Is the keylen that we provide the variation of the the SHA we want? like SHA-256,512 etc?

As you state you're hashing a password in particular, @CodesInChaos is right - keylen (i.e. the length of the output from PBKDF2) would be at most the number of bits of your HMAC's native hash function.

- For SHA-1, that's 160 bits (20 bytes)
- For SHA-256, that's 256 bits (32 bytes), etc.
- The reason for this is that if you ask for a longer hash (keylen) than the hash function supports, the first native length is identical, so an attacker only needs to attack bits. This is the problem 1Password found and fixed when the Hashcat team found it.

Example as a proof:

Here's 22 bytes worth of PBKDF2-HMAC-SHA-1 - that's one native hash size + 2 more bytes (taking a total of 8192 iterations! - the first 4096 iterations generate the first 20 bytes, then we do another 4096 iterations for the set after that!):

- pbkdf2 sha1 "password" "salt" 4096 22
- 4b007901b765489abead49d926f721d065a429c12e46

And here's just getting the first 20 bytes of PBKDF2-HMAC-SHA-1 - i.e. exactly one native hash output size (taking a total of 4096 iterations)

- pbkdf2 sha1 "password" "salt" 4096 20
- 4b007901b765489abead49d926f721d065a429c1

Even if you store 22 bytes of PBKDF2-HMAC-SHA-1, an attacker only needs to compute 20 bytes... which takes about half the time, as to get bytes 21 and 22, another entire set of HMAC values is calculated and then only 2 bytes are kept.

- Yes, you're correct; 21 bytes takes twice the time 20 does for PBKDF2-HMAC-SHA-1, and 40 bytes takes just as long as 21 bytes in practical terms. 41 bytes, however, takes three times as long as 20 bytes, since 41/20 is between 2 and 3, exclusive.

Also how does HMAC change the output?

HMAC RFC2104 is a way of keying hash functions, particularly those with weaknesses when you simply concatenate key and text together. HMAC-SHA-1 is SHA-1 used in an HMAC; HMAC-SHA-512 is SHA-512 used in an HMAC.

And lastly is it strong enough when SHA1 is broken?

If you have enough iterations (upper tens of thousands to lower hundreds of thousands or more in 2014) then it should be all right. PBKDF2-HMAC-SHA-512 in particular has an advantage that it does much worse on current graphics cards (i.e. many attackers) than it does on current CPU's (i.e. most defenders).

For the gold standard, see the answer @ThomasPornin gave in Is SHA-1 secure for password storage?, a tiny part of which is "The known attacks on MD4, MD5 and SHA-1 are about collisions, which do not impact preimage resistance. It has been shown that MD4 has a few weaknesses which can be (only theoretically) exploited when trying to break HMAC/MD4, but this does not apply to your problem. The 2106 second preimage attack in the paper by Kesley and Schneier is a generic trade-off which applies only to very long inputs (260 bytes; that's a million terabytes -- notice how 106+60 exceeds 160; that's where you see that the trade-off has nothing magic in it)."