To be precise, there are three "attacks" that can be performed on a hash function *h*:

**Preimages**: given an "output" *y* (a sequence of bits of the right size, e.g. 128 bits for MD5), find a message *m* (an arbitrary sequence of bits) such that *h(m) = y*.

**Second preimage**: given a message *m*, find another message *m'*, distinct from *m*, such that *h(m) = h(m')*.

**Collision**: find two messages *m* and *m'*, distinct from each other, such that *h(m) = h(m')*.

A good hash function is a function which resists those three attacks as best as can possibly done. What is that best ? It depends on the hash output size *n*.

Consider a theoretically perfect hash function, consisting in a black box; in the box are a gnome, some dice, and a big book. When asked for a hash value, for a given input message, the gnome uses the dice to generate a random output, which he gives back. But he also writes the message and the output in his big book. If he is asked for the hash of the same message again, then he will return the same value as previously. This setup is what theoreticians call a *random oracle*. The random oracle never contradicts itself, but you cannot know anything on what it will answer on a given question (and input message) until that precise question has been asked to him.

If the random oracle outputs strings of length *n* bits, then one can find preimages and second preimages in time *O(2*^{n}), and collisions in time *O(2*^{n/2}). The time is expressed here in terms of requests to the random oracle. The resistance on preimages is easy to understand: the attacker simply tries messages until, by pure luck, the oracle outputs the expected value; he cannot do better since even the gnome does not know anything about what he will get for any new input. Due to the uniformly random nature of the oracle, the expected number of trials is *2*^{n}. Resistance to second preimages flows along the same lines. For collisions, this is related to what is known as the birthday paradox.

A hash function is then deemed secure if its resistances appear to match those of the random oracle. It cannot do better; we require that it does not fare worse either.

A hash function is then said to be "broken" when someone came up with a method for finding preimages, second preimages or collisions with a success rate higher than the generic methods which work on a random oracle. SHA-1 is said to be broken because a method for finding collisions, with cost about *2*^{61}, was found (SHA-1 has a 160-bit output, and thus should resist collisions up to work factor about *2*^{80}). Note that the full method was not run, i.e. we do not have an actual collision. *2*^{61} is still very high, on the fringes of the doable (it would require several thousands of machines, running of several months or years). But *2*^{61} if half a million times smaller than *2*^{80}, so that is a break.

Sometimes, "breaks" are found for which the attack is ludicrously expensive (e.g. an attack in cost *2*^{112} for a theoretical resistance of *2*^{168}). We then talk about an "academic" break: faster than the expected resistance, but still fully undoable with earth-based technology.

Note that not all usages of hash functions rely on resistance to collisions. Actually, most usages rely on resistance to preimages or second preimages. For those attacks, SHA-1 is currently as good as new, with its *2*^{160} resistance.

Conversely, even a perfect hash function with a 128-bit output should be considered as weak, at least for collision resistance: the generic attack, with a work factor of *2*^{64}, is within the realm of the technologically feasible. This is why newer hash standards use larger outputs (e.g. SHA-2 begins at 224 bits of output). A large enough output defeats generic attacks.