The tables below list all of the divisors of the numbers 1 to 1000.

A divisor of an integer n is an integer m, for which n/m is again an integer (which is necessarily also a divisor of n). For example, 3 is a divisor of 21, since 21/7 = 3 (and therefore 7 is also a divisor of 21).

If m is a divisor of n, then so is −m. The tables below only list positive divisors.

• d(n) is the number of positive divisors of n, including 1 and n itself
• σ(n) is the sum of the positive divisors of n, including 1 and n itself
• s(n) is the sum of the proper divisors of n, including 1, but not n itself; that is, s(n) = σ(n) − n
• a deficient number is greater than the sum of its proper divisors; that is, s(n) < n
• a perfect number equals the sum of its proper divisors; that is, s(n) = n
• an abundant number is lesser than the sum of its proper divisors; that is, s(n) > n
• a highly abundant number has a sum of positive divisors that is greater than any lesser number; that is, σ(n) > σ(m) for every positive integer m < n. Counterintuitively, the first seven highly abundant numbers are not abundant numbers.
• a prime number has only 1 and itself as divisors; that is, d(n) = 2
• a composite number has more than just 1 and itself as divisors; that is, d(n) > 2
• a highly composite number has more divisors than any lesser number; that is, d(n) > d(m) for every positive integer m < n. Counterintuitively, the first two highly composite numbers are not composite numbers.
• a superior highly composite number has a ratio between its number of divisors and itself raised to some positive power that equals or is greater than any other number; that is, there exists some ε such that ${\displaystyle {\frac {d(n)}{n^{\varepsilon }}}\geq {\frac {d(m)}{m^{\varepsilon }}}}$ for every other positive integer m
• a primitive abundant number is an abundant number whose proper divisors are all deficient numbers
• a weird number is an abundant number that is not semiperfect; that is, no subset of the proper divisors of n sum to n