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1 2fc92540 Thomas Schöpping
About & License
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===============
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AMiRo-OS is an operating system for the base version of the Autonomous Mini
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Robot (AMiRo) [1]. It utilizes ChibiOS (a real-time operating system for
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embedded devices developed by Giovanni di Sirio; see <http://chibios.org>) as
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system kernel and extends it with platform specific configurations and further
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functionalities and abstractions.
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Copyright (C) 2016..2020  Thomas Schöpping et al.
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(a complete list of all authors is given below)
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or (at
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your option) any later version.
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This program is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program.  If not, see <http://www.gnu.org/licenses/>.
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This research/work was supported by the Cluster of Excellence
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Cognitive Interaction Technology 'CITEC' (EXC 277) at Bielefeld
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University, which is funded by the German Research Foundation (DFG).
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Authors:
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-   Thomas Schöpping (tschoepp@cit-ec.uni-bielefeld.de)
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-   Marc Rothmann
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References:
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[1] S. Herbrechtsmeier, T. Korthals, T. Schopping and U. Rückert, "AMiRo: A
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    modular & customizable open-source mini robot platform," 2016 20th
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    International Conference on System Theory, Control and Computing (ICSTCC),
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    Sinaia, 2016, pp. 687-692.
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--------------------------------------------------------------------------------
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Contents
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========
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1.  Required Software
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    1.  Git
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    2.  Bootloader & Tools (AMiRi-BLT)
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    3.  System Kernel (ChibiOS)
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    4.  Low-Level Drivers (AMiRo-LLD)
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    5.  OpenOCD
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2.  Recommended Software
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    1.  gtkterm and hterm
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    2.  Plantuml
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    3.  Doxygen & Graphviz
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    4.  QtCreator IDE
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3.  Building and Flashing
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4.  Developer Guides
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    1.  Adding a Module
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    2.  Adding a Shell Command
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    3.  Handling a Custom I/O Event in the Main Thread
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    4.  Implementing a Low-Level Driver
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    5.  Writing a Test
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--------------------------------------------------------------------------------
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1 Required Software
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===================
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In order to compile the source code, you need to install the GNU ARM Embedded
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Toolchain. Since this project uses GNU Make for configuring and calling the
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compiler, this tool is requried too. AMiRo-OS uses ChibiOS as system kernel,
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so you need a copy of that project as well.
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1.1 Git
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-------
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Since all main- and subprojects are available as Git repositories, installing a
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recent version of the tool is mandatory. Most Linux distributions like Ubuntu
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provide a sufficient version in their software repositories.
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1.2 Bootloader & Tools (AMiRo-BLT)
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----------------------------------
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AMiRo-OS can take advantage of an installed bootloader and provides an
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interface. By default, AMiRo-BLT is included as Git submodule and can easily be
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initialized via the provided `./setup.sh` script. Simply run
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    >$ ./setup.sh
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from a command line.
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If requried, is is possible to replace the used bootloader by adding an
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according subfolder in the `./bootloader/` directory. Note that you will have to
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adapt the makefiles and scripts, and probably the operating system as well.
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AMiRo-BLT furthermore has its own required and recommended software & tools as
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described in its `README.md` file. Follow the instructions to initialize the
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development environment manually or use the setup script.
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1.3 System Kernel (ChibiOS)
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---------------------------
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Since AMiRo-OS uses ChibiOS as underlying system kernel, you need to acquire a
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copy of it as well. For the sake of compatibility, it is included in AMiRo-OS as
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Git submodule. It is highly recommended to use the setup script for
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initialization. Moreover, you have to apply the patches to ChibiOS in order to
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make AMiRo-OS work properly. It is recommended to use the setup script for this
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purpose as well.
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If you would like to use a different kernel, you can add a subfolder in the
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`./kernel/` directory and adapt the scripts and operating system source code.
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1.4 Low-Level Drivers
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---------------------
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Any required low-level drivers for the AMiRo hardware are available in an
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additional project: AMiRo-LLD. It is included as Git subodule and can be
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initialized via the setup script. Since AMiRo-LLD is also used for
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experimentation and prototyping, it contains drivers even for some hardware that
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is not available on the AMiRo platform.
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1.5 OpenOCD
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-----------
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When running AMiRo-OS on non-AMiRo modules (e.g. NUCLEO development boards),
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those can be flashed using the OpenOCD toolchain (<http://openocd.org/>). It can
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be either installed from the software repositories of your operating system
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(reqiures root permissions) or built from source (no root required).  
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For a list of supported boards, please refer to the OpcenOCD documentation.
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2 Recommended Software
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======================
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The software tools named in this section are not essential for simply using or
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further development of AMiRo-BLT, but can help for both scenarios.
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2.1 gtkterm and hterm
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---------------------
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Depending on your operating system, it is recommended to install `gtkterm` for
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Linux (available in the Ubuntu repositories), or `hterm` for Windows. For
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`gtkterm` you need to modify the configuration file `~/.gtktermrc` (generated
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automatically when you start the application for the first time). For the AMiRo
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modules the configuration is:
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    [AMiRo]
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    port	= /dev/ttyAMiRo0
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    speed	= 115200
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    bits	= 8
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    stopbits	= 1
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    parity	= none
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    flow	= none
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    wait_delay	= 0
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    wait_char	= -1
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    rs485_rts_time_before_tx	= 30
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    rs485_rts_time_after_tx	= 30
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    echo	= False
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    crlfauto	= True
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The according configuration for all NUCLEO boards is:
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    [NUCLEO]
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    port	= /dev/ttyACM0
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    speed	= 115200
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    bits	= 8
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    stopbits	= 1
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    parity	= none
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    flow	= none
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    wait_delay	= 0
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    wait_char	= -1
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    rs485_rts_time_before_tx	= 30
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    rs485_rts_time_after_tx	= 30
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    echo	= False
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    crlfauto	= True
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When running `gtkterm` from the command line, you can select a defined
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configuration via the `-c` option:
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    >$ gtkterm -c AMiRo
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    >$ gtkterm -c NUCLEO
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For `hterm` you need to configure the tool analogously. With either tool the
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robot can be reset by toggling the RTS signal on and off again, and you can
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access the system shell of AMiRo-OS.  
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If you are using an old version of AMiRo-BLT, the `/dev/ttyAMiRo` devices might
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not be available. In order to enable legacy support, replace the port value by
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`/dev/ttyUSB0`.
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Advanced users can use several connections to multiple modules simultaneously.
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Each additional programmer will be available as `/dev/ttyAMiRo<N>` (and
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`/dev/ttyUSB<N>` respectively) with `<N>` being an integer starting from 0.
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Please note: Those interfaces are ordered by the time when they have been
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detected by the operating system, so detaching a cable and plugging it in again
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may result in a different port name.
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2.2 PlantUML
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------------
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PlantUML is a free and open source Java tool to generate UML diagrams via scrips
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(see <https://plantuml.com>). AMiRo-OS provides according scripts in the
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`./doc/` directory. Please refer to the PlantUML documentation for how to
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generate figures from these script files.
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2.3 Doxygen & Graphviz
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----------------------
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In order to generate the documentation from the source code, Doxygen and
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Graphviz are requried. It is recommended to install these tool using the
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default versions for your system. Ubuntu users should simply run
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    >$ sudo apt-get install doxygen graphviz
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2.4 QtCreator IDE
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-----------------
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AMiRo-OS provides support for the QtCreator IDE. In order to setup according
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projects, use the setup script and follow the instructions. It will
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automatically generate the required files and you can import the projects by
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opening the `.creator` files with QtCreator IDE.  
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Please note that you will need to recompile the AMiRo-OS source code after each
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project generation, since the generator runs a compiler call.
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Further instructions for a more advanced configuration of the IDE are provided
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in the `./tools/qtcreator/README.txt` file.
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3 Building and Flashing
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=======================
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Each time you modify any part of AMiRo-OS, you need to recompile the whole
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project for the according AMiRo module. Therefore you can use the `./Makefile`
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by simply executing `make` and follow the instructions:
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    >$ cd /path/to/AMiRo-OS/root/
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    >$ make
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Alternatively, you can either use the makefiles provided per module in
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`./modules/<module_to_compile>/` or the makefile in the `./modules/` folder.
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After the build process has finished successfully, you always have to flash the
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generated program to the module. Therefore you need an appropriate tool, such as
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`SerialBoot` for the AMiRo base modules (provided by AMiRo-BLT) or OpenOCD.
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Similar to the compilation procedure as described above, you can flash either
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each module individually, or all modules at once by using the same makefiles.
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When using `SerialBoot`, please note that you must connect the programming cable
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either to the _DiWheelDrive_ or the _PowerManagement_ module for flashing the
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operating system. All other modules are powered off after reset so that only
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these two offer a running bootloader, which is required for flashing.
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4 Developer Guides
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==================
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Due to the complexity of AMiRo-OS it can be quite troublesome to get started
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with the framework at the beginning. The guides in this chapter will help you
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getting things done, without thorough knowledge of the software structure.
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Whereas the textual descriptions of the guides provide in-depth information
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about the underlying concepts and mechanisms, a short summary is provided at the
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end of each chapter.
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4.1 Adding a Module
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-------------------
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The very first thing to do when adding a new module to support AMiRo-OS, is to
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create an according folder in the `./modules/` directory. The name of this
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folder should be as unambiguous as possible (e.g. containing name and version
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number). All files, which directly depent on the hardware, and thus are not
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portable, belong here. Conversely, any code that can be reused on diferent
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hardware should not be placed in this module folder.
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In a second step you have to initialize all requried files (see below) in the
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newly created module directory. It is recommended to use another module as
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template for your configuration:
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*   alldconf.h  
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    Configuration header for the AMiRo-LLD project, which is part of AMiRo-OS.
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    There are probably only very few configurations done here, since most
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    setting depend on the content of aosconf.h and are handled module
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    unspecifically in the `./modules/aos_alldconf.h` file.
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*   aosconf.h  
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    Configuration header for the AMiRo-OS project. Existing cofiguration files
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    are well documented and name all available settings.
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*   board.h & board.c  
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    Contains definitions of GPIO names and initialization setting of those, as
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    well as initialization functions. These configurations highly depend on the
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    hardware setup.
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*   chconf.h  
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    Configuration header for the ChibiOS/RT system kernel. There are probably
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    only very few configurations done here, since most settings depend on the
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    content of aosconf.h and are handled module unspecifically in the
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    `./modules/aos_chconf.h` file.
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*   halconf.h  
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    Configuration header for ChibiOS/HAL (hardware abstraction layer). Existing
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    files are well documented and name all available settings. Please refer to
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    ChibiOS for further details.
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*   Makefile  
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    The GNU make script to build and flash AMiRo-OS for the module.
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*   mcuconf.h  
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    Configuration file for ChibiOS/HAL to initialize the microcontroller (MCU).
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    It is recommended to check the `./kernel/ChibiOS/demos/` directory for an
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    example using the according MCU and copy the mcuconf.h from there. Depending
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    on your hardware setup you may have to modify it nevertheless, though.
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*   module.h & module.c  
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    These files act as some sort of container, where all module specific aliases
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    for interfaces and GPIOs, configurations, hooks, low-level drivers, and
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    tests are defined. These are the most comprehensive files in the module
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    folder.
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*   <mcu\>.ld  
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    Linker script, defining the memory layout and region aliases. It is
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    recommended to check ChibiOS (`./kernel/ChibiOS/os/common/startup/`) whether
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    a linker script for the according MCU already exists.
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Since all these files are specific to the module hardware, you will have to
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modify the contents according to your setup in a third step. Most settings are
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described in detail within the configuration files, but for others you will have
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to consult the datasheet of your MCU and even take a closer look at how certain
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settings are used in other modules.
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Finally, you need to build and flash the project. The compiler might even help
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you getting everything set up correctly. Take the time needed to understand
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compilation errors and warnings and get rid of all of those (warnings should not
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be ignored since they are hints that something might be amiss and the program
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will not act as intended).
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As you will probably notice, for most modules there is an additional 'test/'
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folder. This folder contains module specific wrapper code for tests (e.g. for
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hardware devices). Since tests are not essential but a more advanced feature,
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a separate guide describes how to write a test in section 4.5.
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**Summing up, you have to**
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1.  create a module directory.
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2.  initialize all files (use an existing module or a ChibiOS demo as template).
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3.  configure all files according to your hardware setup and preferences.
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4.  compile, flash and check for issues.
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4.2 Adding a Shell Command
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--------------------------
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Before going into the technical details, how a new shell command is initialized
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and registered to a shell, some basic concepts of the AMiRo shell should be
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covered first. Most fundamentally, although for most use cases a single shell
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instance on a module will suffice, there can be an arbitrary number of shells.
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Each shell runs in its own thread and has an exclusive list of shell commands.
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That said, each shell command can be registered to only one (or none) shell.  
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Another important aspect of the AMiRo shell are the I/O streams. Each shell
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reads and writes from/to a shell stream. Such a stream may again contain an
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arbitrary number of channels. Whilst only one of those channels can be selected
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as input, each and all channels can be configured as output. As a result, if a
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hardware module features multiple I/O interfaces, according configuration of the
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shell stream and its channels, allows to still use only a single shell instance.
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If not disabled in the aosconf.h file, AMiRo-OS already runs a system shell in
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a thread with minimum priority.
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Depending on the configuration, several commands are registered to the system
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shell by default (e.g. `kernel:test`, `module:info`), which are defined in the
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AMiRo-OS core. In order to add additional custom command, those should be
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defined in the module.h and module.c files. First you need to _declare_ the
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shell command - an instance of the memory structure representing a command - in
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the module.h file. Second, you have to _define_ that structure in the module.c
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file via the `AOS_SHELL_COMMAND(var, name, callback)` macro function. This macro
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takes three arguments:
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1.  `var`  
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    Name of the variable (must be identical to the _declaration_).
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2.  `name`  
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    Command string which will be shown and used in the shell. By convention,
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    command names follow a colon notation, e.g. `module:info`, where the first
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    part denotes the scope of the command (e.g. kernel, module, tests, etc.) and
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    the second part specifies the command in this scope.
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3.  `callback`  
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    Callback function to be executed by the command.
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The callback function is typically defined right before the
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`AOS_SHELL_COMMAND()` macro is called and should be a mere wrapper, calling
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another function. Keep in mind, though, that thos callback are executed within
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the shell thread and thus inherit its (typically very low) priority and there is
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no way to calling a command in a non-blocking manner.
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Finally, you have to register the command to a shell. This is very important and
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a common mistake, but naturally, a shell can only access commands, which are
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known to it. Registration is done via the `aosShellAddCommand()` function,
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preferably before the shell thread is started. Since test commands are the most
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common use case, AMiRo-OS provides the hook `MODULE_INIT_TESTS()`, which is
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defined in each module.h file.
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**Summing up, you have to**
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1.  decllare and define a command.
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2.  implement a callback function.
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3.  register the command to a shell.
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4.3 Handling a Custom I/O Event in the Main Thread
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--------------------------------------------------
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In order to handle custom I/O events in the main thread, AMiRo-OS offers several
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hooks to be used. First of all, you need to configure and enable the interrupt
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for the according GPIO. This can be done by implementing the
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`MODULE_INIT_INTERRUPTS()` hook in the module.h file. For information how to use
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this hook, please have a look at existing modules. In the end, the interrupt
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callback functions has to emit an I/O event with the according bit in the flags
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mask set (such as the `_gpioCallback()` function in `./core/src/aos_system.c`).
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As result, whenever a rising or falling edge (depends on configuration) is
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detected on that particular GPIO, the interrupt service routine is executed and
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hence an I/O event is emitted, which can be received by any thread in the
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system.
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Next, you have to explicitely whitelist the event flag for the main thread,
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because by default it ignores all I/O events other than power down and such.
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This is done via the optional `AMIROOS_CFG_MAIN_LOOP_GPIOEVENT_FLAGSMASK` macro,
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which should be defined in the module.h file, for example:
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    #define AMIROOS_CFG_MAIN_LOOP_GPIOEVENT_FLAGSMASK         \
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            (AOS_GPIOEVENT_FLAG(padX) | AOS_GPIOEVENT_FLAG(padY) | AOS_GPIOEVENT_FLAG(padZ))
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When `AMIROOS_CFG_MAIN_LOOP_GPIOEVENT_FLAGSMASK` has been defined correctly, the
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main thread will be notified by the according events and execute its event
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handling routine. Hence you have to implement another macro in module.h to
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handle the custom event(s) appropriately:
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`MODULE_MAIN_LOOP_GPIOEVENT(eventflags)`. As you can see, the variable
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`eventflags` is propagated to the hook. This variable is a mask, that allows to
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identify the GPIO pad(s), which caused the event, by the individually set bits.
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Following the example above, you can check which GPIOs have caused events by
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using if-clauses in the implementation of the hook:
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    #define MODULE_MAIN_LOOP_GPIOEVENT(eventflags) {          \
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      if (eventflags & AOS_GPIOEVENT_FLAG(padX)) {            \
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        /* handle event */                                    \
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      }                                                       \
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      if (eventflags & (AOS_IOEVENT_FLAG(padY) |              \
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            AOS_GPIOEVENT_FLAG(padZ))) {                      \
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        /* handle combined event */                           \
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      }                                                       \
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    }
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**Summing up, you have to**
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1.  configure and enable the GPIO interrupt.
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2.  define the AMIROOS_CFG_MAIN_LOOP_GPIOEVENT_FLAGSMASK macro.
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3.  implement the MODULE_MAIN_LOOP_GPIOEVENT(eventflags) hook.
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4.4 Implementing a Low-Level Driver
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-----------------------------------
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In the AMiRo-OS framework, low-level drivers are located in the additional Git
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project AMiRo-LLD, which is included in AMiRo-OS as Git submodule at
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`./periphery-lld/AMiRo-LLD/` and acts similar to a static library. When adding a
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new low-level driver to the framework, you first have to implement it of course.
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For details how to do so, please following the instructions givne in the
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`README.md` file in the AMiRo-LLD root directory.
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Now that the new driver is available, it can be enbled by simply including the
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driver's makefile script in the makefile of the module, you are working on. In
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order to make actuale use of the driver, you have to add according memory
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structures to the module.h and module.c files - just have a look at existing
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modules how this is done. In some cases you will have to configure additional
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interrupts and/or alter the configuration of a communication interface
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(e.g. I2C). Once again, you should take a look at existing modules and search
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the module.h for the hooks `MODULE_INIT_INTERRUPTS()`,
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`MODULE_INIT_PERIPHERY_IF()` and `MODULE_SHUTDOWN_PERIPHERY_IF()`.
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Finally, you will probably want to validate your implementation via a test. How
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this can be done is explained in detail in the next guide.
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**Summing up, you have to**
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1.  implement the driver in AMiRo-LLD using periphAL only.
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2.  add the driver to a module (Makefile, module.h and module.c).
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3.  configure interrupts and interfaces as required.
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4.  write a test to verify your setup.
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4.4 Writing a Test
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------------------
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AMiRo-OS provides a test framework for conventient testing and the ability to
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opt-out all tests via the aosconf.h configuration file. There is also a
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dedicated folder, where all test code belongs to. In case you want to implement
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a test for a newly developed low-level driver, you should have a look at the
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folder `./test/periphery-lld/`. As with the low-level drivers, tests are placed
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in individual subfolders (e.g. `./test/periphery-lld/DEVICE1234_v1`) and all
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files should use the prefix `aos_test_` in their name. Moreover, all code must
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be fenced by guards that disable it completely if the `AMIROOS_CFG_TESTS_ENABLE`
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flag is set to false in the aosconf.h configuration file.
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Now you have to add the test to a specific module. Therefore, you should create
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a `test/` directory in the module folder, if such does not exist yet. In this
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directory, you create another subfolder, e.g. `DEVICE1234/` and three additional
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files in there:
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*   module_test_DEVICE1234.mk
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*   module_test_DEVICE1234.h
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*   module_test_DEVICE1234.c
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The makefile script is not required, but recommended to achieve maintainable
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code. This script file should add the folder to the `MODULE_INC` variable and
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all C source files to `MODULE_CSRC`. The header and source files furthermore
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define module specific data structures and a test function. In order to clearly
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indicate that these files are module specific wrappers, their names should begin
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with the `module_test_` prefix.
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In order to be able to call such test function as a command via the AMiRo-OS
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shell, you need to add an according shell command to the module.h and module.c
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files. Whereas the command itself is typically very simple, just calling the
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callback function defined in the `./test/DEVICE1234/module_test_DEVICE1234.h`/
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`.c` files, you have to add the command to a shell. In order to make the command
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available in a shell so a user can run it, it has to be associated with the
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shell. AMiRo-OS provides the hook `MODULE_INIT_TESTS()` for this purpose, which
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has to be implemented in the module.h file. Once again it is recommended to have
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a look at an existing module, how to use this hook. Furthermore, there is more
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detailled guide on adding shell commands.
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**Summing up, you have to**
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1.  implement the common test in the `./test/` folder.
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2.  implement a module specific wrapper in the `./modules/<module>/test/`
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    folder.
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3.  associate the shell command to a shell via the `MODULE_INIT_TESTS()` hook in
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    module.h.