**Practical answer:** no. If the hash function you use is any good, then it is supposed to look like a Random Oracle, the output of which on an exact given input being totally unknown until that input is tried. So you cannot infer anything from the hashes you compute until you hit the exact input ordering that you are looking for. (Strictly speaking, there *could* exist a hash function which has the usual properties of a hash function, namely collision and preimage resistances, without being a random oracle, but departing from the RO model is still considered as a hash function weakness.)(Still strictly speaking, it is slightly improper to talk about a random oracle for a single, unkeyed function.)

**Theoretical answer:** it depends. Assuming, for simplicity, that you have *N* chunks of 512 bits, then you can arrange for the cost not to exceed *N*2*^{160} elementary evaluations of SHA-1, which is lower than *N!* when *N >= 42*. The idea is that the running state of SHA-1, between two successive blocks, is limited to 160 bits. Of course, that cost is ridiculously infeasible anyway. More generally, your problem is about finding a preimage to SHA-1 with inputs in a custom set *S* (the *N!* sequences of your *N* chunks) so the cost has a lower bound of the size of *S* and the preimage resistance of SHA-1, whichever is lower. The size of *S* is *N!*, which grows very fast when *N* is increased. SHA-1 has no known weakness with regards to preimages, so its resistance is still assumed to be about *2*^{160} (since it has a 160-bit output).

**Edit:** this kind of question would be appropriate on the proposed "cryptography" stack exchange, when (if) it is instantiated. Please commit to help create it !