The pumping lemma says:
If a language A is regular => there is a number p (pumping length) where, if s is any string in L such that |s| >= p, then s may be divided into three pieces s=xyz, satisfying the following condition:

- xy
^{i}z is in L for each i>=0
- |y|>=0
- p>=|xy|

The right way to show that a certain language L is not regular is to suppose L regular and try to reach a contradiction.

If you try to suppose that your language is not regular you should first search the kind of string that represents the irregularity of the language.
Lets try with a^{p}b^{n} for n>=0.

We can do some assumption on this string: since |xy|<=p we know that y is only made of a. At this point you can pump it as much times as you prefer but xy^{i}z is a member of your language for every i>=0.

In a similar way you will not reach a contradiction if you choose a^{n}b^{p} for n>=0.

L={a^{n}b^{n} | n>=0} is not regular, but you do not have constraints on p and q(I mean, it is not required to count both occurrences of a and b).

However a language is regular if and only if it can be expressed with a regular expression. And in this case you can do that: a*b*. So you can conclude that this language is regular.

Edit:
for p<=q the language is not regular but you are considering any p and q.