Position operator and Momentum operator in the Energy basis

Right you are: the set ${ |xrangle }$ is uncountable and the set ${ |nrangle }$ is countable. But, when discussing the oscillator, we are not moving around all xs. We are really moving in the Hilbert space of normalizable states, the (real) Hermite polynomials, $psi_n(x)=langle x| nrangle$, a complete orthonormal countable set, s.t. $$ |nrangle= int!! dx ~|xrangle langle x|nrangle = int!! dx ~~psi_n(x) |xrangle $$ square integrable, normalized, etc. So we "pretend" $$ |xrangle = sum_{n=0}^{infty} |nrangle langle n|xrangle = sum_{n=0}^{infty} psi_n(x) |nrangle , $$ as we are not really considering the entire domain of $hat X, hat P$. We are considering the countable part that has eigenvalues $n+1/2$ for the hamiltonian $(hat {X}^2+ hat P^2)/2$ (where we've absorbed the obnoxious constants $hbar, m, omega$ into our normalizations).

We are really moving in a Hilbert space of infinite discrete matrices, as you saw, and your text sensibly doesn't dwell on this projection by the complete Hermite functions. There is an entire continent of "Rigged Hilbert spaces", but I haven't appreciated if you really want to go there. Most practical texts don't.

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NB on comments (geeky)

The above projection on energy (number) eigenstates is consistent, to the extent the action of $$ hat X= (a+a^dagger)/sqrt{2}, qquad hat P= (a^dagger - a) /sqrt{2} $$ on $|nrangle$ raises or lowers n by 1, and so maintains the projection on integer ns, as one may also confirm from the recursion relations of Hermite functions, linked above.

So, the dynamics never slips into the unphysical superselection sectors projected out, e.g., with m = integer plus a noninteger constant, such as 1/2. Freak states such as $|1/2rangle equiv sqrt{ frac{a^dagger}{(1/2)!}}|0rangle= sqrt{ frac{2a^dagger}{ sqrt{pi}}}|0rangle $ orthogonal to the above integer n ones are permanently and safely excluded from consideration.