AMiRo-LLD is a compilation of low-level hardware drivers for the base version of
the Autonomous Mini Robot (AMiRo) [1]. It provides directional interfaces for an
operating system to access the drivers and for the drivers to access the
communication infrastructure via the operating system.
Copyright (C) 2016..2019 Thomas Schöpping et al.
(a complete list of all authors is given below)
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published by
the Free Software Foundation, either version 3 of the License, or (at
your option) any later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License
along with this program. If not, see .
This research/work was supported by the Cluster of Excellence
Cognitive Interaction Technology 'CITEC' (EXC 277) at Bielefeld
University, which is funded by the German Research Foundation (DFG).
Authors:
- Thomas Schöpping
- Marc Rothmann
References:
[1] S. Herbrechtsmeier, T. Korthals, T. Schopping and U. Rückert, "AMiRo: A
modular & customizable open-source mini robot platform," 2016 20th
International Conference on System Theory, Control and Computing (ICSTCC),
Sinaia, 2016, pp. 687-692.
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This file provides information about the purpose of this project, the file
structure and some helpful guides for development of code.
================================================================================
CONTENTS:
1 About the Project
2 File Structure
3 Developer Guides
3.1 Adding a Device
3.2 Implementing a Driver
================================================================================
1 - ABOUT THE PROJECT
=====================
AMiRo-LLD is a compilation of low-level hardware drivers, originally developed
for the Autonomous Mini Robot (AMiRo) [1]. It provides a modular design, so that
each driver can be activated individually as required. Interface functions allow
for bidirectional comunication with an operating system. On the one hand drivers
access according hardware interfaces via defined interface functions (which need
to be implemented by the operating system) and any applications (or the
operating system itself) can take advantage of the drivers by their individual
interfaces. The abstraction layer of the hardware interfaces is called
"periphAL", which is defined by this project. In order to configure which
drivers should be used in which version, the project expects an according file
"alldconf.h" to be found in the include paths.
Although this compilation was originally designed to be used in combination with
the AMiRo operating system (AMiRo-OS; cf. https://opensource.cit-ec.de/projects/amiro-os/),
it is not limited to this use case. The included drivers may be used for any
purpose and contributions of further drivers, even if the according hardware is
not present on the AMiRo platform, are highly appreciated.
2 - FILE STRUCTURE
==================
The files are structured as follows:
./
│ The project root directory contains this file, a license.html file as well as
│ a Makefile that allows to easily integrate the project. Furthermore, two
│ interface headers are provided: amiro-lld.h and periphALtypes.h. These are
│ entry points for any utilizing superproject, so it is not required (and not
│ recommended) to include each driver individually.
│
├── include/
│ For each supported hardware device, there is exactly one directory in this
│ folder. Further subfolders may contain various versions of a driver (e.g.
│ 'v1/', 'v2/', etc.). By convention the root directory of a driver is named
│ by the form
│ "/"
│ is a placeholder for the exact name of the according
│ hardware, or the product familiy, if the driver is compatible with all
│ parts.
│ The root header consequently follows the naming scheme
│ "alld_.h"
│ and header files within the version folders shall be named like
│ "alld_.h"
│
├── source/
│ Any source files are placed in this directory. Naming conventions for
│ folders and files are the same as described before for the include
│ directory, as is the file structure. There is a dedicated folder for each
│ device and further subfolders for multiple driver versions. Source files
│ should only be put in these version folders.
│
└── templates/
AMiRo-LLD requires an implementation of the defined interface and an
configuration header to be accessible in the include paths at compile
time. Template files for both can be found in this folder. It is
recommended to place according implementations of these templated not in
the AMiRo-LLD project, but the superproject which includes AMiRo-LLD.
3 - DEVELOPER GUIDES
====================
In order to keep all code within this project as homogeneous as possible, the
guides of these chapters should help developers to achieve functional and clean
results, which are portable and maintainable for future use. Whereas the textual
descriptions of the guides provide additional information about the underlying
concepts and mechanisms, a short summary is provided at the end of each chapter.
3.1 Adding a Device
--------------------
When adding new device to the project, the very first step is to create the
according folders in the include/ and source/ directories. For this guide, we
will add the fictional DEVICE1234. For this example the folders to be created
are "include/DEVICE1234/" and "source/DEVICE1234/".
The first file should be the root header: "include/DEVICE1234/alld_DEVICE1234.h"
Have a look at existing drivers and use one of those as template. This header
should introduce a new configuration to be set in the alldconf.h file and check
it using the preprocessor. Eventually, another header is included, pointing to
the selected driver version/implementation.
Such implementations are to be put in further subfolders, e.g.
"include/DEVICE1234/v1/" and "source/DEVICE1234/v1/". The header and C-source
files in those folders do not follow a strict scheme, although there are some
conventions to consider (i.e. naming conventions, cf. chapter 2).
Summing up, you have to
1) create device folders.
2) add a root header.
3) add further subfolders and implement the driver there.
3.2 Implementing a Driver
--------------------------
Implementation of a new driver usually is very straight-forward. You most
probably have a comprehensive datasheet of the device, or the manufacturer even
provides a reference driver implementation.
For the former case, you should first write a comprehensive header, containing
all information like constants, register maps, etc. and according abstract
access functions (e.g. for reading and writing registers, and convenient access
to common functionalities). Only the you implement those functions, using
periphAL to interface any hardware interfaces (e.g. I2C, SPI, etc.).
For the latter case, the reference implementation will specify some interface
functions to interact with the hardware (e.g. I2C, SPI etc.). Even though all
functionality should be covered by the reference driver, you still need to
implement those interface functions.
Since AMiRo-LLD does not rely on specific hardware or operating system, the only
valid way to interact with both is through periphAL. Under no circumstances you
must use any function of your operating system and directly or indirectly access
the hardware of your platform. For your driver, there is no knowledge about the
world beyond periphAL! If periphAL does not provide the function you need, you
can do the following: 1) Think again if you really need that funcionality or
whether it can be replicated by existing functions. 2) File a feature request
to extend periphAL. 3) Write a custom patch that modifies periphAL to meet your
requirements.
Summing up, you have to
1) Get and read the datasheet of the device (A) or
acquire a copy of the reference implementation (B).
2) Case A: define constants, register map and access functions in a header file.
Case B: identify the interface functions of the reference implementation.
3) Implement the missing functions using periphAL.
================================================================================