Free operating engineers credit union software for linux

J Operating System is primarily intended for programmers.
Target Users:
- Hobbiests--You used to buy computers to do programming. They didnt do much else. Windows doesnt even come with a compiler, which is ironic since Bill Gates wrote BASIC. The "J" operating system is primarily intended for programmers. Ive attempted to lower the bar, so amateurs can contribute. I hope to recreate the dynamic environment that used to exist when the Commodore 64 was around and everyone was creating odd-ball software.
- Researchers--Im sure many lab researchers still use DOS because they have to interact with hardware, which is difficult with Windows.
Main features:
- No security! You can access all ports, memory and disk blocks to your hearts content. When youre working with your own computer, security just gets in the way and makes things slow--I hate anti-virus and anti-spyware because they just slow things down. When you know you dont have a risk, have no secrets and do regular back-ups, who needs security?
- Uniformity
- There is no virtual memory and everyone is on the same address-map. You can easily communicate between tasks, passing addresses. Addresses start at a base of zero and, essentually, segment registers are not used.
- There is basically one language to learn called "C+" which is a little more than "C", but less than "C++". You dont need to learn a scripting langauge because everything uses this syntax.
- There is an extension of ASCII called "J" rich text which allows colors, links, graphics and various widgets in your documents. This format is used in source code, documents, help, menus, etc.
- Support for compressed, encrypted and contiguous files.
- FAT32, FAT12 and ISO9660 filesystems.
- Blazing-fast compiler which can recompile everything in 5 seconds. It doesnt optimize.
- All source code is included and its still around a Meg.
Hardware:
- PS/2 mouse and keyboard
- VGA graphics
- Some hard drives. Must be on the primary or secondary IDE controller and support LBA28. Drives of 120Gig are the limit.
- Some CD-ROM/DVD drives, including burning.
- Some floppies. Just 1.44Meg and not all types.
- No USB support yet
- No network support yet
- ASCII printers on the parallel port are supported.

Inferno is a compact operating system designed for building distributed and networked systems on a wide variety of devices and platforms.
Inferno was originally developed at Bell Labs (the research division of Lucent Technologies).
Inferno Operating System is a well-designed, economical operating system particularly suitable for use in networked devices such as advanced telephones, hand-held devices, TV set-top boxes, and many other embedded applications.
Inferno can run in native mode on an embedded system or in emulation mode under many different operating systems. Inferno has many features in common with Plan 9.
Cross-Platform Portability
Inferno can run as a user application on top of an existing operating system or as a stand alone operating system. Most of the popular operating systems and processor architectures are supported:
Host Operating Systems:
- Windows NT/2000/XP
- Irix
- Linux
- MacOS X
- FreeBSD
- Solaris
- Plan 9
Supported Architectures:
- Intel x86 (386 & higher)
- Intel XScale
- IBM PowerPC
- ARM StrongARM (ARM & Thumb)
- Sun SPARC
Inferno also runs as a plug-in under Internet Explorer version 4 and higher. Each Inferno system presents an identical environment to the applications, irrespective of the underlying host OS or architecture, allowing the developer to work with a truly homogeneous environment across multiple different platforms.
Portable Applications
Inferno applications are written in Limbo, a modern, safe, modular, concurrent programming language with C-like syntax. It is more powerful than C but considerably easier to understand and debug than C++ or Java. Limbo code is compiled into architecture independent byte code which is then interpreted (or compiled on the fly) on the target processor. This means that any Inferno application will run identically on all Inferno platforms.
Transparent Resources
Inferno offers complete transparency of resources and data using a simple but powerful namespace system. By representing resources as files and having one standard communication protocol, resources such as data stores, services and external devices can easily be shared between Inferno systems. A resource interface may be imported to the local system and used by the applications without them knowing, or needing to know, whether it is local or remote.
Security
High level security is an important part of the Inferno system. By using one standard protocol for all network communication, security can be focused on one point and provided at a system level. Inferno offers full support for authenticated, encrypted connections using a certificate based user identification scheme and variety of algorithms including:
- IDEA, 56 bit DES, 40, 128 and 256 bit RC4 encryption algorithms
- MD4, MD5 and SHA secure hash algorithms
A Complete Solution
Inferno is not only an operating system, it is also a complete development environment, providing all the tools necessary for creating, testing and debugging the applications that run within it.
- Acme IDE: includes editor, shell, advanced pattern matching tools & more
- Fast Compiler: with full syntax and compile time type checking
- Graphical Debugger: with full stack trace for currently executing threads
- Powerful Shell: with sophisticated scripting capabilities
- UNIX like commands: including bind, grep, gzip, mount, ps, tar, yacc...
Enhancements:
- New licence terms (a `dual licence scheme allowing use as Free Software)
- Styx revision based on 9P2000, and consequent changes to Sys
- Authentication changes
- Improved colour graphics support, including compositing
- Scalable fonts using Freetype
- Revamped Tk implementation
- Window management moved out of Tk to a separate window manager in Limbo
- Limbo: exception handling and fixed-point
- Limbo: other possible changes
- Dis VM changes
- More commands and library modules
- Better network service configuration
- /net/dns served by host and native DNS resolver
- Hosted kernels configured from a parts list as for native kernels
- Signed modules
- Internet Explorer plug-in revised and in source form
- Expanded documentation

PAPI aims to provide the tool designer and application engineer with a consistent interface and methodology for use of the performance counter hardware found in most major microprocessors.
PAPI enables software engineers to see, in near real time, the relation between software performance and processor events.
The Performance API (PAPI) project specifies a standard application programming interface (API) for accessing hardware performance counters available on most modern microprocessors.
These counters exist as a small set of registers that count Events, occurrences of specific signals related to the processors function. Monitoring these events facilitates correlation between the structure of source/object code and the efficiency of the mapping of that code to the underlying architecture.
This correlation has a variety of uses in performance analysis including hand tuning, compiler optimization, debugging, benchmarking, monitoring and performance modeling. In addition, it is hoped that this information will prove useful in the development of new compilation technology as well as in steering architectural development towards alleviating commonly occurring bottlenecks in high performance computing.
PAPI provides two interfaces to the underlying counter hardware; a simple, high level interface for the acquisition of simple measurements and a fully programmable, low level interface directed towards users with more sophisticated needs.
The low level PAPI interface deals with hardware events in groups called EventSets. EventSets reflect how the counters are most frequently used, such as taking simultaneous measurements of different hardware events and relating them to one another.
For example, relating cycles to memory references or flops to level 1 cache misses can indicate poor locality and memory management. In addition, EventSets allow a highly efficient implementation which translates to more detailed and accurate measurements.
EventSets are fully programmable and have features such as guaranteed thread safety, writing of counter values, multiplexing and notification on threshold crossing, as well as processor specific features. The high level interface simply provides the ability to start, stop and read specific events, one at a time.
PAPI provides portability across different platforms. It uses the same routines with similar argument lists to control and access the counters for every architecture. As part of PAPI, we have predefined a set of events that we feel represents the lowest common denominator of every good counter implementation.
Our intent is that the same source code will count similar and possibly comparable events when run on different platforms. If the programmer chooses to use this set of standardized events, then the source code need not be changed and only a fresh compilation and link is necessary. However, should the developer wish to access machine specific events, the low level API provides access to all available events and counting modes.
If an event or feature does not exist on the current platform, PAPI returns an appropriate error code. This significantly reduces the porting effort of code using PAPI because the semantics of each call to PAPI remains the same, just the argument lists need updating. In addition to the standard set, each PAPI implementation supports all native events through the ability to directly accept platform specific counter numbers. Definitions for most, if not all of these, are included as conditional macros in the header file. In this way, PAPI avoids having inefficient code to translate all events for all platforms into a uniform representation and back again.
This translation is only done for the relatively few events defined in the standardized set. Some processors like those in the POWER series have counter groups. They enable access to specific groups of counters, instead of individual events. This presents a serious portability problem, thus PAPI abstracts hardware counters from their groups with a packed naming scheme. Each counter control value or event is made up of the counter group number and the number of the specific counter in that group.
PAPI can be divided into two layers of software. The upper layer consists of the API and machine independent support functions. The lower layer defines and exports a machine independent interface to machine dependent functions and data structures. These functions access the substrate, which may consist of the operating system, a kernel extension or assembly functions to directly access the processors registers.
PAPI tries to use the most efficient and flexible of the three, depending on what is available. Naturally, the functionality of the upper layers heavily depends on that provided by the substrate. In cases where the substrates do not provide highly desirable features, PAPI attempts to emulate them as described below.
PAPI makes sure the underlying operating system or library guards against overflow of counter values.
Each counter can potentially be incremented multiple times in a single clock cycle. This combined with increasing clock speeds and the small precision of some of the physical counters means that overflow is likely to occur.
One of the more advanced features of PAPI is to provide a portable implementation of asynchronous notification when counters exceed a user specified value.
This functionality provides the basis for PAPIs SVR4 compatible profiling calls, that generate an accurate histogram of performance interrupts based on hardware metrics, not on time. Such functionality provides the basis for all line level performance analysis software, from the antiquated days of AT&Ts prof to SGIs SpeedShop. Thus for any architecture with even the most rudimentary access to hardware performance counters, PAPI provides the foundation for a truly portable, source level, performance analysis tool based on real processor statistics.
Enhancements:
- The API was extended to decouple abstraction layers from hardware support and to provide initial support for different types of performance counters.

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.

GLIPS Graffiti editor is a cross-platform SVG graphics editor based on Batik and developed by ITRIS.
Main features:
- Shape tools : rectangles, circles, ellipses, lines, polygons, polylines ;
- Path tools : Bezier curves, conversion to a path, union, subtraction, intersection ;
- Group editing ;
- Basic text support ;
- Images import ;
- Transformations : translate, resize, rotate, skew ;
- Property manager ;
- Resource manager : gradient, patterns, markers ;
- Drag and drop support for colors and resources ;
- Export to png, jpg and tiff formats ;
- Print ;
- DOM viewer ;
- Memory monitor.
Requierments:
- Java VM 1.4.2 or higher.
The GLIPS Graffiti editor is a part of the GLIPS Project that aims to be a PLC cross-platform development environment created and maintained by ITRIS.
Enhancements:
- Many improvements and SCADA features were added.
- Two applications can be found in the distribution: the GLIPS Graffiti application with SCADA support, and one without SCADA support.
- Values of external variables updated through sockets, for example, can modify SVG drawings dynamically.