The basic strategy is to hash some "salt" and the password. The salt and the hash result are stored in the database. When a user inputs a password, the salt and their input are hashed in the same way and compared to the stored value. If they match, the user is authenticated.
The devil is in the details. First, a lot depends on the hash algorithm that is chosen. A good hash algorithm makes it "computationally infeasible" to find an input (in this case, a password) that will produce a given output (what an attacker has found in the database). Hash algorithms are "broken" on a fairly regular basis, in the sense that a shortcut is discovered to invert the hash algorithm.
There are two approaches to breaking password tables. The first, a dictionary attack, is preferred by attackers, because its faster, but the second, brute force is the only viable option if you use the correct system.
A dictionary attack is where the attack has a pre-computed map, or dictionary, from hash outputs to passwords. Hashing is slow (or it's supposed to be, anyway), so he hashes all of the likely passwords once, and stores the result indexed in such a way that given a hash, he can lookup a corresponding password. This is a classic tradeoff of space for time. Since password lists can be huge, there are ways to tune the tradeoff (like rainbow tables), so that an attacker can give up a little speed to save a lot of space.
Dictionary attacks are entirely preventable by using "cryptographic salt". This is some data that is hashed with the password. It doesn't need to be a secret, it just needs to be unpredictable for a given password. For each value of salt, an attacker would need a new dictionary. If you use one byte of salt, an attacker needs 256 copies of their dictionary, each generated with a different salt. First, he'd use the salt to lookup the correct dictionary, then he'd use the hash output to look up a usable password. But what if you add 4 bytes? Now he needs 4 billion copies of the the dictionary. By using a large enough salt, a dictionary attack is precluded. In practice, 8 to 16 bytes of data from a cryptographic quality random number generator makes a good salt.
With dictionary attacks off the table, an attacker has to fall back to brute force: hashing every password in his list with the particular salt. How long it takes to find a password now depends entirely on how long it takes to hash a candidate. So, it's important to pick a hash algorithm that is slow, and doesn't have any mathematical loopholes that allow an attacker to take a shortcut.
One round of any common hash algorithm is too fast. To make things slower, there are two accepted approaches. One is to use bcrypt, which actually uses an encryption algorithm with a key generation process that can be parameterized to take as long as you want (after encryption of the password, the encryption key is discarded, providing the effective irreversibility of a traditional hash). The other, more common approach is to use many rounds of a good hash algorithm. You can benchmark hash algorithms to see how long a round takes, but in general, on the order of 1000 rounds is fast enough that legitimate users won't notice a delay during login—but an attacker needs 1000 times the processing power to find a break in a given time.
In practice, I use 8 bytes of salt from a cryptographic RNG, followed by 1024 rounds of SHA1. Slightly paranoid, I'm considering an upgrade to a bcrypt implementation.