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Is it possible to reverse a sha1?

I'm thinking about using a sha1 to create a simple lightweight system to authenticate a small embedded system that communicates over a unencrypted connection.

Let's say that I create a sha1 like this with input from a "secret key" and spice it with a timestamp so that the sha will change all the time.

sha1("My Secret Key"+"a timestamp")

Then I include this sha1 in the communication and the server, that can do the same calculation. And hopefully nobody would be able to figure out the "secret key".

But is this really true?

If you know that this is how I did it, you would know that I did put a timestamp in there and you would see the sha1. Can you then use those two and figure out the "secret key"?

secret_key = bruteforce_sha1(sha1, timestamp)

Thanks Johan


Note1: I guess you could brute force in some way, but how much work would that actually be?

Note2: I don't plan to encrypt any data, I just would like to know who sent it.

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11  
Resembles reversing a pie. Even if you know how much eggs has the baker put in it the best you can do is trying to bake exactly the same pie :). –  Li0liQ Feb 10 '10 at 7:34
    
Cryptographic systems are almost always implemented incorrectly. / If the space of possible plain text is sufficiently small then it is feasible to run through all reasonable combinations. A few years ago on a single core workstation, I ran through 32-bits worth of MD5 in about an hour of brute force (using a trivial Java program). –  Tom Hawtin - tackline Feb 10 '10 at 9:55
    
how do you know that server and client have the exact same time so the server can reproduce a client-created hash? –  Karsten Feb 12 '10 at 22:55
    
@Karsten: client-timestamp needs to be transmitted as part of the message –  Thilo Feb 13 '10 at 1:10
    
Both will probably use some kind of time sync like ntp. –  Johan Feb 13 '10 at 7:41

6 Answers 6

up vote 24 down vote accepted

No, you cannot reverse SHA-1, that is exactly why it is called a Secure Hash Algorithm.

What you should definitely be doing though, is include the message that is being transmitted into the hash calculation. Otherwise a man-in-the-middle could intercept the message, and use the signature (which only contains the sender's key and the timestamp) to attach it to a fake message (where it would still be valid).

And you should probably be using SHA-256 for new systems now.

sha("My Secret Key"+"a timestamp" + the whole message to be signed)

You also need to additionally transmit the timestamp in the clear, because otherwise you have no way to verify the digest (other than trying a lot of plausible timestamps).

If a brute force attack is feasible depends on the length of your secret key.

The security of your whole system would rely on this shared secret (because both sender and receiver need to know, but no one else). An attacker would try to go after the key (either but brute-force guessing or by trying to get it from your device) rather than trying to break SHA-1.

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4  
You definitely can find collisions for SHA-1, it just isn't a very fast process. –  Piskvor Feb 10 '10 at 7:39
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okay, retracted ;-) –  Thilo Feb 10 '10 at 7:51
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rather than hashing like this, you should use HMAC which was written for this purpose and guards against various attacks that this approach above is vulnerable to. Well, vulnerable if you are the NSA or China, that is. –  Will Feb 10 '10 at 10:13
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I have a smaller embedded system in mind, so let's see how far the resources go :) –  Johan Feb 10 '10 at 11:50
    
You'll have to send the timestamp and the message along with the hash, and you'll be exposed to extension attacks and timestamp collisions and such. –  Will Feb 10 '10 at 12:06

SHA-1 is a hash function that was designed to make it impractically difficult to reverse the operation. Such hash functions are often called one-way functions or cryptographic hash functions for this reason.

However SHA-1 has some recently discovered weaknesses that allow finding an input faster than by doing a brute force search of all inputs. You should consider using something stronger like SHA-256 for new applications.

Jon Callas on SHA-1:

It's time to walk, but not run, to the fire exits. You don't see smoke, but the fire alarms have gone off.

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Good that you warn, but does it answer the question at all? –  Will Feb 10 '10 at 8:14
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"impractically difficult to reverse" seems to answer it. –  Thilo Feb 10 '10 at 8:21
    
good sha1 information, but did not really answer my question. –  Johan Feb 10 '10 at 9:26

The question is actually how to authenticate over an insecure session.

The standard why to do this is to use a message digest, e.g. HMAC.

You send the message plaintext as well as an accompanying hash of that message where your secret has been mixed in.

So instead of your:

sha1("My Secret Key"+"a timestamp")

You have:

msg,hmac("My Secret Key",sha(msg+msg_sequence_id))

The message sequence id is a simple counter to keep track by both parties to the number of messages they have exchanged in this 'session' - this prevents an attacker from simply replaying previous-seen messages.

This the industry standard and secure way of authenticating messages, whether they are encrypted or not.


(this is why you can't brute the hash:)

A hash is a one-way function, meaning that many inputs all produce the same output.

As you know the secret, and you can make a sensible guess as to the range of the timestamp, then you could iterate over all those timestamps, compute the hash and compare it.

Of course two or more timestamps within the range you examine might 'collide' i.e. although the timestamps are different, they generate the same hash.

So there is, fundamentally, no way to reverse the hash with any certainty.

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So this could work, and be fairly secure. –  Johan Feb 10 '10 at 9:23
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@Johan "fairly secure" is rather understating it. "Secure" is more accurate. –  Will Feb 10 '10 at 10:10
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Nice, and +1 for the HMAC :) –  Johan Feb 10 '10 at 11:55

In mathematical terms, only bijective functions have an inverse function. But hash functions are not injective as there are multiple input values that result in the same output value (collision).

So, no, hash functions can not be reversed. But you can look for such collisions.


Edit

As you want to authenticate the communication between your systems, I would suggest to use HMAC. This construct to calculate message authenticate codes can use different hash functions. You can use SHA-1, SHA-256 or whatever hash function you want.

And to authenticate the response to a specific request, I would send a nonce along with the request that needs to be used as salt to authenticate the response.

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What’s the reason for the down vote? –  Gumbo Feb 10 '10 at 7:32
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I did not find it very compelling and wanted to see Mark's answer on top (at the time, they both had the same score). Just saying that only bijective functions can be reversed is not very helpful here. You could say the same thing for calculating x mod 4. Not bijective, but not secure, either. –  Thilo Feb 10 '10 at 7:47
    
can you answer your email please :) –  Jeff Atwood Feb 10 '10 at 9:23

Hashes are dependent on the input, and for the same input will give the same output.

So, in addition to the other answers, please keep the following in mind:

If you start the hash with the password, it is possible to pre-compute rainbow tables, and quickly add plausible timestamp values, which is much harder if you start with the timestamp.

So, rather than use sha1("My Secret Key"+"a timestamp")

go for sha1("a timestamp"+"My Secret Key")

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Note that the best attacks against MD5 and SHA-1 have been about finding any two arbitrary messages m1 and m2 where h(m1) = h(m2) or finding m2 such that h(m1) = h(m2) and m1 != m2. Finding m1, given h(m1) is still computationally infeasible.

Also, you are using a MAC (message authentication code), so an attacker can't forget a message without knowing secret with one caveat - the general MAC construction that you used is susceptible to length extension attack - an attacker can in some circumstances forge a message m2|m3, h(secret, m2|m3) given m2, h(secret, m2). This is not an issue with just timestamp but it is an issue when you compute MAC over messages of arbitrary length. You could append the secret to timestamp instead of pre-pending but in general you are better off using HMAC with SHA1 digest (HMAC is just construction and can use MD5 or SHA as digest algorithms).

Finally, you are signing just the timestamp and the not the full request. An active attacker can easily attack the system especially if you have no replay protection (although even with replay protection, this flaw exists). For example, I can capture timestamp, HMAC(timestamp with secret) from one message and then use it in my own message and the server will accept it.

Best to send message, HMAC(message) with sufficiently long secret. The server can be assured of the integrity of the message and authenticity of the client.

You can depending on your threat scenario either add replay protection or note that it is not necessary since a message when replayed in entirety does not cause any problems.

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