Build your hardware, easily!
Go to file
Sebastien Bourdeauducq adffec35f6 utils/misc: add gcd_multiple function to compute GCD or any number of integers 2013-12-12 17:36:50 +01:00
doc fhdl.size: rename to bitcontainer 2013-12-03 22:51:52 +01:00
examples examples/sim/cordic_err: fix rms_err function name 2013-12-02 13:18:37 +01:00
mibuild mibuild/xilinx_ise: use ngdbuild_opt also for xst case 2013-12-06 12:15:22 +01:00
migen utils/misc: add gcd_multiple function to compute GCD or any number of integers 2013-12-12 17:36:50 +01:00
vpi vpi: make it work by default on Arch 2013-03-12 16:51:58 +01:00
.gitignore doc: switch to sphinx 2012-03-09 17:08:38 +01:00
LICENSE Change license to 2-clause BSD 2013-04-15 23:55:30 +02:00
README update pointers 2013-11-23 11:29:57 +01:00
setup.py setup.py: update repository address 2013-11-29 23:26:52 +01:00

README

Migen (Milkymist Generator)
  a Python toolbox for building complex digital hardware

Despite being faster than schematics entry, hardware design with Verilog and
VHDL remains tedious and inefficient for several reasons. The event-driven
model introduces issues and manual coding that are unnecessary for synchronous
circuits, which represent the lion's share of today's logic designs. Counter-
intuitive arithmetic rules result in steeper learning curves and provide a
fertile ground for subtle bugs in designs. Finally, support for procedural
generation of logic (metaprogramming) through "generate" statements is very
limited and restricts the ways code can be made generic, reused and organized.

To address those issues, we have developed the Migen FHDL library that
replaces the event-driven paradigm with the notions of combinatorial and
synchronous statements, has arithmetic rules that make integers always behave
like mathematical integers, and most importantly allows the design's logic to
be constructed by a Python program. This last point enables hardware designers
to take advantage of the richness of the Python language - object oriented
programming, function parameters, generators, operator overloading, libraries,
etc. - to build well organized, reusable and elegant designs.

Other Migen libraries are built on FHDL and provide various tools such as a
system-on-chip interconnect infrastructure, a dataflow programming system, a
more traditional high-level synthesizer that compiles Python routines into
state machines with datapaths, and a simulator that allows test benches to be
written in Python.

See the doc/ folder for more technical information.

Quick intro:

from migen.fhdl.std import *
from mibuild.platforms import m1
plat = m1.Platform()
led = plat.request("user_led")
m = Module()
counter = Signal(26)
m.comb += led.eq(counter[25])
m.sync += counter.eq(counter + 1)
plat.build_cmdline(m)

Code repository:
https://github.com/m-labs/migen
System-on-chip design based on Migen:
https://github.com/m-labs/misoc

Migen is designed for Python 3.3.

Migen is released under the very permissive two-clause BSD license. Under the
terms of this license, you are authorized to use Migen for closed-source
proprietary designs.
Even though we do not require you to do so, those things are awesome, so please
do them if possible:
 * tell us that you are using Migen
 * put the Migen logo (doc/migen_logo.svg) on the page of a product using it,
   with a link to milkymist.org
 * cite Migen in publications related to research it has helped
 * send us feedback and suggestions for improvements
 * send us bug reports when something goes wrong
 * send us the modifications and improvements you have done to Migen. The use
   of "git format-patch" is recommended. If your submission is large and
   complex and/or you are not sure how to proceed, feel free to discuss it on
   the mailing list or IRC (#m-labs on Freenode) beforehand.

See LICENSE file for full copyright and license info. You can contact us on the
public mailing list devel [AT] lists.milkymist.org.

  "Electricity! It's like magic!"