Chisel3 is a new FIRRTL based chisel. It is currently in BETA VERSION, so some Chisel features may change in the coming months.
Please visit the Wiki for a more detailed description.
Chisel3 is much more modular than Chisel2, and the compilation pipeline looks like:
- Chisel3 (Scala) to FIRRTL (this is your "Chisel RTL").
- FIRRTL to Verilog (which then be passed into FPGA or ASIC tools).
- Verilog to C++ for simulation and testing using Verilator.
This will walk you through installing Chisel and its dependencies:
- sbt, which is the preferred Scala build system and what Chisel uses.
- FIRRTL, which compile Chisel's IR down
to Verilog. A beta version of FIRRTL written in Scala is available.
- FIRRTL is currently a separate repository but may eventually be made available as a standalone program through system package managers and/or included in the Chisel source tree.
- FIRRTL has known issues compiling under JDK 8, which manifests as an infinite recursion / stack overflow exception. Instructions for selecting JDK 7 are included.
- Verilator, which compiles Verilog down to C++ for simulation. The included unit testing infrastructure uses this.
- Install sbt, which isn't available by default in the system package manager:
echo "deb https://dl.bintray.com/sbt/debian /" | sudo tee -a /etc/apt/sources.list.d/sbt.list
sudo apt-key adv --keyserver hkp://keyserver.ubuntu.com:80 --recv 642AC823
sudo apt-get update
sudo apt-get install sbt
- Install FIRRTL.
- Clone the FIRRTL repository:
```
git clone [email protected]:ucb-bar/firrtl.git
```
- Build Scala-FIRRTL. In the cloned FIRRTL repository:
```
make build-scala
```
* This compiles FIRRTL into a JAR and creates a wrapper script `firrtl` to
make the JAR executable. The generated files are in `firrtl/utils/bin`.
* If this fails with an infinite recursion / stack overflow exception, this
is a known bug with JDK 8. You can either increase the stack size by
invoking:
```
JAVA_OPTS=-Xss256m make build-scala
```
* Or, revert to JDK 7:
1. Install JDK 7 (if not installed already):
```
sudo apt-get install openjdk-7-jdk
```
2. Select JDK 7 as the default JDK:
```
sudo update-alternatives --config java
```
- Add the FIRRTL executable to your PATH. One way is to add this line to your
.bashrc
:
```
export PATH=$PATH:<path-to-your-firrtl-repository>/utils/bin
```
- Install Verilator. As of February 2016, the version of Verilator included by in Ubuntu's default package repositories are too out of date, so it must be compiled from source.
- Install prerequisites (if not installed already):
```
sudo apt-get install git make autoconf g++ flex bison
```
- Clone the Verilator repository:
```
git clone http://git.veripool.org/git/verilator
```
- In the Verilator repository directory, check out a known good version:
```
git pull
git checkout verilator_3_886
```
- In the Verilator repository directory, build and install:
```
unset VERILATOR_ROOT # For bash, unsetenv for csh
autoconf # Create ./configure script
./configure
make
sudo make install
```
```
yaourt -S firrtl-git verilator sbt
```
TODO: write me. If you really want to see this happen, let us know by filing a bug report!
- Install sbt:
brew cask install sbt
- Install FIRRTL:
- Clone the FIRRTL repository:
```
git clone [email protected]:ucb-bar/firrtl.git
```
- Build Scala-FIRRTL. In the cloned FIRRTL repository:
```
make build-scala
```
* This compiles FIRRTL into a JAR and creates a wrapper script `firrtl` to
make the JAR executable. The generated files are in `firrtl/utils/bin`.
* If this fails with an infinite recursion / stack overflow exception, this
is a known bug with JDK 8. You can either increase the stack size by
invoking
```
JAVA_OPTS=-Xss256m make build-scala`
```
* Or, revert to JDK 7:
```
brew install caskroom/versions/java7
```
- Add the FIRRTL executable to your PATH. One way is to add this line to your
.bashrc
:
```
export PATH=$PATH:<path-to-your-firrtl-repository>/utils/bin
```
- Install Verilator:
brew install verilator
If you are migrating to Chisel3 from Chisel3, please visit Chisel3 vs Chisel2
These are the base data types for defining circuit wires (abstract types which may not be instantiated are greyed out):
This section describes how to get started using Chisel to create a new RTL design from scratch.
TODO: toy example
The simulation unit testing infrastructure is still a work in progress.
See src/test/scala/chiselTests
for example unit tests. Assert.scala is a
pretty bare-bones unittest which also somewhat verifies the testing system
itself.
Unit tests are written with the ScalaTest unit testing framework, optionally with ScalaCheck generators to sweep the parameter space where desired.
BasicTester
-based tests run a single circuit in simulation until either the
test finishes or times out after a set amount of cycles. After compilation,
there is no communication between the testdriver and simulation (unlike
Chisel2's Tester, which allowed dynamic peeks and pokes), so all testvectors
must be determined at compile time.
The circuits run must subclass BasicTester
, which is a Module with the
addition of a stop
function which finishes the testbench and reports success.
Any assert
s that trigger (in either the BasicTester
or a submodule) will
cause the test to fail. printf
s will forward to the console.
To write a test using the BasicTester
that integrates with sbt test, create
a class that extends either ChiselFlatSpec
(BDD-style testing) or
ChiselPropSpec
(ScalaCheck generators). In the test content, use
assert(execute{ new MyTestModule })
where MyTestModule
is your top-level test circuit that extends
BasicTester
.
A more Chisel2-like tester may come in the future.
TODO: commands to compile project to simulation
TODO: running testbenches
This section describes how to get started developing Chisel itself, including how to test your version locally against other projects that pull in Chisel using sbt's managed dependencies.
In the Chisel repository directory, run:
sbt compile
to compile the Chisel library. If the compilation succeeded, you can then run the included unit tests by invoking:
sbt test
Chisel3 is still undergoing rapid development and we haven't pusblished a stable version to the Nexus repository.
You will need to build from source and publish-local
.
The repo version can be found in the build.sbt file.
At last check it was:
version := "3.0",
To publish your version of Chisel to the local Ivy (sbt's dependency manager) repository, run:
sbt publish-local
PROTIP: sbt can automatically run commands on a source change if you prefix
the command with ~
. For example, the above command to publish Chisel locally
becomes sbt ~publish-local
.
sbt's manual
recommends that you use a SNAPSHOT
version suffix to ensure that the local
repository is checked for updates.
Change the version string in build.sbt to:
version := "3.0-SNAPSHOT"
and re-execute sbt publish-local
to accomplish this.
The compiled version gets placed in ~/.ivy2/local/
. You can nuke the relevant
subfolder to un-publish your local copy of Chisel.
In order to have your projects use this version of Chisel, you should update the libraryDependencies setting in your project's build.sbt file to:
libraryDependencies += "edu.berkeley.cs" %% "chisel" % "3.0-SNAPSHOT"
The version specifier in libraryDependencies in the project's build.sbt should match the version string in your local copy of Chisel's build.sbt.
The Chisel3 compiler consists of these main parts:
- The frontend,
chisel.*
, which is the publicly visible "API" of Chisel and what is used in Chisel RTL. These just add data to the... - The Builder,
chisel.internal.Builder
, which maintains global state (like the currently open Module) and contains commands, generating... - The intermediate data structures,
chisel.firrtl.*
, which are syntactically very similar to FIRRTL. Once the entire circuit has been elaborated, the top-level object (aCircuit
) is then passed to... - The FIRRTL emitter,
chisel.firrtl.Emitter
, which turns the intermediate data structures into a string that can be written out into a FIRRTL file for further processing.
Also included is:
- The standard library of circuit generators,
chisel.util.*
. These contain commonly used interfaces and constructors (likeDecoupled
, which wraps a signal with a ready-valid pair) as well as fully parameterizable circuit generators (like arbiters and muxes). - Driver utilities,
chisel.Driver
, which contains compilation and test functions that are invoked in the standard Verilog generation and simulation testing infrastructure. These can also be used as part of custom flows.