# How to handle a dict variable with 2^50 elements?

I have to find SHA256 hashes of 2^25 random strings. And then look for collision (using birthday paradox for the last, say, 50 bits of the hash only).

I am storing the string:hash pair in a dict variable. Then sorting the variable with values (not keys) and then looking for collision using a O(n) loop.

The problem is that since there are 2^25 strings and their 2^25 hashes, so the dict variable has 2^50 values in it. This is EXTREMELY resource intensive. So, how do I do this with limited RAM, say, around 1GB?

1. Running this with a 6GB swap space. The program ran overnight and was still not done. This is essentially even slower than an O(n_square) search! The hashes are calculated with RAM usage of about 3.2 GB. But after that when it comes to the sort command, the RAM used starts shooting up again! I though the python sort uses In-Place-Quicksort :(
2. I have stored only the hashes and found a collision. But could not find the corresponding string since did not store it.

I am not supposed to use databases etc. At the most a text file but that doesn't help. Also, I am pretty new to Python but do not let that limit the level of your answer.

PS: this is an assignment. Some claim to have found the collisions in under one minute with 300MB RAM. Don't know if that is true. I have solved the problem but the answer is unreachable! At work so do not have access to code right now. Will add soon.

Code:

``````from Crypto.Hash import SHA256
import os
import random
import string
from operator import itemgetter

def shaa():

trun=[]
clist={}
for i in range(0,33554432):

sha=SHA256.new(str(i)).hexdigest()
sha=int(bin(int(sha,16))[-50:],2)
clist[i]=sha

print 'Hashes done.'

clist=sorted(clist.items(), key=itemgetter(1))
for i in range(0,33554432):

if(clist[i]==clist[i+1]):
#print string[i],string[i+1]
print clist[i]
return 1
return 2

result=2
while(result==2):
result=shaa()
``````
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It's not so bad, since 2^25 + 2^25 = 2^26 –  sth Apr 10 '12 at 13:06
If you are looking for hash collisions, I would suggest that you make the dict hash:string instead. Then when you try to insert a new pair, you can trivially see if the hash is already present, and retrieve the corresponding colliding string. –  Karl Knechtel Apr 10 '12 at 13:11
You are not supposed to use a database? Not even the `anydbm` module? Strange requirement, though I think there are better solution anway. –  Sven Marnach Apr 10 '12 at 13:11
FYI, Python's `list.sort` uses Timsort. –  delnan Apr 10 '12 at 13:15
oh lol my mistake : 2^26 :D –  ritratt Apr 10 '12 at 13:31

I'd go for something like this:

Open 16 files (opened in binary mode should be fine; this will be easiest if all your strings have the same length). Generate your strings and hashes, and write them to a file depending on the first 4 bit of the hash. Then load and process each file separately. This will reduce memory usage by a factor of 16. (Of course you can use any number of files as long as you don't run out of file handles. Having to open and close each file on every access will become rather slow.)

If generating the strings and hashes is relatively inexpensive, you don't even need the files. Simply do 16 passes, and in each pass keep only thoses hashes the upper nibbles of which match the pass number.

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each text file will be roughly 125 MB (2GB/16 files). Yes this sounds like a good approach. I will try this one out. No idea what a binary file is. Researching that too. Thanks! –  ritratt Apr 10 '12 at 13:39
@ritratt: "binary file" wasn't a particular good description. What I meant was "file opened in binary mode". –  Sven Marnach Apr 10 '12 at 13:40
i tried this. the memory issue was resolved but unable to find collisions. No idea why :S –  ritratt Apr 13 '12 at 15:28

One way to solve the problem is to use a very long bitfield, so that every hash is mapped to certain position in `2^25` bits long memory block.

A better, yet non-100%-assurance manner to solve this kind of problems is done via Bloom filter or other probabilistic data structures.

A Bloom filter is a space-efficient probabilistic data structure that is used to test whether an element is a member of a set. False positives are possible, but false negatives are not; i.e. a query returns either "inside set (may be wrong)" or "definitely not in set".

Bloom filters have a strong space advantage over other data structures for representing sets, such as self-balancing binary search trees, tries, hash tables, or simple arrays or linked lists of the entries.

A Bloom filter with 1% error requires only about 9.6 bits per element — regardless of the size of the elements.

So, 9.6 bits per 2^25 elements, will need just 38.4 MiB of memory.

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I don't understand this answer. How do you map a 256-bit hash to 2^25 bits in a way that lets you establish if there has been a hash collision, and more importantly, what strings caused this collision? I can't figure out how this is supposed to work, and I'm tempted to say it doesn't. –  Sven Marnach Apr 10 '12 at 13:38
@SvenMarnach, I think this could be done in two passes. There will be few collisions, so in the first pass, store only the hashes in a memory-efficient data structure, check for collisions, and store any offending strings. For any colliding pair of strings `(a, b)`, this will give all values of `b`. Store these in a (relatively small) dictionary mapping hashes to strings. Then do a second pass through the strings, checking the dictionary for each one. Does that make sense to you? –  senderle Apr 10 '12 at 14:15
@SvenMarnach, both BasicWolf's suggestions would be probabilistic (the first is really a bloom filter using only one hash function), so some false positives would probably have to be weeded out, but that shouldn't be difficult. –  senderle Apr 10 '12 at 14:19
@senderle: Hmm, I see what you mean. Citing from the original post: "I have stored only the hashes and found a collision. But could not find the corresponding string since did not store it." So the OP already got this part, and the problem is to iterate the strings a second time (there are certainly ways to do this; random seeds etc.). This answer describes how to do what the OP already manages to do in a more memory-efficient way, but is somewhat incomplete in my opinion. –  Sven Marnach Apr 10 '12 at 14:35
@SvenMarnach, yes I think you're right about that -- and when I looked back over the question, I noticed the same passage. Seems like the OP is closer than he realizes. –  senderle Apr 10 '12 at 14:46

I think the key insight here -- which I admit evaded me for some time, till I came back to this a few hours later -- is that the `sha256` hash digest is its own hash. In other words, you don't have to do any additional hashing or set creation. All you have to do is create a custom hash table, using the `sha256` digest as the hash. To save space, don't store the strings; just create a bit-array (using shift operations on integers in an array of ints created with `table = numpy.zeros(table_size / bits_per_int + 1, dtype='i')`) to detect collisions, and then save colliding strings in a dict mapping hashes to strings for lookup in a second pass.

`table_size` should be a large prime -- I picked one slightly larger than 2 ** 31, which made for a 268MB table -- because that will produce few new collisions/false positives (introduced by the modulo operation on the hash). You can save the strings themselves to a text file, which you can iterate over.

So for any string, the index of the corresponding bit to set would be `index = int(hashlib.sha256('foo').hexdigest(), base=16) % table_size`. Then calculate the `major_index = index / bits_in_int` and `minor_index = index % bits_in_int`, use shift and bitwise operations on `minor_index` to check and store the correct bit in the int at `table[major_index]`, and so on.

Now do a pass through the strings. Whenever a string generates a hash that maps to a bit that has already been set, store a `hash:string` pair in a dictionary. Or better yet, store a `hash:[string_list]` pair, appending new strings to the list in the case of multiple collisions. Now for any colliding pair of strings (a, b), the dictionary will contain the hash and value of b. Then do a second pass through the strings, hashing each in turn, and checking the dictionary for each hash. If the hash is in the dictionary, and the string is not already in the corresponding list, add the string to the list. Some of the strings in the dictionary will not correspond to true collisions; the `[string_list]` for most of those hashes will be only one-item long, and those `hash:[string_list]` pairs may be discarded. The others are probably true collisions resulting from the hash function itself, rather than from the modulo operation. However, you may still have a few false positives to weed out, in those cases where there was both a true and a false positive; you'll have to double-check the resulting lists for false positives.

BasicWolf's suggestion of using a bloom filter is a good one, and might result in a smaller table. But it adds a lot of complication; I didn't bother. I tried the above method on newline-terminated strings from `'0\n'` to `'33554431\n'` and found two hashes with a 54-bit overlap. It took 11 minutes, and the maximum memory usage was about 350MB (though that could probably be reduced.) I did some profiling and found that most of the time was spent calculating offsets for the bit-table. Coding this in c would probably provide a significant speed-up, and pre-hashing and storing the hashes as well as the strings would help too.

In fact, I tried pre-hashing the strings, and replaced my rather ad-hoc `numpy`-based bitarray with a `bitarray` from the c-based extension module of the same name. This reduced the runtime to just over 2 minutes, while keeping the memory profile just around 350MB.

Close enough for government work, I think. Since this is an assignment, I won't post the code, but I'm happy to provide additional pointers.

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@ritratt, for what it's worth, I've managed to get fairly close to the numbers you gave (350MB, 2 min). –  senderle Apr 13 '12 at 3:33
This seems complicated. Must learn more python :D –  ritratt Apr 13 '12 at 18:11