f4pga/docs/refs.bib

233 lines
7.7 KiB
BibTeX

@Online{verilator,
author = {Snyder, Wilson and {contributors}},
title = {{Verilator, FOSS tool which converts Verilog to a cycle-accurate behavioral model in C++ or SystemC}},
url = {https://www.veripool.org/verilator/},
year = {2003},
}
@InProceedings{wolf13,
author = {Wolf, Clifford and Glaser, Johann},
title = {{A Free Verilog Synthesis Suite}},
booktitle = {Proceedings of Austrochip 2013},
year = {2013},
url = {https://yosyshq.net/yosys/}
}
@Online{gh:yosys,
author = {Wolf, Claire and {contributors}},
title = {{Yosys Open SYnthesis Suite}},
url = {https://github.com/YosysHQ/yosys},
}
@Online{gh:symbiyosys,
author = {Wolf, Claire and {contributors}},
title = {{SymbiYosys: front-end for Yosys-based formal verification flows}},
url = {https://github.com/YosysHQ/SymbiYosys},
}
@Online{gh:nextpnr,
author = {gatecat and {contributors}},
title = {{nextpnr: portable FPGA place and route tool}},
url = {https://github.com/YosysHQ/nextpnr},
}
@Online{gh:gtkwave,
author = {Bybell, Tony and {contributors}},
title = {{GTKWave: a is a fully featured GTK+ based wave viewer for Unix, Win32, and Mac OSX}},
url = {https://github.com/gtkwave/gtkwave},
year = {1998},
}
@Online{gh:ghdl,
author = {Gingold, Tristan and {contributors}},
title = {{GHDL: open-source analyzer, compiler, simulator and (experimental) synthesizer for VHDL}},
url = {https://github.com/ghdl/ghdl},
month = {Sep},
year = {2003},
}
@Online{gh:ghdl-yosys-plugin,
author = {Gingold, Tristan and {contributors}},
title = {{ghdl-yosys-plugin: VHDL synthesis (based on ghdl and yosys)}},
url = {https://github.com/ghdl/ghdl-yosys-plugin},
year = {2017},
}
@Online{sphinx,
author = {Brandl, Georg and KOMIYA, Takeshi and {contributors}},
year = {2007},
title = {{Sphinx, Python Documentation Generator}},
url = {https://www.sphinx-doc.org},
}
@Online{verible,
author = {Fang, David and Zeller, Henner and {contributors}},
year = {2019},
title = {{Verible, a suite of SystemVerilog developer tools, including a parser, style-linter, and formatter}},
url = {https://chipsalliance.github.io/verible/},
}
@Online{surelog,
author = {Dargelas, Alain and Zeller, Henner and {contributors}},
year = {2019},
title = {{Surelog, SystemVerilog 2017 Pre-processor, Parser, Elaborator, UHDM Compiler}},
url = {https://github.com/alainmarcel/Surelog/},
}
@inproceedings{dargelas20,
title = {{Universal Hardware Data Model}},
author = {Dargelas, Alain and Zeller, Henner},
booktitle = {Workshop on Open-Source EDA Technology 2020 (WOSET)},
year = {2020},
month = {10},
url = {https://woset-workshop.github.io/PDFs/2020/a10.pdf}
}
@Online{iverilog,
author={Williams, Stephen and {contributors}},
title={{Icarus Verilog, a Verilog simulation and synthesis tool}},
url={http://iverilog.icarus.com/}
}
@InProceedings{ansell20,
author = {Ansell, Tim and Saligane, Mehdi},
booktitle = {2020 IEEE/ACM International Conference On Computer Aided Design (ICCAD)},
title = {{The Missing Pieces of Open Design Enablement: A Recent History of Google Efforts : Invited Paper}},
year = {2020},
pages = {1-8},
url = {https://dl.acm.org/doi/abs/10.1145/3400302.3415736}
}
@Online{gcc,
author = {Stallman, Richard and {contributors}},
year = {1987},
title = {{GCC, the GNU Compiler Collection}},
url = {http://gcc.gnu.org/},
month = {May},
}
@Online{gdb,
author = {Stallman, Richard and {GNU Project}},
year = {1986},
title = {{GDB: The GNU Project Debugger}},
url = {https://www.gnu.org/software/gdb/},
}
@Online{llvm,
author = {
Adve, Vikram and
Lattner, Chris and
{LLVM Developer Group}
},
title = {{LLVM Project, a collection of modular and reusable compiler and toolchain technologies}},
url = {https://www.llvm.org/},
year = {2003},
}
@Online{gh:wavedrom,
author = {Chapyzhenka, Aliaksei and {contributors}},
title = {{Wavedrom, digital timing diagram rendering engine}},
url = {https://github.com/wavedrom/wavedrom},
year = {2014},
}
@Online{symbolator,
author = {Thibedeau, Kevin},
title = {{Symbolator, a component diagramming tool for VHDL and Verilog}},
url = {https://kevinpt.github.io/symbolator},
}
@InProceedings{rovinski20,
author={
Rovinski, Austin and
Ajayi, Tutu and
Kim, Minsoo and
Wang, Guanru and
Saligane, Mehdi
},
booktitle={2020 IEEE/ACM International Conference On Computer Aided Design (ICCAD)},
title={{Bridging Academic Open-Source EDA to Real-World Usability}},
year={2020},
pages={1-7},
url={https://dl.acm.org/doi/10.1145/3400302.3415734}
}
@Article{murray20micro,
author={
Murray, Kevin E. and
Elgammal, Mohamed A. and
Betz, Vaughn and
Ansell, Tim and
Rothman, Keith and
Comodi, Alessandro
},
journal={IEEE Micro},
title={{SymbiFlow and VPR: An Open-Source Design Flow for Commercial and Novel FPGAs}},
year={2020},
volume={40},
number={4},
pages={49-57},
doi={10.1109/MM.2020.2998435}
}
@Article{murray20acm,
author = {
Murray, Kevin E. and
Petelin, Oleg and
Zhong, Sheng and
Wang, Jia Min and
Eldafrawy, Mohamed and
Legault, Jean-Philippe and
Sha, Eugene and
Graham, Aaron G. and
Wu, Jean and
Walker, Matthew J. P. and
Zeng, Hanqing and
Patros, Panagiotis and
Luu, Jason and
Kent, Kenneth B. and
Betz, Vaughn
},
title = {{VTR 8: High-Performance CAD and Customizable FPGA Architecture Modelling}},
year = {2020},
issue_date = {June 2020},
publisher = {Association for Computing Machinery},
address = {New York, NY, USA},
volume = {13},
number = {2},
issn = {1936-7406},
url = {https://doi.org/10.1145/3388617},
doi = {10.1145/3388617},
abstract = {Developing Field-programmable Gate Array (FPGA) architectures is challenging due to
the competing requirements of various application domains and changing manufacturing
process technology. This is compounded by the difficulty of fairly evaluating FPGA
architectural choices, which requires sophisticated high-quality Computer Aided Design
(CAD) tools to target each potential architecture. This article describes version
8.0 of the open source Verilog to Routing (VTR) project, which provides such a design
flow. VTR 8 expands the scope of FPGA architectures that can be modelled, allowing
VTR to target and model many details of both commercial and proposed FPGA architectures.
The VTR design flow also serves as a baseline for evaluating new CAD algorithms. It
is therefore important, for both CAD algorithm comparisons and the validity of architectural
conclusions, that VTR produce high-quality circuit implementations. VTR 8 significantly
improves optimization quality (reductions of 15% minimum routable channel width, 41%
wirelength, and 12% critical path delay), run-time (5.3\texttimes{} faster) and memory footprint
(3.3\texttimes{} lower). Finally, we demonstrate VTR is run-time and memory footprint efficient,
while producing circuit implementations of reasonable quality compared to highly-tuned
architecture-specific industrial tools—showing that architecture generality, good
implementation quality, and run-time efficiency are not mutually exclusive goals.},
journal = {ACM Trans. Reconfigurable Technol. Syst.},
month = may,
articleno = {9},
numpages = {55},
keywords = {electronic design automation (EDA), Computer aided design (CAD), versatile place and route (VPR), verilog to routing (VTR), routing, placement, packing, field programmable gate array (FPGA)}
}
@InProceedings{kahng20,
author={Kahng, Andrew B.},
booktitle={2020 IFIP/IEEE 28th International Conference on Very Large Scale Integration (VLSI-SOC)},
title={{Open-Source EDA: If We Build It, Who Will Come?}},
year={2020},
pages={1-6},
doi={10.1109/VLSI-SOC46417.2020.9344073}
}