295 lines
15 KiB
Markdown
295 lines
15 KiB
Markdown
This document provides information on the low-level micro-controller
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commands that are sent from the Klipper "host" software and processed
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by the Klipper micro-controller software. This document is not an
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authoritative reference for these commands, nor is it an exclusive
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list of all available commands.
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This document may be useful for users needing to configure a set of
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hardware actions that their printer may require at startup (via the
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"custom" field in the printer config file), and it may be useful for
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developers wishing to obtain a high-level feel for low-level commands.
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See the [protocol](Protocol.md) document for more information on the
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format of commands and their transmission. The commands here are
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described using their "printf" style syntax - for those unfamiliar
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with that format, just note that where a '%...' sequence is seen it
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should be replaced with an actual integer. For example, a description
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with "count=%c" could be replaced with the text "count=10".
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Startup Commands
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================
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It may be necessary to take certain one-time actions to configure the
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micro-controller and its peripherals. This section lists common
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commands available for that purpose. Unlike most micro-controller
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commands, these commands run as soon as they are received and they do
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not require any particular setup.
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These commands are most useful in the "custom" block of the "mcu"
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section of the printer configuration file. This feature is typically
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used to configure the initial settings of LEDs, to configure
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micro-stepping pins, to configure a digipot, etc.
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Several of these commands will take a "pin=%u" parameter. The
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low-level micro-controller software uses integer encodings of the
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hardware pin numbers, but to make things more readable the host will
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translate human readable pin names (eg, "PA3") to their equivalent
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integer encodings. By convention, any parameter named "pin" or that
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has a "_pin" suffix will use pin name translation by the
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host. Similarly, several commands take time parameters specified in
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clock ticks. One can specify a value for these parameters in seconds
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using the "TICKS()" macro - for example "cycle_ticks=TICKS(0.001)"
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would result in "cycle_ticks=16000" on a micro-controller with a 16Mhz
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clock.
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Common startup commands:
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* `set_digital_out pin=%u value=%c` : This command immediately
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configures the given pin as a digital out GPIO and it sets it to
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either a low level (value=0) or a high level (value=1). This command
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may be useful for configuring the initial value of LEDs and for
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configuring the initial value of stepper driver micro-stepping pins.
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* `set_pwm_out pin=%u cycle_ticks=%u value=%c` : This command will
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immediately configure the given pin to use hardware based
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pulse-width-modulation (PWM) with the given number of
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cycle_ticks. The "cycle_ticks" is the number of MCU clock ticks each
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power on and power off cycle should last. A cycle_ticks value of 1
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can be used to request the fastest possible cycle time. The "value"
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parameter is between 0 and 255 with 0 indicating a full off state
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and 255 indicating a full on state. This command may be useful for
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enabling CPU and nozzle cooling fans.
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* `send_spi_message pin=%u msg=%*s` : This command can be used to
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transmit messages to a serial-peripheral-interface (SPI) component
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connected to the micro-controller. It has been used to configure the
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startup settings of AD5206 digipots. The 'pin' parameter specifies
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the chip select line to use during the transmission. The 'msg'
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indicates the binary message to transmit to the given chip.
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Low-level micro-controller configuration
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========================================
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Most commands in the micro-controller require an initial setup before
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they can be successfully invoked. This section provides an overview of
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the configuration process. This section and the following sections are
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likely only of interest to developers interested in the internal
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details of Klipper.
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When the host first connects to the micro-controller it always starts
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by obtaining a data dictionary (see [protocol](Protocol.md) for more
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information). After the data dictionary is obtained the host will
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check if the micro-controller is in a "configured" state and configure
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it if not. Configuration involves the following phases:
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* `get_config` : The host starts by checking if the micro-controller
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is already configured. The micro-controller responds to this command
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with a "config" response message. The micro-controller software
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always starts in an unconfigured state at power-on. It remains in
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this state until the host completes the configuration processes (by
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issuing a finalize_config command). If the micro-controller is
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already configured from a previous session (and is configured with
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the desired settings) then no further action is needed by the host
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and the configuration process ends successfully.
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* `allocate_oids count=%c` : This command is issued to inform the
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micro-controller of the maximum number of object-ids (oid) that the
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host requires. It is only valid to issue this command once. An oid
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is an integer identifier allocated to each stepper, each endstop,
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and each schedulable gpio pin. The host determines in advance the
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number of oids it will require to operate the hardware and passes
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this to the micro-controller so that it may allocate sufficient
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memory to store a mapping from oid to internal object.
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* `config_XXX oid=%c ...` : By convention any command starting with
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the "config_" prefix creates a new micro-controller object and
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assigns the given oid to it. For example, the config_digital_out
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command will configure the specified pin as a digital output GPIO
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and create an internal object that the host can use to schedule
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changes to the given GPIO. The oid parameter passed into the config
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command is selected by the host and must be between zero and the
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maximum count supplied in the allocate_oids command. The config
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commands may only be run when the micro-controller is not in a
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configured state (ie, prior to the host sending finalize_config) and
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after the allocate_oids command has been sent.
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* `finalize_config crc=%u` : The finalize_config command transitions
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the micro-controller from an unconfigured state to a configured
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state. The crc parameter passed to the micro-controller is stored
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and provided back to the host in "config" response messages. By
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convention, the host takes a 32bit CRC of the configuration it will
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request and at the start of subsequent communication sessions it
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checks that the CRC stored in the micro-controller exactly matches
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its desired CRC. If the CRC does not match then the host knows the
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micro-controller has not been configured in the state desired by the
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host.
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Common micro-controller objects
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-------------------------------
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This section lists some commonly used config commands.
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* `config_digital_out oid=%c pin=%u default_value=%c
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max_duration=%u` : This command creates an internal micro-controller
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object for the given GPIO 'pin'. The pin will be configured in
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digital output mode and set to an initial value as specified by
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'default_value' (0 for low, 1 for high). Creating a digital_out
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object allows the host to schedule GPIO updates for the given pin at
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specified times (see the schedule_digital_out command described
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below). Should the micro-controller software go into shutdown mode
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then all configured digital_out objects will be set back to their
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default values. The 'max_duration' parameter is used to implement a
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safety check - if it is non-zero then it is the maximum number of
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clock ticks that the host may set the given GPIO to a non-default
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value without further updates. For example, if the default_value is
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zero and the max_duration is 16000 then if the host sets the gpio to
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a value of one then it must schedule another update to the gpio pin
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(to either zero or one) within 16000 clock ticks. This safety
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feature can be used with heater pins to ensure the host does not
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enable the heater and then go off-line.
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* `config_pwm_out oid=%c pin=%u cycle_ticks=%u default_value=%c
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max_duration=%u` : This command creates an internal object for
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hardware based PWM pins that the host may schedule updates for. Its
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usage is analogous to config_digital_out - see the description of
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the 'set_pwm_out' and 'config_digital_out' commands for parameter
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description.
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* `config_soft_pwm_out oid=%c pin=%u cycle_ticks=%u default_value=%c
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max_duration=%u` : This command creates an internal micro-controller
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object for software implemented PWM. Unlike hardware pwm pins, a
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software pwm object does not require any special hardware support
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(other than the ability to configure the pin as a digital output
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GPIO). Because the output switching is implemented in the
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micro-controller software, it is recommended that the cycle_ticks
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parameter correspond to a time of 10ms or greater. See the
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description of the 'set_pwm_out' and 'config_digital_out' commands
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for parameter description.
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* `config_analog_in oid=%c pin=%u` : This command is used to configure
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a pin in analog input sampling mode. Once configured, the pin can be
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sampled at regular interval using the query_analog_in command (see
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below).
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* `config_stepper oid=%c step_pin=%c dir_pin=%c min_stop_interval=%u
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invert_step=%c` : This command creates an internal stepper
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object. The 'step_pin' and 'dir_pin' parameters specify the step and
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direction pins respectively; this command will configure them in
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digital output mode. The 'invert_step' parameter specifies whether a
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step occurs on a rising edge (invert_step=0) or falling edge
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(invert_step=1). The 'min_stop_interval' implements a safety
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feature - it is checked when the micro-controller finishes all moves
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for a stepper - if it is non-zero it specifies the minimum number of
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clock ticks since the last step. It is used as a check on the
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maximum stepper velocity that a stepper may have before stopping.
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* `config_end_stop oid=%c pin=%c pull_up=%c stepper_count=%c` : This
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command creates an internal "endstop" object. It is used to specify
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the endstop pins and to enable "homing" operations (see the
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end_stop_home command below). The command will configure the
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specified pin in digital input mode. The 'pull_up' parameter
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determines whether hardware provided pullup resistors for the pin
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(if available) will be enabled. The 'stepper_count' parameter
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specifies the maximum number of steppers that this endstop may need
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to halt during a homing operation (see end_stop_home below).
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Common commands
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===============
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This section lists some commonly used run-time commands. It is likely
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only of interest to developers looking to gain insight into Klipper.
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* `schedule_digital_out oid=%c clock=%u value=%c` : This command will
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schedule a change to a digital output GPIO pin at the given clock
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time. To use this command a 'config_digital_out' command with the
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same 'oid' parameter must have been issued during micro-controller
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configuration.
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* `schedule_pwm_out oid=%c clock=%u value=%c` : Schedules a change to
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a hardware PWM output pin. See the 'schedule_digital_out' and
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'config_pwm_out' commands for more info.
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* `schedule_soft_pwm_out oid=%c clock=%u value=%c` : Schedules a
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change to a software PWM output pin. See the 'schedule_digital_out'
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and 'config_soft_pwm_out' commands for more info.
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* `query_analog_in oid=%c clock=%u sample_ticks=%u sample_count=%c
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rest_ticks=%u min_value=%hu max_value=%hu` : This command sets up a
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recurring schedule of analog input samples. To use this command a
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'config_analog_in' command with the same 'oid' parameter must have
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been issued during micro-controller configuration. The samples will
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start as of 'clock' time, it will report on the obtained value every
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'rest_ticks' clock ticks, it will over-sample 'sample_count' number
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of times, and it will pause 'sample_ticks' number of clock ticks
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between over-sample samples. The 'min_value' and 'max_value'
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parameters implement a safety feature - the micro-controller
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software will verify the sampled value (after any oversampling) is
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always between the supplied range. This is intended for use with
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pins attached to thermistors controlling heaters - it can be used to
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check that a heater is within a temperature range.
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* `get_status` : This command causes the micro-controller to generate
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a "status" response message. The host sends this command once a
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second to obtain the value of the micro-controller clock and to
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estimate the drift between host and micro-controller clocks. It
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enables the host to accurately estimate the micro-controller clock.
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Stepper commands
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----------------
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* `queue_step oid=%c interval=%u count=%hu add=%hi` : This command
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schedules 'count' number of steps for the given stepper, with
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'interval' number of clock ticks between each step. The first step
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will be 'interval' number of clock ticks since the last scheduled
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step for the given stepper. If 'add' is non-zero then the interval
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will be adjusted by 'add' amount after each step. This command
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appends the given interval/count/add sequence to a per-stepper
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queue. There may be hundreds of these sequences queued during normal
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operation. New sequence are appended to the end of the queue and as
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each sequence completes its 'count' number of steps it is popped
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from the front of the queue. This system allows the micro-controller
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to queue potentially hundreds of thousands of steps - all with
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reliable and predictable schedule times.
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* `set_next_step_dir oid=%c dir=%c` : This command specifies the value
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of the dir_pin that the next queue_step command will use.
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* `reset_step_clock oid=%c clock=%u` : Normally, step timing is
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relative to the last step for a given stepper. This command resets
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the clock so that the next step is relative to the supplied 'clock'
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time. The host usually only sends this command at the start of a
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print.
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* `stepper_get_position oid=%c` : This command causes the
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micro-controller to generate a "stepper_position" response message
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with the stepper's current position. The position is the total
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number of steps generated with dir=1 minus the total number of steps
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generated with dir=0.
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* `end_stop_home oid=%c clock=%u rest_ticks=%u pin_value=%c` : This
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command is used during stepper "homing" operations. To use this
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command a 'config_end_stop' command with the same 'oid' parameter
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must have been issued during micro-controller configuration. When
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this command is invoked, the micro-controller will sample the
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endstop pin every 'rest_ticks' clock ticks and check if it has a
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value equal to 'pin_value'. If the value matches then the movement
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queue for the associated stepper will be cleared and the stepper
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will come to an immediate halt. The host uses this command to
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implement homing - the host instructs the endstop to sample for the
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endstop trigger and then it issues a series of queue_step commands
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to move a stepper towards the endstop. Once the stepper hits the
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endstop, the trigger will be detected, the movement halted, and the
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host notified.
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### Move queue
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Each queue_step command utilizes an entry in the micro-controller
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"move queue". This queue is allocated when it receives the
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"finalize_config" command, and it reports the number of available
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queue entries in "config" response messages.
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It is the responsibility of the host to ensure that there is available
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space in the queue before sending a queue_step command. The host does
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this by calculating when each queue_step command completes and
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scheduling new queue_step commands accordingly.
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