While calculating the hash table bucket index from the hash code of a key, why do we avoid use of remainder after division (modulo) when the size of the array of buckets is a power of 2?
When calculating the hash, you want as much information as you can cheaply munge things into with good distribution across the entire range of bits: e.g. 32bit unsigned integers are usually good, unless you have a lot (>3 billion) of items to store in the hash table. It's converting the hash code into a bucket index that you're really interested in. When the number of buckets n is a power of two, all you need to do is do an AND operation between hash code h and (n1), and the result is equal to h mod n. A reason this may be bad is that the AND operation is simply discarding bits  the highlevel bits  from the hash code. This may be good or bad, depending on other things. On one hand, it will be very fast, since AND is a lot faster than division (and is the usual reason why you would choose to use a power of 2 number of buckets), but on the other hand, poor hash functions may have poor entropy in the lower bits: that is, the lower bits don't change much when the data being hashed changes. 


Let us say that the table size is m = 2^p. Let k be a key. Then, whenever we do k mod m, we will only get the last p bits of the binary representation of k. Thus, if I put in several keys that have the same last p bits, the hash function will perform VERY VERY badly as all keys will be hashed to the same slot in the table. Thus, avoid powers of 2 

