laixz d4e85d9c98 | ||
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docs | ||
example | ||
injector | ||
myTests | ||
pyhcl | ||
.DS_Store | ||
.coveragerc | ||
.gitignore | ||
LICENSE | ||
README.md | ||
firrtl.jar | ||
main.py |
README.md
PyHCL
PyHCL is a hardware construct language like Chisel but more lightweight and more relaxed to use. As a novel hardware construction framework embedded in Python, PyHCL supports several useful features include object-oriented, functional programming, and dynamically typed objects.
The goal of PyHCL is providing a complete design and verification tool flow for heterogeneous computing systems flexibly using the same design methodology.
PyHCL is powered by FIRRTL, an intermediate representation for digital circuit design.
PyHCL-generated circuits can be compiled to the widely-used HDL Verilog.
Attention: The back end of the compilation is highly experimental.
Getting Started
Writing A Full Adder
PyHCL defines modules using only simple Python syntax that looks like this:
from pyhcl import *
class FullAdder(Module):
io = IO(
a=Input(Bool),
b=Input(Bool),
cin=Input(Bool),
sum=Output(Bool),
cout=Output(Bool),
)
# Generate the sum
io.sum @= io.a ^ io.b ^ io.cin
# Generate the carry
io.cout @= io.a & io.b | io.b & io.cin | io.a & io.cin
Compiling To High FIRRTL
Compiling module by calling compile_to_highform
:
Emitter.dump(Emitter.emit(FullAdder(), HighForm), "FullAdder.fir")
Will generate the following FIRRTL codes:
circuit FullAdder :
module FullAdder :
input clock : Clock
input reset : UInt<1>
output io : {flip a : UInt<1>, flip b : UInt<1>, flip cin : UInt<1>, s : UInt<1>, cout : UInt<1>}
node _T = xor(io.a, io.b)
node _T_1 = xor(_T, io.cin)
io.s <= _T_1
node _T_2 = and(io.a, io.b)
node _T_3 = and(io.a, io.cin)
node _T_4 = or(_T_2, _T_3)
node _T_5 = and(io.b, io.cin)
node _T_6 = or(_T_4, _T_5)
io.cout <= _T_6
Compiling To Lowered FIRRTL
Compiling module by calling compile_to_lowform
:
Emitter.dump(Emitter.emit(FullAdder(), LowForm), "FullAdder.lo.fir")
Will generate the following FIRRTL codes:
circuit FullAdder :
module FullAdder :
input clock : Clock
input reset : UInt<1>
input io_a : UInt<1>
input io_b : UInt<1>
input io_cin : UInt<1>
output io_s : UInt<1>
output io_cout : UInt<1>
node _T = xor(io_a, io_b)
node _T_1 = xor(_T, io_cin)
io_s <= _T_1
node _T_2 = and(io_a, io_b)
node _T_3 = and(io_a, io_cin)
node _T_4 = or(_T_2, _T_3)
node _T_5 = and(io_b, io_cin)
node _T_6 = or(_T_4, _T_5)
io_cout <= _T_6
Compiling To Verilog
Compiling module by calling compile_to_verilog
:
Emitter.dump(Emitter.emit(FullAdder(), Verilog), "FullAdder.v")
Then FullAdder.v
will be generated:
module FullAdder(
input clock,
input reset,
input io_a,
input io_b,
input io_cin,
output io_s,
output io_cout
);
assign io_s = io_a ^ io_b ^ io_cin;
assign io_cout = io_a & io_b | io_a & io_cin | io_b & io_cin;
endmodule
Features
- Supports multiple data types:
UInt
,SInt
,Vector
,Bundle
,Clock
,Memory
, and casual combination between them. - Supports object-oriented inheritance, can compose modules by writing fewer codes.
- Supports a bunch of convenient operations, such as the addition of
UInt
s,SInt
s,Vector
s andBundle
s. - Supports the parameterization of variables, such as bit width, with the syntax facilities of the host language Python.
TODO
- Supports more operations
- PyHCL's verification facility