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Logik is an open source FPGA toolchain that fully automates converting RTL to bits, including synthesis, placement, routing, bitstream generation, and analysis. Users enter design sources, constraints, and compile options through a simple SiliconCompiler Python API. Once setup is complete, automated compilation can be initiated with a single line run command.
Logik supports most of the features you would expect in a commercial proprietary FPGA tool chain.
Feature
Status
Design languages
Verilog, SystemVerilog, VHDL
ALU synthesis
Supported
RAM synthesis
Supported
Timing constraints (SDC)
Supported
Pin Constraints (PCF)
Supported
Bitstream generation
Supported
IP management
Supported
Remote compilation
Supported
Multi-clock designs
In progress
FPGA devices
ZA
The Logik project is available through PyPi and can be installed using pip. If you want to run locally on your machine, you will need to install all of the pre-requisites or launch the Logik Docker image.
python -m pip install –upgrade logik
The following example illustrate some essential Logik features. For complete documentation of all options available, see the SiliconCompiler project.
from siliconcompiler import Chip
from logik.targets import logik_target
def hello_adder():
# Create compilation object
chip=Chip(‘adder’)
# Specify design sources
chip.input(‘adder.v’)
# Specify pin constraints
chip.input(‘adder.pcf’)
# Compiler options
chip.set(‘option’, ‘quiet’, True)
chip.set(‘option’, ‘remote’, True)
# Select target fpga
chip.set(‘fpga’, ‘partname’, ‘logik_demo’)
# Load target settings
chip.load_target(logik_target)
# Run compiler
chip.run()
# Display compiler results
chip.summary()
if __name__==”__main__”:
hello_adder()
This code can be run with ./adder.py -remote in the examples/adder directory, resulting in an FPGA bitstream at build/adder/job0/convert_bitstream/0/outputs/adder.bin.
To test out the generated bitstream, you can upload it to an emulated FPGA device running in the Zero ASIC Digital Twin Platform.
UMI “Hello World”
UMI FIR Filter
EBRICK demo
Logik Documentation
SiliconCompiler Documentation
Logik is available as wheel packages on PyPI for macOS, Windows and Linux platforms. For a Python 3.8-3.12 environment, just use pip to install.
python -m pip install –upgrade logik
Running natively on your local machine will require installing a number of prerequisites:
Silicon Compiler: Hardware compiler framework
Yosys: Logic synthesis
VPR: FPGA place and route
GHDL: VHDL parser
Surelog: SystemVerilog parser
FASM: FPGA assembly parser and generator
Automated Ubuntu based install scripts are included for convenience within the SiliconCompiler project. Detailed instructions for installing all tools can be found in the SiliconCompiler Installation Guide.
A Docker image is provided for users who wish to avoid the installation of the pre-requisite tools. The following command starts a new container from that image and maps the local directory sc_work to the path /sc_work in the container.
docker run -it -v “${PWD}/sc_work:/sc_work” ghcr.io/siliconcompiler/sc_runner:latest
MIT
We use GitHub Issues for tracking requests and bugs.
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