# How to find a checksum of the same checksum? (job-interview question)

Devise a simple algorithm which creates a file which contains nothing but its own checksum.

Let's say it is CRC-32, so this file must be 4 bytes long.

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There are many ways of calculating checksums, and there certainly isn't an universal algorithm to make this kind of file independent of the checksum calculation algorithm (apart from ridiculously brute-force trial and error). Has the CS algorithm been specified? –  Joonas Pulakka Mar 31 '10 at 15:22
How should the checksum be calculated? SHA1, MD5, or anything I choose, because if I can select the checksum algorithm, this i pretty trivial. –  Tuomas Pelkonen Mar 31 '10 at 15:23
basically you are looking for a fix point function, where f(x) = x. –  Nick Dandoulakis Mar 31 '10 at 15:24
Sorry, too busy moving Mt. Fuji to do this. –  Will Mar 31 '10 at 15:29
@Will, oh! that's why the sun three months ago was setting exactly above Fuji, and now it no longer does! –  Stefano Borini Apr 2 '10 at 2:13

There might be some smart mathematical way of finding it out (or proving that none exists), if you know how the algorithm works.

But since I'm lazy and CRC32 has only 2^32 values, I would brute force it. While waiting for the algorithm to go through all 2^32 values, I would use Google and Stack Overflow to find whether somebody has a solution to it.

In case of SHA-1, MD5 and other more-or-less cryptographically secure algorithms, I would get intimidated by the mathematicians who designed those algorithms and just give up.

EDIT 1: Brute forcing... This far I've found one; CC4FBB6A in big-endian encoding. There might still be more. I'm checking 4 different encodings: ASCII uppercase and lowercase, and binary big-endian and little-endian.

EDIT 2: Brute force done. Here are the results:

CC4FBB6A (big-endian)
FFFFFFFF (big-endian & little-endian)
32F3B737 (uppercase ASCII)

The code is here. On my overclocked C2Q6600 that takes about 1.5 hours to run. Now that program is single-threaded, but it would be easy to make it multi-threaded, which would give a nice linear scalability.

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So you're smart, huh? I thought your head would be bigger. :) –  psihodelia Mar 31 '10 at 15:52
+1 CC4FBB6A :-) –  Samuel Neff Mar 31 '10 at 17:49
well, is seems that nobody has presented any proper answer (offering smth. better than a brute force), but I will give my voice to you because you have highest num of upvotes; anyway, thank you for your efforts! –  psihodelia Apr 12 '10 at 23:16
"While waiting for the algorithm to go through all 2^32 values, I would use Google and Stack Overflow..." That's basically a multi-threaded algorithm, at least in spirit. –  MatrixFrog Jul 13 '11 at 10:39

Aside from Jerry Coffin and Esko Luontola's good answers to an unusual problem, I'd like to add:

Mathematically, we're looking for X such that F(X) = X, where F is the checksum function, and X is the data itself. Since the checksum's output is of fixed size, and the input we are looking for is of the same size, there is no guarantee that such an X even exists! It could very well be that every input value of the fixed size is correlated with a different value of that size.

EDIT: Your question didn't specify the exact way the checksum is supposed to be formatted within the file, so I assumed you mean the byte-representation of the checksum. When strings and encodings and formatted-strings come to play, things become more complex.

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In fact for a good checksum algorithm wouldn't you want to ensure that X != F(X) to stop a whole bunch of collision attacts –  Martin Beckett Mar 31 '10 at 18:22
No if you made that assumption it is actually more vulnerable. This was by far biggest weakness in famous Enigma. At lest i can tell that is something wrong if you can prove that property. –  Luka Rahne Mar 31 '10 at 22:04
@ralu: suppose I take the MD5 function, and define a new hash function to consist of the MD5 sum of its input, preceded by the bit 0 if the first bit of input is 1, and 1 if it is 0. This new hash function provably has no fixed point, and provably is "nearly" as strong as MD5 (if knowing the first bit of a message allows you to crack MD5 in time X, you can crack it without the first bit in time 2X). So I don't think that non-existence of a fixed point is a problem. Enigma had a rather stronger property than not having a fixed point: it never enciphered even a single character to itself. –  Steve Jessop Apr 2 '10 at 2:17
... of course by "crack" I mean reverse, I can't immediately prove that my new hash is as resistant as MD5 other attacks. But I applied a very blunt instrument to avoid a fixed point, giving up an entire bit of information about the input. I could have been more subtle, given that fixed points of MD5 (if any exist) are certainly very rare. It's not immediately obvious to me how flipping one bit of a very few MD5sums would fatally weaken its typical use on data which cannot possibly be a fixed point due to length. You couldn't even tell by examining the data which algorithm I was using. –  Steve Jessop Apr 2 '10 at 2:27
Is there any weakness if fixed point exist, but is unknown? –  Luka Rahne Apr 2 '10 at 15:36

Lacking any specific guidance to the contrary, I'd define the checksum of nonexistent data as a nonexistent checksum, so creating an empty file would fulfill the requirement.

Another typical method is a negative checksum -- i.e. after the data you write a value that makes the checksum of the whole file (including the checksum) come out to zero. In this case, you write a checksum of 0, and it all works out.

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I've specified CRC-32 –  psihodelia Mar 31 '10 at 15:29
The exact checksum you use is (mostly) irrelevant -- it's primarily about how you apply it. –  Jerry Coffin Mar 31 '10 at 15:46

Brute force. This is Adler32, which I haven't implemented before, and didn't bother testing, so it's quite likely I've messed it up. I wouldn't expect a corrected version to run significantly slower, though, unless I've done something colossally wrong.

This assumes that the 32bit checksum value is written to the file little-endian (I didn't find a fixed point with it big-endian):

``````#include <iostream>
#include <stdint.h>
#include <iomanip>

const int modulus = 65521;

void checkAllAdlers(uint32_t sofar, int depth, uint32_t a, uint32_t b) {
if (depth == 4) {
if ((b << 16) + a == sofar) {
std::cout << "Got a fixed point: 0x" <<
std::hex << std::setw(8) << std::setfill('0') <<
sofar << "\n";
}
return;
}
for (uint32_t i = 0; i < 256; ++i) {
uint32_t newa = a + i;
if (newa >= modulus) newa -= modulus;
uint32_t newb = b + a;
if (newb >= modulus) newb -= modulus;

checkAllAdlers(sofar + (i << (depth*8)), depth + 1, newa, newb);
}
return;
}

int main() {
}
``````

Output:

``````\$ g++     adler32fp.cpp   -o adler32fp -O3 && time ./adler32fp
Got a fixed point: 0x03fb01fe

real    0m31.215s
user    0m30.326s
sys     0m0.015s
``````

[Edit: several bugs fixed already, I have no confidence whatever in the correctness of this code ;-) Anyway, you get the idea: a 32 bit checksum which uses each byte of input only once is very cheap to brute force. Checksums are usually designed to be fast to compute, whereas hashes are usually much slower, even though they have superficially similar effects. If your checksum was "2 rounds of Adler32" (meaning that the target checksum was the result of computing the checksum and then computing the checksum of that checksum) then my recursive approach wouldn't help so much, there'd be proportionally less in common between inputs with a common prefix. MD5 has 4 rounds, SHA-512 has 80.]

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