Computer Science Technical Reports
Permanent URI for this collectionhttps://hdl.handle.net/2104/4824
Browse
Browsing Computer Science Technical Reports by Subject "Compiled Simulation"
Now showing 1 - 2 of 2
- Results Per Page
- Sort Options
Item The Inversion-Algorithm Software(2009-11-13T15:41:49Z) Maurer, Peter M.The software in this package implements four versions of the Inversion algorithm. Four executable files are produced.These executables are used in much the same way as the FHDL package, but only AND, OR, NAND, NOR, NOT, BUFF, XOR, and XNOR gates are supported. The four executables are Inversion.exe/Inversion RemoveNots.exe/RemoveNot, CollapseHomo.exe/CollapseHom, and CollapseHetero.exe/CollapseHet. The software will compile under Linux/gcc and under Visual C++. The above list gives the executable names for the two systems. See “The Inversion Algorithm …” in this archive for more information. This software is intended primarily for performance studies.Item Two New Techniques for Unit-Delay Compiled Simulation(2009-11-05T16:43:41Z) Maurer, Peter M.The PC-set method and the parallel technique are two methods for generating compiled unit-delay simulations of acyclic circuits. The PC-set method analyzes the network, determines the set of potential change times for each net, and generates gate simulations for each potential change. The parallel technique, which is based on the concept of bit-parallel simulation, is faster and generates less code than the PC-set method, but is not amenable to data-parallel simulation of multiple input vectors. Both techniques are based on the well known levelization algorithm used to generate zero-delay Levelized Compiled Code simulations. Although the parallel technique provides for efficient simulations with a reasonable amount of generated code, there are several opportunities for optimization. The two optimization schemes presented here are called bit-field trimming and shift-elimination. Two different methods of shift elimination are presented, one which is based on breaking cycles in an undirected graph, and one which is based on tracing paths through a network. Performance results are presented for both simulation techniques, and for all optimizations. Comparisons with interpreted event-driven simulation using the ISCAS 85 benchmarks show a factor of 4 improvement for the PC-set method and a factor of ten improvement for the parallel technique. Similar studies for the optimization schemes show an average performance improvement of 47% over the unoptimized simulations.