This is Hewitt and Stromberg's Real and Abstract Analysis Problem 21.22. My approach was to compare with this question
How to derive $\int_0^1 \int_0^1 \frac{1}{1-xy} \,dy\,dx = \sum_{n=1}^{\infty}\frac{1}{n^{2}}$
and use the series expansion of $\frac{1}{(1-xy)^ p}$ to calculate this integral. I found this expansion to be
$$\frac{1}{(1-xy)^ p}=\sum_{n=0}^ \infty \frac{p \cdots (p+n-1)}{n!} (xy)^ n.$$
However, I got this integral is
$$\lim_{r \to 1} \int_0^ r \int_0^ r (\sum_{n=0}^ \infty \frac{p \cdots (p+n-1)}{n!} (xy)^ n) dxdy = \sum_{n=0}^ \infty \frac{p\cdots (p+n-1)}{n!(n+1)^ 2}.$$
But, I don't seem to find if this series converges or diverges, much less what is the value of the integral. Also it says to calculate the following integrals,
$$\int_{0}^ 1 \int_{0}^ 1 \frac{1}{(1-xy)^ p} dydx, \int_{0}^ 1 \int_{0}^ 1 \Bigg|\frac{1}{(1-xy)^ p}\Bigg| dxdy, \int_{0}^ 1 \int_{0}^ 1 \Bigg|\frac{1}{(1-xy)^ p}\Bigg| dydx$$
and to compare with Fubini's Theorem.
Have I done something wrong?
Thanks a lot!
