mirror of https://github.com/Desuuuu/klipper.git
453 lines
24 KiB
Markdown
453 lines
24 KiB
Markdown
This document describes the overall code layout and major code flow of
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Klipper.
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Directory Layout
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================
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The **src/** directory contains the C source for the micro-controller
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code. The **src/avr/** directory contains specific code for Atmel
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ATmega micro-controllers. The **src/sam3x8e/** directory contains code
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specific to the Arduino Due style ARM micro-controllers. The
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**src/pru/** directory contains code specific to the Beaglebone's
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on-board PRU micro-controller. The **src/simulator/** contains code
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stubs that allow the micro-controller to be test compiled on other
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architectures. The **src/generic/** directory contains helper code
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that may be useful across different host architectures. The build
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arranges for includes of "board/somefile.h" to first look in the
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current architecture directory (eg, src/avr/somefile.h) and then in
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the generic directory (eg, src/generic/somefile.h).
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The **klippy/** directory contains the host software. Most of the host
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software is written in Python, however the **klippy/chelper/**
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directory contains some C code helpers. The **klippy/extras/**
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directory contains the host code extensible "modules".
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The **lib/** directory contains external 3rd-party library code that
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is necessary to build some targets.
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The **config/** directory contains example printer configuration
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files.
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The **scripts/** directory contains build-time scripts useful for
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compiling the micro-controller code.
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The **test/** directory contains automated test cases.
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During compilation, the build may create an **out/** directory. This
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contains temporary build time objects. The final micro-controller
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object that is built is **out/klipper.elf.hex** on AVR and
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**out/klipper.bin** on ARM.
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Micro-controller code flow
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==========================
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Execution of the micro-controller code starts in architecture specific
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code (eg, **src/avr/main.c**) which ultimately calls sched_main()
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located in **src/sched.c**. The sched_main() code starts by running
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all functions that have been tagged with the DECL_INIT() macro. It
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then goes on to repeatedly run all functions tagged with the
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DECL_TASK() macro.
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One of the main task functions is command_dispatch() located in
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**src/command.c**. This function is called from the board specific
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input/output code (eg, **src/avr/serial.c**) and it runs the command
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functions associated with the commands found in the input
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stream. Command functions are declared using the DECL_COMMAND() macro
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(see the [protocol](Protocol.md) document for more information).
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Task, init, and command functions always run with interrupts enabled
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(however, they can temporarily disable interrupts if needed). These
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functions should never pause, delay, or do any work that lasts more
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than a few micro-seconds. These functions schedule work at specific
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times by scheduling timers.
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Timer functions are scheduled by calling sched_add_timer() (located in
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**src/sched.c**). The scheduler code will arrange for the given
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function to be called at the requested clock time. Timer interrupts
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are initially handled in an architecture specific interrupt handler
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(eg, **src/avr/timer.c**) which calls sched_timer_dispatch() located
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in **src/sched.c**. The timer interrupt leads to execution of schedule
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timer functions. Timer functions always run with interrupts
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disabled. The timer functions should always complete within a few
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micro-seconds. At completion of the timer event, the function may
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choose to reschedule itself.
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In the event an error is detected the code can invoke shutdown() (a
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macro which calls sched_shutdown() located in **src/sched.c**).
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Invoking shutdown() causes all functions tagged with the
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DECL_SHUTDOWN() macro to be run. Shutdown functions always run with
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interrupts disabled.
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Much of the functionality of the micro-controller involves working
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with General-Purpose Input/Output pins (GPIO). In order to abstract
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the low-level architecture specific code from the high-level task
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code, all GPIO events are implemented in architecture specific
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wrappers (eg, **src/avr/gpio.c**). The code is compiled with gcc's
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"-flto -fwhole-program" optimization which does an excellent job of
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inlining functions across compilation units, so most of these tiny
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gpio functions are inlined into their callers, and there is no
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run-time cost to using them.
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Klippy code overview
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====================
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The host code (Klippy) is intended to run on a low-cost computer (such
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as a Raspberry Pi) paired with the micro-controller. The code is
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primarily written in Python, however it does use CFFI to implement
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some functionality in C code.
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Initial execution starts in **klippy/klippy.py**. This reads the
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command-line arguments, opens the printer config file, instantiates
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the main printer objects, and starts the serial connection. The main
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execution of G-code commands is in the process_commands() method in
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**klippy/gcode.py**. This code translates the G-code commands into
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printer object calls, which frequently translate the actions to
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commands to be executed on the micro-controller (as declared via the
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DECL_COMMAND macro in the micro-controller code).
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There are four threads in the Klippy host code. The main thread
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handles incoming gcode commands. A second thread (which resides
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entirely in the **klippy/chelper/serialqueue.c** C code) handles
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low-level IO with the serial port. The third thread is used to process
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response messages from the micro-controller in the Python code (see
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**klippy/serialhdl.py**). The fourth thread writes debug messages to
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the log (see **klippy/queuelogger.py**) so that the other threads
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never block on log writes.
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Code flow of a move command
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===========================
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A typical printer movement starts when a "G1" command is sent to the
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Klippy host and it completes when the corresponding step pulses are
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produced on the micro-controller. This section outlines the code flow
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of a typical move command. The [kinematics](Kinematics.md) document
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provides further information on the mechanics of moves.
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* Processing for a move command starts in gcode.py. The goal of
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gcode.py is to translate G-code into internal calls. Changes in
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origin (eg, G92), changes in relative vs absolute positions (eg,
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G90), and unit changes (eg, F6000=100mm/s) are handled here. The
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code path for a move is: `process_data() -> process_commands() ->
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cmd_G1()`. Ultimately the ToolHead class is invoked to execute the
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actual request: `cmd_G1() -> ToolHead.move()`
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* The ToolHead class (in toolhead.py) handles "look-ahead" and tracks
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the timing of printing actions. The codepath for a move is:
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`ToolHead.move() -> MoveQueue.add_move() -> MoveQueue.flush() ->
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Move.set_junction() -> Move.move()`.
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* ToolHead.move() creates a Move() object with the parameters of the
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move (in cartesian space and in units of seconds and millimeters).
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* MoveQueue.add_move() places the move object on the "look-ahead"
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queue.
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* MoveQueue.flush() determines the start and end velocities of each
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move.
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* Move.set_junction() implements the "trapezoid generator" on a
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move. The "trapezoid generator" breaks every move into three parts:
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a constant acceleration phase, followed by a constant velocity
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phase, followed by a constant deceleration phase. Every move
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contains these three phases in this order, but some phases may be of
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zero duration.
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* When Move.move() is called, everything about the move is known -
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its start location, its end location, its acceleration, its
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start/cruising/end velocity, and distance traveled during
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acceleration/cruising/deceleration. All the information is stored in
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the Move() class and is in cartesian space in units of millimeters
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and seconds.
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The move is then handed off to the kinematics classes: `Move.move()
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-> kin.move()`
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* The goal of the kinematics classes is to translate the movement in
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cartesian space to movement on each stepper. The kinematics classes
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are in cartesian.py, corexy.py, delta.py, and extruder.py. The
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kinematic class is given a chance to audit the move
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(`ToolHead.move() -> kin.check_move()`) before it goes on the
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look-ahead queue, but once the move arrives in *kin*.move() the
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kinematic class is required to handle the move as specified. Note
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that the extruder is handled in its own kinematic class. Since the
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Move() class specifies the exact movement time and since step pulses
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are sent to the micro-controller with specific timing, stepper
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movements produced by the extruder class will be in sync with head
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movement even though the code is kept separate.
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* Klipper uses an
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[iterative solver](https://en.wikipedia.org/wiki/Root-finding_algorithm)
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to generate the step times for each stepper. For efficiency reasons,
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the stepper pulse times are generated in C code. The code flow is:
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`kin.move() -> MCU_Stepper.step_itersolve() ->
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itersolve_gen_steps()` (in klippy/chelper/itersolve.c). The goal of
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the iterative solver is to find step times given a function that
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calculates a stepper position from a time. This is done by
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repeatedly "guessing" various times until the stepper position
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formula returns the desired position of the next step on the
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stepper. The feedback produced from each guess is used to improve
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future guesses so that the process rapidly converges to the desired
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time. The kinematic stepper position formulas are located in the
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klippy/chelper/ directory (eg, kin_cart.c, kin_corexy.c,
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kin_delta.c, kin_extruder.c).
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* After the iterative solver calculates the step times they are added
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to an array: `itersolve_gen_steps() -> queue_append()` (in
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klippy/chelper/stepcompress.c). The array (struct
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stepcompress.queue) stores the corresponding micro-controller clock
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counter times for every step. Here the "micro-controller clock
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counter" value directly corresponds to the micro-controller's
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hardware counter - it is relative to when the micro-controller was
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last powered up.
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* The next major step is to compress the steps: `stepcompress_flush()
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-> compress_bisect_add()` (in klippy/chelper/stepcompress.c). This
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code generates and encodes a series of micro-controller "queue_step"
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commands that correspond to the list of stepper step times built in
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the previous stage. These "queue_step" commands are then queued,
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prioritized, and sent to the micro-controller (via
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stepcompress.c:steppersync and serialqueue.c:serialqueue).
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* Processing of the queue_step commands on the micro-controller starts
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in src/command.c which parses the command and calls
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`command_queue_step()`. The command_queue_step() code (in
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src/stepper.c) just appends the parameters of each queue_step
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command to a per stepper queue. Under normal operation the
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queue_step command is parsed and queued at least 100ms before the
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time of its first step. Finally, the generation of stepper events is
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done in `stepper_event()`. It's called from the hardware timer
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interrupt at the scheduled time of the first step. The
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stepper_event() code generates a step pulse and then reschedules
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itself to run at the time of the next step pulse for the given
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queue_step parameters. The parameters for each queue_step command
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are "interval", "count", and "add". At a high-level, stepper_event()
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runs the following, 'count' times: `do_step(); next_wake_time =
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last_wake_time + interval; interval += add;`
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The above may seem like a lot of complexity to execute a
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movement. However, the only really interesting parts are in the
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ToolHead and kinematic classes. It's this part of the code which
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specifies the movements and their timings. The remaining parts of the
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processing is mostly just communication and plumbing.
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Adding a host module
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====================
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The Klippy host code has a dynamic module loading capability. If a
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config section named "[my_module]" is found in the printer config file
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then the software will automatically attempt to load the python module
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klippy/extras/my_module.py . This module system is the preferred
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method for adding new functionality to Klipper.
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The easiest way to add a new module is to use an existing module as a
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reference - see **klippy/extras/servo.py** as an example.
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The following may also be useful:
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* Execution of the module starts in the module level `load_config()`
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function (for config sections of the form [my_module]) or in
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`load_config_prefix()` (for config sections of the form
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[my_module my_name]). This function is passed a "config" object and
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it must return a new "printer object" associated with the given
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config section.
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* During the process of instantiating a new printer object, the config
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object can be used to read parameters from the given config
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section. This is done using `config.get()`, `config.getfloat()`,
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`config.getint()`, etc. methods. Be sure to read all values from the
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config during the construction of the printer object - if the user
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specifies a config parameter that is not read during this phase then
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it will be assumed it is a typo in the config and an error will be
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raised.
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* Use the `config.get_printer()` method to obtain a reference to the
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main "printer" class. This "printer" class stores references to all
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the "printer objects" that have been instantiated. Use the
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`printer.lookup_object()` method to find references to other printer
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objects. Almost all functionality (even core kinematic modules) are
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encapsulated in one of these printer objects. Note, though, that
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when a new module is instantiated, not all other printer objects
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will have been instantiated. The "gcode" and "pins" modules will
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always be available, but for other modules it is a good idea to
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defer the lookup.
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* Define a `printer_state()` method if the code needs to be called
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during printer setup and/or shutdown. This method is called twice
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during setup (with "connect" and then "ready") and may also be
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called at run-time (with "shutdown" or "disconnect"). It is common
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to perform "printer object" lookup during the "connect" and "ready"
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phases.
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* If there is an error in the user's config, be sure to raise it
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during the `load_config()` or `printer_state("connect")` phases. Use
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either `raise config.error("my error")` or `raise
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printer.config_error("my error")` to report the error.
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* Use the "pins" module to configure a pin on a micro-controller. This
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is typically done with something similar to
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`printer.lookup_object("pins").setup_pin("pwm",
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config.get("my_pin"))`. The returned object can then be commanded at
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run-time.
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* If the module needs access to system timing or external file
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descriptors then use `printer.get_reactor()` to obtain access to the
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global "event reactor" class. This reactor class allows one to
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schedule timers, wait for input on file descriptors, and to "sleep"
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the host code.
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* Do not use global variables. All state should be stored in the
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printer object returned from the `load_config()` function. This is
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important as otherwise the RESTART command may not perform as
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expected. Also, for similar reasons, if any external files (or
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sockets) are opened then be sure to close them from the
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`printer_state("disconnect")` callback.
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* Avoid accessing the internal member variables (or calling methods
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that start with an underscore) of other printer objects. Observing
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this convention makes it easier to manage future changes.
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* If submitting the module for inclusion in the main Klipper code, be
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sure to place a copyright notice at the top of the module. See the
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existing modules for the preferred format.
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Adding new kinematics
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=====================
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This section provides some tips on adding support to Klipper for
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additional types of printer kinematics. This type of activity requires
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excellent understanding of the math formulas for the target
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kinematics. It also requires software development skills - though one
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should only need to update the host software.
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Useful steps:
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1. Start by studying the
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"[code flow of a move](#code-flow-of-a-move-command)" section and
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the [Kinematics document](Kinematics.md).
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2. Review the existing kinematic classes in cartesian.py, corexy.py,
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and delta.py. The kinematic classes are tasked with converting a
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move in cartesian coordinates to the movement on each stepper. One
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should be able to copy one of these files as a starting point.
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3. Implement the C stepper kinematic position functions for each
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stepper if they are not already available (see kin_cart.c,
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kin_corexy.c, and kin_delta.c in klippy/chelper/). The function
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should call `move_get_coord()` to convert a given move time (in
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seconds) to a cartesian coordinate (in millimeters), and then
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calculate the desired stepper position (in millimeters) from that
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cartesian coordinate.
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4. Implement the `calc_position()` method in the new kinematics class.
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This method calculates the position of the toolhead in cartesian
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coordinates from the current position of each stepper. It does not
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need to be efficient as it is typically only called during homing
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and probing operations.
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5. Other methods. The `move()`, `home()`, `check_move()`, and other
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methods should also be implemented. These functions are typically
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used to provide kinematic specific checks. However, at the start of
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development one can use boiler-plate code here.
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6. Implement test cases. Create a g-code file with a series of moves
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that can test important cases for the given kinematics. Follow the
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[debugging documentation](Debugging.md) to convert this g-code file
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to micro-controller commands. This is useful to exercise corner
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cases and to check for regressions.
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Porting to a new micro-controller
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=================================
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This section provides some tips on porting Klipper's micro-controller
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code to a new architecture. This type of activity requires good
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knowledge of embedded development and hands-on access to the target
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micro-controller.
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Useful steps:
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1. Start by identifying any 3rd party libraries that will be used
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during the port. Common examples include "CMSIS" wrappers and
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manufacturer "HAL" libraries. All 3rd party code needs to be GNU
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GPLv3 compatible. The 3rd party code should be committed to the
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Klipper lib/ directory. Update the lib/README file with information
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on where and when the library was obtained. It is preferable to
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copy the code into the Klipper repository unchanged, but if any
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changes are required then those changes should be listed explicitly
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in the lib/README file.
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2. Create a new architecture sub-directory in the src/ directory and
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add initial Kconfig and Makefile support. Use the existing
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architectures as a guide. The src/simulator provides a basic
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example of a minimum starting point.
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3. The first main coding task is to bring up communication support to
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the target board. This is the most difficult step in a new port.
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Once basic communication is working, the remaining steps tend to be
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much easier. It is typical to use an RS-232 style serial port
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during initial development as these types of hardware devices are
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generally easier to enable and control. During this phase, make
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liberal use of helper code from the src/generic/ directory (check
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how src/simulator/Makefile includes the generic C code into the
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build). It is also necessary to define timer_read_time() (which
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returns the current system clock) in this phase, but it is not
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necessary to fully support timer irq handling.
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4. Get familiar with the the console.py tool (as described in the
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[debugging document](Debugging.md)) and verify connectivity to the
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micro-controller with it. This tool translates the low-level
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micro-controller communication protocol to a human readable form.
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5. Add support for timer dispatch from hardware interrupts. See
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Klipper
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[commit 970831ee](https://github.com/KevinOConnor/klipper/commit/970831ee0d3b91897196e92270d98b2a3067427f)
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as an example of steps 1-5 done for the LPC176x architecture.
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6. Bring up basic GPIO input and output support. See Klipper
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[commit c78b9076](https://github.com/KevinOConnor/klipper/commit/c78b90767f19c9e8510c3155b89fb7ad64ca3c54)
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as an example of this.
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7. Bring up additional peripherals - for example see Klipper commit
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[65613aed](https://github.com/KevinOConnor/klipper/commit/65613aeddfb9ef86905cb1dade9e773a02ef3c27),
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[c812a40a](https://github.com/KevinOConnor/klipper/commit/c812a40a3782415e454b04bf7bd2158a6f0ec8b5),
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and
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[c381d03a](https://github.com/KevinOConnor/klipper/commit/c381d03aad5c3ee761169b7c7bced519cc14da29).
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8. Create a sample Klipper config file in the config/ directory. Test
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the micro-controller with the main klippy.py program.
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9. Consider adding build test cases in the test/ directory.
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Time
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====
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Fundamental to the operation of Klipper is the handling of clocks,
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times, and timestamps. Klipper executes actions on the printer by
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scheduling events to occur in the near future. For example, to turn on
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a fan, the code might schedule a change to a GPIO pin in a 100ms. It
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is rare for the code to attempt to take an instantaneous action. Thus,
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the handling of time within Klipper is critical to correct operation.
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There are three types of times tracked internally in the Klipper host
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software:
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* System time. The system time uses the system's monotonic clock - it
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is a floating point number stored as seconds and it is (generally)
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relative to when the host computer was last started. System times
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have limited use in the software - they are primarily used when
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interacting with the operating system. Within the host code, system
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times are frequently stored in variables named *eventtime* or
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*curtime*.
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* Print time. The print time is synchronized to the main
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micro-controller clock (the micro-controller defined in the "[mcu]"
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|
config section). It is a floating point number stored as seconds and
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|
is relative to when the main mcu was last restarted. It is possible
|
|
to convert from a "print time" to the main micro-controller's
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|
hardware clock by multiplying the print time by the mcu's statically
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|
configured frequency rate. The high-level host code uses print times
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|
to calculates almost all physical actions (eg, head movement, heater
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|
changes, etc.). Within the host code, print times are generally
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|
stored in variables named *print_time* or *move_time*.
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|
* MCU clock. This is the hardware clock counter on each
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|
micro-controller. It is stored as an integer and its update rate is
|
|
relative to the frequency of the given micro-controller. The host
|
|
software translates its internal times to clocks before transmission
|
|
to the mcu. The mcu code only ever tracks time in clock
|
|
ticks. Within the host code, clock values are tracked as 64bit
|
|
integers, while the mcu code uses 32bit integers. Within the host
|
|
code, clocks are generally stored in variables with names containing
|
|
*clock* or *ticks*.
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|
|
|
Conversion between the different time formats is primarily implemented
|
|
in the **klippy/clocksync.py** code.
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|
|
|
Some things to be aware of when reviewing the code:
|
|
* 32bit and 64bit clocks: To reduce bandwidth and to improve
|
|
micro-controller efficiency, clocks on the micro-controller are
|
|
tracked as 32bit integers. When comparing two clocks in the mcu
|
|
code, the `timer_is_before()` function must always be used to ensure
|
|
integer rollovers are handled properly. The host software converts
|
|
32bit clocks to 64bit clocks by appending the high-order bits from
|
|
the last mcu timestamp it has received - no message from the mcu is
|
|
ever more than 2^31 clock ticks in the future or past so this
|
|
conversion is never ambiguous. The host converts from 64bit clocks
|
|
to 32bit clocks by simply truncating the high-order bits. To ensure
|
|
there is no ambiguity in this conversion, the
|
|
**klippy/chelper/serialqueue.c** code will buffer messages until
|
|
they are within 2^31 clock ticks of their target time.
|
|
* Multiple micro-controllers: The host software supports using
|
|
multiple micro-controllers on a single printer. In this case, the
|
|
"MCU clock" of each micro-controller is tracked separately. The
|
|
clocksync.py code handles clock drift between micro-controllers by
|
|
modifying the way it converts from "print time" to "MCU clock". On
|
|
secondary mcus, the mcu frequency that is used in this conversion is
|
|
regularly updated to account for measured drift.
|