Today FuseSoC is turning six years old. That is probably something like 35 in software years. It has had a colourful past with some breakups and an identity crisis, but has now settled down and realized that it will not change the world in the same way that it used to think. It has spawned a few child projects which are not yet able to handle themselves in the world and still need their loving parent project. Being 35 also means that we can expect a FuseSoC middle-age crisis in a few years where it will try to reinvent itself in a desperate attempt to appear youthful. All in all, it's pretty similar to it's author.
As with most software, there is no birth certificate, but we will use the date of the first commit to the repo of what would become FuseSoC as the birth date. So what really happened on that fateful day that would become forever etched into history as the day when everything changed? According to Wikipedia, it wasn't a happy day overall, but none of those events are really related to FuseSoC.
As so often, we need to go back further in time and take a look at the events leading up to this day. It all started with the OpenRISC Reference Platform System on Chip version 2, or ORPSoCv2. This project was a combination of RTL code for the OpenRISC CPU together with a bunch of peripheral controller cores, drivers, example applications and miles of makefiles to build everything together into FPGA images that could be loaded onto a few select boards for running OpenRISC-based systems. Despite having one of the least sexy names ever, it was widely used by most people who dealt with OpenRISC and seems to still be in use by some people. But it wasn't without flaws. Due to the tightly integrated nature of the project, everyone who wanted to add support for a new FPGA board or add some extra peripheral driver ended up with their own version of the project, each with their own bugs and features. Fixes were rarely submitted back upstream to the main ORPSoCv2 repo. Also, the RTL code for the CPU and peripheral controllers were copies of other repositories, which quickly started to diverge from their upstream counterparts. Again, none of that code was submitted upstream. There were also other issues with regards to scalability that started to show when more features were added. In short, it was time for something new.
I started sketching out what I would like to see in a successor, and then started implementing ORPSoCv3. Just like ORPSoCv2 this was a system of makefiles calling into other makefiles, but with a major difference. Instead of storing copies of cores, the upstream versions were fetched when they were requested in a SoC to avoid all the code duplication. After some time, I was ready to present my work in progress to the world. At that time I was working for the company that owned and maintained OpenCores. The git hype had already started to sweep through the software landscape and I had been trying to convince my co-workers that we needed to start making OpenCores support git instead of just SVN. I never managed to convince them, but at least I got them to set up a git server where I could put my project as a trial. Except for three or four outdated clones of other OpenRISC-related projects, I had the only git repo at the now defunct git.opencores.org. On August 30 20111 I made the first commit.
The better part of the coming year was spent on writing makefiles calling other makefile until one day I had enough and decided that I will never in my life write another makefile calling other makefiles. It was time to kill my darling. I started a new implementation in Python with the lessons learned and soon got to a state where I wanted to present it to the world. As I only had this one git repo and no real understanding of git work flows, my instinct was to clean out the old repo and just push the new code in. Unfortunately I never figured out how to get rid of the first commit, which resulted in this sequence of commits:
Even after the Python migration, FuseSoC (or ORPSoCv3 really) was still storing a lot of RTL code in the repo. It was a shaky relationship, and in August 2013 there was an inevitable separation of tool and RTL code. The RTL code went into a new project called orpsoc-cores. There wasn't any crying involved an both parties realized that it was best to go separate ways. A day later, the first released version, ORPSoC 3.0 was released.
Life went on, new features were added, bugs were fixed, ORPSoCv3 became older and fatter, but it became more and more evident that ORPSoC really didn't have anything to do with OpenRISC. Everything that was OpenRISC-specific had already moved to the orpsoc-cores repository and ORPSoCv3 was really a dependency manager and build system for any RTL code. It was once again time to cut some ties. As usual, names are harder than code, and I spent some time trying to figure out what to call the thing I had created. One of the main alternatives was SoCify, but it turned out someone else had already used that name. In hindsight, I'm really grateful for that. SoCify as it is a horrible name. The idea of FuseSoC came from the analogy of fusion reactions to build something bigger from a number of smaller cores. The minimalist in me also considered FuSoC, which is also pretty bad and sounds a bit like F*** you SoC. I do like FuseSoC though. In February 2014 the big rename was made, the project was moved to its current location and FuseSoC 1.0 was released.
Since then not much has happened. New features are added. Bugs are fixed, reintroduced and fixed again. FuseSoC is getting older and fatter. I'm really grateful for all help that I have received over the years. According to github, there have been 20 contributors to the code base, but there are also a number of other people who have submitted bugs or contributed to the RTL code in the standard core library. Big thanks to everyone involved.
Birthdays usually involve presents. But what can we give to a project that already has everything? How about a logo and a home page? That's the perfect gift for a six year old and on this big day I can proudly announce the brand new home page (Ssshhh...I have had the domain name since 2014, but don't tell FuseSoC) and the FuseSoC logo.
Happy birthday FuseSoC! I will now leave the word to the millions of users to tell their stories of how FuseSoC has changed their lives.
Goings-on in the FuseSoC project and other Open Source Silicon related news
Wednesday, August 30, 2017
Monday, August 21, 2017
OSDDI: Director's commentaries
Andrew Back of AB Open and FOSSi Foundation has been working on this great series of interviews called Open Source Digital Design Insights, in which he has been interviewing some of the great minds of the Free and Open Source Silicon movement (+ me). In the fourth episode the turn has come to me. As I watch the video myself, I realize how quickly time moves in the open source silicon world and how many things that have happened since then. I would therefore like to take the opportunity to add some more context as an addendum to the interview.
The interview was made at ORConf 2015, the same day as we publicly announced the Free and Open Source Silicon Foundation. We had been working on this for a year and it was a great feeling to present our ambitions to the world. The first thing that strikes during this interview is that we hadn't yet embraced the Open Source Silicon epithet ourselves and were still referring to our work as Open Source Hardware.
Another major theme that can use some more explanation is to role of the OpenRISC project nowadays. I would believe that most people coming in contact with open source silicon at this time will do so through the RISC-V project. When I started out, the RISC-V project was not yet born and OpenRISC was just about to become a teenager. OpenRISC wasn't the only free ISA around at the time. Most notably there were also free implementations of SPARC (both the LEON and the Sun T1/T2) and Lattice Mico 32 (lm32). OpenRISC was likely the most widely used architecture however and is still used in some critical infrastructure, which I'm unfortunately not allowed to speak freely of. Despite being widely used, the OpenRISC ISA hasn't been without faults, and already in 2011, we started work on a successor to the OpenRISC 1000 ISA, called OpenRISC 2000. Some of the things we wanted to fix was removal of the branch delay slots, better support for wider instruction lengths, instruction compression, more modular instruction set, revised memory model and other things. Unfortunately, we never got around to implement any of that, as we were a small group and there was barely enough manpower to do all the necessary work on or1k. Turns out, we never needed to, because a year or two after that, RISC-V came along and did all those things that we had planned for or2k - and more. In that regard, we see RISC-V as the spiritual successor to OpenRISC and we are happy to pass the dutch to RISC-V for future free thinking ISA development.
So what's the deal with OpenRISC in 2017? Well, it's not seeing as many design starts as it used to do since most new designs are based on RISC-V. My guess is that the ones who make new designs based on OpenRISC do it because they either already have a working OpenRISC environment and have no need to replace that, or because they know that it's a stable code base that has been ASIC-proven numerous times for more than a decade. On the software side we are still pushing to upstream some of the last bits of the toolchains, notably GDB and GCC. There are also some updates and clarifications to the specification, mostly related to the ABI.
I believe that the greatest legacy of OpenRISC will not be the ISA, but the idea and realization of a free and open source silicon ecosystem. A CPU isn't very useful by itself and much of what came out of the OpenRISC project was IP cores, such as peripheral controllers and a lot of support software. For example, the i2c and ethernet drivers for the controllers that came out from the OpenRISC project has been in the Linux kernel since 2006, which is seven years before the OpenRISC CPU support was added to the kernel. Some of the debug infrastructure that originated from OpenRISC is widely used in RISC-V-based designs. The FOSSi Foundation was born from a group of OpenRISC developers who saw the need for a vendor-independent group to foster the open source silicon ecosystem, regardless of which ISA is currently in vogue. ORConf was originally the OpenRISC conference. We have considered renaming it, but we like the name so we just have to find a good backronym (the best proposal is still Olof's Rock'n'roll Conference). Even FuseSoC was born as a tool to make it easier to build OpenRISC-based SoCs, and for the first year or two it was still called ORPSoCv3 (OpenRISC Reference Platform System on Chip version 3)
Enough said about OpenRISC. I think the most amazing aspect of the interview is that I did not mention FuseSoC even once. Nope. Not a single mention of FuseSoC in over 8 minutes! And if you think I look a bit like a zombie sloth on heroin in the interview, that's because I usually spend the months leading up to ORConf as Sonic the Hedgehog on amphetamine, so once everyone is seated and the conference starts, that's when I start to relax. It's a lot of work to organize a conference, but I absolutely love doing it and I hope that you will come to visit and enjoy as well. And if you haven't seen the other entries in the OSDDI series, please watch them now. They really are insights in the world of open source silicon from some of the most knowledgeable people in the field (+me).
Saturday, August 12, 2017
FuseSoC 1.7
Lock up your wifes and daughters! FuseSoC 1.7 has been unleashed on the world. This unstoppable force will organize your HDL dependencies and provide abstractions to your EDA tools without giving you a chance to defend yourself.
Actually, there's not that much new on the surface of this release. Most of the work has been spent on internal refactoring in order to bring in two new major features for the next cycle. The first of these is a separation of the frontend - which handles reading core files, maintains the core database and does dependency resolution - and the backends - which launch the EDA tools. There are several reasons for doing this, but I hope to write more about this specifically in another post. The other major feature is the preparation for a new core description format, called CAPI2. This will be added early in the FuseSoC 1.8 cycle, so expect to read more about this in the future as well. If you are interested in taking an early peek, there's a CAPI2 branch of FuseSoC together with corresponding branch of fusesoc-cores which is used as a playground for now.
So, onto the actual changes.
Test coverage has now reached 72% of the code base. Unit testing is something I should had done from day one, as it has uncovered plenty of bugs and been a huge help when doing refactoring. So kids, get tested you too!
Failure is always an option, and should be handled with the same loving care as success. FuseSoC now exits with an error code when a build or simulation fails, making it easier for external tools to pick up failures. Also, failing scripts now print out the error code on failures to make it easier to analyze what went wrong. Speaking of things going wrong, the parsing of the core files have been made improved to warn for syntax errors instead of leaving the user with a Python stack trace. In general, there has also been many improvements to the logging, so that running with the --verbose option might actually be helpful when debugging strange errors.
There have been a number of improvements in the tool backends, mostly related to parameter passing. The Vivado backend had a bug that prevented passing multiple parameters to the backend. Quartus now supports passing verilog defines on the command-line. Parameters are properly escaped before being passed to the backend, which fixes string parameters for some backends. Other than that, ISIM now supports multiple toplevels, which is required for example when simulating Xilinx primitives that require glbl.v as a parallel toplevel. The Vivado flow now works on Windows after discovering that Vivado prefer forward regardless of what the OS uses as path separator. The Icarus backend has been rewritten so that it's easier to rebuild the simulation model from an exported build tree.
In addition to fixes and new features, a few features have been removed. Mostly because they made no sense, were broken or turned out to be hard to maintain with little gain. The system-info command is removed, as all details are shown in core-info anyway. The submodule provider was likely broken for a long time without anyone complaining, and was a bad fit for the FuseSoC depedency model, so it has been removed too. There was also a semi-working feature of the verilator backend that aimed to convert files containing verilog `define statements to a correspondent C header file. As there might be users out there actually using this, I added an entry to the FuseSoC migration guide with information on how to replicate this functionality in newer versions of FuseSoC.
Other than that, there are some other bug fixes, like FuseSoC now supports putting IP-XACT files in subdirectories of the core tree. There is also a --version command-line option to show, surprise, the current version of FuseSoC.
That's more or less it. Make sure to upgrade and get prepared for the wild ride that will be FuseSoC 1.8
Peace out!
Actually, there's not that much new on the surface of this release. Most of the work has been spent on internal refactoring in order to bring in two new major features for the next cycle. The first of these is a separation of the frontend - which handles reading core files, maintains the core database and does dependency resolution - and the backends - which launch the EDA tools. There are several reasons for doing this, but I hope to write more about this specifically in another post. The other major feature is the preparation for a new core description format, called CAPI2. This will be added early in the FuseSoC 1.8 cycle, so expect to read more about this in the future as well. If you are interested in taking an early peek, there's a CAPI2 branch of FuseSoC together with corresponding branch of fusesoc-cores which is used as a playground for now.
So, onto the actual changes.
Test coverage has now reached 72% of the code base. Unit testing is something I should had done from day one, as it has uncovered plenty of bugs and been a huge help when doing refactoring. So kids, get tested you too!
Failure is always an option, and should be handled with the same loving care as success. FuseSoC now exits with an error code when a build or simulation fails, making it easier for external tools to pick up failures. Also, failing scripts now print out the error code on failures to make it easier to analyze what went wrong. Speaking of things going wrong, the parsing of the core files have been made improved to warn for syntax errors instead of leaving the user with a Python stack trace. In general, there has also been many improvements to the logging, so that running with the --verbose option might actually be helpful when debugging strange errors.
There have been a number of improvements in the tool backends, mostly related to parameter passing. The Vivado backend had a bug that prevented passing multiple parameters to the backend. Quartus now supports passing verilog defines on the command-line. Parameters are properly escaped before being passed to the backend, which fixes string parameters for some backends. Other than that, ISIM now supports multiple toplevels, which is required for example when simulating Xilinx primitives that require glbl.v as a parallel toplevel. The Vivado flow now works on Windows after discovering that Vivado prefer forward regardless of what the OS uses as path separator. The Icarus backend has been rewritten so that it's easier to rebuild the simulation model from an exported build tree.
In addition to fixes and new features, a few features have been removed. Mostly because they made no sense, were broken or turned out to be hard to maintain with little gain. The system-info command is removed, as all details are shown in core-info anyway. The submodule provider was likely broken for a long time without anyone complaining, and was a bad fit for the FuseSoC depedency model, so it has been removed too. There was also a semi-working feature of the verilator backend that aimed to convert files containing verilog `define statements to a correspondent C header file. As there might be users out there actually using this, I added an entry to the FuseSoC migration guide with information on how to replicate this functionality in newer versions of FuseSoC.
Other than that, there are some other bug fixes, like FuseSoC now supports putting IP-XACT files in subdirectories of the core tree. There is also a --version command-line option to show, surprise, the current version of FuseSoC.
That's more or less it. Make sure to upgrade and get prepared for the wild ride that will be FuseSoC 1.8
Peace out!