1. Have you used FBP for a real project?
We've designed and implemented a DF server for our automation project (dispatcher, component iterface, a bunch of components, DF language, DF compiler, UI). It is written in bare C++, and runs on several Unix-like systems (Linux x86, MIPS, avr32 etc., Mac OSX). It lacks several features, e.g. sophisticated flow control, complex thread control (there is only a not too advanced component for it), so it is just a prototype, even it works. We're now working on a full-featured server. We've learnt lot during implementing and using the prototype.
Also, we'll make a visual editor some day.
2. What is your opinion of FBP?
2.1. First of all, dataflow programming is ultimate fun
When I met dataflow programming, I was feel like 20 years ago, when I met programming first. Altough, DF programming differs from procedural/OOP programming, it's just a kind of programming. There are lot of things to discover, even sooo simple ones! It's very funny, when, as an experienced programmer, you met a DF problem, which is a very-very basic thing, but it was completely unknown for you before. So, if you jump into DF programming, you will feel like a rookie programmer, who first met the "cycle" or "condition".
2.2. It can be used only for specific architectures
It's just a hammer, which are for hammering nails. DF is not suitable for UIs, web server and so on.
2.3. Dataflow architecture is optimal for some problems
A dataflow framework can make magic things. It can paralellize procedures, which are not originally designed for paralellization. Components are single-threaded, but when they're organized into a DF graph, they became multi-threaded.
Example: did you know, that make is a DF system? Try make -j (see man, what -j is used for). If you have multi-core machine, compile your project with and without -j, and compare times.
2.4. Optimal split of the problem
If you're writing a program, you often split up the problem for smaller sub-problems. There are usual split points for well-known sub-problems, which you don't need to implement, just use the existing solutions, like SQL for DB, or OpenGL for graphics/animation, etc.
DF architecture splits your problem a very interesting way:
- the dataflow framework, which provides the architecture (just use an existing one),
- the components: the programmer creates components; the components are simple, well-separated units - it's easy to make components;
- the configuration: a.k.a. dataflow programming: the configurator puts the dataflow graph (program) together using components provided by the programmer.
If your component set is well-designed, the configurator can build such system, which the programmer has never even dreamed about. Configurator can implement new features without disturbing the programmer. Customers are happy, because they have personalised solution. Software manufacturer is also happy, because he/she don't need to maintain several customer-specific branches of the software, just customer-specific configurations.
If the system is built on native components, the DF program is fast. The only time loss is the message dispatching between components compared to a simple OOP program, it's also minimal.
3. Does FBP have a future?
The main reason is that it can solve massive multiprocessing issues without introducing brand new strange software architectures, weird languages. Dataflow programming is easy, and I mean both: component programming and dataflow configuration building. (Even dataflow framework writing is not a rocket science.)
Also, it's very economic. If you have a good set of components, you need only put the lego bricks together. A DF program is easy to maintain. The DF config building requires no experienced programmer, just a system integrator.
I would be happy, if native systems spread, with doors open for custom component creating. Also there should be a standard DF language, which means that it can be used with platform-independent visual editors and several DF servers.