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AMiRo-LLD is a compilation of low-level hardware drivers for the base version of
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the Autonomous Mini Robot (AMiRo) [1]. It provides directional interfaces for an
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operating system to access the drivers and for the drivers to access the
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communication infrastructure via the operating system.
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Copyright (C) 2016..2019  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 Lesser 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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Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser 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[at]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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################################################################################
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This file provides information about the purpose of this project, the file
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structure and some helpful guides for development of code.
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================================================================================
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CONTENTS:
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  1  About the Project
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  2  File Structure
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  3  Developer Guides
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    3.1  Adding a Device
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    3.2  Implementing a Driver
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================================================================================
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1 - ABOUT THE PROJECT
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=====================
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AMiRo-LLD is a compilation of low-level hardware drivers, originally developed
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for the Autonomous Mini Robot (AMiRo) [1]. It provides a modular design, so that
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each driver can be activated individually as required. Interface functions allow
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for bidirectional comunication with an operating system. On the one hand drivers
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access according hardware interfaces via defined interface functions (which need
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to be implemented by the operating system) and any applications (or the
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operating system itself) can take advantage of the drivers by their individual
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interfaces. The abstraction layer of the hardware interfaces is called
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"periphAL", which is defined by this project. In order to configure which
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drivers should be used in which version, the project expects an according file
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"alldconf.h" to be found in the include paths.
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Although this compilation was originally designed to be used in combination with
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the AMiRo operating system (AMiRo-OS; cf. https://opensource.cit-ec.de/projects/amiro-os/),
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it is not limited to this use case. The included drivers may be used for any
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purpose and contributions of further drivers, even if the according hardware is
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not present on the AMiRo platform, are highly appreciated.
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2 - FILE STRUCTURE
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==================
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The files are structured as follows:
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./
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│ The project root directory contains this file, a license.html file as well as
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│ a Makefile that allows to easily integrate the project. Furthermore, two
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│ interface headers are provided: amiro-lld.h and periphALtypes.h. These are
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│ entry points for any utilizing superproject, so it is not required (and not
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│ recommended) to include each driver individually.
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├── include/
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│     For each supported hardware device, there is exactly one directory in this
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│     folder. Further subfolders may contain various versions of a driver (e.g.
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│     'v1/', 'v2/', etc.). By convention the root directory of a driver is named
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│     by the form
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│     "<product_name>/"
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│     <product_name> is a placeholder for the exact name of the according
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│     hardware, or the product familiy, if the driver is compatible with all
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│     parts.
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│     The root header consequently follows the naming scheme
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│     "alld_<product_name>.h"
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│     and header files within the version folders shall be named like
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│     "alld<product_name>_<driver_version>.h"
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├── source/
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│     Any source files are placed in this directory. Naming conventions for
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│     folders and files are the same as described before for the include
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│     directory, as is the file structure. There is a dedicated folder for each
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│     device and further subfolders for multiple driver versions. Source files
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│     should only be put in these version folders.
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└── templates/
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      AMiRo-LLD requires an implementation of the defined interface and an
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      configuration header to be accessible in the include paths at compile
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      time. Template files for both can be found in this folder. It is
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      recommended to place according implementations of these templated not in
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      the AMiRo-LLD project, but the superproject which includes AMiRo-LLD.
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3 - DEVELOPER GUIDES
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====================
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In order to keep all code within this project as homogeneous as possible, the
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guides of these chapters should help developers to achieve functional and clean
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results, which are portable and maintainable for future use. Whereas the textual
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descriptions of the guides provide additional information about the underlying
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concepts and mechanisms, a short summary is provided at the end of each chapter.
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3.1  Adding a Device
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--------------------
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When adding new device to the project, the very first step is to create the
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according folders in the include/ and source/ directories. For this guide, we
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will add the fictional DEVICE1234. For this example the folders to be created
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are "include/DEVICE1234/" and "source/DEVICE1234/".
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The first file should be the root header: "include/DEVICE1234/alld_DEVICE1234.h"
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Have a look at existing drivers and use one of those as template. This header
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should introduce a new configuration to be set in the alldconf.h file and check
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it using the preprocessor. Eventually, another header is included, pointing to
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the selected driver version/implementation.
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Such implementations are to be put in further subfolders, e.g.
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"include/DEVICE1234/v1/" and "source/DEVICE1234/v1/". The header and C-source
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files in those folders do not follow a strict scheme, although there are some
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conventions to consider (i.e. naming conventions, cf. chapter 2).
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Summing up, you have to
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1) create device folders.
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2) add a root header.
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3) add further subfolders and implement the driver there.
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3.2  Implementing a Driver
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--------------------------
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Implementation of a new driver usually is very straight-forward. You most
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probably have a comprehensive datasheet of the device, or the manufacturer even
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provides a reference driver implementation.
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For the former case, you should first write a comprehensive header, containing
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all information like constants, register maps, etc. and according abstract
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access functions (e.g. for reading and writing registers, and convenient access
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to common functionalities). Only the you implement those functions, using
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periphAL to interface any hardware interfaces (e.g. I2C, SPI, etc.).
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For the latter case, the reference implementation will specify some interface
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functions to interact with the hardware (e.g. I2C, SPI etc.). Even though all
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functionality should be covered by the reference driver, you still need to
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implement those interface functions.
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Since AMiRo-LLD does not rely on specific hardware or operating system, the only
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valid way to interact with both is through periphAL. Under no circumstances you
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must use any function of your operating system and directly or indirectly access
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the hardware of your platform. For your driver, there is no knowledge about the
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world beyond periphAL! If periphAL does not provide the function you need, you
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can do the following: 1) Think again if you really need that funcionality or
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whether it can be replicated by existing functions. 2) File a feature request
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to extend periphAL. 3) Write a custom patch that modifies periphAL to meet your
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requirements.
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Summing up, you have to
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1) Get and read the datasheet of the device (A) or
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   acquire a copy of the reference implementation (B).
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2) Case A: define constants, register map and access functions in a header file.
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   Case B: identify the interface functions of the reference implementation.
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3) Implement the missing functions using periphAL.
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================================================================================
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