mirror of https://github.com/Desuuuu/klipper.git
442 lines
15 KiB
Markdown
442 lines
15 KiB
Markdown
This document provides information on common bootloaders found on
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micro-controllers that Klipper supports.
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The bootloader is 3rd-party software that runs on the micro-controller
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when it is first powered on. It is typically used to flash a new
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application (eg, Klipper) to the micro-controller without requiring
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specialized hardware. Unfortunately, there is no industry wide
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standard for flashing a micro-controller, nor is there a standard
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bootloader that works across all micro-controllers. Worse, it is
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common for each bootloader to require a different set of steps to
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flash an application.
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If one can flash a bootloader to a micro-controller then one can
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generally also use that mechanism to flash an application, but care
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should be taken when doing this as one may inadvertently remove the
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bootloader. In contrast, a bootloader will generally only permit a
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user to flash an application. It is therefore recommended to use a
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bootloader to flash an application where possible.
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This document attempts to describe common bootloaders, the steps
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needed to flash a bootloader, and the steps needed to flash an
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application. This document is not an authoritative reference; it is
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intended as a collection of useful information that the Klipper
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developers have accumulated.
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AVR micro-controllers
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=====================
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In general, the Arduino project is a good reference for bootloaders
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and flashing procedures on the 8-bit Atmel Atmega micro-controllers.
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In particular, the "boards.txt" file:
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[https://github.com/arduino/Arduino/blob/1.8.5/hardware/arduino/avr/boards.txt](https://github.com/arduino/Arduino/blob/1.8.5/hardware/arduino/avr/boards.txt)
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is a useful reference.
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To flash a bootloader itself, the AVR chips require an external
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hardware flashing tool (which communicates with the chip using
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SPI). This tool can be purchased (for example, do a web search for
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"avr isp", "arduino isp", or "usb tiny isp"). It is also possible to
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use another Arduino or Raspberry Pi to flash an AVR bootloader (for
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example, do a web search for "program an avr using raspberry pi"). The
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examples below are written assuming an "AVR ISP Mk2" type device is in
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use.
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The "avrdude" program is the most common tool used to flash atmega
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chips (both bootloader flashing and application flashing).
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## Atmega2560 ##
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This chip is typically found in the "Arduino Mega" and is very common
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in 3d printer boards.
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To flash the bootloader itself use something like:
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```
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wget 'https://github.com/arduino/Arduino/raw/1.8.5/hardware/arduino/avr/bootloaders/stk500v2/stk500boot_v2_mega2560.hex'
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avrdude -cavrispv2 -patmega2560 -P/dev/ttyACM0 -b115200 -e -u -U lock:w:0x3F:m -U efuse:w:0xFD:m -U hfuse:w:0xD8:m -U lfuse:w:0xFF:m
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avrdude -cavrispv2 -patmega2560 -P/dev/ttyACM0 -b115200 -U flash:w:stk500boot_v2_mega2560.hex
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avrdude -cavrispv2 -patmega2560 -P/dev/ttyACM0 -b115200 -U lock:w:0x0F:m
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```
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To flash an application use something like:
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```
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avrdude -cwiring -patmega2560 -P/dev/ttyACM0 -b115200 -D -Uflash:w:out/klipper.elf.hex:i
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```
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## Atmega1280 ##
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This chip is typically found in earlier versions of the "Arduino
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Mega".
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To flash the bootloader itself use something like:
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```
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wget 'https://github.com/arduino/Arduino/raw/1.8.5/hardware/arduino/avr/bootloaders/atmega/ATmegaBOOT_168_atmega1280.hex'
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avrdude -cavrispv2 -patmega1280 -P/dev/ttyACM0 -b115200 -e -u -U lock:w:0x3F:m -U efuse:w:0xF5:m -U hfuse:w:0xDA:m -U lfuse:w:0xFF:m
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avrdude -cavrispv2 -patmega1280 -P/dev/ttyACM0 -b115200 -U flash:w:ATmegaBOOT_168_atmega1280.hex
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avrdude -cavrispv2 -patmega1280 -P/dev/ttyACM0 -b115200 -U lock:w:0x0F:m
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```
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To flash an application use something like:
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```
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avrdude -carduino -patmega1280 -P/dev/ttyACM0 -b57600 -D -Uflash:w:out/klipper.elf.hex:i
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```
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## Atmega1284p ##
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This chip is commonly found in "Melzi" style 3d printer boards.
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To flash the bootloader itself use something like:
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```
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wget 'https://github.com/Lauszus/Sanguino/raw/1.0.2/bootloaders/optiboot/optiboot_atmega1284p.hex'
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avrdude -cavrispv2 -patmega1284p -P/dev/ttyACM0 -b115200 -e -u -U lock:w:0x3F:m -U efuse:w:0xFD:m -U hfuse:w:0xDE:m -U lfuse:w:0xFF:m
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avrdude -cavrispv2 -patmega1284p -P/dev/ttyACM0 -b115200 -U flash:w:optiboot_atmega1284p.hex
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avrdude -cavrispv2 -patmega1284p -P/dev/ttyACM0 -b115200 -U lock:w:0x0F:m
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```
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To flash an application use something like:
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```
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avrdude -carduino -patmega1284p -P/dev/ttyACM0 -b115200 -D -Uflash:w:out/klipper.elf.hex:i
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```
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Note that a number of "Melzi" style boards come preloaded with a
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bootloader that uses a baud rate of 57600. In this case, to flash an
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application use something like this instead:
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```
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avrdude -carduino -patmega1284p -P/dev/ttyACM0 -b57600 -D -Uflash:w:out/klipper.elf.hex:i
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```
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## At90usb1286 ##
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This document does not cover the method to flash a bootloader to the
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At90usb1286 nor does it cover general application flashing to this
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device.
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The Teensy++ device from pjrc.com comes with a proprietary bootloader.
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It requires a custom flashing tool from
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[https://github.com/PaulStoffregen/teensy_loader_cli](https://github.com/PaulStoffregen/teensy_loader_cli).
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One can flash an application with it using something like:
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```
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teensy_loader_cli --mcu=at90usb1286 out/klipper.elf.hex -v
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```
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## Atmega168 ##
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The atmega168 has limited flash space. If using a bootloader, it is
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recommended to use the Optiboot bootloader. To flash that bootloader
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use something like:
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```
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wget 'https://github.com/arduino/Arduino/raw/1.8.5/hardware/arduino/avr/bootloaders/optiboot/optiboot_atmega168.hex'
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avrdude -cavrispv2 -patmega168 -P/dev/ttyACM0 -b115200 -e -u -U lock:w:0x3F:m -U efuse:w:0x04:m -U hfuse:w:0xDD:m -U lfuse:w:0xFF:m
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avrdude -cavrispv2 -patmega168 -P/dev/ttyACM0 -b115200 -U flash:w:optiboot_atmega168.hex
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avrdude -cavrispv2 -patmega168 -P/dev/ttyACM0 -b115200 -U lock:w:0x0F:m
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```
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To flash an application via the Optiboot bootloader use something
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like:
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```
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avrdude -carduino -patmega168 -P/dev/ttyACM0 -b115200 -D -Uflash:w:out/klipper.elf.hex:i
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```
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SAM3 micro-controllers (Arduino Due)
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====================================
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It is not common to use a bootloader with the SAM3 mcu. The chip
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itself has a ROM that allows the flash to be programmed from 3.3V
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serial port or from USB.
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To enable the ROM, the "erase" pin is held high during a reset, which
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erases the flash contents, and causes the ROM to run. On an Arduino
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Due, this sequence can be accomplished by setting a baud rate of 1200
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on the "programming usb port" (the USB port closest to the power
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supply).
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The code at
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[https://github.com/shumatech/BOSSA](https://github.com/shumatech/BOSSA)
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can be used to program the SAM3. It is recommended to use version 1.9
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or later.
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To flash an application use something like:
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```
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bossac -U -p /dev/ttyACM0 -a -e -w out/klipper.bin -v -b
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bossac -U -p /dev/ttyACM0 -R
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```
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SAM4 micro-controllers (Duet Wifi)
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====================================
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It is not common to use a bootloader with the SAM4 mcu. The chip
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itself has a ROM that allows the flash to be programmed from 3.3V
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serial port or from USB.
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To enable the ROM, the "erase" pin is held high during a reset, which
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erases the flash contents, and causes the ROM to run.
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The code at
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[https://github.com/shumatech/BOSSA](https://github.com/shumatech/BOSSA)
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can be used to program the SAM4. It is necessary to use version
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`1.8.0` or higher.
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To flash an application use something like:
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```
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bossac --port=/dev/ttyACM0 -b -U -e -w -v -R out/klipper.bin
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```
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SAMD21 micro-controllers (Arduino Zero)
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=======================================
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The SAMD21 bootloader is flashed via the ARM Serial Wire Debug (SWD)
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interface. This is commonly done with a dedicated SWD hardware dongle.
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Alternatively, one can use a
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[Raspberry Pi with OpenOCD](#running-openocd-on-the-raspberry-pi).
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To flash a bootloader with OpenOCD use the following chip config:
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```
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source [find target/at91samdXX.cfg]
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```
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Obtain a bootloader - for example:
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```
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wget 'https://github.com/arduino/ArduinoCore-samd/raw/1.8.3/bootloaders/zero/samd21_sam_ba.bin'
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```
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Flash with OpenOCD commands similar to:
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```
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at91samd bootloader 0
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program samd21_sam_ba.bin verify
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```
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The most common bootloader on the SAMD21 is the one found on the
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"Arduino Zero". It uses an 8KiB bootloader (the application must be
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compiled with a start address of 8KiB). One can enter this bootloader
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by double clicking the reset button. To flash an application use
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something like:
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```
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bossac -U -p /dev/ttyACM0 --offset=0x2000 -w out/klipper.bin -v -b -R
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```
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In contrast, the "Arduino M0" uses a 16KiB bootloader (the application
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must be compiled with a start address of 16KiB). To flash an
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application on this bootloader, reset the micro-controller and run the
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flash command within the first few seconds of boot - something like:
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```
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avrdude -c stk500v2 -p atmega2560 -P /dev/ttyACM0 -u -Uflash:w:out/klipper.elf.hex:i
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```
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SAMD51 micro-controllers (Adafruit Metro-M4 and similar)
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========================================================
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Like the SAMD21, the SAMD51 bootloader is flashed via the ARM Serial
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Wire Debug (SWD) interface. To flash a bootloader with
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[OpenOCD on a Raspberry Pi](#running-openocd-on-the-raspberry-pi) use
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the following chip config:
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```
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source [find target/atsame5x.cfg]
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```
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Obtain a bootloader - several bootloaders are available from
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[https://github.com/adafruit/uf2-samdx1/releases/latest](https://github.com/adafruit/uf2-samdx1/releases/latest). For example:
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```
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wget 'https://github.com/adafruit/uf2-samdx1/releases/download/v3.7.0/bootloader-itsybitsy_m4-v3.7.0.bin'
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```
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Flash with OpenOCD commands similar to:
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```
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at91samd bootloader 0
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program bootloader-itsybitsy_m4-v3.7.0.bin verify
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at91samd bootloader 16384
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```
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The SAMD51 uses a 16KiB bootloader (the application must be compiled
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with a start address of 16KiB). To flash an application use something
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like:
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```
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bossac -U -p /dev/ttyACM0 --offset=0x4000 -w out/klipper.bin -v -b -R
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```
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STM32F103 micro-controllers (Blue Pill devices)
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===============================================
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The STM32F103 devices have a ROM that can flash a bootloader or
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application via 3.3V serial. To access this ROM, one should connect
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the "boot 0" pin to high and "boot 1" pin to low, and then reset the
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device. The "stm32flash" package can then be used to flash the device
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using something like:
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```
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stm32flash -w out/klipper.bin -v -g 0 /dev/ttyAMA0
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```
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Note that if one is using a Raspberry Pi for the 3.3V serial, the
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stm32flash protocol uses a serial parity mode which the Raspberry Pi's
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"miniuart" does not support. See
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[https://www.raspberrypi.org/documentation/configuration/uart.md](https://www.raspberrypi.org/documentation/configuration/uart.md)
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for details on enabling the full uart on the Raspberry Pi GPIO pins.
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After flashing, set both "boot 0" and "boot 1" back to low so that
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future resets boot from flash.
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## STM32F103 with stm32duino bootloader ##
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The "stm32duino" project has a USB capable bootloader - see:
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[https://github.com/rogerclarkmelbourne/STM32duino-bootloader](https://github.com/rogerclarkmelbourne/STM32duino-bootloader)
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This bootloader can be flashed via 3.3V serial with something like:
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```
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wget 'https://github.com/rogerclarkmelbourne/STM32duino-bootloader/raw/master/binaries/generic_boot20_pc13.bin'
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stm32flash -w generic_boot20_pc13.bin -v -g 0 /dev/ttyAMA0
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```
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This bootloader uses 8KiB of flash space (the application must be
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compiled with a start address of 8KiB). Flash an application with
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something like:
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```
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dfu-util -d 1eaf:0003 -a 2 -R -D out/klipper.bin
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```
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The bootloader typically runs for only a short period after boot. It
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may be necessary to time the above command so that it runs while the
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bootloader is still active (the bootloader will flash a board led
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while it is running). Alternatively, set the "boot 0" pin to low and
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"boot 1" pin to high to stay in the bootloader after a reset.
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LPC176x micro-controllers (Smoothieboards)
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==========================================
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This document does not describe the method to flash a bootloader
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itself - see:
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[http://smoothieware.org/flashing-the-bootloader](http://smoothieware.org/flashing-the-bootloader)
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for further information on that topic.
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It is common for Smoothieboards to come with a bootloader from:
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[https://github.com/triffid/LPC17xx-DFU-Bootloader](https://github.com/triffid/LPC17xx-DFU-Bootloader).
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When using this bootloader the application must be compiled with a
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start address of 16KiB. The easiest way to flash an application with
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this bootloader is to copy the application file (eg,
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`out/klipper.bin`) to a file named `firmware.bin` on an SD card, and
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then to reboot the micro-controller with that SD card.
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Running OpenOCD on the Raspberry PI
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===================================
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OpenOCD is a software package that can perform low-level chip flashing
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and debugging. It can use the GPIO pins on a Raspberry Pi to
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communicate with a variety of ARM chips.
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This section describes how one can install and launch OpenOCD. It is
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derived from the instructions at:
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[https://learn.adafruit.com/programming-microcontrollers-using-openocd-on-raspberry-pi](https://learn.adafruit.com/programming-microcontrollers-using-openocd-on-raspberry-pi)
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Begin by downloading and compiling the software (each step may take
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several minutes and the "make" step may take 30+ minutes):
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```
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sudo apt-get update
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sudo apt-get install autoconf libtool telnet
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mkdir ~/openocd
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cd ~/openocd/
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git clone http://openocd.zylin.com/openocd
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cd openocd
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./bootstrap
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./configure --enable-sysfsgpio --enable-bcm2835gpio --prefix=/home/pi/openocd/install
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make
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make install
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```
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## Configure OpenOCD
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Create an OpenOCD config file:
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```
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nano ~/openocd/openocd.cfg
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```
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Use a config similar to the following:
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```
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# Uses RPi pins: GPIO25 for SWDCLK, GPIO24 for SWDIO, GPIO18 for nRST
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source [find interface/raspberrypi2-native.cfg]
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bcm2835gpio_swd_nums 25 24
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bcm2835gpio_srst_num 18
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transport select swd
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# Use hardware reset wire for chip resets
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reset_config srst_only
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adapter_nsrst_delay 100
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adapter_nsrst_assert_width 100
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# Specify the chip type
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source [find target/atsame5x.cfg]
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# Set the adapter speed
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adapter_khz 40
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# Connect to chip
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init
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targets
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reset halt
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```
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## Wire the Raspberry Pi to the target chip
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Poweroff both the the Raspberry Pi and the target chip before wiring!
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Verify the target chip uses 3.3V prior to connecting to a Raspberry
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Pi!
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Connect GND, SWDCLK, SWDIO, and RST on the target chip to GND, GPIO25,
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GPIO24, and GPIO18 respectively on the Raspberry Pi.
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Then power up the Raspberry Pi and provide power to the target chip.
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## Run OpenOCD
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Run OpenOCD:
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```
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cd ~/openocd/
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sudo ~/openocd/install/bin/openocd -f ~/openocd/openocd.cfg
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```
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The above should cause OpenOCD to emit some text messages and then
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wait (it should not immediately return to the Unix shell prompt). If
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OpenOCD exits on its own or if it continues to emit text messages then
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double check the wiring.
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Once OpenOCD is running and is stable, one can send it commands via
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telnet. Open another ssh session and run the following:
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```
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telnet 127.0.0.1 4444
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```
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(One can exit telnet by pressing ctrl+] and then running the "quit"
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command.)
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## OpenOCD and gdb
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It is possible to use OpenOCD with gdb to debug Klipper. The following
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commands assume one is running gdb on a desktop class machine.
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Add the following to the OpenOCD config file:
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```
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bindto 0.0.0.0
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gdb_port 44444
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```
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Restart OpenOCD on the Raspberry Pi and then run the following Unix
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command on the desktop machine:
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```
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cd /path/to/klipper/
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gdb out/klipper.elf
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```
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Within gdb run:
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```
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target remote octopi:44444
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```
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(Replace "octopi" with the host name of the Raspberry Pi.) Once gdb is
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running it is possible to set breakpoints and to inspect registers.
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