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I'm writing a file comparison function. I know of filecmp.cmp but in my dataset it is expected that a lot of the files will be the same so I thought rather than comparing each potential match with each other it would be better to implement a multi-file comparison that can compare them all at once. (Also, since I'm new to python I thought it was a good learning exercise.) It seems to be going O.K. so far, in fact with some inputs it is faster then unix's cmp (which actually has me a little worried, because I don't quite believe that's possible and therefore think there maybe something wrong with my implementation!)

So, I have the code written, but I'm now trying to determine what the ideal chunk size for each read would be. Part of me is thinking that the data retrieved will all have to be compared anyway so, the more I can get into memory at one time the better, but I wonder if there are limitations of the python data structures that may influence this above that. For example, I'm maintaing, potentially large, lists of chunks and using dictionaries where the keys are the read chunks.

So, what should I be aware of in the python built-in data structures that may affect this, or is this something that will only be determined by hardware and should be determined by profiling on a particular machine?

Reading that back I realise it's not the most clear question, but (despite attempts) I'm not sure how to clarify it. I'm happy to post my code if that will make things clearer, but it's a bit longer than your average code sample (not too bad though). Please, comment if further clarification is needed.


Update Re. SHA1: I have tested my algorithm vs a SHA1 on just 2 identical input files (more are expected in the real data), running each 100 times. I realise this is not a thorough test but the results are different enough for it to be worth commenting on.

(The computer wasn't under any other load during either test, and despite what I said in the comments, this wasn't running on a target machine, it was running on one with quite reasonable specs. Both tests had the potential to run in two threads; that is the SHA1 occurred in two threads, and two threads were started for mine but due to the implementation only one would have been used. The single threaded SHA1 version took much longer. Both tests read the same size of chunk at a time. Three sets of results are given.)

Now I'm confused. Are the comments (re. SHA1) right? Therefore this is indicative of a faulty implementation or is something else going on?


real    5m35.865s    6m17.737s    5m57.010s
user    10m18.963s   11m34.178s   10m58.760s
sys     0m47.030s    0m52.707s    0m47.807s


real    3m47.185s    4m31.548s    4m40.628s
user    2m47.849s    3m26.207s    3m36.013s
sys     0m59.193s    1m5.139s     1m4.406s
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Do you only want to know which files are equal? Or do you need detailed information about the differences? If it si the former, just compare the SHA1 hashes of the files, and you are done. –  Sven Marnach Nov 1 '11 at 20:46
Or another checksum if SHA1 is too slow and you don't need cryptographic security. –  agf Nov 1 '11 at 20:52
@SvenMarnach, All I need is to know if they're equal, but there are likely to be large numbers of big identical files, and I thought doing it this way I could avoid the overhead of calculating the hash for each file (and the, highly unlikely, possibility of a hash collision!) –  tjm Nov 1 '11 at 20:53
@agf: On my machine, computing a SHA1 is at least hundred times faster than reading from disc, so this will never become the bottleneck. –  Sven Marnach Nov 1 '11 at 21:00
@tjm: The cost of computing the SHA1 of a file is completely negligible compared to the cost of reading it from disk. And SHA1 hashes are 160 bits. You will never encounter a hash collision. –  Sven Marnach Nov 1 '11 at 21:03

2 Answers 2

Please correct me if I'm wrong. Your question states: (1) You have a set of files. (2) Your pulling chunks of them in sequentially in parallel. (3) And you're comparing all such chunks at once. You're asking what the ideal chunk size is.

The answer is: do not do this. The reason is: dealing with algorithms whose main bottleneck is memory access should be IO-efficient. In the case of sequential comparison, the memory access latency is literally so prohibitive that it almost doesn't matter what you're doing when you're processing. Consider that it takes 200 times longer to get to main memory than it does to get to L1 cache; that doesn't sound like a lot, but if you are constantly pulling data from one object, comparing it, and then throwing it away and pulling data from another object, this will stack up.

What would be ideal is to process each file in sequence, and then look at the aggregated results. As other users mention, you can do so using SHA or MD5 and comparing the hex output.

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1, yes. 2, yes. 3, yes. (4), sort of! I'm really asking whether there are (and what are the) limitations of the python standard data structures that would affect the choice of chunk size (with the implementation I have). But I admit that fact did get a bit lost in the (ever growing) rambling of my question. :) Thanks for the links though; I'll have a read. I'm not sure a hash is the way to go however, as without one I can bail out early on files that don't match, and my (limited) tests on files that do, show it not to be as efficient (see my update). But maybe I've done something wrong there. –  tjm Nov 2 '11 at 4:37
The specific solution will depend on a lot of things, I admit: file size, number of files, and so on. At scale, IO-efficiency is a huge deal, but maybe not so much at a small scale. Unfortunately, I don't know about the data structure limitations you ask about really, so perhaps it would have been better that I kept my mouth shut. :( –  apc Nov 2 '11 at 5:00
No not at all. Thanks for your input. –  tjm Nov 2 '11 at 6:30

I suggest you use a binary search methodology to select the size value.

Start with a large value (one that you know to be too large) and reduce it by half. If it's faster, reduce it by half again. If it's slower, go to the next half interval. Continue until you hit the best value.

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