Components 4 Java is a development tool for Java. It provides a framework to organize and separate different parts of code, and fills the gap between the class level and the library level as provided by the Java SE architecture. Additionally, you can organize your classes in well-separated and loosely coupled components. Those can be stuck together graphically into larger compositions. Finally, components and compositions will be distributed among Java archives as specified in assemblies.
Embedded GLIBC (EGLIBC) is a variant of the GNU C Library (GLIBC) which is designed to work well on embedded systems. It strives to be source- and binary-compatible with GLIBC. EGLIBC's goals include a reduced footprint, configurable components, and better support for cross-compilation and cross-testing.
The Smart Card Detective (SCD) is a general framework for research on smart cards. It allows you to monitor any smart card application (including Chip and PIN / EMV transactions) and create your custom applications. The software is completely open source, and the hardware can be bought from Smart Architects. The device has a smart card interface as well as a terminal/reader interface, allowing the SCD to act as a passive/active monitor between a card and a reader or emulate a card or a terminal. Using the Python command line interface, you can interact with the SCD using a PC. This allows more flexible operation, although the SCD also features many stand-alone applications and a battery so that you can also use it without a PC.
pichart is a GUI for pigrammar, an assembler and programmer for picloader-programmed devices. pichart offers a user-friendly interface, making programming PIC chips easy. It looks like a flow chart designer and permits operations like reading from the device's serial port, writing on it, setting ports' value, and setting timers. It also permits programming directly during execution.
pmbw is a set of assembler routines to measure the parallel memory (cache and RAM) bandwidth of modern multi-core machines. Memory bandwidth is one of the key performance factors of any computer system. Today, measuring the memory performance often gives a more realistic view of the overall speed of a machine than pure arithmetic or floating-point benchmarks. pmbw contains a set of very basic functions which are all hand-coded in assembler to avoid any compiler optimizations. These basic functions are modeled after the basic inner loops found in any data processing, sequential scanning and pure random access. Any application will have a memory access pattern which is somewhere between these two extremes. The current version of pmbw supports benchmarking 16-, 32-, 64-, 128-, or 256-bit memory transfers on x86_32-bit, x86_64-bit, and ARMv6 systems.