# Can a deterministic hashing function be easily decrypted? [duplicate]

Possible Duplicates:
Is it possible to decrypt md5 hashes?
Is it possible to reverse a sha1?

and got a great answer and i followed the advice. i used this: http://splinter.com.au/blog/?p=86

and i hashed about 300,000 different elements in a column in an excel spreadsheet

since you can do:

``````=SHA1HASH('The quick brown fox jumps over the lazy dog')
``````

And you'd get back:

``````2fd4e1c67a2d28fced849ee1bb76e7391b93eb12
``````

couldnt you go backwards as well?

im saying if it encrypts the same text the same way every single time, what is the point?

if you do know the hash algorithm, is it possible to go backwards?

can you please explain to me very simply how does hashing work? how can you convert a 20gb to a 40 character hash? does it take a long time to hash a 20gb hardrive?

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A better title to this question would be "Can a hash easily be decrypted?" –  matt b Jun 30 '10 at 20:48
Who told you can go backwards? –  KennyTM Jun 30 '10 at 20:49
Did you try to go backward? Have you found a function which actually does go backward? –  S.Lott Jun 30 '10 at 20:49
can you reverse entropy? –  herzmeister Jun 30 '10 at 20:51
For simple hashes idea is to map very wide range of values to some small amount with a good distribution. For cryptographic hashes idea s to make it hard to find values hits for hash. –  ony Jun 30 '10 at 20:53

## marked as duplicate by gnovice, bmargulies, Roger Pate, redsquare, interjayJul 2 '10 at 23:00

I see your point based on the fact that you are trying to hide Social security numbers. If someone knows you are using an SHA1HASH on the SSN to create a unique identifier, then can just generate a quick list of all SSN numbers, SHA1HASH them, then compare to automatically have the SSN of the person in the record. Even worse, they can pregenerate all these in a hash lookup table, and have a key of 1 hash for every SSN. This is called a hash lookup table, and more complex forms are called rainbow tables.

This is why a second feature of hashing was invented. It is called salting. Salting is basically this; you create a salt, then modify your data using the salt. For instance, say you had the SSN 123-45-6789 . You could salt it with the string "MOONBEAM". Your new string for hashing is "123-45-6789MOONBEAM"

Now, even if someone knows that you are hashing the SSN to generate your unique ID, they still don't know the salt you will be using, and so are unable to derive the original SSN by pre-hashing a list of all SSNs and comparing to your ID. You however, can always take the user's SSN, use the salt, and rehash the SSN+SALT to see if the user SSN matches up with their ID.

Finally, if you use just 1 salt for everything, and keep it secret, instead of being able to see the salt, and generate the corresponding SSN by running SSN increments + salt 100 million times and picking the match, they have to do a lot more work to retrieve SSN. This is because the 100 million SSN numbers have a relatively low amount of entropy. (10^9 combinations). By adding your salt and keeping it secret, instead of just running

``````SHA1HASH(111-11-1111) -> check hash match
SHA1HASH(111-11-1112) -> check hash match
SHA1HASH(111-11-1113) -> check hash match
``````

They would have to run

``````SHA1HASH(111-11-1111a) -> check hash match
SHA1HASH(111-11-1111b) -> check hash match
SHA1HASH(111-11-1111c) -> check hash match
...
SHA1HASH(111-11-1111azdfg) -> check hash match
SHA1HASH(111-11-1111azdfh) -> check hash match
....
SHA1HASH(111-11-1111zzzzzzzzzzzzzzzz) -> check hash match
SHA1HASH(111-11-1112a) -> check hash match
SHA1HASH(111-11-1112b) -> check hash match
``````

.. and so on until they finally get to

``````SHA1HASH(123-45-6789MOONBEAM) -> check hash match
``````

at which point they finally did manage to crack the SSN + SALT

They don't even know how many characters long your salt is So that is 10^(number of characters of your salt) times more work for them to do just to get 1 SSN, let alone get the whole table.

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A salt is not a secret! Salts should be appended to the hashed value, and serve to prevent precomputation for dictionary attacks. What you are referring to is more like an HMAC - in which case you should use a proper HMAC rather than this ad-hoc scheme. –  Nick Johnson Jun 30 '10 at 21:45
A possible attack on storing H(SSN || salt): If the attacker registers themselves (or someone else, or a fictitious SSN) into the system they can probably find the row corresponding to their registration and the hash of their SSN. Since they already know their own SSN so they can use this informatin to brute force the salt (MOONBEAM). Once they know the salt they can get the other SSNs relatively easily. –  Mark Byers Jun 30 '10 at 22:37
@Zak A secret salt is just a poorly implemented HMAC. Salts are always stored alongside the hash. @Mark Salts, used properly, are generated randomly for each stored value - the salt on one entry bears no relationship to the salt on another. –  Nick Johnson Jul 1 '10 at 8:36
@Nick Johnson: Unless you are talking about non-secret salts as they are traditionally used, in which case we are talking about two completely different things... maybe I didn't make that clear enough? I am replying to the answer and in particular to this part: "they still don't know the salt you will be using". In my opinion this answer is flawed and I was demonstrating an attack on it. If you want to propose a different scheme I suggest you post it as a separate answer so I can comment on your scheme there and not here and so that the two different schemes are not confused. –  Mark Byers Jul 1 '10 at 19:06
@Mark If storing a meaningless identifier for each user were sufficient, then I doubt the OP would be asking about hashing SSNs in the first place. Presumably they have a compelling reason why they have to store a hash of the SSN. As I already said, a "secret salt" is not a salt - it's a poorly implemented HMAC. As to knowing the salt - the salt becomes part of the hashed value - HASH(value + salt) + salt. This is pretty basic crypto. –  Nick Johnson Jul 1 '10 at 19:25

A cryptographic hash function cannot be easily reversed. This is why it is also sometimes called a one-way function. There is no going back.

You should also be careful about calling this 'decryption'. Hashing is not the same as encryption. The set of possible hash value is typically smaller than set of possible inputs so multiple inputs map to the same output.

For any hash function given the output you can't know which of the many inputs was used to generate this particular output.

For cryptographic hashes like SHA1 it is very difficult to even find one input that produces that output.

The simplest way to reverse a cryptographic hash is to guess the input and hash it to see if it gives the right output. If you are wrong, guess again. Another approach is to use rainbow tables.

Regarding using hashing to encrypt SSNs

With your use case of SSNs an attack is feasible due to the relatively small number of possible input values. If you are worried about people getting access to SSNs then it might be best to not store or use the SSN at all in your application, and in particular do not use them as an identifier. Instead you could find or create another identifier, for example an email address, a login name, a GUID or just an incrementing number. It can be tempting to use the SSN as it is already there and at first glance appears to be a unique unchanging identifier, but in practice using it just causes problems. If you absolutely need to store it for some reason then use strong non-deterministic encryption with a secret key and make sure you keep that key safe.

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No, not possible with a hash algorithm. –  blockhead Jun 30 '10 at 20:50
+1, once you go black there is no going back –  VoodooChild Jun 30 '10 at 20:51
@Zak that's assuming you know that the target here is a SSN –  blockhead Jun 30 '10 at 21:00
@user Rainbow tables are a bit too complex to give a complete tutorial on in a SO answer (but the Internet has plenty of info on them, so do a search). The general idea is that you pre-compute hashes for a whole bunch of candidate plaintexts and then use a clever means of doing a reverse lookup to find which plaintext corresponds to a given hash. This technique, however, is easily defeated by "salting" the plaintexts (modifying each of them in a unique yet deterministic way, before hashing). –  Tyler McHenry Jun 30 '10 at 21:05
@Zak Salting alone will not suffice for a small domain such as SSNs. It'll make life more difficult by requiring the attacker to brute-force each one separately, but the domain is still small enough a brute-force attack is practical. –  Nick Johnson Jun 30 '10 at 21:43

The whole point of a cryptographic hash is that you can't decrypt it and that it does encrypt the same way every time.

Another common use of cryptographic hashes is integrity checking. Suppose a given file (e.g. an image of a Linux distribution CD) has a known, publicly available cryptographic hash. If you have a file which purports to be the same thing, you can hash it yourself and see if the hashes match. Here, the fact that it hashes the same way every time allows you to independently validate it, and the fact that it is cryptographically secure means that no one can feasibly create a different, fake file (e.g. with a trojan in it) that has the same hash.

Keep in mind the very important distinction between hashing and encryption, though: hashing loses information. This is why you can't go backwards (decrypt) the hash. You can hash a 20 GiB file and end up with a 40-some character hash. Obviously, this has lost a lot of information in the process. How could you possibly "decrypt" 40-some characters into 20GiB? There's no such thing as compression that works that well! But this is also an advantage, because in order to check the integrity of a 20 GiB file, you only have to distribute a 40-some character hash.

Because information is lost, many files will have the same hash, but the key feature of a cryptographic hash (which is what you're talking about) is that despite the fact that information is lost, it is computationally infeasible to start with a file and construct a second, slightly different file that has the same hash. Any other file with the same hash would be radically different, and not easily mistakable for the original file.

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this is a great answer! thank you. if you do know the hash algorithm, is it possible to go backwards? –  Артём Царионов Jun 30 '10 at 20:51
No, you can't go backwards, that's the whole point. The reason is because hashing loses information. I edited that into my answer. –  Tyler McHenry Jun 30 '10 at 20:53
+1 for "hashing loses information", that's why you can't go back! –  FrustratedWithFormsDesigner Jun 30 '10 at 21:00
@user29823498750932874509823745- You can't "go backwards" in the sense of inverting the mathematical formula, applying your hash, and re-generating your original input. You can, however, create a table of all possible inputs, run them through the hash function, and store the input + hash result in a table. Use this table to reverse-lookup what possible inputs could have generated this output. As Tyler mentioned, several different inputs will give you the same output. Even if you had the time/storage to generate such a table, you would still have a number of possible inputs to choose from. –  bta Jun 30 '10 at 21:10
The user is targeting SSN numbers though. Everyone here should be reminding him to salt his hashes.. –  Zak Jun 30 '10 at 21:23

No, you cannot go backwards because not enough information is preserved by the hashing function.

You can think of it as the hash function mapping the original text to a single, huge, number. This same number may also be mapped to other texts as well, although a good hash function will have few collisions:

If the original message were encrypted then yes, you could go back.

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Encrypting and hashing are two different things.

Hashing simply digests the string into a number. Encryption preserves the contents of the string so that it can later be decrypted. There is no method from getting the original string from a hash. The contents are just not there.

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'xept if you got all the strings that matched the hash, then browsed through them. –  vlad-ardelean Dec 28 '12 at 18:11
I'm no math man but wouldn't that be infinity strings? –  BC. Jan 9 at 23:58

No. The point of a hash is that it's one way encryption (as other's have pointed out, its not really "encryption", but stay with me here). The downside is the, in theory, there is a small possibilities of "collisions", when two or more string return the same hash. But it's usually worth this downside.

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A good hash is one way, meaning you shouldn't be able to go backwards. The point is to provide a key of a string without revealing the string. For instance, this is a good way to match passwords without storing a password. Instead, you store a hash and compare the resultant hash of inputs.

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if you do know the hash algorithm, is it possible to go backwards? –  Артём Царионов Jun 30 '10 at 20:50
Possibly, but many are designed to make this very difficult. Some algorithms generate the same hash for different inputs, and many, if not all, rely on the length of the input. You need to know a lot about the data being hashed to go back to it. –  SB. Jun 30 '10 at 20:58
This is the difference between a "normal" hash function, like you'd use in a python map or java.util.HashMap and cryptographic hash function like SHA1. Normal hash functions are mostly optimized for spreading out bits in the input (coverage over the whole range of hash output) and efficiency. A cryptographic hash also adds the non-reversible constraint, with efficiency as a second-order constraint. –  Paul Rubel Jun 30 '10 at 21:48

No. At least not easily.

SHA1 is still considered cryptographically secure. A hash algorithm is secure if it is easy to compute one way, but very hard (exhaustive search) to compute the other way. It is true that every time you encrypt a specific phrase, it will result in the same hash, but there are infinite phrases that will also hash to that same value. The security comes from not knowing what those other phrases are until you run them all through the SHA1 function.

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No, you cannot go back. Count how many different hashes you can have. Now count how many different strings you can have. The first is finite, the second is infinite. There are lots of (infinitely many, to be precise) strings which have the same SHA1 sum. The point is, however, it's very hard to find two texts, which have the same hash.

You can think of hashing as shortening something. For example take a hashing function which sums all the ASCII codes of the letters in a string. You can't tell what was before hashing, just knowing the sum of ASCII codes of the letters. It is similar with SHA1, but more complicated.

The point of hashing is not to encrypt something. The point of hashing is to shorten something, so that checking whether two things are the same takes less time. Now how can you tell that two things are indeed the same if you know that lots of things have the same hash? Well, you can't. You just assume that it's so rare that it won't happen.

But hashing is not just about checking, as checking equality using hashes is usually used just for confirmation/validation and it is not deterministic. If you see that hashes are the same, then basing on the parameters of a particular hashing function, you can estimate the probability that the hashed objects are indeed the same.

And that's why the fact that a hashing function always yields the same results for the same objects is the most important feature of a hashing function. It lets you validate and compare objects.

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