Skip to content

Latest commit

 

History

History
55 lines (41 loc) · 2.98 KB

README.md

File metadata and controls

55 lines (41 loc) · 2.98 KB

SPEF-Extractor

A Python library that reads LEF and DEF files, extracts the RC parasitics and generates their corresponding SPEF file.:

Dependancies:

In order to parse the lef and def files, we used trimcao's def and lef parser

Build Instructions:

To install the library run the following commands:


pip install numpy

pip install sympy

pip install matplotlib   

git clone https://github.com/Cloud-V/SPEF_EXTRACTOR/

Using the library

In order to use the project, use the terminal to run main.py using the following format.
python3 main.py <lef_file_path> <def_file_path> <wire_model which can be L or Pi> <edge_capacitance_factor which is a value between 0 and 1 where the default is 1>
For example: python3 main.py osu035.lef rle_rec.def L 1
where osu035.lef is the provided lef file and rle_rec.def is its corresponding def file. Aftwards, we extract the RC parasitics and output them in a SPEF file named rle_rec.spef (holds the same name as the def file)

Testing

  • Initially, we tested the generated SPEF manually. This was done through checking a number of nets, and comparing the parasitics in the file with the theoretical value.
  • Later on, we tested using "openSTA" that verified that the produced SPEF file is syntax error free. "openSTA" was able to successfuly read the SPEF file and produce timing reports based on the parasitics provided.
  • Additionally, we used openSTA to compare the delays for multiple designs using available spef files vs. our generated spef files.

Assumptions

During our development, we had to make some assumptions to for the sake of simplicity:

  1. It is assumed that the values that do not exist in the LEF file are considered to be 0.
  2. We represented each wire segment as a single resistance and a capacitance (In the L model)
  3. We consider the capacitance of a segment to be at the end node of the segment (In the L model)
  4. Testing was done using openSTA that verified our SPEF is syntax error free.

Limitations

  1. Testing was only done on a handful of designs and further testing might help
  2. Only Pi and L models are available to represent the resistance and capacitance of a segment (even for long wire segments)
  3. We don't handle the RC parasitics of the special nets

Name Remapping

  1. We implemented an algorithm to rename long names.
  2. All nets are renamed to decrease the size of files.
  3. Names were remapped based on the standard remapping scheme of SPEF files.

Acknowledgement:

This was initially created for the Digital Design 2 Course CSCE3304 at the American University in Cairo under the supervision of Doctor Mohamed Shalan. Its development was ongoing afterwards as a part of an undergraduate research internship at the American Univeristy in Cairo.

Authors: