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I want to load the following hexadecimal file that has

1) initializing value (IV) on the first line,
2) encrption key on the second line,
3) number of plain texts on the third line, and
4) actual plain texts for AES encryption in Cipher Block Chaining (CBC) mode

into numpy array.


If the uniformity of the file is bothering you, you may ignore the third line which tells about the number of plain texts to be encrypted. All lines except the third line are 128 bit hexadecimal entries

The idea is to load this file into numpy array and then do AES encryption efficiently.

How can i load this into numpy array and then use AES from Crypto.Cipher to do AES encryption of this file and similar files. I have files of this format having as large as 100 million plain texts.

Thanks and please let me know if you have any questions

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Are you sure that loading 1.6GB+ of data into one giant array in memory, and not doing any processing until the loading and preprocessing (de-hexlifying) is done, will be faster than just processing it iteratively? –  abarnert May 30 '13 at 18:11
Why do you want to load this into a numpy array? It's not going to make Crypto.Cipher.AES any faster, I shouldn't think. –  DSM May 30 '13 at 18:15
Whether this makes it faster or not is what i want to see. May be it does ? Who knows ? So better check it out –  user2065276 May 30 '13 at 18:21
@DSM: From a test, it looks like it does make it faster. That surprised me, because AES is slow. But if you're only AES'ing 16 bytes… that's apparently only an order of magnitude or so slower than Python iteration. –  abarnert May 30 '13 at 18:38

1 Answer 1

up vote 4 down vote accepted

I'm assuming you want to unhexlify the data, and store the resulting bytestrings as fixed-length character strings rather than object. (You can't store them as some kind of int128 type, because numpy doesn't have such a type.)

To avoid reading 3.2GB of text into memory, and using roughly the same amount pre-processing it into the desired form, you probably want to use fromiter, so:

with open(myfile) as f:
    iv = binascii.unhexlify(f.readline().strip())
    key = binascii.unhexlify(f.readline().strip())
    count = int(f.readline())
    a = np.fromiter((binascii.unhexlify(line.strip()) for line in f), dtype='|S16')

If you have 10GB of RAM to spare (rough ballpark guess), it might be faster to read the whole thing in as an array of object, then transform it twice… but I doubt it.

As to whether this will help… You might get a little benefit, because AES-ing 16 bytes may be fast enough that the cost of iteration is noticeable. Let's test it and see.

With 64-bit Mac Python 2.7.2, I created an array of 100000 S16s by copying your example repeatedly. Then:

In [514]: %timeit [aes.encrypt(x) for x in a]
10 loops, best of 3: 166 ms per loop
In [515]: %timeit np.vectorize(aes.encrypt)(a)
10 loops, best of 3: 126 ms per loop

So, that's almost a 25% savings. Not bad.

Of course the array takes longer to build than just keeping things in an iterator in the first place—but even taking that into account, there's still a 9% performance gain. And it may well be reasonable to trade 1.6GB for a 9% speedup in your use case.

Keep in mind that I'm only building an array of 100K objects out of a pre-existing 100K list; with 100M objects read off disk, I/O is probably going to become a serious factor, and it's quite possible that iterative processing (which allows you to interleave the CPU costs with disk waits) will do a whole lot better.

In other words, you need to test with your own real data and scenario. But you already knew that.

For a wider variety of implementations, with a simple perf-testing scaffolding, see this pastebin.

You might want to try combining different approaches. For example, you can use the grouper recipe from itertools to batch things into, say, 32K plaintexts at a time, then process each batch with numpy, to get the best of both. And then pool.imap that numpy processing, to get the best of all 3. Or, alternatively, put the one big numpy array into shared memory, and make each multiprocessing task process a slice of that array.

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I have 8GB RAM. So don't worry about that –  user2065276 May 30 '13 at 18:24
@user2065276: If you have 8GB of RAM, using 3.2GB for the file, at least 3.2GB for intermediate storage, and 1.6GB for the final result is going to swap to disk, so you very definitely should worry about it. –  abarnert May 30 '13 at 18:26
Thanks abarnert a million. You are too good! –  user2065276 May 30 '13 at 18:49
@user2065276: One last comment: Multiprocessing. Just using the default chunking in multiprocessing.Pool I cut out 79% of the time (on an 8-core hyperthreaded machine) from the array solution, and you'd probably do even better with an iterative solution and/or with smarter chunking. Unless you turn out to be I/O bound, of course. –  abarnert May 30 '13 at 18:55
which aes package are you using? Please share details. –  user2065276 May 30 '13 at 18:58

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