# What is the reason that it is not possible to reverse an MD5 hash? (esp. with a salt)

Why can't you just reverse the algorithm? And how is it possible to make an algorithm that isn't reversible?

And if you use a rainbow table, what makes using a salt impossible to crack it? If you are making a rainbow table with brute force to generate it, then it invents each plaintext value possible (to a length), which would end up including the salt for each possible password and each possible salt (the salt and password/text would just come together as a single piece of text).

I am just very curious about this and how everything works and I could not find any articles about it. So if you can send me a link to an article about this stuff or if you can briefly describe it yourself, I would be very happy!

Thank you!

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Have a look at the wikipedia article about cartographic hashes – Ulrich Dangel Jul 6 '11 at 22:37
@mru: Cartographic hash? You mean like for geohashing? – Nemo Jul 6 '11 at 22:40
@Nemo aeh typo, i can't edit my comment anymore. i meant cryptographic :/ at least the link is correct – Ulrich Dangel Jul 6 '11 at 22:43
Wait. I am unable to edit my own question? – Keavon Jul 7 '11 at 0:33

MD5 is designed to be cryptographically irreversible. In this case, the most important property is that it is computationally unfeasible to find the reverse of a hash, but it is easy to find the hash of any data. For example, let's think about just operating on numbers (binary files after all, could be interpreted as just a very long number).

Let's say we have the number "7", and we want to take the hash of it. Perhaps the first thing we try as our hash function is "multiply by two". As we'll see, this is not a very good hash function, but we'll try it, to illustrate a point. In this case, the hash of the number will be "14". That was pretty easy to calculate. But now, if we look at how hard it is to reverse it, we find that it is also just as easy! Given any hash, we can just divide it by two to get the original number! This is not a good hash, because the whole point of a hash is that it is much harder to calculate the inverse than it is to calculate the hash (this is the most important property in at least some contexts).

Now, let's try another hash. For this one, I'm going to have to introduce the idea of clock arithmetic. On a clock, there aren't an infinite amount of number. In fact, it just goes from 0 to 11 (remember, 0 and 12 are the same on a clock). So if you "add one" to 11, you just get zero. You can extend the ideas of multiplication, addition, and exponentiation to a clock. For example, 8+7=15, but 15 on a clock is really just 3! So on a clock, you would say 8+7=3! 6*6=36, but on a clock, 36=0! so 6*6=0! Now, for the concept of powers, you can do the same thing. 2^4=16, but 16 is just 4. So 2^4=4! Now, here's how it ties into hashing. How about we try the hash function f(x)=5^x, but with clock arithmetic. As you'll see, this leads to some interesting results. Let's try taking the hash of 7 as before.

We see that 5^7=78125 but on a clock, that's just 5 (if you do the math, you see that we've wrapped around the clock 6510 times). So we get f(7)=5. Now, the question is, if I told you that the hash of my number was 5, would you be able to figure out that my number was 7? Well, it's actually very hard to calculate the reverse of this function in the general case. People much smarter than me have proved that in certain cases, reversing this function is way harder than calculating it forward. (EDIT: Nemo has pointed out that this in fact has not been "proven"; in fact, the only guarantee you get is that a lot of smart people have tried a long time to find an easy way to do so, and none of them have succeeded.) The problem of reversing this operation is called the "Discrete Logarithm Problem". Look it up for more in depth coverage. This is at least the beginning of a good hash function.

With real world hash functions, the idea is basically the same: You find some function that is hard to reverse. People much smarter than me have engineered MD5 and other hashes to make them provably hard to reverse.

Now, perhaps earlier the thought has occurred to you: "it would be easy to calculate the inverse! I'd just take the hash of every number until I found the one that matched!" Now, for the case where the numbers are all less than twelve, this would be feasible. But for the analog of a real-world hash function, imagine all the numbers involved are huge. The idea is that it is still relatively easy to calculate the hash function for these large numbers, but to search through all possible inputs becomes harder much quicker. But what you've stumbled upon is the still a very important idea though: searching through the input space for an input which will give a matching output. Rainbow tables are a more complex variation on the idea, which use precomputed tables of input-output pairs in smart ways in order to make it possible to quickly search through a large number of possible inputs.

An attacker's best bet is a bruteforce attack, where they try a bunch of passwords. Just like you might try the numbers less that 12 in the previous problem, an attacker might try all the passwords just composed of numbers and letters less than 7 characters long, or all words which show up in the dictionary. The important thing here is that he can't try all possible passwords, because there are way too many possible 16 character passwords, for example, to ever test. So the point is that an attacker has to restrict the possible passwords he tests, otherwise he will never even check a small percentage of them.

So the basic mechanics of logging in remain unchanged, but for an attacker, they are now faced with a more daunting challenge: rather than a list of MD5 hashes, they are faced with a list of MD5 sums and salts. They essentially have two options:

1. They can ignore the fact that the hashes are salted, and try to crack the passwords with their lookup table as is. However, the chances that they'll actually crack a password are much reduced. For example, even if "shittypassword" is on their list of inputs to check, most likely "fa9elshittypassword" isn't. In order to get even a small percentage of the probability of cracking a password that they had before, they'll need to test orders of magnitude more possible passwords.

2. They can recalculate the hashes on a per-user basis. So rather than calculating MD5(passwordguess), for each user X, they calculate MD5( Salt_of_user_X + passwordguess). Not only does this force them to calculate a new hash for each user they want to crack, but also most importantly, it prevents them from being able to use precalculated tables (like rainbow table, for example), because they can't know what Salt_of_user_X is before hand, so they can't precalculate the hashes to test.

So basically, if they are trying to use precalculated tables, using a salt effectively greatly increases the possible inputs they have to test in order to crack the password, and even if they aren't using precalculated tables, it still slows them down by a factor of N, where N is the number of passwords you are storing.

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Think of 2 numbers from 1 to 9999. Add them. Now tell me the final digit.

I can't, from that information, deduce which numbers you originally thought of. That is a very simple example of a one-way hash.

Now, I can think of two numbers which give the same result, and this is where this simple example differs from a 'proper' cryptographic hash like MD5 or SHA1. With those algorithms, it should be computationally difficult to come up with an input which produces a specific hash.

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Wow, now I get it. That was a very good and simple way of putting it. THANK YOU! – Keavon Jul 6 '11 at 23:01

I don't think the md5 gives you the whole result - so you can't work backwards to find the original things that was md5-ed

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Even if it were 1-to-1, it would not necessarily be easy to invert. Consider taking the product of two large prime numbers, for instance... MD5 is hard to invert, but it has nothing to do with being many-to-one. – Nemo Jul 6 '11 at 22:39
Steve, that's a pretty simple way of saying it too. Thanks. – Keavon Jul 6 '11 at 23:03

One big reason you can't reverse the hash function is because data is lost.

Consider a simple example function: 'OR'. If you apply that to your input data of 1 and 0, it yields 1. But now, if you know the answer is '1', how do you back out the original data? You can't. It could have been 1,1 or maybe 0,1, or maybe 1,0.

As for salting and rainbow tables. Yes, theoretically, you could have a rainbow table which would encompass all possible salts and passwords, but practically, that's just too big. If you tried every possible combination of lower case letters, upper case, numbers, and twelve punctuation symbols, up to 50 characters long, that's (26+26+10+12)^50 = 2.9 x 10^93 different possibilities. That's more than the number of atoms in the visible universe.

The idea behind rainbow tables is to calculate the hash for a bunch of possible passwords in advance, and passwords are much shorter than 50 characters, so it's possible to do so. That's why you want to add a salt in front: if you add on '57sjflk43380h4ljs9flj4ay' to the front of the password. While someone may have already computed the hash for "pa55w0rd", no one will have already calculated the has for '57sjflk43380h4ljs9flj4aypa55w0rd'.

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 Wow, I see. I am used to seeing salts (for an MMO called Flyff I used to spend some time doing private server work with for fun) super short, like Flyff's was "kikugalanet" which is relativly short. But thanks for the tip on making long and totally random hashes. I'm still a little confused about the first part of the answer about how the data is lost. How does it match up the hashes if it's either of the two, a 1 or a 0? Thank you for the great answer though! – Keavon Jul 6 '11 at 22:59

md5 is 128bit, that's 3.4*10^38 combinations.

the total number of eight character length passwords:

• only lowercase characters and numbers: 36^8 = 2.8*10^12
• lower&uppercase and numbers: 62^8 = 2.18*10^14

You have to store 8 bytes for the password, 16 for the md5 value, that's 24 bytes total per entry.

So you need approx 67000G or 5200000G storage for your rainbow table. The only reason that it's actually possible to figure out passwords is because people use obvious ones.

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