TDD does permit you to use common sense if you want to. There's no point defining your version of TDD to be stupid, just so that you can say "we're not doing TDD, we're doing something less stupid".
You can write a single test case that calls the function under test more than once, passing in different arguments. This prevents "write code to factorize 1", "write code to factorize 2", "write code to factorize 3" being separate development tasks.
How many distinct values to test really depends how much time you have to run the tests. You want to test anything that might be a corner case (so in the case of factorization at least 0, 1, 2, 3,
LONG_MAX+1 since it has the most factors, whichever value has the most distinct factors, a Carmichael number, and a few perfect squares with various numbers of prime factors) plus as big a range of values as you can in the hope of covering something that you didn't realise was a corner case, but is. This may well mean writing the test, then writing the function, then adjusting the size of the range based on its observed performance.
You're also allowed to read the function specification, and implement the function as if more values are tested than actually will be. This doesn't really contradict "only implement what's tested", it just acknowledges that there isn't enough time before ship date to run all 2^64 possible inputs, and so the actual test is a representative sample of the "logical" test that you'd run if you had time. You can still code to what you want to test, rather than what you actually have time to test.
You could even test randomly-selected inputs (common as part of "fuzzing" by security analysts), if you find that your programmers (i.e. yourself) are determined to be perverse, and keep writing code that only solves the inputs tested, and no others. Obviously there are issues around the repeatability of random tests, so use a PRNG and log the seed. You see a similar thing with competition programming, online judge programs, and the like, to prevent cheating. The programmer doesn't know exactly which inputs will be tested, so must attempt to write code that solves all possible inputs. Since you can't keep secrets from yourself, random input does the same job. In real life programmers using TDD don't cheat on purpose, but might cheat accidentally because the same person writes the test and the code. Funnily enough, the tests then miss the same difficult corner cases that the code does.
The problem is even more obvious with a function that takes a string input, there are far more than
2^64 possible test values. Choosing the best ones, that is to say ones the programmer is most likely to get wrong, is at best an inexact science.
You can also let the tester cheat, moving beyond TDD. First write the test, then write the code to pass the test, then go back and write more white box tests, that (a) include values that look like they might be edge cases in the implementation actually written; and (b) include enough values to get 100% code coverage, for whatever code coverage metric you have the time and willpower to work to. The TDD part of the process is still useful, it helps write the code, but then you iterate. If any of these new tests fail you could call it "adding new requirements", in which case I suppose what you're doing is still pure TDD. But it's solely a question of what you call it, really you aren't adding new requirements, you're testing the original requirements more thoroughly than was possible before the code was written.