Let's take a step back. First off, what do we mean by
H(k|m)? And what is this for?
The goal here is as follows. Alice and Bob share a secret key. How they share it, we don't know. Somehow Alice and Bob have agreed upon a secret key, and no one else knows it.
Alice wishes to send a message to Bob. Alice does not care if anyone can read the message, but Alice cares very much that Bob knows that Alice wrote the message.
They come up with the following scheme. Alice will create a message that consists of the secret key followed by the rest of the message. She will then hash the whole thing. She then transmits the message without the secret key to Bob, along with the hash.
Bob attempts to verify that the message came from Alice. He puts the secret key in front of the message and hashes it. If Bob gets the same hash out, then Bob knows that whomever made the message possessed the secret key. He knows it wasn't him, so it must have been Alice.
This scheme is not secure. Mallory wishes to send a false message to Bob and trick him into thinking it is from Alice.
One day Alice takes her secret key "123SesameStreet" and a message "Dear Bob, I love you!", and she appends them together to "123SesameStreetDear Bob, I love you!" She hashes that to "398942358092" and sends the hash and the message "Dear Bob, I love you!" to Bob.
Mallory intercepts the message before it gets to Bob. Mallory does not know the secret key, but she does know the message and the hash. Mallory sets up the SHA1 algorithm to have the state 398942358092, and then runs the characters "Just kidding I hate you!", and gets a hash out of 92358023934. Now Mallory sends the new hash and the message "Dear Bob, I love you!Just kidding I hate you!" to Bob.
How precisely does this work? Here's the deal. Basically, SHA1 works like this oversimplified sketch:
int hash = 0;
foreach(char c in message)
hash = MakeNextHash(hash, c);
That is, you start with zero. Then you hash the first character and the number 0. Then you hash that hash with the second character. That makes a new hash. Then you hash that with the third character, to make a third hash. Keep doing that until you run out of characters; the last hash you made is the hash of the whole message.
The real SHA1 algorithm uses blocks larger than a single character and state larger than an int, but basically that's how it goes. It transforms a bunch of state one block at a time, using the previous state as the input for the next state.
So if I tell you "Here's a string M. Also, the string KM has hash H(K|M)." then obviously you can work out the hash H(K|M|Z) of KMZ for any Z, even if you don't know K. You just say:
int hash = HKM;
foreach(char c in Z)
hash = MakeNextHash(hash, c);
and the result is H(K|M|Z), even though you don't know K.
So, you see how this goes. Bob prepends the secret key to the message and runs it through the SHA1 algorithm, and he gets back the right hash. So he has verified that the message is from Alice, when really half the message is from Mallory.
That's why the key has to go last. You have to put the key after the message, not before. You'd think. Turns out that though the attack is now not trivial as it is with the key-first scheme, it is still not safe. The
H(m|k) scheme is also no good.
Suppose Mallory has intercepted a message M and a hash H which is H(M|K), where K is the secret key. She prevents the message from arriving.
Mallory computes H(M), easily enough. The hard part is that Mallory deduces a damaging message N such that H(N) = H(M). How she does that, we do not yet know, but it is widely believed that such a technique exists, we just have not found it yet.
Mallory knows that H(N|K) is the same as H(M|K), by the same reasoning as before -- because to compute H(N|K) we're going to do:
int hash = HN;
foreach(char c in key)
to work out H(N|K). Mallory needs not know K in order to make a message N such that H(N|K) is H(M|K).
So now Mallory sends N and H(M|K) / H(N|K) -- they are the same thing -- to Bob. Bob appends K to N, and verifies that the message came from Alice, when in fact it came from Mallory.
It gets worse. Suppose Mallory has captured a million messages M1, M2, ... and a million hashes H(M1|K), H(M2|K), ... that have passed between Alice and Bob. Mallory needs to craft a message N such that H(N) matches any of H(M1), H(M2), H(M3), ... Her job just got a million times easier. She finds such a message N such that H(N) matches, say, H(M1234), and then sends N and H(M1234|K) to Bob. Bob fails to notice that he's seen that hash before, and believes that this is a message from Alice.
It gets worse. Let's change up the scheme a little to see how it gets worse. Carol has a message that she would like to send to Bob via Alice. The message M is "Hey Bob, this is Carol. Let's you and me and Alice all have lunch together next week. If Alice agrees she will send you this message with her authenticator." Carol does not know the secret key K, but Alice does. Alice agrees with the message M, so she computes H(M|K) and sends M and H(M|K) to Bob.
Now Mallory wants to cause trouble, so she searches for two messages B (for benign) and D (for dangerous) such that H(B) is equal to H(D), and such that Alice will agree with B but will not agree with D. This is much easier than searching for a message N which matches a given message from Alice because now Mallory gets to choose both messages. The job of finding a collision is orders of magnitude easier.
Mallory finds those two messages and sends B to Alice. Alice agrees with the message, computes H(B|K), and sends H(B|K) and B to Bob. Mallory intercepts the message B and replaces it with D. H(B|K) and H(D|K) are the same by the same reasoning as before. Bob receives message D and verifies that H(D|K) matches the hash he was sent, so he knows that Alice approved of the message, even though she did not.
No one has yet found a way to make SHA1 reliably produce collisions like that, but just about everyone believes that we will solve this problem.
The first moral of the story is do not use either of these techniques as a message verifier. The first is trivially broken, and the second will likely be broken in our lifetime.
The second moral is never allow a potential attacker to choose the message that you are going to process with your secret key.