So, I think the concrete answer to your question is "zero", but that's simply because you are asking the wrong question.
Right, so a cache with a given size X, that is directly mapped, will simply use the lower part [or some other part(s)] of the address to form the index into the cache. So index is a value between 0 and (chace-size-1). In other words, "address modulo size". Since sizes of caches are nearly always 2n, we make use of the fact that both of these can be performed using simple bitwise "and" with (size-1) instead of using divide.
In your code, each cache entry (cache-line) holds a "BLOCK" of 32 bytes, so the address should be divided (shifted) down by the block-size. 25 = 32. This shift remains a constant for a constant cache-line size. Since there is no other shift in your example code, I presume you are misunderstanding what you should do.
In a set-associative cache, there are multiple sets of cache-lines that can be used for the same index. So instead of simply taking the lower part of the address as an index, we take a SMALLER part of the lower address. So, the
index = address_of_block & (CACHE_SIZE-1) should become
address_of_block & ((CACHE_SIZE-1) / ways. Since we are dealing with a 2n number again, we can use the old "shift instead of divide" trick -
x / y where
y is 2n can be done by
x >> n.
So, now you just have to figure out what
n is for your number of ways.
And of course, figure out how you determine which of the ways to use when replacing something in the cache, but that is certainly a completely different question.