
 quality taps is an area of active research.
 Klipper also lacks support for re-locating a probe point if the
 location has become fouled by filament ooze. Modules like `quad_gantry_level`
 will repeatedly probe the same coordinates even if a probe previously failed
 there.
 Give the above it is strongly suggested not to probe at printing temperatures.
 ### Hot Nozzle Protection
 The Voron project has a great macro for protecting your print surface from the
 hot nozzle. See [Voron Tap's
 `activate_gcode`](https://github.com/VoronDesign/Voron-Tap/blob/main/config/tap_klipper_instructions.md)
 It is highly suggested to add something like this to your config.
 ### Nozzle Cleaning
 Before probing the nozzle should be clean. You could do this manually before
 every print. You can also implement a nozzle scrubber and automate the process.
 Here is a suggested sequence:
 1. Wait for the nozzle to heat up to probing temp (e.g. `M109 S140`)
 1. Home the machine (`G28`)
 1. Scrub the nozzle on a brush
 1. Heat soak the print bed
 1. Perform probing tasks: QGL, bed mesh etc.
 ### Temperature Compensation for Nozzle Growth
 If you are probing at a safe temperature, the nozzle will expand after
 heating to printing temperatures. This will cause the nozzle to get longer
 and closer to the print surface. You can compensate for this with
 [[z_thermal_adjust]](Config_Reference.md#z_thermal_adjust). This adjustment will
 work across a range of printing
 temperatures from PLA to PC.
 #### Calculating the `temp_coeff` for `[z_thermal_adjust]`
 The easiest way to do this is to measure at 2 different temperatures.
 Ideally these should be the upper and lower limits of the printing
 temperature range. E.g. 180C and 290C. You can perform a `PROBE_ACCURACY` at
 both temperatures and then calculate the difference of the `average z` at both.
 The adjustment value is the change in nozzle length divided by the change in
 temperature. e.g.
 ```
 temp_coeff = -0.05 / (290 - 180) = -0.00045455
 ```
 The expected result is a negative number. Positive values for `temp_coeff` move
 the nozzle closer to the bed and negative values move it further away.
 Expect to have to move the nozzle further away as it gets longer when hot.
 #### Configure `[z_thermal_adjust]`
 Set up z_thermal_adjust to reference the `extruder` as the source of temperature
 data. E.g.:
 ```
 [z_thermal_adjust nozzle]
 temp_coeff=-0.00045455
 sensor_type: temperature_combined
 sensor_list: extruder
 combination_method: max
 min_temp: 0
 max_temp: 400
 max_z_adjustment: 0.1
 ```
 ## Continuous Tare Filters for Toolhead Load Cells
 Klipper implements a configurable IIR filter on the MCU to provide continuous
 tareing of the load cell while probing. Continuous taring means the 0 value
 moves with drift caused by external factors like bowden tubes and thermal
 changes. This is aimed at toolhead sensors and moving beds that experience lots
 of external forces that change while probing.
 ### Installing SciPy
 The filtering code uses the excellent [SciPy](https://scipy.org/) library to
 compute the filter coefficients based on the values your enter into the config.
 Pre-compiled SciPi builds are available for Python 3 on 32 bit Raspberry Pi
 systems. 32 bit + Python 3 is strongly recommended because it will streamline
 your installation experience. It does work with Python 2 but installation can
 take 30+ minutes and require installing additional tools.
 ```bash
 ~/klippy-env/bin/pip install scipy
 ```
 ### Filter Workbench
 The filter parameters should be selected based on drift seen on the printer
 during normal operation. A Jupyter notebook is provided in scripts,
 [filter_workbench.ipynb](../scripts/filter_workbench.ipynb), to perform a
 detailed investigation with real captured data and FFTs.
 ### Filtering Suggestions
 For those just trying to get a filter working follow these suggestions:
 * The only essential option is `drift_filter_cutoff_frequency`. A conservative
  starting value is `0.5`Hz. Prusa shipped the MK4 with a setting of `0.8`Hz and
  the XL with `11.2`Hz. This is probably a safe range to experiment with. This
  value should be increased only until normal drift due to bowden tube force is
  eliminated. Setting this value too high will result in slow triggering and
  excess force going through the toolhead.
 * Keep `trigger_force` low. The default is `75`g. The drift filter keeps the
  internal grams value very close to 0 so a large trigger force is not needed.
 * Keep `force_safety_limit` to a conservative value. The default value is 2Kg
  and should keep your toolhead safe while experimenting. If you hit this limit
  the `drift_filter_cutoff_frequency` value may be too high.
 ## Suggestions for Load Cell Tool Boards
 This section covers suggestions for those developing toolhead boards that want
 to support [load_cell_probe]
 ### ADC Sensor Selection & Board Development Hints
 Ideally a sensor would meet these criteria:
 * At least 24 bits wide
 * Use SPI communications
 * Has a pin can be used to indicate sample ready without SPI communications.
  This is often called the "data ready" or "DRDY" pin. Checking a pin is much
  faster than running an SPI query.
 * Has a programmable gain amplifier gain setting of 128. This should eliminate
  the need for a separate amplifier.
 * Indicates via SPI if the sensor has been reset. Detecting resets avoids
  timing errors in homing and using noisy data at startup. It can also help
  users
  track down wiring and grounding issues.
 * A selectable sample rate between 350Hz and 2Khz. Very high sample rates don't
  turn out to be beneficial in our 3D printers because they produce so much
  noise
  when moving fast. Sample rates below 250Hz will require slower probing speeds.
  They also increase the force on the toolhead due to longer delays between
  measurements. E.g. a 500Hz sensor moving at 5mm/s has the same safety factor
  as
  a 100Hz sensor moving at only 1mm/s.
 * If designing for under-bed applications, and you want to sense multiple load
  cells, use a chip that can sample all of its inputs simultaneously. Multiplex
  ADCs that require switching channels have a settling of several samples after
  each channel switch making them unsuitable for probing applications.
 Implementing support for a new sensor chip is not particularly difficult with
 Klipper's `bulk_sensor` and `load_cell_endstop` infrastructure.
 ### 5V Power Filtering
 It is strongly suggested to use larger capacitors than specified by the ADC chip
 manufacturer. ADC chips are usually targeted at low noise environments, like
 battery powered devices. Sensor manufacturers suggested application notes
 generally assume a quiet power supply. Treat their suggested capacitor values as
 minimums.
 3D printers put huge amounts of noise onto the 5V bus and this can ruin the
 sensor's accuracy. Test the sensor on the board with a typical 3D printer power
 supply and active stepper drivers before deciding on smoothing capacitor sizes.
 ### Grounding & Ground Planes
 Analog ADC chips contain components that are very vulnerable to noise and
 ESD. A large ground plane on the first board layer under the chip can help with
 noise. Keep the chip away from power sections and DC to DC converters. The board
 should have proper grounding back to the DC supply.
 ### HX711 and HX717 Notes
 This sensor is popular because of its low cost and availability in the
 supply chain. However, this is a sensor with some drawbacks:
 * The HX71x sensors use bit-bang communication which has a high overhead on the
  MCU. Using a sensor that communicates via SPI would save resources on the tool
  board's CPU.
 * The HX71x lacks a way to communicate reset events to the MCU. Klipper detects
  resets with a timing heuristic but this is not ideal. Resets indicate a
  problem with wiring or grounding.
 * For probing applications the HX717 version is strongly preferred because
  of its higher sample rate (320 vs 80). Probing speed on the HX711 should be
  limited to less than 2mm/s.
 * The sample rate on the HX71x cannot be set from klipper's config. If you have
  the 10SPS version of the sensor (which is widely distributed) it needs to
  be physically re-wired to run at 80SPS.
--- a/docs/Measuring_Resonances.md
+++ b/docs/Measuring_Resonances.md
@@ -18,9 +18,9 @@ board designs and different clones of them. If it is going to be connected to a
 For ADXL345s, make sure that the board supports SPI mode (a small number of
 boards appear to be hard-configured for I2C by pulling SDO to GND).
-For MPU-9250/MPU-9255/MPU-6515/MPU-6050/MPU-6500/ICM20948s and LIS2DW/LIS3DH there
+For MPU-9250/MPU-9255/MPU-6515/MPU-6050/MPU-6500s and LIS2DW/LIS3DH there are also
-are also a variety of board designs and clones with different I2C pull-up resistors
+a variety of board designs and clones with different I2C pull-up resistors which
-which will need supplementing.
+will need supplementing.
 ## MCUs with Klipper I2C *fast-mode* Support
@@ -136,7 +136,7 @@ GND+SCL
 Note that unlike a cable shield, any GND(s) should be connected at both ends.
-#### MPU-9250/MPU-9255/MPU-6515/MPU-6050/MPU-6500/ICM20948
+#### MPU-9250/MPU-9255/MPU-6515/MPU-6050/MPU-6500
 These accelerometers have been tested to work over I2C on the RPi, RP2040 (Pico)
 and AVR at 400kbit/s (*fast mode*). Some MPU accelerometer modules include
@@ -152,7 +152,7 @@ Recommended connection scheme for I2C on the Raspberry Pi:
 | SDA | 03 | GPIO02 (SDA1) |
 | SCL | 05 | GPIO03 (SCL1) |
-The RPi has built-in 1.8K pull-ups on both SCL and SDA.
+The RPi has buit-in 1.8K pull-ups on both SCL and SDA.
 ![MPU-9250 connected to Pi](img/mpu9250-PI-fritzing.png)
@@ -355,7 +355,6 @@ accel_chip: mpu9250
 probe_points:
    100, 100, 20  # an example
 ```
 If you are using the ICM20948, replace instances of "mpu9250" with "icm20948".
 #### Configure MPU-9520 Compatibles With Pico
@@ -378,7 +377,6 @@ probe_points:
 [static_digital_output pico_3V3pwm] # Improve power stability
 pins: pico:gpio23
 ```
 If you are using the ICM20948, replace instances of "mpu9250" with "icm20948".
 #### Configure MPU-9520 Compatibles with AVR
@@ -397,7 +395,6 @@ accel_chip: mpu9250
 probe_points:
    100, 100, 20  # an example
 ```
 If you are using the ICM20948, replace instances of "mpu9250" with "icm20948".
 Restart Klipper via the `RESTART` command.
--- a/docs/Overview.md
+++ b/docs/Overview.md
@@ -101,4 +101,3 @@ communication with the Klipper developers.
 - [TSL1401CL filament width sensor](TSL1401CL_Filament_Width_Sensor.md)
 - [Hall filament width sensor](Hall_Filament_Width_Sensor.md)
 - [Eddy Current Inductive probe](Eddy_Probe.md)
 - [Load Cells](Load_Cell.md)
--- a/docs/Pressure_Advance.md
+++ b/docs/Pressure_Advance.md
@@ -22,7 +22,7 @@ Use a slicer to generate g-code for the large hollow square found in
 [docs/prints/square_tower.stl](prints/square_tower.stl). Use a high
 speed (eg, 100mm/s), zero infill, and a coarse layer height (the layer
 height should be around 75% of the nozzle diameter). Make sure any
-"dynamic acceleration control" and "scarf joint" seams are disabled in the slicer.
+"dynamic acceleration control" is disabled in the slicer.
 Prepare for the test by issuing the following G-Code command:
 ```
--- a/docs/Releases.md
+++ b/docs/Releases.md
@@ -3,35 +3,6 @@
 History of Klipper releases. Please see
 [installation](Installation.md) for information on installing Klipper.
 ## Klipper 0.13.0
 Available on 20250411. Major changes in this release:
 * New "sweeping vibrations" resonance testing mechanism for input
  shaper.
 * Fans and GPIO pins can now be assigned a formula (via Jinja2
  "templates").
 * The bed_mesh code now supports "adaptive bed mesh". The area probed
  can be adjusted for the size of the print.
 * A new `minimum_cruise_ratio` kinematic parameter has been added (it
  replaces the previous `max_accel_to_decel` parameter).
 * Several new sensors added:
  * Support for ldc1612 "eddy" current sensors. This includes probing
    support, fast "scan" probing, and temperature calibration.
  * New support for "load cell" measurements. Support for connecting
    these load cells to hx71x and ads1220 ADC sensors.
  * Support for BMP180, BMP388, and SHT3x temperature sensors. Support
    for measuring temperature with ADS1x1x ADC chips.
  * New lis3dh and icm20948 accelerometer support.
  * Support for mt6816 and mt6826s "hall angle" sensors.
 * New micro-controller improvements:
  * New support for rp2350 micro-controllers.
  * Existing rp2040 chips now run at 200MHz (up from 125Mhz).
  * The micro-controller code can now define many more commands (up to
    16384 from 128).
 * Other modules added: aip31068_spi, canbus_stats, error_mcu,
  garbage_collection, pwm_cycle_time, pwm_tool, garbage_collection.
 * Several bug fixes and code cleanups.
 ## Klipper 0.12.0
 Available on 20231110. Major changes in this release:
--- a/docs/Skew_Correction.md
+++ b/docs/Skew_Correction.md
@@ -31,7 +31,7 @@ AD do not include the flats on the corners that some test objects provide.
 ## Configure your skew
 Make sure `[skew_correction]` is in printer.cfg.  You may now use the `SET_SKEW`
-gcode to configure skew_correction.  For example, if your measured lengths
+gcode to configure skew_correcton.  For example, if your measured lengths
 along XY are as follows:
 ```
--- a/docs/Slicers.md
+++ b/docs/Slicers.md
@@ -121,5 +121,5 @@ M104 S0
 before the macro call. Also note that SuperSlicer has a
 "custom gcode only" button option, which achieves the same outcome.
-An example of a START_PRINT macro using these parameters can
+An example of a START_PRINT macro using these paramaters can
 be found in config/sample-macros.cfg
--- a/docs/Status_Reference.md
+++ b/docs/Status_Reference.md
@@ -31,7 +31,7 @@ The following information is available in the
 ## bed_screws
 The following information is available in the
-[bed_screws](Config_Reference.md#bed_screws) object:
+`Config_Reference.md#bed_screws` object:
 - `is_active`: Returns True if the bed screws adjustment tool is currently
 active.
 - `state`: The bed screws adjustment tool state. It is one of
@@ -39,27 +39,6 @@ the following strings: "adjust", "fine".
 - `current_screw`: The index for the current screw being adjusted.
 - `accepted_screws`: The number of accepted screws.
 ## canbus_stats
 The following information is available in the `canbus_stats
 some_mcu_name` object (this object is automatically available if an
 mcu is configured to use canbus):
 - `rx_error`: The number of receive errors detected by the
  micro-controller canbus hardware.
 - `tx_error`: The number of transmit errors detected by the
  micro-controller canbus hardware.
 - `tx_retries`: The number of transmit attempts that were retried due
  to bus contention or errors.
 - `bus_state`: The status of the interface (typically "active" for a
  bus in normal operation, "warn" for a bus with recent errors,
  "passive" for a bus that will no longer transmit canbus error
  frames, or "off" for a bus that will no longer transmit or receive
  messages).
 Note that only the rp2XXX micro-controllers report a non-zero
 `tx_retries` field and the rp2XXX micro-controllers always report
 `tx_error` as zero and `bus_state` as "active".
 ## configfile
 The following information is available in the `configfile` object
@@ -242,8 +221,6 @@ The following information is available in the `gcode_move` object
 The following information is available in the
 [hall_filament_width_sensor](Config_Reference.md#hall_filament_width_sensor)
 object:
 - all items from
  [filament_switch_sensor](Status_Reference.md#filament_switch_sensor)
 - `is_active`: Returns True if the sensor is currently active.
 - `Diameter`: The last reading from the sensor in mm.
 - `Raw`: The last raw ADC reading from the sensor.
@@ -291,9 +268,6 @@ is always available):
 - `printing_time`: The amount of time (in seconds) the printer has
  been in the "Printing" state (as tracked by the idle_timeout
  module).
 - `idle_timeout`: The current 'timeout' (in seconds)
   to wait for the gcode to be triggered.
   (as set by [SET_IDLE_TIMEOUT](G-Codes.md#set_idle_timeout))
 ## led
@@ -303,31 +277,11 @@ The following information is available for each `[led led_name]`,
 - `color_data`: A list of color lists containing the RGBW values for a
  led in the chain. Each value is represented as a float from 0.0 to
  1.0. Each color list contains 4 items (red, green, blue, white) even
-  if the underlying LED supports fewer color channels. For example,
+  if the underyling LED supports fewer color channels. For example,
  the blue value (3rd item in color list) of the second neopixel in a
  chain could be accessed at
  `printer["neopixel <config_name>"].color_data[1][2]`.
 ## load_cell
 The following information is available for each `[load_cell name]`:
 - 'is_calibrated': True/False is the load cell calibrated
 - 'counts_per_gram': The number of raw sensor counts that equals 1 gram of force
 - 'reference_tare_counts': The reference number of raw sensor counts for 0 force
 - 'tare_counts': The current number of raw sensor counts for 0 force
 - 'force_g': The force in grams, averaged over the last polling period.
 - 'min_force_g': The minimum force in grams, over the last polling period.
 - 'max_force_g': The maximum force in grams, over the last polling period.
 ## load_cell_probe
 The following information is available for `[load_cell_probe]`:
 - all items from [load_cell](Status_Reference.md#load_cell)
 - all items from [probe](Status_Reference.md#probe)
 - 'endstop_tare_counts': the load cell probe keeps a tare value independent of
 the load cell. This re-set at the start of each probe.
 - 'last_trigger_time': timestamp of the last homing trigger
 ## manual_probe
 The following information is available in the
@@ -472,12 +426,6 @@ The following information is available in
 - `printer["servo <config_name>"].value`: The last setting of the PWM
  pin (a value between 0.0 and 1.0) associated with the servo.
 ## skew_correction.py
 The following information is available in the `skew_correction` object (this
 object is available if any skew_correction is defined):
 - `current_profile_name`: Returns the name of the currently loaded SKEW_PROFILE.
 ## stepper_enable
 The following information is available in the `stepper_enable` object (this
@@ -582,12 +530,6 @@ on a cartesian, hybrid_corexy or hybrid_corexz robot
 - `carriage_1`: The mode of the carriage 1. Possible values are:
  "INACTIVE", "PRIMARY", "COPY", and "MIRROR".
 On a `generic_cartesian` kinematic, the following information is
 available in `dual_carriage`:
 - `carriages["<carriage>"]`: The mode of the carriage `<carriage>`. Possible
  values are "INACTIVE" and "PRIMARY" for the primary carriage and "INACTIVE",
  "PRIMARY", "COPY", and "MIRROR" for the dual carriage.
 ## virtual_sdcard
 The following information is available in the
--- a/docs/TMC_Drivers.md
+++ b/docs/TMC_Drivers.md
@@ -83,10 +83,6 @@ setting `stealthchop_threshold` to 999999). Unfortunately, the drivers
 often produce poor and confusing results if the mode changes while the
 motor is at a non-zero velocity.
 Note that the `stealthchop_threshold` config option does not impact
 sensorless homing as Klipper automatically switches the TMC driver to
 an appropriate mode during sensorless homing operations.
 ## TMC interpolate setting introduces small position deviation
 The TMC driver `interpolate` setting may reduce the audible noise of
--- a/docs/_klipper3d/README
+++ b/docs/_klipper3d/README
@@ -8,13 +8,13 @@ directory, the docs/CNAME file also controls the website generation.
 To test deploy the main English site locally one can use commands
 similar to the following:
-virtualenv ~/mkdocs-env && ~/mkdocs-env/bin/pip install -r ~/klipper/docs/_klipper3d/mkdocs-requirements.txt
+virtualenv ~/mkdocs-env && ~/python-env/bin/pip install -r ~/klipper/docs/_klipper3d/mkdocs-requirements.txt
 cd ~/klipper && ~/mkdocs-env/bin/mkdocs serve --config-file ~/klipper/docs/_klipper3d/mkdocs.yml -a 0.0.0.0:8000
 To test deploy the multi-language site locally one can use commands
 similar to the following:
-virtualenv ~/mkdocs-env && ~/mkdocs-env/bin/pip install -r ~/klipper/docs/_klipper3d/mkdocs-requirements.txt
+virtualenv ~/mkdocs-env && ~/python-env/bin/pip install -r ~/klipper/docs/_klipper3d/mkdocs-requirements.txt
 source ~/mkdocs-env/bin/activate
 cd ~/klipper && ./docs/_klipper3d/build-translations.sh
 cd ~/klipper/site/ && python3 -m http.server 8000
--- a/docs/_klipper3d/mkdocs-requirements.txt
+++ b/docs/_klipper3d/mkdocs-requirements.txt
@@ -1,5 +1,5 @@
 # Python virtualenv module requirements for mkdocs
-jinja2==3.1.6
+jinja2==3.1.4
 mkdocs==1.2.4
 mkdocs-material==8.1.3
 mkdocs-simple-hooks==0.1.3
--- a/docs/_klipper3d/mkdocs.yml
+++ b/docs/_klipper3d/mkdocs.yml
@@ -141,5 +141,4 @@ nav:
    - TSL1401CL_Filament_Width_Sensor.md
    - Hall_Filament_Width_Sensor.md
    - Eddy_Probe.md
    - Load_Cell.md
  - Sponsors.md
--- a/docs/index.md
+++ b/docs/index.md
@@ -8,12 +8,14 @@ title: Welcome
 The Klipper firmware controls 3d-Printers. It combines the power of a
 general purpose computer with one or more micro-controllers. See the
-[features document](Features.md) for more information on why you
+[features document](https://www.klipper3d.org/Features.html) for more
-should use the Klipper software.
+information on why you should use the Klipper software.
-Start by [installing Klipper software](Installation.md).
+Start by [installing Klipper software](https://www.klipper3d.org/Installation.html).
 Klipper software is Free Software. Read the
-[documentation](Overview.md), see the [license](../COPYING), or
+[documentation](https://www.klipper3d.org/Overview.html), see the
 [license](COPYING), or
 [download](https://github.com/Klipper3d/Klipper) the software. We
-depend on the generous support from our [sponsors](Sponsors.md).
+depend on the generous support from our
 [sponsors](https://www.klipper3d.org/Sponsors.html).
--- a/klippy/chelper/init.py
+++ b/klippy/chelper/init.py
@@ -17,16 +17,16 @@ COMPILE_ARGS = ("-Wall -g -O2 -shared -fPIC"
                " -o %s %s")
 SSE_FLAGS = "-mfpmath=sse -msse2"
 SOURCE_FILES = [
-    'pyhelper.c', 'serialqueue.c', 'stepcompress.c', 'steppersync.c',
+    'pyhelper.c', 'serialqueue.c', 'stepcompress.c', 'itersolve.c', 'trapq.c',
-    'itersolve.c', 'trapq.c', 'pollreactor.c', 'msgblock.c', 'trdispatch.c',
+    'pollreactor.c', 'msgblock.c', 'trdispatch.c',
    'kin_cartesian.c', 'kin_corexy.c', 'kin_corexz.c', 'kin_delta.c',
    'kin_deltesian.c', 'kin_polar.c', 'kin_rotary_delta.c', 'kin_winch.c',
-    'kin_extruder.c', 'kin_shaper.c', 'kin_idex.c', 'kin_generic.c'
+    'kin_extruder.c', 'kin_shaper.c', 'kin_idex.c',
 ]
 DEST_LIB = "c_helper.so"
 OTHER_FILES = [
-    'list.h', 'serialqueue.h', 'stepcompress.h', 'steppersync.h',
+    'list.h', 'serialqueue.h', 'stepcompress.h', 'itersolve.h', 'pyhelper.h',
-    'itersolve.h', 'pyhelper.h', 'trapq.h', 'pollreactor.h', 'msgblock.h'
+    'trapq.h', 'pollreactor.h', 'msgblock.h'
 ]
 defs_stepcompress = """
@@ -54,28 +54,25 @@ defs_stepcompress = """
    int stepcompress_extract_old(struct stepcompress *sc
        , struct pull_history_steps *p, int max
        , uint64_t start_clock, uint64_t end_clock);
    void stepcompress_set_stepper_kinematics(struct stepcompress *sc
        , struct stepper_kinematics *sk);
 """
 defs_steppersync = """
    struct steppersync *steppersync_alloc(struct serialqueue *sq
        , struct stepcompress **sc_list, int sc_num, int move_num);
    void steppersync_free(struct steppersync *ss);
    void steppersync_set_time(struct steppersync *ss
        , double time_offset, double mcu_freq);
-    int32_t steppersync_generate_steps(struct steppersync *ss
+    int steppersync_flush(struct steppersync *ss, uint64_t move_clock
-        , double gen_steps_time, uint64_t flush_clock);
+        , uint64_t clear_history_clock);
    void steppersync_history_expire(struct steppersync *ss, uint64_t end_clock);
    int steppersync_flush(struct steppersync *ss, uint64_t move_clock);
 """
 defs_itersolve = """
    int32_t itersolve_generate_steps(struct stepper_kinematics *sk
        , double flush_time);
    double itersolve_check_active(struct stepper_kinematics *sk
        , double flush_time);
    int32_t itersolve_is_active_axis(struct stepper_kinematics *sk, char axis);
-    void itersolve_set_trapq(struct stepper_kinematics *sk, struct trapq *tq
+    void itersolve_set_trapq(struct stepper_kinematics *sk, struct trapq *tq);
-        , double step_dist);
+    void itersolve_set_stepcompress(struct stepper_kinematics *sk
        , struct stepcompress *sc, double step_dist);
    double itersolve_calc_position_from_coord(struct stepper_kinematics *sk
        , double x, double y, double z);
    void itersolve_set_position(struct stepper_kinematics *sk
@@ -109,12 +106,6 @@ defs_trapq = """
 defs_kin_cartesian = """
    struct stepper_kinematics *cartesian_stepper_alloc(char axis);
 """
 defs_kin_generic_cartesian = """
    struct stepper_kinematics *generic_cartesian_stepper_alloc(double a_x
        , double a_y, double a_z);
    void generic_cartesian_stepper_set_coeffs(struct stepper_kinematics *sk
        , double a_x, double a_y, double a_z);
 """
 defs_kin_corexy = """
    struct stepper_kinematics *corexy_stepper_alloc(char type);
@@ -163,7 +154,6 @@ defs_kin_shaper = """
        , int n, double a[], double t[]);
    int input_shaper_set_sk(struct stepper_kinematics *sk
        , struct stepper_kinematics *orig_sk);
    void input_shaper_update_sk(struct stepper_kinematics *sk);
    struct stepper_kinematics * input_shaper_alloc(void);
 """
@@ -185,7 +175,7 @@ defs_serialqueue = """
    };
    struct serialqueue *serialqueue_alloc(int serial_fd, char serial_fd_type
-        , int client_id, char name[16]);
+        , int client_id);
    void serialqueue_exit(struct serialqueue *sq);
    void serialqueue_free(struct serialqueue *sq);
    struct command_queue *serialqueue_alloc_commandqueue(void);
@@ -222,7 +212,6 @@ defs_trdispatch = """
 defs_pyhelper = """
    void set_python_logging_callback(void (*func)(const char *));
    double get_monotonic(void);
    int set_thread_name(char name[16]);
 """
 defs_std = """
@@ -231,11 +220,10 @@ defs_std = """
 defs_all = [
    defs_pyhelper, defs_serialqueue, defs_std, defs_stepcompress,
-    defs_steppersync, defs_itersolve, defs_trapq, defs_trdispatch,
+    defs_itersolve, defs_trapq, defs_trdispatch,
    defs_kin_cartesian, defs_kin_corexy, defs_kin_corexz, defs_kin_delta,
    defs_kin_deltesian, defs_kin_polar, defs_kin_rotary_delta, defs_kin_winch,
    defs_kin_extruder, defs_kin_shaper, defs_kin_idex,
    defs_kin_generic_cartesian,
 ]
 # Update filenames to an absolute path
@@ -274,33 +262,11 @@ def do_build_code(cmd):
        logging.error(msg)
        raise Exception(msg)
 # Build the main c_helper.so c code library
 def check_build_c_library():
    srcdir = os.path.dirname(os.path.realpath(__file__))
    srcfiles = get_abs_files(srcdir, SOURCE_FILES)
    ofiles = get_abs_files(srcdir, OTHER_FILES)
    destlib = get_abs_files(srcdir, [DEST_LIB])[0]
    if not check_build_code(srcfiles+ofiles+[__file__], destlib):
        # Code already built
        return destlib
    # Select command line options
    if check_gcc_option(SSE_FLAGS):
        cmd = "%s %s %s" % (GCC_CMD, SSE_FLAGS, COMPILE_ARGS)
    else:
        cmd = "%s %s" % (GCC_CMD, COMPILE_ARGS)
    # Invoke compiler
    logging.info("Building C code module %s", DEST_LIB)
    tempdestlib = get_abs_files(srcdir, ["_temp_" + DEST_LIB])[0]
    do_build_code(cmd % (tempdestlib, ' '.join(srcfiles)))
    # Rename from temporary file to final file name
    os.rename(tempdestlib, destlib)
    return destlib
 FFI_main = None
 FFI_lib = None
 pyhelper_logging_callback = None
-# Helper invoked from C errorf() code to log errors
+# Hepler invoked from C errorf() code to log errors
 def logging_callback(msg):
    logging.error(FFI_main.string(msg))
@@ -308,9 +274,17 @@ def logging_callback(msg):
 def get_ffi():
    global FFI_main, FFI_lib, pyhelper_logging_callback
    if FFI_lib is None:
-        # Check if library needs to be built, and build if so
+        srcdir = os.path.dirname(os.path.realpath(__file__))
-        destlib = check_build_c_library()
+        srcfiles = get_abs_files(srcdir, SOURCE_FILES)
-        # Open library
+        ofiles = get_abs_files(srcdir, OTHER_FILES)
        destlib = get_abs_files(srcdir, [DEST_LIB])[0]
        if check_build_code(srcfiles+ofiles+[__file__], destlib):
            if check_gcc_option(SSE_FLAGS):
                cmd = "%s %s %s" % (GCC_CMD, SSE_FLAGS, COMPILE_ARGS)
            else:
                cmd = "%s %s" % (GCC_CMD, COMPILE_ARGS)
            logging.info("Building C code module %s", DEST_LIB)
            do_build_code(cmd % (destlib, ' '.join(srcfiles)))
        FFI_main = cffi.FFI()
        for d in defs_all:
            FFI_main.cdef(d)
--- a/klippy/chelper/itersolve.c
+++ b/klippy/chelper/itersolve.c
@@ -26,8 +26,8 @@ struct timepos {
 // Generate step times for a portion of a move
 static int32_t
-itersolve_gen_steps_range(struct stepper_kinematics *sk, struct stepcompress *sc
+itersolve_gen_steps_range(struct stepper_kinematics *sk, struct move *m
-                          , struct move *m, double abs_start, double abs_end)
+                          , double abs_start, double abs_end)
 {
    sk_calc_callback calc_position_cb = sk->calc_position_cb;
    double half_step = .5 * sk->step_dist;
@@ -37,7 +37,7 @@ itersolve_gen_steps_range(struct stepper_kinematics *sk, struct stepcompress *sc
    if (end > m->move_t)
        end = m->move_t;
    struct timepos old_guess = {start, sk->commanded_pos}, guess = old_guess;
-    int sdir = stepcompress_get_step_dir(sc);
+    int sdir = stepcompress_get_step_dir(sk->sc);
    int is_dir_change = 0, have_bracket = 0, check_oscillate = 0;
    double target = sk->commanded_pos + (sdir ? half_step : -half_step);
    double last_time=start, low_time=start, high_time=start + SEEK_TIME_RESET;
@@ -99,13 +99,13 @@ itersolve_gen_steps_range(struct stepper_kinematics *sk, struct stepcompress *sc
            if (!have_bracket || high_time - low_time > .000000001) {
                if (!is_dir_change && rel_dist >= -half_step)
                    // Avoid rollback if stepper fully reaches step position
-                    stepcompress_commit(sc);
+                    stepcompress_commit(sk->sc);
                // Guess is not close enough - guess again with new time
                continue;
            }
        }
        // Found next step - submit it
-        int ret = stepcompress_append(sc, sdir, m->print_time, guess.time);
+        int ret = stepcompress_append(sk->sc, sdir, m->print_time, guess.time);
        if (ret)
            return ret;
        target = sdir ? target+half_step+half_step : target-half_step-half_step;
@@ -143,9 +143,8 @@ check_active(struct stepper_kinematics *sk, struct move *m)
 }
 // Generate step times for a range of moves on the trapq
-int32_t
+int32_t __visible
-itersolve_generate_steps(struct stepper_kinematics *sk, struct stepcompress *sc
+itersolve_generate_steps(struct stepper_kinematics *sk, double flush_time)
                         , double flush_time)
 {
    double last_flush_time = sk->last_flush_time;
    sk->last_flush_time = flush_time;
@@ -171,15 +170,15 @@ itersolve_generate_steps(struct stepper_kinematics *sk, struct stepcompress *sc
                while (--skip_count && pm->print_time > abs_start)
                    pm = list_prev_entry(pm, node);
                do {
-                    int32_t ret = itersolve_gen_steps_range(
+                    int32_t ret = itersolve_gen_steps_range(sk, pm, abs_start
-                        sk, sc, pm, abs_start, flush_time);
+                                                            , flush_time);
                    if (ret)
                        return ret;
                    pm = list_next_entry(pm, node);
                } while (pm != m);
            }
            // Generate steps for this move
-            int32_t ret = itersolve_gen_steps_range(sk, sc, m, last_flush_time
+            int32_t ret = itersolve_gen_steps_range(sk, m, last_flush_time
                                                    , flush_time);
            if (ret)
                return ret;
@@ -196,8 +195,8 @@ itersolve_generate_steps(struct stepper_kinematics *sk, struct stepcompress *sc
                double abs_end = force_steps_time;
                if (abs_end > flush_time)
                    abs_end = flush_time;
-                int32_t ret = itersolve_gen_steps_range(
+                int32_t ret = itersolve_gen_steps_range(sk, m, last_flush_time
-                    sk, sc, m, last_flush_time, abs_end);
+                                                        , abs_end);
                if (ret)
                    return ret;
                skip_count = 1;
@@ -241,10 +240,16 @@ itersolve_is_active_axis(struct stepper_kinematics *sk, char axis)
 }
 void __visible
-itersolve_set_trapq(struct stepper_kinematics *sk, struct trapq *tq
+itersolve_set_trapq(struct stepper_kinematics *sk, struct trapq *tq)
                    , double step_dist)
 {
    sk->tq = tq;
 }
 void __visible
 itersolve_set_stepcompress(struct stepper_kinematics *sk
                           , struct stepcompress *sc, double step_dist)
 {
    sk->sc = sc;
    sk->step_dist = step_dist;
 }
--- a/klippy/chelper/itersolve.h
+++ b/klippy/chelper/itersolve.h
@@ -26,11 +26,12 @@ struct stepper_kinematics {
 };
 int32_t itersolve_generate_steps(struct stepper_kinematics *sk
-                                 , struct stepcompress *sc, double flush_time);
+                                 , double flush_time);
 double itersolve_check_active(struct stepper_kinematics *sk, double flush_time);
 int32_t itersolve_is_active_axis(struct stepper_kinematics *sk, char axis);
-void itersolve_set_trapq(struct stepper_kinematics *sk, struct trapq *tq
+void itersolve_set_trapq(struct stepper_kinematics *sk, struct trapq *tq);
-                         , double step_dist);
+void itersolve_set_stepcompress(struct stepper_kinematics *sk
                                , struct stepcompress *sc, double step_dist);
 double itersolve_calc_position_from_coord(struct stepper_kinematics *sk
                                          , double x, double y, double z);
 void itersolve_set_position(struct stepper_kinematics *sk
--- a/klippy/chelper/kin_generic.c
+++ b/klippy/chelper/kin_generic.c
@@ -1,52 +0,0 @@
 // Generic cartesian kinematics stepper position calculation
 //
 // Copyright (C) 2024  Dmitry Butyugin <dmbutyugin@google.com>
 //
 // This file may be distributed under the terms of the GNU GPLv3 license.
 #include <stddef.h> // offsetof
 #include <stdlib.h> // malloc
 #include <string.h> // memset
 #include "compiler.h" // __visible
 #include "itersolve.h" // struct stepper_kinematics
 #include "trapq.h" // move_get_coord
 struct generic_cartesian_stepper {
    struct stepper_kinematics sk;
    struct coord a;
 };
 static double
 generic_cartesian_stepper_calc_position(struct stepper_kinematics *sk
                                        , struct move *m, double move_time)
 {
    struct generic_cartesian_stepper *cs = container_of(
            sk, struct generic_cartesian_stepper, sk);
    struct coord c = move_get_coord(m, move_time);
    return cs->a.x * c.x + cs->a.y * c.y + cs->a.z * c.z;
 }
 void __visible
 generic_cartesian_stepper_set_coeffs(struct stepper_kinematics *sk
                                     , double a_x, double a_y, double a_z)
 {
    struct generic_cartesian_stepper *cs = container_of(
            sk, struct generic_cartesian_stepper, sk);
    cs->a.x = a_x;
    cs->a.y = a_y;
    cs->a.z = a_z;
    cs->sk.active_flags = 0;
    if (a_x) cs->sk.active_flags |= AF_X;
    if (a_y) cs->sk.active_flags |= AF_Y;
    if (a_z) cs->sk.active_flags |= AF_Z;
 }
 struct stepper_kinematics * __visible
 generic_cartesian_stepper_alloc(double a_x, double a_y, double a_z)
 {
    struct generic_cartesian_stepper *cs = malloc(sizeof(*cs));
    memset(cs, 0, sizeof(*cs));
    cs->sk.calc_position_cb = generic_cartesian_stepper_calc_position;
    generic_cartesian_stepper_set_coeffs(&cs->sk, a_x, a_y, a_z);
    return &cs->sk;
 }
--- a/klippy/chelper/kin_idex.c
+++ b/klippy/chelper/kin_idex.c
@@ -77,6 +77,5 @@ dual_carriage_alloc(void)
    struct dual_carriage_stepper *dc = malloc(sizeof(*dc));
    memset(dc, 0, sizeof(*dc));
    dc->m.move_t = 2. * DUMMY_T;
    dc->x_scale = dc->y_scale = 1.0;
    return &dc->sk;
 }
--- a/klippy/chelper/kin_shaper.c
+++ b/klippy/chelper/kin_shaper.c
@@ -156,48 +156,6 @@ shaper_xy_calc_position(struct stepper_kinematics *sk, struct move *m
    return is->orig_sk->calc_position_cb(is->orig_sk, &is->m, DUMMY_T);
 }
 // A callback that forwards post_cb call to the original kinematics
 static void
 shaper_commanded_pos_post_fixup(struct stepper_kinematics *sk)
 {
    struct input_shaper *is = container_of(sk, struct input_shaper, sk);
    is->orig_sk->commanded_pos = sk->commanded_pos;
    is->orig_sk->post_cb(is->orig_sk);
    sk->commanded_pos = is->orig_sk->commanded_pos;
 }
 static void
 shaper_note_generation_time(struct input_shaper *is)
 {
    double pre_active = 0., post_active = 0.;
    if ((is->sk.active_flags & AF_X) && is->sx.num_pulses) {
        pre_active = is->sx.pulses[is->sx.num_pulses-1].t;
        post_active = -is->sx.pulses[0].t;
    }
    if ((is->sk.active_flags & AF_Y) && is->sy.num_pulses) {
        pre_active = is->sy.pulses[is->sy.num_pulses-1].t > pre_active
            ? is->sy.pulses[is->sy.num_pulses-1].t : pre_active;
        post_active = -is->sy.pulses[0].t > post_active
            ? -is->sy.pulses[0].t : post_active;
    }
    is->sk.gen_steps_pre_active = pre_active;
    is->sk.gen_steps_post_active = post_active;
 }
 void __visible
 input_shaper_update_sk(struct stepper_kinematics *sk)
 {
    struct input_shaper *is = container_of(sk, struct input_shaper, sk);
    if ((is->orig_sk->active_flags & (AF_X | AF_Y)) == (AF_X | AF_Y))
        is->sk.calc_position_cb = shaper_xy_calc_position;
    else if (is->orig_sk->active_flags & AF_X)
        is->sk.calc_position_cb = shaper_x_calc_position;
    else if (is->orig_sk->active_flags & AF_Y)
        is->sk.calc_position_cb = shaper_y_calc_position;
    is->sk.active_flags = is->orig_sk->active_flags;
    shaper_note_generation_time(is);
 }
 int __visible
 input_shaper_set_sk(struct stepper_kinematics *sk
                    , struct stepper_kinematics *orig_sk)
@@ -216,12 +174,27 @@ input_shaper_set_sk(struct stepper_kinematics *sk
    is->sk.commanded_pos = orig_sk->commanded_pos;
    is->sk.last_flush_time = orig_sk->last_flush_time;
    is->sk.last_move_time = orig_sk->last_move_time;
    if (orig_sk->post_cb) {
        is->sk.post_cb = shaper_commanded_pos_post_fixup;
    }
    return 0;
 }
 static void
 shaper_note_generation_time(struct input_shaper *is)
 {
    double pre_active = 0., post_active = 0.;
    if ((is->sk.active_flags & AF_X) && is->sx.num_pulses) {
        pre_active = is->sx.pulses[is->sx.num_pulses-1].t;
        post_active = -is->sx.pulses[0].t;
    }
    if ((is->sk.active_flags & AF_Y) && is->sy.num_pulses) {
        pre_active = is->sy.pulses[is->sy.num_pulses-1].t > pre_active
            ? is->sy.pulses[is->sy.num_pulses-1].t : pre_active;
        post_active = -is->sy.pulses[0].t > post_active
            ? -is->sy.pulses[0].t : post_active;
    }
    is->sk.gen_steps_pre_active = pre_active;
    is->sk.gen_steps_post_active = post_active;
 }
 int __visible
 input_shaper_set_shaper_params(struct stepper_kinematics *sk, char axis
                               , int n, double a[], double t[])
--- a/klippy/chelper/pyhelper.c
+++ b/klippy/chelper/pyhelper.c
@@ -10,8 +10,6 @@
 #include <stdio.h> // fprintf
 #include <string.h> // strerror
 #include <time.h> // struct timespec
 #include <linux/prctl.h>  // PR_SET_NAME
 #include <sys/prctl.h>  // prctl
 #include "compiler.h" // __visible
 #include "pyhelper.h" // get_monotonic
@@ -94,10 +92,3 @@ dump_string(char *outbuf, int outbuf_size, char *inbuf, int inbuf_size)
    *o = '\0';
    return outbuf;
 }
 // Set custom thread names
 int __visible
 set_thread_name(char name[16])
 {
    return prctl(PR_SET_NAME, name);
 }
--- a/klippy/chelper/pyhelper.h
+++ b/klippy/chelper/pyhelper.h
@@ -7,6 +7,5 @@ void set_python_logging_callback(void (*func)(const char *));
 void errorf(const char *fmt, ...) __attribute__ ((format (printf, 1, 2)));
 void report_errno(char *where, int rc);
 char *dump_string(char *outbuf, int outbuf_size, char *inbuf, int inbuf_size);
 int set_thread_name(char name[16]);
 #endif // pyhelper.h
--- a/klippy/chelper/serialqueue.c
+++ b/klippy/chelper/serialqueue.c
@@ -43,7 +43,6 @@ struct serialqueue {
    uint8_t need_sync;
    int input_pos;
    // Threading
    char name[16];
    pthread_t tid;
    pthread_mutex_t lock; // protects variables below
    pthread_cond_t cond;
@@ -613,7 +612,6 @@ static void *
 background_thread(void *data)
 {
    struct serialqueue *sq = data;
    set_thread_name(sq->name);
    pollreactor_run(sq->pr);
    pthread_mutex_lock(&sq->lock);
@@ -625,16 +623,13 @@ background_thread(void *data)
 // Create a new 'struct serialqueue' object
 struct serialqueue * __visible
-serialqueue_alloc(int serial_fd, char serial_fd_type, int client_id
+serialqueue_alloc(int serial_fd, char serial_fd_type, int client_id)
                  , char name[16])
 {
    struct serialqueue *sq = malloc(sizeof(*sq));
    memset(sq, 0, sizeof(*sq));
    sq->serial_fd = serial_fd;
    sq->serial_fd_type = serial_fd_type;
    sq->client_id = client_id;
    strncpy(sq->name, name, sizeof(sq->name));
    sq->name[sizeof(sq->name)-1] = '\0';
    int ret = pipe(sq->pipe_fds);
    if (ret)
--- a/klippy/chelper/serialqueue.h
+++ b/klippy/chelper/serialqueue.h
@@ -27,7 +27,7 @@ struct pull_queue_message {
 struct serialqueue;
 struct serialqueue *serialqueue_alloc(int serial_fd, char serial_fd_type
-                                      , int client_id, char name[16]);
+                                      , int client_id);
 void serialqueue_exit(struct serialqueue *sq);
 void serialqueue_free(struct serialqueue *sq);
 struct command_queue *serialqueue_alloc_commandqueue(void);
--- a/klippy/chelper/stepcompress.c
+++ b/klippy/chelper/stepcompress.c
@@ -1,6 +1,6 @@
 // Stepper pulse schedule compression
 //
-// Copyright (C) 2016-2025  Kevin O'Connor <kevin@koconnor.net>
+// Copyright (C) 2016-2021  Kevin O'Connor <kevin@koconnor.net>
 //
 // This file may be distributed under the terms of the GNU GPLv3 license.
@@ -21,7 +21,6 @@
 #include <stdlib.h> // malloc
 #include <string.h> // memset
 #include "compiler.h" // DIV_ROUND_UP
 #include "itersolve.h" // itersolve_generate_steps
 #include "pyhelper.h" // errorf
 #include "serialqueue.h" // struct queue_message
 #include "stepcompress.h" // stepcompress_alloc
@@ -47,8 +46,6 @@ struct stepcompress {
    // History tracking
    int64_t last_position;
    struct list_head history_list;
    // Itersolve reference
    struct stepper_kinematics *sk;
 };
 struct step_move {
@@ -279,9 +276,9 @@ stepcompress_set_invert_sdir(struct stepcompress *sc, uint32_t invert_sdir)
    }
 }
-// Expire the stepcompress history older than the given clock
+// Helper to free items from the history_list
-void
+static void
-stepcompress_history_expire(struct stepcompress *sc, uint64_t end_clock)
+free_history(struct stepcompress *sc, uint64_t end_clock)
 {
    while (!list_empty(&sc->history_list)) {
        struct history_steps *hs = list_last_entry(
@@ -293,6 +290,13 @@ stepcompress_history_expire(struct stepcompress *sc, uint64_t end_clock)
    }
 }
 // Expire the stepcompress history older than the given clock
 static void
 stepcompress_history_expire(struct stepcompress *sc, uint64_t end_clock)
 {
    free_history(sc, end_clock);
 }
 // Free memory associated with a 'stepcompress' object
 void __visible
 stepcompress_free(struct stepcompress *sc)
@@ -301,7 +305,7 @@ stepcompress_free(struct stepcompress *sc)
        return;
    free(sc->queue);
    message_queue_free(&sc->msg_queue);
-    stepcompress_history_expire(sc, UINT64_MAX);
+    free_history(sc, UINT64_MAX);
    free(sc);
 }
@@ -317,12 +321,6 @@ stepcompress_get_step_dir(struct stepcompress *sc)
    return sc->next_step_dir;
 }
 struct list_head *
 stepcompress_get_msg_queue(struct stepcompress *sc)
 {
    return &sc->msg_queue;
 }
 // Determine the "print time" of the last_step_clock
 static void
 calc_last_step_print_time(struct stepcompress *sc)
@@ -332,7 +330,7 @@ calc_last_step_print_time(struct stepcompress *sc)
 }
 // Set the conversion rate of 'print_time' to mcu clock
-void
+static void
 stepcompress_set_time(struct stepcompress *sc
                      , double time_offset, double mcu_freq)
 {
@@ -666,25 +664,164 @@ stepcompress_extract_old(struct stepcompress *sc, struct pull_history_steps *p
    return res;
 }
-// Store a reference to stepper_kinematics
+
-void __visible
+/****************************************************************
-stepcompress_set_stepper_kinematics(struct stepcompress *sc
+ * Step compress synchronization
-                                    , struct stepper_kinematics *sk)
+ ****************************************************************/
 // The steppersync object is used to synchronize the output of mcu
 // step commands.  The mcu can only queue a limited number of step
 // commands - this code tracks when items on the mcu step queue become
 // free so that new commands can be transmitted.  It also ensures the
 // mcu step queue is ordered between steppers so that no stepper
 // starves the other steppers of space in the mcu step queue.
 struct steppersync {
    // Serial port
    struct serialqueue *sq;
    struct command_queue *cq;
    // Storage for associated stepcompress objects
    struct stepcompress **sc_list;
    int sc_num;
    // Storage for list of pending move clocks
    uint64_t *move_clocks;
    int num_move_clocks;
 };
 // Allocate a new 'steppersync' object
 struct steppersync * __visible
 steppersync_alloc(struct serialqueue *sq, struct stepcompress **sc_list
                  , int sc_num, int move_num)
 {
-    sc->sk = sk;
+    struct steppersync *ss = malloc(sizeof(*ss));
    memset(ss, 0, sizeof(*ss));
    ss->sq = sq;
    ss->cq = serialqueue_alloc_commandqueue();
    ss->sc_list = malloc(sizeof(*sc_list)*sc_num);
    memcpy(ss->sc_list, sc_list, sizeof(*sc_list)*sc_num);
    ss->sc_num = sc_num;
    ss->move_clocks = malloc(sizeof(*ss->move_clocks)*move_num);
    memset(ss->move_clocks, 0, sizeof(*ss->move_clocks)*move_num);
    ss->num_move_clocks = move_num;
    return ss;
 }
-// Generate steps (via itersolve) and flush
+// Free memory associated with a 'steppersync' object
-int32_t
+void __visible
-stepcompress_generate_steps(struct stepcompress *sc, double gen_steps_time
+steppersync_free(struct steppersync *ss)
                            , uint64_t flush_clock)
 {
-    if (!sc->sk)
+    if (!ss)
-        return 0;
+        return;
-    // Generate steps
+    free(ss->sc_list);
-    int32_t ret = itersolve_generate_steps(sc->sk, sc, gen_steps_time);
+    free(ss->move_clocks);
    serialqueue_free_commandqueue(ss->cq);
    free(ss);
 }
 // Set the conversion rate of 'print_time' to mcu clock
 void __visible
 steppersync_set_time(struct steppersync *ss, double time_offset
                     , double mcu_freq)
 {
    int i;
    for (i=0; i<ss->sc_num; i++) {
        struct stepcompress *sc = ss->sc_list[i];
        stepcompress_set_time(sc, time_offset, mcu_freq);
    }
 }
 // Expire the stepcompress history before the given clock time
 static void
 steppersync_history_expire(struct steppersync *ss, uint64_t end_clock)
 {
    int i;
    for (i = 0; i < ss->sc_num; i++)
    {
        struct stepcompress *sc = ss->sc_list[i];
        stepcompress_history_expire(sc, end_clock);
    }
 }
 // Implement a binary heap algorithm to track when the next available
 // 'struct move' in the mcu will be available
 static void
 heap_replace(struct steppersync *ss, uint64_t req_clock)
 {
    uint64_t *mc = ss->move_clocks;
    int nmc = ss->num_move_clocks, pos = 0;
    for (;;) {
        int child1_pos = 2*pos+1, child2_pos = 2*pos+2;
        uint64_t child2_clock = child2_pos < nmc ? mc[child2_pos] : UINT64_MAX;
        uint64_t child1_clock = child1_pos < nmc ? mc[child1_pos] : UINT64_MAX;
        if (req_clock <= child1_clock && req_clock <= child2_clock) {
            mc[pos] = req_clock;
            break;
        }
        if (child1_clock < child2_clock) {
            mc[pos] = child1_clock;
            pos = child1_pos;
        } else {
            mc[pos] = child2_clock;
            pos = child2_pos;
        }
    }
 }
 // Find and transmit any scheduled steps prior to the given 'move_clock'
 int __visible
 steppersync_flush(struct steppersync *ss, uint64_t move_clock
                  , uint64_t clear_history_clock)
 {
    // Flush each stepcompress to the specified move_clock
    int i;
    for (i=0; i<ss->sc_num; i++) {
        int ret = stepcompress_flush(ss->sc_list[i], move_clock);
        if (ret)
            return ret;
-    // Flush steps
+    }
-    return stepcompress_flush(sc, flush_clock);
+
    // Order commands by the reqclock of each pending command
    struct list_head msgs;
    list_init(&msgs);
    for (;;) {
        // Find message with lowest reqclock
        uint64_t req_clock = MAX_CLOCK;
        struct queue_message *qm = NULL;
        for (i=0; i<ss->sc_num; i++) {
            struct stepcompress *sc = ss->sc_list[i];
            if (!list_empty(&sc->msg_queue)) {
                struct queue_message *m = list_first_entry(
                    &sc->msg_queue, struct queue_message, node);
                if (m->req_clock < req_clock) {
                    qm = m;
                    req_clock = m->req_clock;
                }
            }
        }
        if (!qm || (qm->min_clock && req_clock > move_clock))
            break;
        uint64_t next_avail = ss->move_clocks[0];
        if (qm->min_clock)
            // The qm->min_clock field is overloaded to indicate that
            // the command uses the 'move queue' and to store the time
            // that move queue item becomes available.
            heap_replace(ss, qm->min_clock);
        // Reset the min_clock to its normal meaning (minimum transmit time)
        qm->min_clock = next_avail;
        // Batch this command
        list_del(&qm->node);
        list_add_tail(&qm->node, &msgs);
    }
    // Transmit commands
    if (!list_empty(&msgs))
        serialqueue_send_batch(ss->sq, ss->cq, &msgs);
    steppersync_history_expire(ss, clear_history_clock);
    return 0;
 }
--- a/klippy/chelper/stepcompress.h
+++ b/klippy/chelper/stepcompress.h
@@ -17,13 +17,9 @@ void stepcompress_fill(struct stepcompress *sc, uint32_t max_error
                       , int32_t set_next_step_dir_msgtag);
 void stepcompress_set_invert_sdir(struct stepcompress *sc
                                  , uint32_t invert_sdir);
 void stepcompress_history_expire(struct stepcompress *sc, uint64_t end_clock);
 void stepcompress_free(struct stepcompress *sc);
 uint32_t stepcompress_get_oid(struct stepcompress *sc);
 int stepcompress_get_step_dir(struct stepcompress *sc);
 struct list_head *stepcompress_get_msg_queue(struct stepcompress *sc);
 void stepcompress_set_time(struct stepcompress *sc
                           , double time_offset, double mcu_freq);
 int stepcompress_append(struct stepcompress *sc, int sdir
                        , double print_time, double step_time);
 int stepcompress_commit(struct stepcompress *sc);
@@ -38,11 +34,15 @@ int stepcompress_queue_mq_msg(struct stepcompress *sc, uint64_t req_clock
 int stepcompress_extract_old(struct stepcompress *sc
                             , struct pull_history_steps *p, int max
                             , uint64_t start_clock, uint64_t end_clock);
-struct stepper_kinematics;
+
-void stepcompress_set_stepper_kinematics(struct stepcompress *sc
+struct serialqueue;
-                                         , struct stepper_kinematics *sk);
+struct steppersync *steppersync_alloc(
-int32_t stepcompress_generate_steps(struct stepcompress *sc
+    struct serialqueue *sq, struct stepcompress **sc_list, int sc_num
-                                    , double gen_steps_time
+    , int move_num);
-                                    , uint64_t flush_clock);
+void steppersync_free(struct steppersync *ss);
 void steppersync_set_time(struct steppersync *ss, double time_offset
                          , double mcu_freq);
 int steppersync_flush(struct steppersync *ss, uint64_t move_clock
                      , uint64_t clear_history_clock);
 #endif // stepcompress.h
--- a/klippy/chelper/steppersync.c
+++ b/klippy/chelper/steppersync.c
@@ -1,177 +0,0 @@
 // Stepper step transmit synchronization
 //
 // Copyright (C) 2016-2025  Kevin O'Connor <kevin@koconnor.net>
 //
 // This file may be distributed under the terms of the GNU GPLv3 license.
 // The steppersync object is used to synchronize the output of mcu
 // step commands.  The mcu can only queue a limited number of step
 // commands - this code tracks when items on the mcu step queue become
 // free so that new commands can be transmitted.  It also ensures the
 // mcu step queue is ordered between steppers so that no stepper
 // starves the other steppers of space in the mcu step queue.
 #include <stddef.h> // offsetof
 #include <stdlib.h> // malloc
 #include <string.h> // memset
 #include "compiler.h" // __visible
 #include "serialqueue.h" // struct queue_message
 #include "stepcompress.h" // stepcompress_flush
 #include "steppersync.h" // steppersync_alloc
 struct steppersync {
    // Serial port
    struct serialqueue *sq;
    struct command_queue *cq;
    // Storage for associated stepcompress objects
    struct stepcompress **sc_list;
    int sc_num;
    // Storage for list of pending move clocks
    uint64_t *move_clocks;
    int num_move_clocks;
 };
 // Allocate a new 'steppersync' object
 struct steppersync * __visible
 steppersync_alloc(struct serialqueue *sq, struct stepcompress **sc_list
                  , int sc_num, int move_num)
 {
    struct steppersync *ss = malloc(sizeof(*ss));
    memset(ss, 0, sizeof(*ss));
    ss->sq = sq;
    ss->cq = serialqueue_alloc_commandqueue();
    ss->sc_list = malloc(sizeof(*sc_list)*sc_num);
    memcpy(ss->sc_list, sc_list, sizeof(*sc_list)*sc_num);
    ss->sc_num = sc_num;
    ss->move_clocks = malloc(sizeof(*ss->move_clocks)*move_num);
    memset(ss->move_clocks, 0, sizeof(*ss->move_clocks)*move_num);
    ss->num_move_clocks = move_num;
    return ss;
 }
 // Free memory associated with a 'steppersync' object
 void __visible
 steppersync_free(struct steppersync *ss)
 {
    if (!ss)
        return;
    free(ss->sc_list);
    free(ss->move_clocks);
    serialqueue_free_commandqueue(ss->cq);
    free(ss);
 }
 // Set the conversion rate of 'print_time' to mcu clock
 void __visible
 steppersync_set_time(struct steppersync *ss, double time_offset
                     , double mcu_freq)
 {
    int i;
    for (i=0; i<ss->sc_num; i++) {
        struct stepcompress *sc = ss->sc_list[i];
        stepcompress_set_time(sc, time_offset, mcu_freq);
    }
 }
 // Generate steps and flush stepcompress objects
 int32_t __visible
 steppersync_generate_steps(struct steppersync *ss, double gen_steps_time
                           , uint64_t flush_clock)
 {
    int i;
    for (i=0; i<ss->sc_num; i++) {
        struct stepcompress *sc = ss->sc_list[i];
        int32_t ret = stepcompress_generate_steps(sc, gen_steps_time
                                                  , flush_clock);
        if (ret)
            return ret;
    }
    return 0;
 }
 // Expire the stepcompress history before the given clock time
 void __visible
 steppersync_history_expire(struct steppersync *ss, uint64_t end_clock)
 {
    int i;
    for (i = 0; i < ss->sc_num; i++) {
        struct stepcompress *sc = ss->sc_list[i];
        stepcompress_history_expire(sc, end_clock);
    }
 }
 // Implement a binary heap algorithm to track when the next available
 // 'struct move' in the mcu will be available
 static void
 heap_replace(struct steppersync *ss, uint64_t req_clock)
 {
    uint64_t *mc = ss->move_clocks;
    int nmc = ss->num_move_clocks, pos = 0;
    for (;;) {
        int child1_pos = 2*pos+1, child2_pos = 2*pos+2;
        uint64_t child2_clock = child2_pos < nmc ? mc[child2_pos] : UINT64_MAX;
        uint64_t child1_clock = child1_pos < nmc ? mc[child1_pos] : UINT64_MAX;
        if (req_clock <= child1_clock && req_clock <= child2_clock) {
            mc[pos] = req_clock;
            break;
        }
        if (child1_clock < child2_clock) {
            mc[pos] = child1_clock;
            pos = child1_pos;
        } else {
            mc[pos] = child2_clock;
            pos = child2_pos;
        }
    }
 }
 // Find and transmit any scheduled steps prior to the given 'move_clock'
 int __visible
 steppersync_flush(struct steppersync *ss, uint64_t move_clock)
 {
    // Order commands by the reqclock of each pending command
    struct list_head msgs;
    list_init(&msgs);
    for (;;) {
        // Find message with lowest reqclock
        uint64_t req_clock = MAX_CLOCK;
        struct queue_message *qm = NULL;
        int i;
        for (i=0; i<ss->sc_num; i++) {
            struct stepcompress *sc = ss->sc_list[i];
            struct list_head *sc_mq = stepcompress_get_msg_queue(sc);
            if (!list_empty(sc_mq)) {
                struct queue_message *m = list_first_entry(
                    sc_mq, struct queue_message, node);
                if (m->req_clock < req_clock) {
                    qm = m;
                    req_clock = m->req_clock;
                }
            }
        }
        if (!qm || (qm->min_clock && req_clock > move_clock))
            break;
        uint64_t next_avail = ss->move_clocks[0];
        if (qm->min_clock)
            // The qm->min_clock field is overloaded to indicate that
            // the command uses the 'move queue' and to store the time
            // that move queue item becomes available.
            heap_replace(ss, qm->min_clock);
        // Reset the min_clock to its normal meaning (minimum transmit time)
        qm->min_clock = next_avail;
        // Batch this command
        list_del(&qm->node);
        list_add_tail(&qm->node, &msgs);
    }
    // Transmit commands
    if (!list_empty(&msgs))
        serialqueue_send_batch(ss->sq, ss->cq, &msgs);
    return 0;
 }
--- a/klippy/chelper/steppersync.h
+++ b/klippy/chelper/steppersync.h
@@ -1,18 +0,0 @@
 #ifndef STEPPERSYNC_H
 #define STEPPERSYNC_H
 #include <stdint.h> // uint64_t
 struct serialqueue;
 struct steppersync *steppersync_alloc(
    struct serialqueue *sq, struct stepcompress **sc_list, int sc_num
    , int move_num);
 void steppersync_free(struct steppersync *ss);
 void steppersync_set_time(struct steppersync *ss, double time_offset
                          , double mcu_freq);
 int32_t steppersync_generate_steps(struct steppersync *ss, double gen_steps_time
                                   , uint64_t flush_clock);
 void steppersync_history_expire(struct steppersync *ss, uint64_t end_clock);
 int steppersync_flush(struct steppersync *ss, uint64_t move_clock);
 #endif // steppersync.h
--- a/klippy/extras/ads1220.py
+++ b/klippy/extras/ads1220.py
@@ -95,8 +95,11 @@ class ADS1220:
        self.batch_bulk = bulk_sensor.BatchBulkHelper(
            self.printer, self._process_batch, self._start_measurements,
            self._finish_measurements, UPDATE_INTERVAL)
        # publish raw samples to the socket
        hdr = {'header': ('time', 'counts', 'value')}
        self.batch_bulk.add_mux_endpoint("ads1220/dump_ads1220", "sensor",
                                         self.name, hdr)
        # Command Configuration
        self.attach_probe_cmd = None
        mcu.add_config_cmd(
            "config_ads1220 oid=%d spi_oid=%d data_ready_pin=%s"
            % (self.oid, self.spi.get_oid(), self.data_ready_pin))
@@ -109,8 +112,6 @@ class ADS1220:
        cmdqueue = self.spi.get_command_queue()
        self.query_ads1220_cmd = self.mcu.lookup_command(
            "query_ads1220 oid=%c rest_ticks=%u", cq=cmdqueue)
        self.attach_probe_cmd = self.mcu.lookup_command(
            "ads1220_attach_load_cell_probe oid=%c load_cell_probe_oid=%c")
        self.ffreader.setup_query_command("query_ads1220_status oid=%c",
                                          oid=self.oid, cq=cmdqueue)
@@ -129,9 +130,6 @@ class ADS1220:
    def add_client(self, callback):
        self.batch_bulk.add_client(callback)
    def attach_load_cell_probe(self, load_cell_probe_oid):
        self.attach_probe_cmd.send([self.oid, load_cell_probe_oid])
    # Measurement decoding
    def _convert_samples(self, samples):
        adc_factor = 1. / (1 << 23)
--- a/klippy/extras/ads1x1x.py
+++ b/klippy/extras/ads1x1x.py
@@ -210,28 +210,28 @@ class ADS1X1X_chip:
                raise pins.error('ADS1x1x pin %s is not valid' % \
                                 pin_params['pin'])
-            pcfg = 0
+            config = 0
-            pcfg |= (ADS1X1X_OS['OS_SINGLE'] & \
+            config |= (ADS1X1X_OS['OS_SINGLE'] & \
                       ADS1X1X_REG_CONFIG['OS_MASK'])
-            pcfg |= (ADS1X1X_MUX[pin_params['pin']] & \
+            config |= (ADS1X1X_MUX[pin_params['pin']] & \
                       ADS1X1X_REG_CONFIG['MULTIPLEXER_MASK'])
-            pcfg |= (self.pga & ADS1X1X_REG_CONFIG['PGA_MASK'])
+            config |= (self.pga & ADS1X1X_REG_CONFIG['PGA_MASK'])
            # Have to use single mode, because in continuous, it never reaches
            # idle state, which we use to determine if the sampling is done.
-            pcfg |= (ADS1X1X_MODE['single'] & \
+            config |= (ADS1X1X_MODE['single'] & \
                       ADS1X1X_REG_CONFIG['MODE_MASK'])
            # lowest sample rate per default, until report time has been set in
            # setup_adc_sample
-            pcfg |= (self.comp_mode \
+            config |= (self.comp_mode \
                & ADS1X1X_REG_CONFIG['COMPARATOR_MODE_MASK'])
-            pcfg |= (self.comp_polarity \
+            config |= (self.comp_polarity \
                & ADS1X1X_REG_CONFIG['COMPARATOR_POLARITY_MASK'])
-            pcfg |= (self.comp_latching \
+            config |= (self.comp_latching \
                & ADS1X1X_REG_CONFIG['COMPARATOR_LATCHING_MASK'])
-            pcfg |= (self.comp_queue \
+            config |= (self.comp_queue \
                & ADS1X1X_REG_CONFIG['COMPARATOR_QUEUE_MASK'])
-            pin_obj = ADS1X1X_pin(self, pcfg)
+            pin_obj = ADS1X1X_pin(self, config)
            if pin in self._pins:
                raise pins.error(
                    'pin %s for chip %s is used multiple times' \
@@ -250,8 +250,8 @@ class ADS1X1X_chip:
            logging.exception("ADS1X1X: error while resetting device")
    def is_ready(self):
-        cfg = self._read_register(ADS1X1X_REG_POINTER['CONFIG'])
+        config = self._read_register(ADS1X1X_REG_POINTER['CONFIG'])
-        return bool((cfg & ADS1X1X_REG_CONFIG['OS_MASK']) == \
+        return bool((config & ADS1X1X_REG_CONFIG['OS_MASK']) == \
                    ADS1X1X_OS['OS_IDLE'])
    def calculate_sample_rate(self):
@@ -281,7 +281,7 @@ class ADS1X1X_chip:
        (sample_rate, sample_rate_bits) = self.calculate_sample_rate()
        for pin in self._pins.values():
-            pin.pcfg = (pin.pcfg & ~ADS1X1X_REG_CONFIG['DATA_RATE_MASK']) \
+            pin.config = (pin.config & ~ADS1X1X_REG_CONFIG['DATA_RATE_MASK']) \
                | (sample_rate_bits & ADS1X1X_REG_CONFIG['DATA_RATE_MASK'])
        self.delay = 1 / float(sample_rate)
@@ -289,7 +289,7 @@ class ADS1X1X_chip:
    def sample(self, pin):
        with self._mutex:
            try:
-                self._write_register(ADS1X1X_REG_POINTER['CONFIG'], pin.pcfg)
+                self._write_register(ADS1X1X_REG_POINTER['CONFIG'], pin.config)
                self._reactor.pause(self._reactor.monotonic() + self.delay)
                start_time = self._reactor.monotonic()
                while not self.is_ready():
@@ -318,10 +318,10 @@ class ADS1X1X_chip:
        self._i2c.i2c_write(data)
 class ADS1X1X_pin:
-    def __init__(self, chip, pcfg):
+    def __init__(self, chip, config):
        self.mcu = chip.mcu
        self.chip = chip
-        self.pcfg = pcfg
+        self.config = config
        self.invalid_count = 0
--- a/klippy/extras/adxl345.py
+++ b/klippy/extras/adxl345.py
@@ -166,12 +166,12 @@ class AccelCommandHelper:
                          % (accel_x, accel_y, accel_z))
    cmd_ACCELEROMETER_DEBUG_READ_help = "Query register (for debugging)"
    def cmd_ACCELEROMETER_DEBUG_READ(self, gcmd):
-        reg = gcmd.get("REG", minval=0, maxval=127, parser=lambda x: int(x, 0))
+        reg = gcmd.get("REG", minval=0, maxval=126, parser=lambda x: int(x, 0))
        val = self.chip.read_reg(reg)
        gcmd.respond_info("Accelerometer REG[0x%x] = 0x%x" % (reg, val))
    cmd_ACCELEROMETER_DEBUG_WRITE_help = "Set register (for debugging)"
    def cmd_ACCELEROMETER_DEBUG_WRITE(self, gcmd):
-        reg = gcmd.get("REG", minval=0, maxval=127, parser=lambda x: int(x, 0))
+        reg = gcmd.get("REG", minval=0, maxval=126, parser=lambda x: int(x, 0))
        val = gcmd.get("VAL", minval=0, maxval=255, parser=lambda x: int(x, 0))
        self.chip.set_reg(reg, val)
--- a/klippy/extras/angle.py
+++ b/klippy/extras/angle.py
@@ -97,7 +97,7 @@ class AngleCalibration:
                return None
        return self.mcu_stepper.mcu_to_commanded_position(self.mcu_pos_offset)
    def load_calibration(self, angles):
-        # Calculate linear interpolation calibration buckets by solving
+        # Calculate linear intepolation calibration buckets by solving
        # linear equations
        angle_max = 1 << ANGLE_BITS
        calibration_count = 1 << CALIBRATION_BITS
--- a/klippy/extras/axis_twist_compensation.py
+++ b/klippy/extras/axis_twist_compensation.py
@@ -125,8 +125,9 @@ class Calibrater:
    def _handle_connect(self):
        self.probe = self.printer.lookup_object('probe', None)
-        if self.probe is None:
+        if (self.probe is None):
-            raise self.printer.config_error(
+            config = self.printer.lookup_object('configfile')
            raise config.error(
                "AXIS_TWIST_COMPENSATION requires [probe] to be defined")
        self.lift_speed = self.probe.get_probe_params()['lift_speed']
        self.probe_x_offset, self.probe_y_offset, _ = \
@@ -149,7 +150,20 @@ class Calibrater:
    def cmd_AXIS_TWIST_COMPENSATION_CALIBRATE(self, gcmd):
        self.gcmd = gcmd
        sample_count = gcmd.get_int('SAMPLE_COUNT', DEFAULT_SAMPLE_COUNT)
-        axis = gcmd.get('AXIS', 'X')
+        axis = gcmd.get('AXIS', None)
        auto = gcmd.get('AUTO', False)
        if axis is not None and auto:
            raise self.gcmd.error(
                "Cannot use both 'AXIS' and 'AUTO' at the same time."
            )
        if auto:
            self._start_autocalibration(sample_count)
            return
        if axis is None and not auto:
            axis = 'X'
        # check for valid sample_count
        if sample_count < 2:
@@ -230,6 +244,153 @@ class Calibrater:
        self.current_axis = axis
        self._calibration(probe_points, nozzle_points, interval_dist)
    def _calculate_corrections(self, coordinates):
        # Extracting x, y, and z values from coordinates
        x_coords = [coord[0] for coord in coordinates]
        y_coords = [coord[1] for coord in coordinates]
        z_coords = [coord[2] for coord in coordinates]
        # Calculate the desired point (average of all corner points in z)
        # For a general case, we should extract the unique
        # combinations of corner points
        z_corners = [z_coords[i] for i, coord in enumerate(coordinates)
                        if (coord[0] in [x_coords[0], x_coords[-1]])
                        and (coord[1] in [y_coords[0], y_coords[-1]])]
        z_desired = sum(z_corners) / len(z_corners)
        # Calculate average deformation per axis
        unique_x_coords = sorted(set(x_coords))
        unique_y_coords = sorted(set(y_coords))
        avg_z_x = []
        for x in unique_x_coords:
            indices = [i for i, coord in enumerate(coordinates)
                        if coord[0] == x]
            avg_z = sum(z_coords[i] for i in indices) / len(indices)
            avg_z_x.append(avg_z)
        avg_z_y = []
        for y in unique_y_coords:
            indices = [i for i, coord in enumerate(coordinates)
                        if coord[1] == y]
            avg_z = sum(z_coords[i] for i in indices) / len(indices)
            avg_z_y.append(avg_z)
        # Calculate corrections to reach the desired point
        x_corrections = [z_desired - avg for avg in avg_z_x]
        y_corrections = [z_desired - avg for avg in avg_z_y]
        return x_corrections, y_corrections
    def _start_autocalibration(self, sample_count):
        if not all([
                self.x_start_point[0],
                self.x_end_point[0],
                self.y_start_point[0],
                self.y_end_point[0]
                ]):
                raise self.gcmd.error(
                    """AXIS_TWIST_COMPENSATION_AUTOCALIBRATE requires
                    calibrate_start_x, calibrate_end_x, calibrate_start_y
                    and calibrate_end_y to be defined
                    """
                    )
        # check for valid sample_count
        if sample_count is None or sample_count < 2:
            raise self.gcmd.error(
                "SAMPLE_COUNT to probe must be at least 2")
        # verify no other manual probe is in progress
        manual_probe.verify_no_manual_probe(self.printer)
        # clear the current config
        self.compensation.clear_compensations()
        min_x = self.x_start_point[0]
        max_x = self.x_end_point[0]
        min_y = self.y_start_point[1]
        max_y = self.y_end_point[1]
        # calculate x positions
        interval_x = (max_x - min_x) / (sample_count - 1)
        xps = [min_x + interval_x * i for i in range(sample_count)]
        # Calculate points array
        interval_y = (max_y - min_y) / (sample_count - 1)
        flip = False
        points = []
        for i in range(sample_count):
            for j in range(sample_count):
                if(not flip):
                    idx = j
                else:
                    idx = sample_count -1 - j
                points.append([xps[i], min_y + interval_y * idx ])
            flip = not flip
        # calculate the points to put the nozzle at, and probe
        probe_points = []
        for i in range(len(points)):
            x = points[i][0] - self.probe_x_offset
            y = points[i][1] - self.probe_y_offset
            probe_points.append([x, y, self._auto_calibration((x,y))[2]])
        # calculate corrections
        x_corr, y_corr = self._calculate_corrections(probe_points)
        x_corr_str = ', '.join(["{:.6f}".format(x)
                                    for x in x_corr])
        y_corr_str = ', '.join(["{:.6f}".format(x)
                                    for x in y_corr])
        # finalize
        configfile = self.printer.lookup_object('configfile')
        configfile.set(self.configname, 'z_compensations', x_corr_str)
        configfile.set(self.configname, 'compensation_start_x',
                    self.x_start_point[0])
        configfile.set(self.configname, 'compensation_end_x',
                    self.x_end_point[0])
        configfile.set(self.configname, 'zy_compensations', y_corr_str)
        configfile.set(self.configname, 'compensation_start_y',
                    self.y_start_point[1])
        configfile.set(self.configname, 'compensation_end_y',
                    self.y_end_point[1])
        self.gcode.respond_info(
            "AXIS_TWIST_COMPENSATION state has been saved "
            "for the current session.  The SAVE_CONFIG command will "
            "update the printer config file and restart the printer.")
        # output result
        self.gcmd.respond_info(
            "AXIS_TWIST_COMPENSATION_AUTOCALIBRATE: Calibration complete: ")
        self.gcmd.respond_info("\n".join(map(str, [x_corr, y_corr])), log=False)
    def _auto_calibration(self, probe_point):
        # horizontal_move_z (to prevent probe trigger or hitting bed)
        self._move_helper((None, None, self.horizontal_move_z))
        # move to point to probe
        self._move_helper((probe_point[0],
                            probe_point[1], None))
        # probe the point
        pos = probe.run_single_probe(self.probe, self.gcmd)
        # horizontal_move_z (to prevent probe trigger or hitting bed)
        self._move_helper((None, None, self.horizontal_move_z))
        return pos
    def _calculate_probe_points(self, nozzle_points,
        probe_x_offset, probe_y_offset):
        # calculate the points to put the nozzle at
--- a/klippy/extras/bed_mesh.py
+++ b/klippy/extras/bed_mesh.py
@@ -34,7 +34,7 @@ def constrain(val, min_val, max_val):
 def lerp(t, v0, v1):
    return (1. - t) * v0 + t * v1
-# retrieve comma separated pair from config
+# retreive commma separated pair from config
 def parse_config_pair(config, option, default, minval=None, maxval=None):
    pair = config.getintlist(option, (default, default))
    if len(pair) != 2:
@@ -54,7 +54,7 @@ def parse_config_pair(config, option, default, minval=None, maxval=None):
                % (option, str(maxval)))
    return pair
-# retrieve comma separated pair from a g-code command
+# retreive commma separated pair from a g-code command
 def parse_gcmd_pair(gcmd, name, minval=None, maxval=None):
    try:
        pair = [int(v.strip()) for v in gcmd.get(name).split(',')]
@@ -74,7 +74,7 @@ def parse_gcmd_pair(gcmd, name, minval=None, maxval=None):
                             % (name, maxval))
    return pair
-# retrieve comma separated coordinate from a g-code command
+# retreive commma separated coordinate from a g-code command
 def parse_gcmd_coord(gcmd, name):
    try:
        v1, v2 = [float(v.strip()) for v in gcmd.get(name).split(',')]
@@ -133,7 +133,7 @@ class BedMesh:
        self.update_status()
    def handle_connect(self):
        self.toolhead = self.printer.lookup_object('toolhead')
-        self.bmc.print_generated_points(logging.info, truncate=True)
+        self.bmc.print_generated_points(logging.info)
    def set_mesh(self, mesh):
        if mesh is not None and self.fade_end != self.FADE_DISABLE:
            self.log_fade_complete = True
@@ -186,8 +186,7 @@ class BedMesh:
            self.last_position[2] -= self.fade_target
        else:
            # return current position minus the current z-adjustment
-            cur_pos = self.toolhead.get_position()
+            x, y, z, e = self.toolhead.get_position()
            x, y, z = cur_pos[:3]
            max_adj = self.z_mesh.calc_z(x, y)
            factor = 1.
            z_adj = max_adj - self.fade_target
@@ -203,19 +202,19 @@ class BedMesh:
                          (self.fade_dist - z_adj))
                factor = constrain(factor, 0., 1.)
            final_z_adj = factor * z_adj + self.fade_target
-            self.last_position[:] = [x, y, z - final_z_adj] + cur_pos[3:]
+            self.last_position[:] = [x, y, z - final_z_adj, e]
        return list(self.last_position)
    def move(self, newpos, speed):
        factor = self.get_z_factor(newpos[2])
        if self.z_mesh is None or not factor:
            # No mesh calibrated, or mesh leveling phased out.
-            x, y, z = newpos[:3]
+            x, y, z, e = newpos
            if self.log_fade_complete:
                self.log_fade_complete = False
                logging.info(
                    "bed_mesh fade complete: Current Z: %.4f fade_target: %.4f "
                    % (z, self.fade_target))
-            self.toolhead.move([x, y, z + self.fade_target] + newpos[3:], speed)
+            self.toolhead.move([x, y, z + self.fade_target, e], speed)
        else:
            self.splitter.build_move(self.last_position, newpos, factor)
            while not self.splitter.traverse_complete:
@@ -347,7 +346,7 @@ class BedMeshCalibrate:
        self.gcode.register_command(
            'BED_MESH_CALIBRATE', self.cmd_BED_MESH_CALIBRATE,
            desc=self.cmd_BED_MESH_CALIBRATE_help)
-    def print_generated_points(self, print_func, truncate=False):
+    def print_generated_points(self, print_func):
        x_offset = y_offset = 0.
        probe = self.printer.lookup_object('probe', None)
        if probe is not None:
@@ -356,10 +355,6 @@ class BedMeshCalibrate:
                   " |  Tool Adjusted  |   Probe")
        points = self.probe_mgr.get_base_points()
        for i, (x, y) in enumerate(points):
            if i >= 50 and truncate:
                end = len(points) - 1
                print_func("...points %d through %d truncated" % (i, end))
                break
            adj_pt = "(%.1f, %.1f)" % (x - x_offset, y - y_offset)
            mesh_pt = "(%.1f, %.1f)" % (x, y)
            print_func(
@@ -618,6 +613,8 @@ class BedMeshCalibrate:
                self.mesh_config, self.mesh_min, self.mesh_max,
                self.radius, self.origin, probe_method
            )
            gcmd.respond_info("Generating new points...")
            self.print_generated_points(gcmd.respond_info)
            msg = "\n".join(["%s: %s" % (k, v)
                             for k, v in self.mesh_config.items()])
            logging.info("Updated Mesh Configuration:\n" + msg)
@@ -914,7 +911,7 @@ class ProbeManager:
        for i in range(y_cnt):
            for j in range(x_cnt):
                if not i % 2:
-                    # move in positive direction
+                    # move in positive directon
                    pos_x = min_x + j * x_dist
                else:
                    # move in negative direction
@@ -1164,7 +1161,7 @@ class ProbeManager:
    def _gen_arc(self, origin, radius, start, step, count):
        end = start + step * count
-        # create a segent for every 3 degrees of travel
+        # create a segent for every 3 degress of travel
        for angle in range(start, end, step):
            rad = math.radians(angle % 360)
            opp = math.sin(rad) * radius
@@ -1274,7 +1271,7 @@ class MoveSplitter:
        self.z_offset = self._calc_z_offset(prev_pos)
        self.traverse_complete = False
        self.distance_checked = 0.
-        axes_d = [np - pp for np, pp in zip(self.next_pos, self.prev_pos)]
+        axes_d = [self.next_pos[i] - self.prev_pos[i] for i in range(4)]
        self.total_move_length = math.sqrt(sum([d*d for d in axes_d[:3]]))
        self.axis_move = [not isclose(d, 0., abs_tol=1e-10) for d in axes_d]
    def _calc_z_offset(self, pos):
@@ -1287,7 +1284,7 @@ class MoveSplitter:
            raise self.gcode.error(
                "bed_mesh: Slice distance is negative "
                "or greater than entire move length")
-        for i in range(len(self.next_pos)):
+        for i in range(4):
            if self.axis_move[i]:
                self.current_pos[i] = lerp(
                    t, self.prev_pos[i], self.next_pos[i])
@@ -1302,9 +1299,9 @@ class MoveSplitter:
                    next_z = self._calc_z_offset(self.current_pos)
                    if abs(next_z - self.z_offset) >= self.split_delta_z:
                        self.z_offset = next_z
-                        newpos = list(self.current_pos)
+                        return self.current_pos[0], self.current_pos[1], \
-                        newpos[2] += self.z_offset
+                            self.current_pos[2] + self.z_offset, \
-                        return newpos
+                            self.current_pos[3]
            # end of move reached
            self.current_pos[:] = self.next_pos
            self.z_offset = self._calc_z_offset(self.current_pos)
--- a/klippy/extras/bed_tilt.py
+++ b/klippy/extras/bed_tilt.py
@@ -24,14 +24,12 @@ class BedTilt:
    def handle_connect(self):
        self.toolhead = self.printer.lookup_object('toolhead')
    def get_position(self):
-        pos = self.toolhead.get_position()
+        x, y, z, e = self.toolhead.get_position()
-        x, y, z = pos[:3]
+        return [x, y, z - x*self.x_adjust - y*self.y_adjust - self.z_adjust, e]
        z -= x*self.x_adjust + y*self.y_adjust + self.z_adjust
        return [x, y, z] + pos[3:]
    def move(self, newpos, speed):
-        x, y, z = newpos[:3]
+        x, y, z, e = newpos
-        z += x*self.x_adjust + y*self.y_adjust + self.z_adjust
+        self.toolhead.move([x, y, z + x*self.x_adjust + y*self.y_adjust
-        self.toolhead.move([x, y, z] + newpos[3:], speed)
+                            + self.z_adjust, e], speed)
    def update_adjust(self, x_adjust, y_adjust, z_adjust):
        self.x_adjust = x_adjust
        self.y_adjust = y_adjust
--- a/klippy/extras/bltouch.py
+++ b/klippy/extras/bltouch.py
@@ -64,11 +64,7 @@ class BLTouchProbe:
        self.cmd_helper = probe.ProbeCommandHelper(
            config, self, self.mcu_endstop.query_endstop)
        self.probe_offsets = probe.ProbeOffsetsHelper(config)
-        self.param_helper = probe.ProbeParameterHelper(config)
+        self.probe_session = probe.ProbeSessionHelper(config, self)
        self.homing_helper = probe.HomingViaProbeHelper(config, self,
                                                        self.param_helper)
        self.probe_session = probe.ProbeSessionHelper(
            config, self.param_helper, self.homing_helper.start_probe_session)
        # Register BLTOUCH_DEBUG command
        self.gcode = self.printer.lookup_object('gcode')
        self.gcode.register_command("BLTOUCH_DEBUG", self.cmd_BLTOUCH_DEBUG,
@@ -79,7 +75,7 @@ class BLTouchProbe:
        self.printer.register_event_handler("klippy:connect",
                                            self.handle_connect)
    def get_probe_params(self, gcmd=None):
-        return self.param_helper.get_probe_params(gcmd)
+        return self.probe_session.get_probe_params(gcmd)
    def get_offsets(self):
        return self.probe_offsets.get_offsets()
    def get_status(self, eventtime):
@@ -195,6 +191,9 @@ class BLTouchProbe:
        self.verify_raise_probe()
        self.sync_print_time()
        self.multi = 'OFF'
    def probing_move(self, pos, speed):
        phoming = self.printer.lookup_object('homing')
        return phoming.probing_move(self, pos, speed)
    def probe_prepare(self, hmove):
        if self.multi == 'OFF' or self.multi == 'FIRST':
            self.lower_probe()
--- a/klippy/extras/bme280.py
+++ b/klippy/extras/bme280.py
@@ -284,7 +284,7 @@ class BME280:
                self.chip_type, self.i2c.i2c_address))
        # Reset chip
-        self.write_register('RESET', [RESET_CHIP_VALUE])
+        self.write_register('RESET', [RESET_CHIP_VALUE], wait=True)
        self.reactor.pause(self.reactor.monotonic() + .5)
        # Make sure non-volatile memory has been copied to registers
@@ -394,7 +394,7 @@ class BME280:
                self.write_register('CTRL_HUM', self.os_hum)
            # Enter normal (periodic) mode
            meas = self.os_temp << 5 | self.os_pres << 2 | MODE_PERIODIC
-            self.write_register('CTRL_MEAS', meas)
+            self.write_register('CTRL_MEAS', meas, wait=True)
        if self.chip_type == 'BME680':
            self.write_register('CONFIG', self.iir_filter << 2)
@@ -528,7 +528,7 @@ class BME280:
        # Enter forced mode
        meas = self.os_temp << 5 | self.os_pres << 2 | MODE
-        self.write_register('CTRL_MEAS', meas)
+        self.write_register('CTRL_MEAS', meas, wait=True)
        max_sample_time = self.max_sample_time
        if run_gas:
            max_sample_time += self.gas_heat_duration / 1000
@@ -776,12 +776,15 @@ class BME280:
        params = self.i2c.i2c_read(regs, read_len)
        return bytearray(params['response'])
-    def write_register(self, reg_name, data):
+    def write_register(self, reg_name, data, wait = False):
        if type(data) is not list:
            data = [data]
        reg = self.chip_registers[reg_name]
        data.insert(0, reg)
        if not wait:
            self.i2c.i2c_write(data)
        else:
            self.i2c.i2c_write_wait_ack(data)
    def get_status(self, eventtime):
        data = {
--- a/klippy/extras/bus.py
+++ b/klippy/extras/bus.py
@@ -43,7 +43,6 @@ class MCU_SPI:
                 cs_active_high=False):
        self.mcu = mcu
        self.bus = bus
        self.speed = speed
        # Config SPI object (set all CS pins high before spi_set_bus commands)
        self.oid = mcu.create_oid()
        if pin is None:
@@ -52,17 +51,11 @@ class MCU_SPI:
            mcu.add_config_cmd("config_spi oid=%d pin=%s cs_active_high=%d"
                               % (self.oid, pin, cs_active_high))
        # Generate SPI bus config message
        self.config_fmt_ticks = None
        if sw_pins is not None:
            self.config_fmt = (
                "spi_set_software_bus oid=%d"
                " miso_pin=%s mosi_pin=%s sclk_pin=%s mode=%d rate=%d"
                % (self.oid, sw_pins[0], sw_pins[1], sw_pins[2], mode, speed))
            self.config_fmt_ticks = (
                "spi_set_sw_bus oid=%d"
                " miso_pin=%s mosi_pin=%s sclk_pin=%s mode=%d pulse_ticks=%%d"
                % (self.oid, sw_pins[0], sw_pins[1],
                    sw_pins[2], mode))
        else:
            self.config_fmt = (
                "spi_set_bus oid=%d spi_bus=%%s mode=%d rate=%d"
@@ -85,12 +78,6 @@ class MCU_SPI:
        if '%' in self.config_fmt:
            bus = resolve_bus_name(self.mcu, "spi_bus", self.bus)
            self.config_fmt = self.config_fmt % (bus,)
        if self.config_fmt_ticks:
            if self.mcu.try_lookup_command("spi_set_sw_bus oid=%c miso_pin=%u "
                                           "mosi_pin=%u sclk_pin=%u "
                                           "mode=%u pulse_ticks=%u"):
                pulse_ticks = self.mcu.seconds_to_clock(1./self.speed)
                self.config_fmt = self.config_fmt_ticks % (pulse_ticks,)
        self.mcu.add_config_cmd(self.config_fmt)
        self.spi_send_cmd = self.mcu.lookup_command(
            "spi_send oid=%c data=%*s", cq=self.cmd_queue)
@@ -160,8 +147,6 @@ class MCU_I2C:
        self.bus = bus
        self.i2c_address = addr
        self.oid = self.mcu.create_oid()
        self.speed = speed
        self.config_fmt_ticks = None
        mcu.add_config_cmd("config_i2c oid=%d" % (self.oid,))
        # Generate I2C bus config message
        if sw_pins is not None:
@@ -169,10 +154,6 @@ class MCU_I2C:
                "i2c_set_software_bus oid=%d"
                " scl_pin=%s sda_pin=%s rate=%d address=%d"
                % (self.oid, sw_pins[0], sw_pins[1], speed, addr))
            self.config_fmt_ticks = (
                "i2c_set_sw_bus oid=%d"
                " scl_pin=%s sda_pin=%s pulse_ticks=%%d address=%d"
                % (self.oid, sw_pins[0], sw_pins[1], addr))
        else:
            self.config_fmt = (
                "i2c_set_bus oid=%d i2c_bus=%%s rate=%d address=%d"
@@ -180,13 +161,6 @@ class MCU_I2C:
        self.cmd_queue = self.mcu.alloc_command_queue()
        self.mcu.register_config_callback(self.build_config)
        self.i2c_write_cmd = self.i2c_read_cmd = None
        printer = self.mcu.get_printer()
        printer.register_event_handler("klippy:connect", self._handle_connect)
        # backward support i2c_write inside the init section
        self._to_write = []
    def _handle_connect(self):
        for data in self._to_write:
            self.i2c_write(data)
    def get_oid(self):
        return self.oid
    def get_mcu(self):
@@ -199,12 +173,6 @@ class MCU_I2C:
        if '%' in self.config_fmt:
            bus = resolve_bus_name(self.mcu, "i2c_bus", self.bus)
            self.config_fmt = self.config_fmt % (bus,)
        if self.config_fmt_ticks:
            if self.mcu.try_lookup_command("i2c_set_sw_bus oid=%c"
                                           " scl_pin=%u sda_pin=%u"
                                           " pulse_ticks=%u address=%u"):
                pulse_ticks = self.mcu.seconds_to_clock(1./self.speed/2)
                self.config_fmt = self.config_fmt_ticks % (pulse_ticks,)
        self.mcu.add_config_cmd(self.config_fmt)
        self.i2c_write_cmd = self.mcu.lookup_command(
            "i2c_write oid=%c data=%*s", cq=self.cmd_queue)
@@ -214,12 +182,18 @@ class MCU_I2C:
            cq=self.cmd_queue)
    def i2c_write(self, data, minclock=0, reqclock=0):
        if self.i2c_write_cmd is None:
-            self._to_write.append(data)
+            # Send setup message via mcu initialization
            data_msg = "".join(["%02x" % (x,) for x in data])
            self.mcu.add_config_cmd("i2c_write oid=%d data=%s" % (
                self.oid, data_msg), is_init=True)
            return
        self.i2c_write_cmd.send([self.oid, data],
                                minclock=minclock, reqclock=reqclock)
    def i2c_write_wait_ack(self, data, minclock=0, reqclock=0):
        self.i2c_write_cmd.send_wait_ack([self.oid, data],
                                minclock=minclock, reqclock=reqclock)
-    def i2c_read(self, write, read_len, retry=True):
+    def i2c_read(self, write, read_len):
-        return self.i2c_read_cmd.send([self.oid, write, read_len], retry)
+        return self.i2c_read_cmd.send([self.oid, write, read_len])
 def MCU_I2C_from_config(config, default_addr=None, default_speed=100000):
    # Load bus parameters
--- a/klippy/extras/buttons.py
+++ b/klippy/extras/buttons.py
@@ -244,33 +244,6 @@ class HalfStepRotaryEncoder(BaseRotaryEncoder):
         BaseRotaryEncoder.R_START | BaseRotaryEncoder.R_DIR_CCW),
    )
 class DebounceButton:
    def __init__(self, config, button_action):
        self.printer = config.get_printer()
        self.reactor = self.printer.get_reactor()
        self.button_action = button_action
        self.debounce_delay = config.getfloat('debounce_delay', 0., minval=0.)
        self.logical_state = None
        self.physical_state = None
        self.latest_eventtime = None
    def button_handler(self, eventtime, state):
        self.physical_state = state
        self.latest_eventtime = eventtime
        # if there would be no state transition, ignore the event:
        if self.logical_state == self.physical_state:
            return
        trigger_time = eventtime + self.debounce_delay
        self.reactor.register_callback(self._debounce_event, trigger_time)
    def _debounce_event(self, eventtime):
        # if there would be no state transition, ignore the event:
        if self.logical_state == self.physical_state:
            return
        # if there were more recent events, they supersede this one:
        if (eventtime - self.debounce_delay) < self.latest_eventtime:
            return
        # enact state transition and trigger action
        self.logical_state = self.physical_state
        self.button_action(self.latest_eventtime, self.logical_state)
 ######################################################################
 # Button registration code
@@ -288,14 +261,6 @@ class PrinterButtons:
            self.adc_buttons[pin] = adc_buttons = MCU_ADC_buttons(
                self.printer, pin, pullup)
        adc_buttons.setup_button(min_val, max_val, callback)
    def register_debounce_button(self, pin, callback, config):
        debounce = DebounceButton(config, callback)
        return self.register_buttons([pin], debounce.button_handler)
    def register_debounce_adc_button(self, pin, min_val, max_val, pullup
                                     , callback, config):
        debounce = DebounceButton(config, callback)
        return self.register_adc_button(pin, min_val, max_val, pullup
                                        , debounce.button_handler)
    def register_adc_button_push(self, pin, min_val, max_val, pullup, callback):
        def helper(eventtime, state, callback=callback):
            if state:
--- a/klippy/extras/canbus_stats.py
+++ b/klippy/extras/canbus_stats.py
@@ -1,80 +0,0 @@
 # Report canbus connection status
 #
 # Copyright (C) 2025  Kevin O'Connor <kevin@koconnor.net>
 #
 # This file may be distributed under the terms of the GNU GPLv3 license.
 import logging
 class PrinterCANBusStats:
    def __init__(self, config):
        self.printer = config.get_printer()
        self.reactor = self.printer.get_reactor()
        self.name = config.get_name().split()[-1]
        self.mcu = None
        self.get_canbus_status_cmd = None
        self.status = {'rx_error': None, 'tx_error': None, 'tx_retries': None,
                       'bus_state': None}
        self.printer.register_event_handler("klippy:connect",
                                            self.handle_connect)
        self.printer.register_event_handler("klippy:shutdown",
                                            self.handle_shutdown)
    def handle_shutdown(self):
        status = self.status.copy()
        if status['bus_state'] is not None:
            # Clear bus_state on shutdown to note that the values may be stale
            status['bus_state'] = 'unknown'
            self.status = status
    def handle_connect(self):
        # Lookup mcu
        mcu_name = self.name
        if mcu_name != 'mcu':
            mcu_name = 'mcu ' + mcu_name
        self.mcu = self.printer.lookup_object(mcu_name)
        # Lookup status query command
        if self.mcu.try_lookup_command("get_canbus_status") is None:
            return
        self.get_canbus_status_cmd = self.mcu.lookup_query_command(
            "get_canbus_status",
            "canbus_status rx_error=%u tx_error=%u tx_retries=%u"
            " canbus_bus_state=%u")
        # Register usb_canbus_state message handling (for usb to canbus bridge)
        self.mcu.register_response(self.handle_usb_canbus_state,
                                   "usb_canbus_state")
        # Register periodic query timer
        self.reactor.register_timer(self.query_event, self.reactor.NOW)
    def handle_usb_canbus_state(self, params):
        discard = params['discard']
        if discard:
            logging.warning("USB CANBUS bridge '%s' is discarding!"
                            % (self.name,))
        else:
            logging.warning("USB CANBUS bridge '%s' is no longer discarding."
                            % (self.name,))
    def query_event(self, eventtime):
        prev_rx = self.status['rx_error']
        prev_tx = self.status['tx_error']
        prev_retries = self.status['tx_retries']
        if prev_rx is None:
            prev_rx = prev_tx = prev_retries = 0
        params = self.get_canbus_status_cmd.send()
        rx = prev_rx + ((params['rx_error'] - prev_rx) & 0xffffffff)
        tx = prev_tx + ((params['tx_error'] - prev_tx) & 0xffffffff)
        retries = prev_retries + ((params['tx_retries'] - prev_retries)
                                  & 0xffffffff)
        state = params['canbus_bus_state']
        self.status = {'rx_error': rx, 'tx_error': tx, 'tx_retries': retries,
                       'bus_state': state}
        return self.reactor.monotonic() + 1.
    def stats(self, eventtime):
        status = self.status
        if status['rx_error'] is None:
            return (False, '')
        return (False, 'canstat_%s: bus_state=%s rx_error=%d'
                ' tx_error=%d tx_retries=%d'
                % (self.name, status['bus_state'], status['rx_error'],
                   status['tx_error'], status['tx_retries']))
    def get_status(self, eventtime):
        return self.status
 def load_config_prefix(config):
    return PrinterCANBusStats(config)
--- a/klippy/extras/display/init.py
+++ b/klippy/extras/display/init.py
@@ -12,7 +12,7 @@ def load_config_prefix(config):
    if not config.has_section('display'):
        raise config.error(
            "A primary [display] section must be defined in printer.cfg "
-            "to use auxiliary displays")
+            "to use auxilary displays")
    name = config.get_name().split()[-1]
    if name == "display":
        raise config.error(
--- a/klippy/extras/display/font8x14.py
+++ b/klippy/extras/display/font8x14.py
@@ -13,7 +13,7 @@
 # ftp://ftp.simtel.net/pub/simtelnet/msdos/screen/fntcol16.zip
 # (c) Joseph Gil
 #
-# Individual fonts are public domain
+# Indivdual fonts are public domain
 ######################################################################
 VGA_FONT = [
--- a/klippy/extras/endstop_phase.py
+++ b/klippy/extras/endstop_phase.py
@@ -52,7 +52,7 @@ class PhaseCalc:
 class EndstopPhase:
    def __init__(self, config):
        self.printer = config.get_printer()
-        self.name = " ".join(config.get_name().split()[1:])
+        self.name = config.get_name().split()[1]
        # Obtain step_distance and microsteps from stepper config section
        sconfig = config.getsection(self.name)
        rotation_dist, steps_per_rotation = stepper.parse_step_distance(sconfig)
@@ -118,7 +118,7 @@ class EndstopPhase:
        return delta * self.step_dist
    def handle_home_rails_end(self, homing_state, rails):
        for rail in rails:
-            stepper = rail.get_endstops()[0][0].get_steppers()[0]
+            stepper = rail.get_steppers()[0]
            if stepper.get_name() == self.name:
                trig_mcu_pos = homing_state.get_trigger_position(self.name)
                align = self.align_endstop(rail)
--- a/klippy/extras/exclude_object.py
+++ b/klippy/extras/exclude_object.py
@@ -82,25 +82,24 @@ class ExcludeObject:
        self._reset_state()
        self._unregister_transform()
-    def _get_extrusion_offsets(self, num_coord):
+    def _get_extrusion_offsets(self):
-        ename = self.toolhead.get_extruder().get_name()
+        offset = self.extrusion_offsets.get(
-        offset = self.extrusion_offsets.get(ename)
+            self.toolhead.get_extruder().get_name())
        if offset is None:
-            offset = [0.] * num_coord
+            offset = [0., 0., 0., 0.]
-            self.extrusion_offsets[ename] = offset
+            self.extrusion_offsets[self.toolhead.get_extruder().get_name()] = \
-        if len(offset) < num_coord:
+                offset
            offset.extend([0.] * (len(num_coord) - len(offset)))
        return offset
    def get_position(self):
        offset = self._get_extrusion_offsets()
        pos = self.next_transform.get_position()
-        offset = self._get_extrusion_offsets(len(pos))
+        for i in range(4):
        for i in range(len(pos)):
            self.last_position[i] = pos[i] + offset[i]
        return list(self.last_position)
    def _normal_move(self, newpos, speed):
-        offset = self._get_extrusion_offsets(len(newpos))
+        offset = self._get_extrusion_offsets()
        if self.initial_extrusion_moves > 0 and \
            self.last_position[3] != newpos[3]:
@@ -123,9 +122,9 @@ class ExcludeObject:
        if (offset[0] != 0 or offset[1] != 0) and \
            (newpos[0] != self.last_position_excluded[0] or \
            newpos[1] != self.last_position_excluded[1]):
-            for i in range(len(newpos)):
+            offset[0] = 0
-                if i != 3:
+            offset[1] = 0
-                    offset[i] = 0
+            offset[2] = 0
            offset[3] += self.extruder_adj
            self.extruder_adj = 0
@@ -138,14 +137,13 @@ class ExcludeObject:
            self.extruder_adj = 0
        tx_pos = newpos[:]
-        for i in range(len(newpos)):
+        for i in range(4):
            tx_pos[i] = newpos[i] - offset[i]
        self.next_transform.move(tx_pos, speed)
    def _ignore_move(self, newpos, speed):
-        offset = self._get_extrusion_offsets(len(newpos))
+        offset = self._get_extrusion_offsets()
-        for i in range(len(newpos)):
+        for i in range(3):
            if i != 3:
            offset[i] = newpos[i] - self.last_position_extruded[i]
        offset[3] = offset[3] + newpos[3] - self.last_position[3]
        self.last_position[:] = newpos
--- a/klippy/extras/fan_generic.py
+++ b/klippy/extras/fan_generic.py
@@ -29,7 +29,6 @@ class PrinterFanGeneric:
            value = float(text)
        except ValueError as e:
            logging.exception("fan_generic template render error")
            value = 0.
        self.fan.set_speed(value)
    def cmd_SET_FAN_SPEED(self, gcmd):
        speed = gcmd.get_float('SPEED', None, 0.)
--- a/klippy/extras/filament_motion_sensor.py
+++ b/klippy/extras/filament_motion_sensor.py
@@ -63,7 +63,7 @@ class EncoderSensor:
    def _extruder_pos_update_event(self, eventtime):
        extruder_pos = self._get_extruder_pos(eventtime)
        # Check for filament runout
-        self.runout_helper.note_filament_present(eventtime,
+        self.runout_helper.note_filament_present(
                extruder_pos < self.filament_runout_pos)
        return eventtime + CHECK_RUNOUT_TIMEOUT
    def encoder_event(self, eventtime, state):
@@ -71,7 +71,7 @@ class EncoderSensor:
            self._update_filament_runout_pos(eventtime)
            # Check for filament insertion
            # Filament is always assumed to be present on an encoder event
-            self.runout_helper.note_filament_present(eventtime, True)
+            self.runout_helper.note_filament_present(True)
 def load_config_prefix(config):
    return EncoderSensor(config)
--- a/klippy/extras/filament_switch_sensor.py
+++ b/klippy/extras/filament_switch_sensor.py
@@ -5,7 +5,6 @@
 # This file may be distributed under the terms of the GNU GPLv3 license.
 import logging
 class RunoutHelper:
    def __init__(self, config):
        self.name = config.get_name().split()[-1]
@@ -25,7 +24,7 @@ class RunoutHelper:
            self.insert_gcode = gcode_macro.load_template(
                config, 'insert_gcode')
        self.pause_delay = config.getfloat('pause_delay', .5, above=.0)
-        self.event_delay = config.getfloat('event_delay', 3., minval=.0)
+        self.event_delay = config.getfloat('event_delay', 3., above=0.)
        # Internal state
        self.min_event_systime = self.reactor.NEVER
        self.filament_present = False
@@ -60,20 +59,19 @@ class RunoutHelper:
        except Exception:
            logging.exception("Script running error")
        self.min_event_systime = self.reactor.monotonic() + self.event_delay
-    def note_filament_present(self, eventtime, is_filament_present):
+    def note_filament_present(self, is_filament_present):
        if is_filament_present == self.filament_present:
            return
        self.filament_present = is_filament_present
-
+        eventtime = self.reactor.monotonic()
        if eventtime < self.min_event_systime or not self.sensor_enabled:
            # do not process during the initialization time, duplicates,
            # during the event delay time, while an event is running, or
            # when the sensor is disabled
            return
        # Determine "printing" status
        now = self.reactor.monotonic()
        idle_timeout = self.printer.lookup_object("idle_timeout")
-        is_printing = idle_timeout.get_status(now)["state"] == "Printing"
+        is_printing = idle_timeout.get_status(eventtime)["state"] == "Printing"
        # Perform filament action associated with status change (if any)
        if is_filament_present:
            if not is_printing and self.insert_gcode is not None:
@@ -81,14 +79,14 @@ class RunoutHelper:
                self.min_event_systime = self.reactor.NEVER
                logging.info(
                    "Filament Sensor %s: insert event detected, Time %.2f" %
-                    (self.name, now))
+                    (self.name, eventtime))
                self.reactor.register_callback(self._insert_event_handler)
        elif is_printing and self.runout_gcode is not None:
            # runout detected
            self.min_event_systime = self.reactor.NEVER
            logging.info(
                "Filament Sensor %s: runout event detected, Time %.2f" %
-                (self.name, now))
+                (self.name, eventtime))
            self.reactor.register_callback(self._runout_event_handler)
    def get_status(self, eventtime):
        return {
@@ -110,12 +108,11 @@ class SwitchSensor:
        printer = config.get_printer()
        buttons = printer.load_object(config, 'buttons')
        switch_pin = config.get('switch_pin')
-        buttons.register_debounce_button(switch_pin, self._button_handler
+        buttons.register_buttons([switch_pin], self._button_handler)
                                         , config)
        self.runout_helper = RunoutHelper(config)
        self.get_status = self.runout_helper.get_status
    def _button_handler(self, eventtime, state):
-        self.runout_helper.note_filament_present(eventtime, state)
+        self.runout_helper.note_filament_present(state)
 def load_config_prefix(config):
    return SwitchSensor(config)
--- a/klippy/extras/firmware_retraction.py
+++ b/klippy/extras/firmware_retraction.py
@@ -43,7 +43,7 @@ class FirmwareRetraction:
        self.unretract_length = (self.retract_length
                                 + self.unretract_extra_length)
        self.is_retracted = False
-    cmd_GET_RETRACTION_help = ("Report firmware retraction parameters")
+    cmd_GET_RETRACTION_help = ("Report firmware retraction paramters")
    def cmd_GET_RETRACTION(self, gcmd):
        gcmd.respond_info("RETRACT_LENGTH=%.5f RETRACT_SPEED=%.5f"
                          " UNRETRACT_EXTRA_LENGTH=%.5f UNRETRACT_SPEED=%.5f"
--- a/klippy/extras/force_move.py
+++ b/klippy/extras/force_move.py
@@ -33,10 +33,10 @@ class ForceMove:
        self.printer = config.get_printer()
        self.steppers = {}
        # Setup iterative solver
        self.motion_queuing = self.printer.load_object(config, 'motion_queuing')
        self.trapq = self.motion_queuing.allocate_trapq()
        self.trapq_append = self.motion_queuing.lookup_trapq_append()
        ffi_main, ffi_lib = chelper.get_ffi()
        self.trapq = ffi_main.gc(ffi_lib.trapq_alloc(), ffi_lib.trapq_free)
        self.trapq_append = ffi_lib.trapq_append
        self.trapq_finalize_moves = ffi_lib.trapq_finalize_moves
        self.stepper_kinematics = ffi_main.gc(
            ffi_lib.cartesian_stepper_alloc(b'x'), ffi_lib.free)
        # Register commands
@@ -85,12 +85,14 @@ class ForceMove:
        self.trapq_append(self.trapq, print_time, accel_t, cruise_t, accel_t,
                          0., 0., 0., axis_r, 0., 0., 0., cruise_v, accel)
        print_time = print_time + accel_t + cruise_t + accel_t
        stepper.generate_steps(print_time)
        self.trapq_finalize_moves(self.trapq, print_time + 99999.9,
                                  print_time + 99999.9)
        stepper.set_trapq(prev_trapq)
        stepper.set_stepper_kinematics(prev_sk)
        toolhead.note_mcu_movequeue_activity(print_time)
        toolhead.dwell(accel_t + cruise_t + accel_t)
        toolhead.flush_step_generation()
        stepper.set_trapq(prev_trapq)
        stepper.set_stepper_kinematics(prev_sk)
        self.motion_queuing.wipe_trapq(self.trapq)
    def _lookup_stepper(self, gcmd):
        name = gcmd.get('STEPPER')
        if name not in self.steppers:
@@ -129,19 +131,12 @@ class ForceMove:
        x = gcmd.get_float('X', curpos[0])
        y = gcmd.get_float('Y', curpos[1])
        z = gcmd.get_float('Z', curpos[2])
-        set_homed = gcmd.get('SET_HOMED', 'xyz').lower()
+        clear = gcmd.get('CLEAR', '').lower()
-        set_homed_axes = "".join([a for a in "xyz" if a in set_homed])
+        clear_axes = "".join([a for a in "xyz" if a in clear])
-        if gcmd.get('CLEAR_HOMED', None) is None:
+        logging.info("SET_KINEMATIC_POSITION pos=%.3f,%.3f,%.3f clear=%s",
-            # "CLEAR" is an alias for "CLEAR_HOMED"; should deprecate
+                     x, y, z, clear_axes)
-            clear_homed = gcmd.get('CLEAR', '').lower()
+        toolhead.set_position([x, y, z, curpos[3]], homing_axes="xyz")
-        else:
+        toolhead.get_kinematics().clear_homing_state(clear_axes)
            clear_homed = gcmd.get('CLEAR_HOMED', '').lower()
        clear_homed_axes = "".join([a for a in "xyz" if a in clear_homed])
        logging.info("SET_KINEMATIC_POSITION pos=%.3f,%.3f,%.3f"
                     " set_homed=%s clear_homed=%s",
                     x, y, z, set_homed_axes, clear_homed_axes)
        toolhead.set_position([x, y, z], homing_axes=set_homed_axes)
        toolhead.get_kinematics().clear_homing_state(clear_homed_axes)
 def load_config(config):
    return ForceMove(config)
--- a/klippy/extras/garbage_collection.py
+++ b/klippy/extras/garbage_collection.py
@@ -1,31 +0,0 @@
 # Garbage collection optimizations
 #
 # Copyright (C) 2025  Branden Cash <ammmze@gmail.com>
 #
 # This file may be distributed under the terms of the GNU GPLv3 license.
 import gc
 import logging
 class GarbageCollection:
    def __init__(self, config):
        self.printer = config.get_printer()
        # feature check ... freeze/unfreeze is only available in python 3.7+
        can_freeze = hasattr(gc, 'freeze') and hasattr(gc, 'unfreeze')
        if can_freeze:
            self.printer.register_event_handler("klippy:ready",
                                                self._handle_ready)
            self.printer.register_event_handler("klippy:disconnect",
                                                self._handle_disconnect)
    def _handle_ready(self):
        logging.debug("Running full garbage collection and freezing")
        for n in range(3):
            gc.collect(n)
        gc.freeze()
    def _handle_disconnect(self):
        logging.debug("Unfreezing garbage collection")
        gc.unfreeze()
 def load_config(config):
    return GarbageCollection(config)
--- a/klippy/extras/gcode_button.py
+++ b/klippy/extras/gcode_button.py
@@ -5,7 +5,6 @@
 # This file may be distributed under the terms of the GNU GPLv3 license.
 import logging
 class GCodeButton:
    def __init__(self, config):
        self.printer = config.get_printer()
@@ -14,13 +13,12 @@ class GCodeButton:
        self.last_state = 0
        buttons = self.printer.load_object(config, "buttons")
        if config.get('analog_range', None) is None:
-            buttons.register_debounce_button(self.pin, self.button_callback
+            buttons.register_buttons([self.pin], self.button_callback)
                                             , config)
        else:
            amin, amax = config.getfloatlist('analog_range', count=2)
            pullup = config.getfloat('analog_pullup_resistor', 4700., above=0.)
-            buttons.register_debounce_adc_button(self.pin, amin, amax, pullup,
+            buttons.register_adc_button(self.pin, amin, amax, pullup,
-                                        self.button_callback, config)
+                                        self.button_callback)
        gcode_macro = self.printer.load_object(config, 'gcode_macro')
        self.press_template = gcode_macro.load_template(config, 'press_gcode')
        self.release_template = gcode_macro.load_template(config,
--- a/klippy/extras/gcode_macro.py
+++ b/klippy/extras/gcode_macro.py
@@ -49,12 +49,6 @@ class TemplateWrapper:
        self.create_template_context = gcode_macro.create_template_context
        try:
            self.template = env.from_string(script)
        except jinja2.exceptions.TemplateSyntaxError as e:
            lines = script.splitlines()
            msg = "Error loading template '%s'\nline %s: %s # %s" % (
                name, e.lineno, lines[e.lineno-1], e.message)
            logging.exception(msg)
            raise self.gcode.error(msg)
        except Exception as e:
            msg = "Error loading template '%s': %s" % (
                 name, traceback.format_exception_only(type(e), e)[-1])
@@ -178,8 +172,8 @@ class GCodeMacro:
            literal = ast.literal_eval(value)
            json.dumps(literal, separators=(',', ':'))
        except (SyntaxError, TypeError, ValueError) as e:
-            raise gcmd.error("Unable to parse '%s' as a literal: %s in '%s'" %
+            raise gcmd.error("Unable to parse '%s' as a literal: %s" %
-                             (value, e, gcmd.get_commandline()))
+                             (value, e))
        v = dict(self.variables)
        v[variable] = literal
        self.variables = v
--- a/klippy/extras/gcode_move.py
+++ b/klippy/extras/gcode_move.py
@@ -1,6 +1,6 @@
 # G-Code G1 movement commands (and associated coordinate manipulation)
 #
-# Copyright (C) 2016-2025  Kevin O'Connor <kevin@koconnor.net>
+# Copyright (C) 2016-2021  Kevin O'Connor <kevin@koconnor.net>
 #
 # This file may be distributed under the terms of the GNU GPLv3 license.
 import logging
@@ -14,8 +14,6 @@ class GCodeMove:
                                       self.reset_last_position)
        printer.register_event_handler("toolhead:manual_move",
                                       self.reset_last_position)
        printer.register_event_handler("toolhead:update_extra_axes",
                                       self._update_extra_axes)
        printer.register_event_handler("gcode:command_error",
                                       self.reset_last_position)
        printer.register_event_handler("extruder:activate_extruder",
@@ -44,7 +42,6 @@ class GCodeMove:
        self.base_position = [0.0, 0.0, 0.0, 0.0]
        self.last_position = [0.0, 0.0, 0.0, 0.0]
        self.homing_position = [0.0, 0.0, 0.0, 0.0]
        self.axis_map = {'X':0, 'Y': 1, 'Z': 2, 'E': 3}
        self.speed = 25.
        self.speed_factor = 1. / 60.
        self.extrude_factor = 1.
@@ -105,46 +102,35 @@ class GCodeMove:
            'extrude_factor': self.extrude_factor,
            'absolute_coordinates': self.absolute_coord,
            'absolute_extrude': self.absolute_extrude,
-            'homing_origin': self.Coord(*self.homing_position[:4]),
+            'homing_origin': self.Coord(*self.homing_position),
-            'position': self.Coord(*self.last_position[:4]),
+            'position': self.Coord(*self.last_position),
-            'gcode_position': self.Coord(*move_position[:4]),
+            'gcode_position': self.Coord(*move_position),
        }
    def reset_last_position(self):
        if self.is_printer_ready:
            self.last_position = self.position_with_transform()
    def _update_extra_axes(self):
        toolhead = self.printer.lookup_object('toolhead')
        axis_map = {'X':0, 'Y': 1, 'Z': 2, 'E': 3}
        extra_axes = toolhead.get_extra_axes()
        for index, ea in enumerate(extra_axes):
            if ea is None:
                continue
            gcode_id = ea.get_axis_gcode_id()
            if gcode_id is None or gcode_id in axis_map or gcode_id in "FN":
                continue
            axis_map[gcode_id] = index
        self.axis_map = axis_map
        self.base_position[4:] = [0.] * (len(extra_axes) - 4)
        self.reset_last_position()
    # G-Code movement commands
    def cmd_G1(self, gcmd):
        # Move
        params = gcmd.get_command_parameters()
        try:
-            for axis, pos in self.axis_map.items():
+            for pos, axis in enumerate('XYZ'):
                if axis in params:
                    v = float(params[axis])
-                    absolute_coord = self.absolute_coord
+                    if not self.absolute_coord:
                    if axis == 'E':
                        v *= self.extrude_factor
                        if not self.absolute_extrude:
                            absolute_coord = False
                    if not absolute_coord:
                        # value relative to position of last move
                        self.last_position[pos] += v
                    else:
                        # value relative to base coordinate position
                        self.last_position[pos] = v + self.base_position[pos]
            if 'E' in params:
                v = float(params['E']) * self.extrude_factor
                if not self.absolute_coord or not self.absolute_extrude:
                    # value relative to position of last move
                    self.last_position[3] += v
                else:
                    # value relative to base coordinate position
                    self.last_position[3] = v + self.base_position[3]
            if 'F' in params:
                gcode_speed = float(params['F'])
                if gcode_speed <= 0.:
@@ -183,7 +169,7 @@ class GCodeMove:
                    offset *= self.extrude_factor
                self.base_position[i] = self.last_position[i] - offset
        if offsets == [None, None, None, None]:
-            self.base_position[:4] = self.last_position[:4]
+            self.base_position = list(self.last_position)
    def cmd_M114(self, gcmd):
        # Get Current Position
        p = self._get_gcode_position()
@@ -241,7 +227,7 @@ class GCodeMove:
        # Restore state
        self.absolute_coord = state['absolute_coord']
        self.absolute_extrude = state['absolute_extrude']
-        self.base_position[:4] = state['base_position'][:4]
+        self.base_position = list(state['base_position'])
        self.homing_position = list(state['homing_position'])
        self.speed = state['speed']
        self.speed_factor = state['speed_factor']
@@ -269,7 +255,7 @@ class GCodeMove:
        kinfo = zip("XYZ", kin.calc_position(dict(cinfo)))
        kin_pos = " ".join(["%s:%.6f" % (a, v) for a, v in kinfo])
        toolhead_pos = " ".join(["%s:%.6f" % (a, v) for a, v in zip(
-            "XYZE", toolhead.get_position()[:4])])
+            "XYZE", toolhead.get_position())])
        gcode_pos = " ".join(["%s:%.6f"  % (a, v)
                              for a, v in zip("XYZE", self.last_position)])
        base_pos = " ".join(["%s:%.6f"  % (a, v)
--- a/klippy/extras/hall_filament_width_sensor.py
+++ b/klippy/extras/hall_filament_width_sensor.py
@@ -125,7 +125,7 @@ class HallFilamentWidthSensor:
        # Update filament array for lastFilamentWidthReading
        self.update_filament_array(last_epos)
        # Check runout
-        self.runout_helper.note_filament_present(eventtime,
+        self.runout_helper.note_filament_present(
            self.runout_dia_min <= self.diameter <= self.runout_dia_max)
        # Does filament exists
        if self.diameter > 0.5:
@@ -209,12 +209,10 @@ class HallFilamentWidthSensor:
                      +self.lastFilamentWidthReading2))
        gcmd.respond_info(response)
    def get_status(self, eventtime):
-        status = self.runout_helper.get_status(eventtime)
+        return {'Diameter': self.diameter,
        status.update({'Diameter': self.diameter,
                'Raw':(self.lastFilamentWidthReading+
                 self.lastFilamentWidthReading2),
-                'is_active':self.is_active})
+                'is_active':self.is_active}
        return status
    def cmd_log_enable(self, gcmd):
        self.is_log = True
        gcmd.respond_info("Filament width logging Turned On")
--- a/klippy/extras/heaters.py
+++ b/klippy/extras/heaters.py
@@ -1,6 +1,6 @@
 # Tracking of PWM controlled heaters and their temperature control
 #
-# Copyright (C) 2016-2025  Kevin O'Connor <kevin@koconnor.net>
+# Copyright (C) 2016-2020  Kevin O'Connor <kevin@koconnor.net>
 #
 # This file may be distributed under the terms of the GNU GPLv3 license.
 import os, logging, threading
@@ -11,11 +11,10 @@ import os, logging, threading
 ######################################################################
 KELVIN_TO_CELSIUS = -273.15
-MAX_HEAT_TIME = 3.0
+MAX_HEAT_TIME = 5.0
 AMBIENT_TEMP = 25.
 PID_PARAM_BASE = 255.
 MAX_MAINTHREAD_TIME = 5.0
 QUELL_STALE_TIME = 7.0
 class Heater:
    def __init__(self, config, sensor):
@@ -75,8 +74,7 @@ class Heater:
            # No significant change in value - can suppress update
            return
        pwm_time = read_time + self.pwm_delay
-        self.next_pwm_time = (pwm_time + MAX_HEAT_TIME
+        self.next_pwm_time = pwm_time + 0.75 * MAX_HEAT_TIME
                              - (3. * self.pwm_delay + 0.001))
        self.last_pwm_value = value
        self.mcu_pwm.set_pwm(pwm_time, value)
        #logging.debug("%s: pwm=%.3f@%.3f (from %.3f@%.3f [%.3f])",
@@ -112,10 +110,9 @@ class Heater:
        with self.lock:
            self.target_temp = degrees
    def get_temp(self, eventtime):
-        est_print_time = self.mcu_pwm.get_mcu().estimated_print_time(eventtime)
+        print_time = self.mcu_pwm.get_mcu().estimated_print_time(eventtime) - 5.
        quell_time = est_print_time - QUELL_STALE_TIME
        with self.lock:
-            if self.last_temp_time < quell_time:
+            if self.last_temp_time < print_time:
                return 0., self.target_temp
            return self.smoothed_temp, self.target_temp
    def check_busy(self, eventtime):
--- a/klippy/extras/homing.py
+++ b/klippy/extras/homing.py
@@ -45,7 +45,7 @@ class StepperPosition:
 class HomingMove:
    def __init__(self, printer, endstops, toolhead=None):
        self.printer = printer
-        self.endstops = [es for es in endstops if es[0].get_steppers()]
+        self.endstops = endstops
        if toolhead is None:
            toolhead = printer.lookup_object('toolhead')
        self.toolhead = toolhead
@@ -71,9 +71,7 @@ class HomingMove:
            sname = stepper.get_name()
            kin_spos[sname] += offsets.get(sname, 0) * stepper.get_step_dist()
        thpos = self.toolhead.get_position()
-        cpos = kin.calc_position(kin_spos)
+        return list(kin.calc_position(kin_spos))[:3] + thpos[3:]
        return [cp if cp is not None else tp
                for cp, tp in zip(cpos, thpos[:3])] + thpos[3:]
    def homing_move(self, movepos, speed, probe_pos=False,
                    triggered=True, check_triggered=True):
        # Notify start of homing/probing move
@@ -235,10 +233,6 @@ class Homing:
                        for s in kin.get_steppers()}
            newpos = kin.calc_position(kin_spos)
            for axis in force_axes:
                if newpos[axis] is None:
                    raise self.printer.command_error(
                            "Cannot determine position of toolhead on "
                            "axis %s after homing" % "xyz"[axis])
                homepos[axis] = newpos[axis]
            self.toolhead.set_position(homepos)
--- a/klippy/extras/htu21d.py
+++ b/klippy/extras/htu21d.py
@@ -15,7 +15,7 @@ from . import bus
 #       Si7013 - Untested
 #       Si7020 - Untested
 #       Si7021 - Tested on Pico MCU
-#       SHT21  - Tested on Linux MCU.
+#       SHT21  - Untested
 #
 ######################################################################
@@ -34,7 +34,7 @@ HTU21D_COMMANDS = {
 }
-HTU21D_RESOLUTION_MASK = 0x7E
+HTU21D_RESOLUTION_MASK = 0x7E;
 HTU21D_RESOLUTIONS = {
    'TEMP14_HUM12':int('00000000',2),
    'TEMP13_HUM10':int('10000000',2),
@@ -42,40 +42,31 @@ HTU21D_RESOLUTIONS = {
    'TEMP11_HUM11':int('10000001',2)
 }
 ID_MAP = {
    0x0D: 'SI7013',
    0x14: 'SI7020',
    0x15: 'SI7021',
    0x31: 'SHT21',
    0x01: 'SHT21',
    0x32: 'HTU21D',
 }
 # Device with conversion time for tmp/resolution bit
 # The format is:
 #  <CHIPNAME>:{id:<ID>, ..<RESOlUTION>:[<temp time>,<humidity time>].. }
 HTU21D_DEVICES = {
-    'SI7013':{
+    'SI7013':{'id':0x0D,
        'TEMP14_HUM12':[.11,.12],
        'TEMP13_HUM10':[ .7, .5],
        'TEMP12_HUM08':[ .4, .4],
        'TEMP11_HUM11':[ .3, .7]},
-    'SI7020':{
+    'SI7020':{'id':0x14,
        'TEMP14_HUM12':[.11,.12],
        'TEMP13_HUM10':[ .7, .5],
        'TEMP12_HUM08':[ .4, .4],
        'TEMP11_HUM11':[ .3, .7]},
-    'SI7021':{
+    'SI7021':{'id':0x15,
        'TEMP14_HUM12':[.11,.12],
        'TEMP13_HUM10':[ .7, .5],
        'TEMP12_HUM08':[ .4, .4],
        'TEMP11_HUM11':[ .3, .7]},
-    'SHT21': {
+    'SHT21': {'id':0x31,
        'TEMP14_HUM12':[.85,.29],
        'TEMP13_HUM10':[.43, .9],
        'TEMP12_HUM08':[.22, .4],
        'TEMP11_HUM11':[.11,.15]},
-    'HTU21D':{
+    'HTU21D':{'id':0x32,
        'TEMP14_HUM12':[.50,.16],
        'TEMP13_HUM10':[.25, .5],
        'TEMP12_HUM08':[.13, .3],
@@ -137,16 +128,19 @@ class HTU21D:
        if self._chekCRC8(rdevId) != checksum:
            logging.warning("htu21d: Reading deviceId !Checksum error!")
        rdevId = rdevId >> 8
-        guess_dev = ID_MAP.get(rdevId, "Unknown")
+        deviceId_list = list(
-        if guess_dev == self.deviceId:
+            filter(
-            logging.info("htu21d: Found Device Type %s" % guess_dev)
+              lambda elem: HTU21D_DEVICES[elem]['id'] == rdevId,HTU21D_DEVICES)
            )
        if len(deviceId_list) != 0:
            logging.info("htu21d: Found Device Type %s" % deviceId_list[0])
        else:
            logging.warning("htu21d: Unknown Device ID %#x " % rdevId)
-        if self.deviceId != guess_dev:
+        if self.deviceId != deviceId_list[0]:
            logging.warning(
-                "htu21d: Found device %s. Forcing to type %s as config." %
+                "htu21d: Found device %s. Forcing to type %s as config.",
-                 (guess_dev, self.deviceId))
+                 deviceId_list[0],self.deviceId)
        # Set Resolution
        params = self.i2c.i2c_read([HTU21D_COMMANDS['READ']], 1)
@@ -158,7 +152,7 @@ class HTU21D:
    def _sample_htu21d(self, eventtime):
        try:
-            # Read Temperature
+            # Read Temeprature
            if self.hold_master_mode:
                params = self.i2c.i2c_write([HTU21D_COMMANDS['HTU21D_TEMP']])
            else:
--- a/klippy/extras/hx71x.py
+++ b/klippy/extras/hx71x.py
@@ -51,9 +51,12 @@ class HX71xBase:
        self.batch_bulk = bulk_sensor.BatchBulkHelper(
            self.printer, self._process_batch, self._start_measurements,
            self._finish_measurements, UPDATE_INTERVAL)
        # publish raw samples to the socket
        dump_path = "%s/dump_%s" % (sensor_type, sensor_type)
        hdr = {'header': ('time', 'counts', 'value')}
        self.batch_bulk.add_mux_endpoint(dump_path, "sensor", self.name, hdr)
        # Command Configuration
        self.query_hx71x_cmd = None
        self.attach_probe_cmd = None
        mcu.add_config_cmd(
            "config_hx71x oid=%d gain_channel=%d dout_pin=%s sclk_pin=%s"
            % (self.oid, self.gain_channel, self.dout_pin, self.sclk_pin))
@@ -65,13 +68,10 @@ class HX71xBase:
    def _build_config(self):
        self.query_hx71x_cmd = self.mcu.lookup_command(
            "query_hx71x oid=%c rest_ticks=%u")
        self.attach_probe_cmd = self.mcu.lookup_command(
            "hx71x_attach_load_cell_probe oid=%c load_cell_probe_oid=%c")
        self.ffreader.setup_query_command("query_hx71x_status oid=%c",
                                          oid=self.oid,
                                          cq=self.mcu.alloc_command_queue())
    def get_mcu(self):
        return self.mcu
@@ -87,9 +87,6 @@ class HX71xBase:
    def add_client(self, callback):
        self.batch_bulk.add_client(callback)
    def attach_load_cell_probe(self, load_cell_probe_oid):
        self.attach_probe_cmd.send([self.oid, load_cell_probe_oid])
    # Measurement decoding
    def _convert_samples(self, samples):
        adc_factor = 1. / (1 << 23)
--- a/klippy/extras/icm20948.py
+++ b/klippy/extras/icm20948.py
@@ -1,173 +0,0 @@
 # Support for reading acceleration data from an icm20948 chip
 #
 # Copyright (C) 2024 Paul Hansel <github@paulhansel.com>
 # Copyright (C) 2022  Harry Beyel <harry3b9@gmail.com>
 # Copyright (C) 2020-2021 Kevin O'Connor <kevin@koconnor.net>
 #
 # This file may be distributed under the terms of the GNU GPLv3 license.
 # From https://invensense.tdk.com/wp-content/uploads/
 #               2016/06/DS-000189-ICM-20948-v1.3.pdf
 import logging
 from . import bus, adxl345, bulk_sensor
 ICM20948_ADDR =         0x68
 ICM_DEV_IDS = {
    0xEA: "icm-20948",
    #everything above are normal ICM IDs
 }
 # ICM20948 registers
 REG_DEVID =             0x00 # 0xEA
 REG_FIFO_EN =           0x67 # FIFO_EN_2
 REG_ACCEL_SMPLRT_DIV1 = 0x10 # MSB
 REG_ACCEL_SMPLRT_DIV2 = 0x11 # LSB
 REG_ACCEL_CONFIG =      0x14
 REG_USER_CTRL =         0x03
 REG_PWR_MGMT_1 =        0x06
 REG_PWR_MGMT_2 =        0x07
 REG_INT_STATUS =        0x19
 REG_BANK_SEL =          0x7F
 SAMPLE_RATE_DIVS = { 4500: 0x00 }
 SET_BANK_0 =            0x00
 SET_BANK_1 =            0x10
 SET_BANK_2 =            0x20
 SET_BANK_3 =            0x30
 SET_ACCEL_CONFIG =      0x06 # 16g full scale, 1209Hz BW, 4.5kHz samp rate
 SET_PWR_MGMT_1_WAKE =   0x01
 SET_PWR_MGMT_1_SLEEP =  0x41
 SET_PWR_MGMT_2_ACCEL_ON = 0x07
 SET_PWR_MGMT_2_OFF =    0x3F
 SET_USER_FIFO_RESET =   0x0E
 SET_USER_FIFO_EN =      0x40
 SET_ENABLE_FIFO  =      0x10
 SET_DISABLE_FIFO =      0x00
 FREEFALL_ACCEL = 9.80665 * 1000.
 # SCALE = 1/2048 g/LSB @16g scale * Earth gravity in mm/s**2
 SCALE = 0.00048828125 * FREEFALL_ACCEL
 FIFO_SIZE = 512
 BATCH_UPDATES = 0.100
 # Printer class that controls ICM20948 chip
 class ICM20948:
    def __init__(self, config):
        self.printer = config.get_printer()
        adxl345.AccelCommandHelper(config, self)
        self.axes_map = adxl345.read_axes_map(config, SCALE, SCALE, SCALE)
        self.data_rate = config.getint('rate', 4500)
        if self.data_rate not in SAMPLE_RATE_DIVS:
            raise config.error("Invalid rate parameter: %d" % (self.data_rate,))
        # Setup mcu sensor_icm20948 bulk query code
        self.i2c = bus.MCU_I2C_from_config(config,
                                           default_addr=ICM20948_ADDR,
                                           default_speed=400000)
        self.mcu = mcu = self.i2c.get_mcu()
        self.oid = mcu.create_oid()
        self.query_icm20948_cmd = None
        mcu.register_config_callback(self._build_config)
        # Bulk sample message reading
        chip_smooth = self.data_rate * BATCH_UPDATES * 2
        self.ffreader = bulk_sensor.FixedFreqReader(mcu, chip_smooth, ">hhh")
        self.last_error_count = 0
        # Process messages in batches
        self.batch_bulk = bulk_sensor.BatchBulkHelper(
            self.printer, self._process_batch,
            self._start_measurements, self._finish_measurements, BATCH_UPDATES)
        self.name = config.get_name().split()[-1]
        hdr = ('time', 'x_acceleration', 'y_acceleration', 'z_acceleration')
        self.batch_bulk.add_mux_endpoint("icm20948/dump_icm20948", "sensor",
                                         self.name, {'header': hdr})
    def _build_config(self):
        cmdqueue = self.i2c.get_command_queue()
        self.mcu.add_config_cmd("config_icm20948 oid=%d i2c_oid=%d"
                           % (self.oid, self.i2c.get_oid()))
        self.mcu.add_config_cmd("query_icm20948 oid=%d rest_ticks=0"
                           % (self.oid,), on_restart=True)
        self.query_icm20948_cmd = self.mcu.lookup_command(
            "query_icm20948 oid=%c rest_ticks=%u", cq=cmdqueue)
        self.ffreader.setup_query_command("query_icm20948_status oid=%c",
                                          oid=self.oid, cq=cmdqueue)
    def read_reg(self, reg):
        params = self.i2c.i2c_read([reg], 1)
        return bytearray(params['response'])[0]
    def set_reg(self, reg, val, minclock=0):
        self.i2c.i2c_write([reg, val & 0xFF], minclock=minclock)
    def start_internal_client(self):
        aqh = adxl345.AccelQueryHelper(self.printer)
        self.batch_bulk.add_client(aqh.handle_batch)
        return aqh
    # Measurement decoding
    def _convert_samples(self, samples):
        (x_pos, x_scale), (y_pos, y_scale), (z_pos, z_scale) = self.axes_map
        count = 0
        for ptime, rx, ry, rz in samples:
            raw_xyz = (rx, ry, rz)
            x = round(raw_xyz[x_pos] * x_scale, 6)
            y = round(raw_xyz[y_pos] * y_scale, 6)
            z = round(raw_xyz[z_pos] * z_scale, 6)
            samples[count] = (round(ptime, 6), x, y, z)
            count += 1
    # Start, stop, and process message batches
    def _start_measurements(self):
        # In case of miswiring, testing ICM20948 device ID prevents treating
        # noise or wrong signal as a correctly initialized device
        dev_id = self.read_reg(REG_DEVID)
        if dev_id not in ICM_DEV_IDS.keys():
            raise self.printer.command_error(
                "Invalid mpu id (got %x).\n"
                "This is generally indicative of connection problems\n"
                "(e.g. faulty wiring) or a faulty chip."
                % (dev_id))
        else:
            logging.info("Found %s with id %x"% (ICM_DEV_IDS[dev_id], dev_id))
        # Setup chip in requested query rate
        self.set_reg(REG_PWR_MGMT_1, SET_PWR_MGMT_1_WAKE)
        self.set_reg(REG_PWR_MGMT_2, SET_PWR_MGMT_2_ACCEL_ON)
        # Don't add 20ms pause for accelerometer chip wake up
        self.read_reg(REG_DEVID) # Dummy read to ensure queues flushed
        self.set_reg(REG_ACCEL_SMPLRT_DIV1, SAMPLE_RATE_DIVS[self.data_rate])
        self.set_reg(REG_ACCEL_SMPLRT_DIV2, SAMPLE_RATE_DIVS[self.data_rate])
        self.set_reg(REG_BANK_SEL, SET_BANK_2)
        self.set_reg(REG_ACCEL_CONFIG, SET_ACCEL_CONFIG)
        self.set_reg(REG_BANK_SEL, SET_BANK_0)
        # Reset fifo
        self.set_reg(REG_FIFO_EN, SET_DISABLE_FIFO)
        self.set_reg(REG_USER_CTRL, SET_USER_FIFO_RESET)
        self.set_reg(REG_USER_CTRL, SET_USER_FIFO_EN)
        self.read_reg(REG_INT_STATUS) # clear FIFO overflow flag
        # Start bulk reading
        rest_ticks = self.mcu.seconds_to_clock(4. / self.data_rate)
        self.query_icm20948_cmd.send([self.oid, rest_ticks])
        self.set_reg(REG_FIFO_EN, SET_ENABLE_FIFO)
        logging.info("ICM20948 starting '%s' measurements", self.name)
        # Initialize clock tracking
        self.ffreader.note_start()
        self.last_error_count = 0
    def _finish_measurements(self):
        # Halt bulk reading
        self.set_reg(REG_FIFO_EN, SET_DISABLE_FIFO)
        self.query_icm20948_cmd.send_wait_ack([self.oid, 0])
        self.ffreader.note_end()
        logging.info("ICM20948 finished '%s' measurements", self.name)
        self.set_reg(REG_PWR_MGMT_1, SET_PWR_MGMT_1_SLEEP)
        self.set_reg(REG_PWR_MGMT_2, SET_PWR_MGMT_2_OFF)
    def _process_batch(self, eventtime):
        samples = self.ffreader.pull_samples()
        self._convert_samples(samples)
        if not samples:
            return {}
        return {'data': samples, 'errors': self.last_error_count,
                'overflows': self.ffreader.get_last_overflows()}
 def load_config(config):
    return ICM20948(config)
 def load_config_prefix(config):
    return ICM20948(config)
--- a/klippy/extras/idle_timeout.py
+++ b/klippy/extras/idle_timeout.py
@@ -35,9 +35,7 @@ class IdleTimeout:
        printing_time = 0.
        if self.state == "Printing":
            printing_time = eventtime - self.last_print_start_systime
-        return {"state": self.state,
+        return { "state": self.state, "printing_time": printing_time }
                "printing_time": printing_time,
                "idle_timeout": self.idle_timeout}
    def handle_ready(self):
        self.toolhead = self.printer.lookup_object('toolhead')
        self.timeout_timer = self.reactor.register_timer(self.timeout_handler)
--- a/klippy/extras/input_shaper.py
+++ b/klippy/extras/input_shaper.py
@@ -69,8 +69,6 @@ class AxisInputShaper:
            ffi_lib.input_shaper_set_shaper_params(
                    sk, self.axis.encode(), self.n, self.A, self.T)
        return success
    def is_enabled(self):
        return self.n > 0
    def disable_shaping(self):
        if self.saved is None and self.n:
            self.saved = (self.n, self.A, self.T)
@@ -91,8 +89,6 @@ class InputShaper:
    def __init__(self, config):
        self.printer = config.get_printer()
        self.printer.register_event_handler("klippy:connect", self.connect)
        self.printer.register_event_handler("dual_carriage:update_kinematics",
                                            self._update_kinematics)
        self.toolhead = None
        self.shapers = [AxisInputShaper('x', config),
                        AxisInputShaper('y', config)]
@@ -107,23 +103,17 @@ class InputShaper:
        return self.shapers
    def connect(self):
        self.toolhead = self.printer.lookup_object("toolhead")
        dual_carriage = self.printer.lookup_object('dual_carriage', None)
        if dual_carriage is not None:
            for shaper in self.shapers:
                if shaper.is_enabled():
                    raise self.printer.config_error(
                            'Input shaper parameters cannot be configured via'
                            ' [input_shaper] section with dual_carriage(s) '
                            ' enabled. Refer to Klipper documentation on how '
                            ' to configure input shaper for dual_carriage(s).')
            return
        # Configure initial values
        self._update_input_shaping(error=self.printer.config_error)
    def _get_input_shaper_stepper_kinematics(self, stepper):
        # Lookup stepper kinematics
        sk = stepper.get_stepper_kinematics()
        if sk in self.orig_stepper_kinematics:
            # Already processed this stepper kinematics unsuccessfully
            return None
        if sk in self.input_shaper_stepper_kinematics:
            return sk
        self.orig_stepper_kinematics.append(sk)
        ffi_main, ffi_lib = chelper.get_ffi()
        is_sk = ffi_main.gc(ffi_lib.input_shaper_alloc(), ffi_lib.free)
        stepper.set_stepper_kinematics(is_sk)
@@ -131,27 +121,8 @@ class InputShaper:
        if res < 0:
            stepper.set_stepper_kinematics(sk)
            return None
        self.orig_stepper_kinematics.append(sk)
        self.input_shaper_stepper_kinematics.append(is_sk)
        return is_sk
    def _update_kinematics(self):
        if self.toolhead is None:
            # Klipper initialization is not yet completed
            return
        ffi_main, ffi_lib = chelper.get_ffi()
        kin = self.toolhead.get_kinematics()
        for s in kin.get_steppers():
            if s.get_trapq() is None:
                continue
            is_sk = self._get_input_shaper_stepper_kinematics(s)
            if is_sk is None:
                continue
            old_delay = ffi_lib.input_shaper_get_step_generation_window(is_sk)
            ffi_lib.input_shaper_update_sk(is_sk)
            new_delay = ffi_lib.input_shaper_get_step_generation_window(is_sk)
            if old_delay != new_delay:
                self.toolhead.note_step_generation_scan_time(new_delay,
                                                             old_delay)
    def _update_input_shaping(self, error=None):
        self.toolhead.flush_step_generation()
        ffi_main, ffi_lib = chelper.get_ffi()
--- a/klippy/extras/ldc1612.py
+++ b/klippy/extras/ldc1612.py
@@ -12,7 +12,7 @@ BATCH_UPDATES = 0.100
 LDC1612_ADDR = 0x2a
-DEFAULT_LDC1612_FREQ = 12000000
+LDC1612_FREQ = 12000000
 SETTLETIME = 0.005
 DRIVECUR = 15
 DEGLITCH = 0x05 # 10 Mhz
@@ -87,8 +87,6 @@ class LDC1612:
        self.oid = oid = mcu.create_oid()
        self.query_ldc1612_cmd = None
        self.ldc1612_setup_home_cmd = self.query_ldc1612_home_state_cmd = None
        self.frequency = config.getint("frequency", DEFAULT_LDC1612_FREQ,
                                       2000000, 40000000)
        if config.get('intb_pin', None) is not None:
            ppins = config.get_printer().lookup_object("pins")
            pin_params = ppins.lookup_pin(config.get('intb_pin'))
@@ -143,7 +141,7 @@ class LDC1612:
    def setup_home(self, print_time, trigger_freq,
                   trsync_oid, hit_reason, err_reason):
        clock = self.mcu.print_time_to_clock(print_time)
-        tfreq = int(trigger_freq * (1<<28) / float(self.frequency) + 0.5)
+        tfreq = int(trigger_freq * (1<<28) / float(LDC1612_FREQ) + 0.5)
        self.ldc1612_setup_home_cmd.send(
            [self.oid, clock, tfreq, trsync_oid, hit_reason, err_reason])
    def clear_home(self):
@@ -155,7 +153,7 @@ class LDC1612:
        return self.mcu.clock_to_print_time(tclock)
    # Measurement decoding
    def _convert_samples(self, samples):
-        freq_conv = float(self.frequency) / (1<<28)
+        freq_conv = float(LDC1612_FREQ) / (1<<28)
        count = 0
        for ptime, val in samples:
            mv = val & 0x0fffffff
@@ -176,10 +174,10 @@ class LDC1612:
                "(e.g. faulty wiring) or a faulty ldc1612 chip."
                % (manuf_id, dev_id, LDC1612_MANUF_ID, LDC1612_DEV_ID))
        # Setup chip in requested query rate
-        rcount0 = self.frequency / (16. * (self.data_rate - 4))
+        rcount0 = LDC1612_FREQ / (16. * (self.data_rate - 4))
        self.set_reg(REG_RCOUNT0, int(rcount0 + 0.5))
        self.set_reg(REG_OFFSET0, 0)
-        self.set_reg(REG_SETTLECOUNT0, int(SETTLETIME*self.frequency/16. + .5))
+        self.set_reg(REG_SETTLECOUNT0, int(SETTLETIME*LDC1612_FREQ/16. + .5))
        self.set_reg(REG_CLOCK_DIVIDERS0, (1 << 12) | 1)
        self.set_reg(REG_ERROR_CONFIG, (0x1f << 11) | 1)
        self.set_reg(REG_MUX_CONFIG, 0x0208 | DEGLITCH)
--- a/Show More
+++ b/Show More