What best practices should be observed when implementing HDL code?
What are the commonalities and differences when compared to more common software development fields?
The best book on this topic is Reuse Methodology Manual. It covers both VHDL and Verilog.
And in particular some issues that don't have an exact match in software:
Some that are the same include
Sort of an old thread, but wanted to put in my $0.02. This isn't really specific to Verilog/VHDL.. more on hardware design in general... specifically synthesizable design for custom ASICs.
This is my opinion based on years of industry (as opposed to academic) experience on design. They are in no particular order
My umbrella statement is to Design for validation execution. In hardware design, validation is paramount. Bugs are a lot more expensive when found in actual silicon. You can't just re-compile. Therefore, pre-silicon is given much more focus.
As for comparing against more traditional software design:
... for completeness, I need to also discuss best test-bench design practices... but that's for another day
Sorry for the length.. I was in "The Zone" :)
HDL's like Verilog and VHDL really seem to encourage spaghetti code. Most modules consist of several 'always' (Verilog) or 'process' (VHDL) blocks that can be in any order. The overall algorithm or function of the module is often totally obscured. Figuring out how the code works (if you didn't write it) is a painful process.
A few years ago I came across this paper that outlines a more structured method for VHDL design. The basic idea is that each module has only 2 process blocks. One for combinatorial code, and other for synchronous (the registers). It is great for producing readable and maintainable code.
Debugging on hardware is usually much harder than debugging software so:
Some debugging tips:
By smart protocols, I've meant that should two of your physical units connect, they should communicate with the simplest communication protocol available. that is, do not use any sophisticated home-made protocols, between them.
The reason, is this - Fidning bugs "inside" an FPGA/ASIC is reletivly easy as you have simulators. So if you are sure that data comes as you want it, and goes out as your program sends it, you've reached Hardware utopia - being able to work at software level :) (with the simulator). But if your data doesn't get to you, the way you want it to, and you have to figure out why... you'll have to connect to the lines, and that's not that easy.
Finding a bug on the lines, is hard as you have to connect to the lines with special equipment, that record the states of the lines, on different times, and you'll have to make sure your lines act according to the protocol.
If you need to connect two of your physical units make the "protocol" as simple as it can , up to the point it won't be called a protocol :) For example if the units share a clock, add x data lines between them, and make one unit write those and the other unit read, thus passing one "word" which has x bits between them on each clock fall, for example. If you have FPGA's, should the original clock rate be too fast for parallel data - you can control the speed of this, according to your experiments, for example making the data stay on lines of at least 't' clock cycles etc'. I assume parallel data transfer is simpler, as you can work with at lower clock rates and get the same performances, without the need to split your words on one unit, and reassemble on the other. (hopefully there is no delay between the 'clock' each unit receives). Even this is probably too complex :)
Regarding SPI, I2C etc' I haven't implemented any of them, I can say that I've connected legs of two FPGA's running from the same clock, (don't remember the exact formation of resistors in the middle), at much higher rates, so I really can't think of a good reason to use those, as the main way to pass data between your own FPGA's, unless the FPGA's are located very far one from another, which is one reason to use a serial rather than a parallel bus.
JTAG is used by some FPGA companies, to test/program their products, but not sure if it's used as way to transport data at high speeds, and It is a protocol... (still one which may have some built-in on chip support).
If you do have to implement any known protocol, consider using a pre-made HDL code for this - which can be found or purchased.
This is the question that requires JBDAVID's 10 commandments for Hardware design.
For FPGAs, Xilinx has this great page (missing, new location TBD). Almost all would apply to other FPGA vendors, or would have equivalent rules. A great deal is applicable to ASIC designs.
Altera has Recommended HDL Coding Styles (PDF) and Design Recommendations for Altera Devices and the Quartus II Design Assistant. Altera has this pay course. It is more about productivity however. I have no other information how good it is.