Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

So I am playing a bit with DCT implementations and noticed they are (relative) slow due to the necessary multiplier calculations.

After googling a bit, I came across BinDCT, which results in very good approximations of the DCT and only uses bit shifts.

While scanning a paper about it (http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.7.834&rep=rep1&type=pdf and http://www.docstoc.com/docs/130118150/Image-Compression-Using-BinDCT) and reading some code I found on ohlo (http://code.ohloh.net/file?fid=vz-HijUWVLFS65NRaGZpLZwZFq8&cid=mt_ZjvIU0Us&s=&fp=461906&projSelected=true#L0), I noticed there are only implementations for a 8x8 matrix.

I am looking for an implementation of this BinDCT for a 32x32 matrix so I can use it in a faster variation of the perceptual hash algorithm (phash).

I am no mathematician and although I tried to understand what's going on in the paper and the c code I found I just can't wrap my head around how to transform this implementation to apply to a 32x32 matrix.

Has anyone ever written one? Is it even possible?

I understand that extending the implementation requires a lot more bit shifting and tmp variables. But although I could try with trial and error, I don't even understand the theory, so I would never know if I get the correct result.

I am writing this in C#, but any language would suffice as it's all basic operations and can be easily translated.

share|improve this question

1.you have fixed input size

  • so you multiply by the same weights all the time
  • pre-compute them once and then use only them
  • this ditch all sin,cos operations

2.2D DCT can be computed as 1D DCT (similar to FFT)

  • first do DCT on rows
  • then on collumns of the DCTed rows
  • multiply by normalization constant
  • so this converts O(N^4) to O(N^3)

3.use FastDCT

  • well this is very tricky
  • Fast algorithm is fusion between (I)DST and (I)DCT
  • there are few papers about it
  • but there are vague (and all equations are different in different papers and not whole)
  • I actually newer see a functional equation nor program for it
  • the only almost functional approach is by use of FFT
  • but for small N is there no gain because of switching to complex domain
  • and the values are not really a DCT but a close approximation to it.
  • of course I am no expert in this field so I can overlooked something
  • in all that hundreds of paper pages equations
  • anyway after Fast algorith implementation the 2D (I)DCT and the bullet 2
  • is complexity around O((N^2).log(N))

4.ditching the FPU multiplications

  • you can take all the weights and convert them to a1=a0*1024
  • or any other mask
  • so:

    x*a0 = (x*a1)/1024 = (x*a1)>>10
    
  • the same can be done for input data

  • so now just integer operations remains
  • but on modern machines can be this approach slower then FPU usage (depends on platform and implementation)

4.ditching integer multiplications

  • you can ditch all multiplications by shift and add operations (look for binary multiplication)
  • but on modern machines will this actually slow things down
  • of course if you are wiring this on some logic board/IO then it has its merit
share|improve this answer
    
Hey! thank for the response. 1. yeah I'm doing this I have a precomputed 32x32 matrix. 2. Tried this though I got weird results, probably a mistake in my code though. 3. uuuuurh. 4. Tried it but adds more overhead then just working with floats. 5. this is indeed (very) slower. I'm actually pretty happy with how it performs at the moment so I didn't look further really. (I can create 1000 phashes in 447ms). Don't have numbers on the actual dct calculation but it's neglectable compared to the rest of the application. +1 for looking into this! – Remco Ros Jan 31 '14 at 10:52
    
glad to be of help. btw for bullet 2 you need to multiply the whole result by normalization constant dependent on the input data size and DCT type used. if you got something wrong then its probably only wrong constant. I am using normalized transformation (magnitude is not changing) so the constant for me is usually c=1/N – Spektre Jan 31 '14 at 16:09

My only understanding of applying matrices is related to manipulating 3D vectors so I don't know the answer to your question directly. But in looking around, I did find this link to a blog where your specific issue is addressed. The comments at the bottom are from a bunch of people that could be a good pool of resources to chat with who have knowledge in this area. Also, If you follow the links there is a lot of good image compression info.

The author appears to be heavily involved in photo forensics. He explains how pHash is more robust than the average hash and mentions using a 32 x 32 matrix.

This could be a really good starting point. Take care.

http://www.hackerfactor.com/blog/?/archives/432-Looks-Like-It.html

share|improve this answer
    
This blog post was actually my initial starting point when starting looking into perceptual image hashing. From there I've read the c++ code of phash and converted it to C#. The main issue I have though, is that they use the DCT algorithm, which is (relative) slow because of the multiply calculations needed. Because I need a very very high performance algorithm, which is also very accurate. I started looking into near approximations of the DCT algorithm, which led me to BinDCT. Thanks though :) – Remco Ros Jan 14 '14 at 8:54
    
Were you able to make a 32x32 version of the DCT algorithm before looking into the binDCT version? Also, I've done extensive testing of bitwise computations in C# and it is a rare case indeed where a significant performance increase can be seen vs using regular expression operators. It's because in C# we're not working with the memory directly but through IL. After compiler optimization, the IL is nearly always comparable in speed. My point is that the bitwise operations in the binDCT code you linked to is less important in C# as is the fact that you're not doing floating arithmetic. – drankin2112 Jan 14 '14 at 16:47
    
I have a working implementation of phash in C# at the moment yes. I compared it to pinvoking a native c++ dll and it doesn't really gain anything. Using a profiler I see that ~80 % of the time spent in the dct function comes from the for(for(for() multiply needed. That's a feature of the algorithm you can't avoid. BinDCT doesn't need multiplications only bit shifts and additions. I optimized the dct function already to the point that it uses jagged arrays. converting it to IL (or PInvoking a native dll) would probably not even give me a 1% speed gain, so that's why I am looking for a complete – Remco Ros Jan 14 '14 at 16:59
    
-- complete different algorithm (ditching the multiplications) – Remco Ros Jan 14 '14 at 16:59
1  
Yes.. also add the algorithm tag to your post. The brainiacs with have lots to offer! – drankin2112 Jan 14 '14 at 17:16

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.