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I'm trying to find a little bit more information for efficient square root algorithms which are most likely implemented on FPGA. A lot of algorithms are found already but which one are for example from Intel or AMD? By efficient I mean they are either really fast or they don't need much memory.

EDIT: I should probably mention that the question is generally a floating point number and since most of the hardware implements the IEEE 754 standard where the number is represented as: 1 sign bit, 8 bits biased exponent and 23 bits mantissa.

Thanks!

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stackoverflow.com/questions/1528727/… has detailed information. –  Vladislav Zorov Jan 15 '12 at 17:07
    
Why not implement this? You only do shifts and adds and no extra memory is needed for things like look-up tables. Looks like a good candidate for an FPGA. –  Alexey Frunze Jan 15 '12 at 18:36
    
Thanks for the comment @Alex. I'll try to find some more resources, because I still don't how can I implement that in VHDL. One more question, doesn't that find just the integer part of sqrt? –  Dimitar Petrov Jan 15 '12 at 19:49
    
Do you want to solve one square root as fast as possible, or solve a continuous stream of square roots as fast as possible? –  GregS Jan 16 '12 at 2:08
    
@DimitarPetrov: right, that particular piece of code calculates the integer square root of an integer. But you can reuse it for floating-point values too because sqrt(mantissa*2^exponent)=sqrt(mantissa)*2^(exponent/2) and you can always represent your number as an integer mantissa times some even power of 2. You should have included the details about floating-point square root and VHDL in the question. Actually, the VHDL probably deserves a separate question. –  Alexey Frunze Jan 16 '12 at 5:15
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2 Answers 2

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Not a full solution, but a couple of pointers.

I assume you're working in floating point, so point 1 is remember that floating point is stored as a mantissa and exponent. The exponent of the square root will be approximately half the exponent of the original number thanks to logarithms.

Then the mantissa can be approximated with a look-up table, and then you can use a couple of newton-raphson rounds to give some accuracy to the result from the LUT.

I haven't implemented anything like this for about 8 years, but I think this is how I did it and was able to get a result in 3 or 4 cycles.

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Thanks Paul! Can you point me to particular algorithm? Yep, I'm working in floating point and just editted my question... or could you expand a little bit your explanation because I didn't quite understand everyhing :) –  Dimitar Petrov Jan 16 '12 at 14:40
    
Unfortunately it's been so long that I can't remember the precise details, and it was for a previous employer so I can't look it up either. If you have specific questions I'll do my best to answer them. –  Paul S Jan 16 '12 at 16:00
    
Thanks @Paul. I've marked your question as best answer, since that gave me some ideas and point me (hopefully) in the right direction. Thanks –  Dimitar Petrov Jan 16 '12 at 22:01
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This is a great one for fast inverse-quare root.
Have a look at it here. Notice it's pretty much about the initial guess, rather amazing document :)

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Thanks a lot! I've seen that already and looks pretty impresive, however the "magic number" scared me a little bit in the beginning. I will take a look again :) –  Dimitar Petrov Jan 15 '12 at 17:41
    
I don't feel this answer is really relevant to the question. This algorithm only computes a rough approximation of the inverse of the square root, and definitely is not was is implemented on FPGA's –  Sven Marnach Jan 15 '12 at 18:09
    
Thanks Sven. Does most implementations on FPGAs just use some variant on the Newton-Raphson method? Like some inversion to get rid from the division, which itself is a expensive operation? –  Dimitar Petrov Jan 15 '12 at 18:13
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