Free amiga hardware software for linux

Unix Amiga Delitracker Emulator (UADE) plays most Amiga music file formats by simulating Amiga hardware and software.
Unix Amiga Delitracker Emulator plays over 180 Amiga music file formats and has three frontends for playing: a command line tool, an XMMS plugin, and a Beep Media Player frontend.
Enhancements:
- An improved version of the Special FX replayer was added.
- A new Special FX ST replayer was added.
- Bugs in song length database handling were fixed.
- Audacious 1.3 is supported.
- 15 instrument soundtracker module detection is supported.

UAE is a mostly complete software emulation of the hardware of the Commodore Amiga 500/1000/2000.
A Commodore Amiga, for those who dont know, is a 16/32 bit computer system based on the Motorola 680x0 CPU and a few specially designed custom chips that provide very good graphics and sound capabilities. Its first incarnation, the A1000, appeared in 1985, followed by the highly successful A500 and A2000 models.
UAE is written for Unixish systems; it is developed on a Linux machine but it should compile and run on any half-recent Unix-like operating system. It has also been ported to a wide variety of machines and operating systems, including DOS, Windows 95/NT, MacOS, RiscOS, BeOS and NextStep.
UAE is free software: you are welcome to distribute copies of it and/or modify it, under certain conditions. There is no warranty of any kind for UAE. For more details concerning these issues, please read the GNU General Public License, which describes the terms under which UAE is distributed.
Main features:
- A 68000/010/020/040 CPU, optionally a 68881 FPU
- OCS, ECS and AGA Graphics Chipset (including sprite-playfield collisions)
- Up to 2MB Chip RAM and up to 8MB Fast RAM, or 8MB Chip RAM without Fast RAM
- Up to 64MB Zorro III Fast RAM, independent of Chip RAM setting (68020+ only)
- Up to 1MB Slow RAM, for extended compatibility with problem software
- Up to 8MB of graphics card memory, usable by software that supports Picasso 96 compatible graphics cards
- 4 x 3.5" floppy disk drives (DF0:, DF1:, DF2: and DF3:). Its not possible to read Amiga disks, so these are emulated with disk files.
- A hard-disk: either a harddisk image file or part of the native filesystem
- Joystick support (with option of mapping joystick to numeric keypad)
- Mouse support
- Ability to run in various screen modes (for better display quality or better speed)
- Full stereo sound support, consisting of 4 x 8bit channels
- Simple parallel and serial port support. Note: the parallel port is not really implemented. Though its sufficient for printing.
- state-saving. you can save the state of your emulated Amiga and continue later on.
- some other things which dont work well enough to mention them here...

Amiga Research Operating System (AROS) is a portable and free desktop operating system aiming at being compatible with AmigaOS 3.1, while improving on it in many areas. The source code is available under an open source license, which allows anyone to freely improve upon it.

Goals

The goals of the AROS project is it to create an OS which:

1. Is as compatible as possible with AmigaOS 3.1.
2. Can be ported to different kinds of hardware architectures and processors, such as x86, PowerPC, Alpha, Sparc, HPPA and other.
3. Should be binary compatible on Amiga and source compatible on any other hardware.
4. Can run as a standalone version which boots directly from hard disk and as an emulation which opens a window on an existing OS to develop software and run Amiga and native applications at the same time.
5. Improves upon the functionality of AmigaOS.

To reach this goal, we use a number of techniques. First of all, we make heavy use of the Internet. You can participate in our project even if you can write only one single OS function. The most current version of the source is accessible 24 hours per day and patches can be merged into it at any time. A small database with open tasks makes sure work is not duplicated.

History

Some time back in the year 1993, the situation for the Amiga looked somewhat worse than usual and some Amiga fans got together and discussed what should be done to increase the acceptance of our beloved machine. Immediately the main reason for the missing success of the Amiga became clear: it was propagation, or rather the lack thereof. The Amiga should get a more widespread basis to make it more attractive for everyone to use and to develop for. So plans were made to reach this goal. One of the plans was to fix the bugs of the AmigaOS, another was to make it an modern operating system. The AOS project was born.

But exactly what was a bug? And how should the bugs be fixed? What are the features a so-called modern OS must have? And how should they be implemented into the AmigaOS?

Two years later, people were still arguing about this and not even one line of code had been written (or at least no one had ever seen that code). Discussions were still of the pattern where someone stated that "we must have ..." and someone answered "read the old mails" or "this is impossible to do, because ..." which was shortly followed by "youre wrong because ..." and so on.

In the winter of 1995, Aaron Digulla got fed up with this situation and posted an RFC (request for comments) to the AOS mailing list in which I asked what the minimal common ground might be. Several options were given and the conclusion was that almost everyone would like to see an open OS which is compatible to AmigaOS 3.1 (kickstart 40.68) on which further discussions could be based upon to see what is possible and what is not.

So the work began and AROS was born.

Hardware::iButton::Device is a Perl object to represent iButtons.

SYNOPSIS

use Hardware::iButton::Connection;
$c = new Hardware::iButton::Connection "/dev/ttyS0";
@b = $c->scan();
foreach $b (@b) {
print "id: ", $b->id(), ", reg0: ",$b->readreg(0),"n";
}

This module talks to iButtons via the "active" serial interface (anything using the DS2480, including the DS1411k and the DS 9097U). It builds up a list of devices available, lets you read and write their registers, etc.

The connection object is an Hardware::iButton::Connection. The main user-visible purpose of it is to provide a list of Hardware::iButton::Device objects. These can be subclassed once their family codes are known to provide specialized methods unique to the capabilities of that device. Those devices will then be Hardware::iButton::Device::DS1920, etc.

Hardware Monitor is a multi-purpose, beautiful system-monitoring applet.
The Hardware Monitor applet is an applet for the GNOME panel which tries to be a beautiful all-around solution to system monitoring. It also strives to be user-friendly and generally nice and sensible, integrating pleasantly with the rest of your GNOME desktop.
Includes different viewers, including a flame effect, allows multiple devices to be monitored in the samme applet, uses smooth updating, polished graphs, clean HIG-compliant interface.
Main features:
- A graphical view where each monitor is represented by a (time, measurement) colored curve
- A bar-plot view with a horizontal bar per monitor
- A column view with a column (time, measurement) diagram for each monitor
- A textual view which simply lists the monitors and the currently measured values
- A flame view which produces spiffy flames, the sizes of which are determined by the values of the monitored device
And the applet supports monitoring the following hardware characteristics:
- CPU usage (all CPUs, or one at the time) - niced background processes such as SETI@home are automatically ignored
- Memory usage - cache and buffers are automatically ignored
- Swap usage
- Load average
- Disk usage (or disk space free)
- Network throughput (Ethernet, wireless, modem, serial link), either incoming or outgoing or both
- Temperatures from internal sensors (e.g. system board and CPU temperatures)
- Fan speeds from internal sensors

Hardware::Simulator is a Perl extension for Perl Hardware Descriptor Language.

SYNOPSIS

use Hardware::Simulator;

# NewSignal( perl_variable [, initial_value]);
# create a signal called $in_clk, give it an initial value of 1
NewSignal(my $in_clk,1);

# Repeater ( time_units , code_ref)
# every time_units, call the code reference, starting at the current time
Repeater ( 5, sub{if ( $in_clk==0) { $in_clk=1;} else { $in_clk=0;}});

# Responder ( [signal_name ... signal_name], code_ref );
# respond to any changes to signals by calling code reference.
# any time out_clk changes, print value of clock and simulation time.
Responder ( $out_clk, sub
{
my $time = SimTime();
print "out_clk = $out_clk. time=$timen";
});

# start processing of events and event scheduling.
EventLoop();

Hardware::Simulator ==> a Perl Hardware Descriptor Language

Hardware::Simulator is a lightweight version of VHDL or Verilog HDL. All of these languages were developed as means to describe hardware.

Hardware::Simulator was created as a means to quickly prototype a basic hardware design and simulate it. VHDL and Verilog are both restrictive in their own ways. Hardware::Simulator was created to quickly put something together as a "proof of concept", to show that a design concept would work or not. and then the design could be translated to VHDL or Verilog.

The problem that started all of this was designing a fifo for a video scaling asic. The chip used a buffer to store incoming video data. The asic read the buffer to generate the outgoing video image. We estimated how large we thought the buffer needed to be, but we wanted to confirm that our numbers were right by running simulations.

The problem was we needed to run hundreds of different simulations, given the permutations of input image formats, output image formats, and input/output clock frequencies. We also had text files containing valid formats and frequencies. A text file as input called for perl to manipulate, split, format, and extract the data properly.

This data then had to be translated onto the a HDL simulation. The problem was that there was no easy way to write a perl script that would simulate hardware, so the only solution was to have perl drive a Verilog simulator and pass all these parameters via command line parameters. so then verilog files had to be created, and the simulator had to be driven, and the end result was a lot of work to simulate a simple fifo.

Time contraints did not allow me to develop a HDL package for perl to solve the original problem, but I took it on in my spare time. and eventually Hardware::Simulator was born.

lupengo project is a classic arcade game.

lupengo is the most famous arcade game involving penguins, now without penguins, for one or two players (team).

An Amiga version is also available.