Do quark charges repel one another?

This is not a meaningful question.

No, really, it isn't. Quarks don't exist as free charged objects on which we could take the classical limit and consider "forces" on them. They are confined, and occur only as constituents of bound states. In quantum mechanics, it doesn't make sense to ask whether the constituents of a bound state "repel" or "attract" each other. The electrons in an atom are not in any meaningful sense "attracted" by the nucleus except for the "attractive" Coulomb potential being responsible for the existence of the bound electron states in the first place - but there is no "force". All that is left of the classical idea of force will be a certain contribution to the binding energy by the corresponding potential.

Do quark charges repel one another?

No. Quarks aren't little balls, and nor are they point charges. It's quantum field theory, not quantum point-particle theory. It's the wave nature of matter, not the point-particle nature of matter. Take a look at some pictures of electromagnetic waves. The first part of the wave is positive, the second part is negative. But the two parts don't repel each other. It's similar for quarks. You can kind of work this out by thinking about proton diffraction and pair production and annihilation. In low-energy proton-antiproton annihilation to gamma photons, you started with 2 wavelike things and you ended up with 2 wavelike things. The fact that the former have three parts and the latter have two doesn't make much difference.

Positive electrical charges repel other positive charges, and negatives repel negatives. But does that happen for quarks, too?

No, because a quark is not actually a charged particle like an electron. I know people say it's a fundamental particle, but nobody has every seen a free quark. IMHO it's better to think of it as a "lowest-common-denominator particle component" rather than an actual particle in its own right. It's similar for gluons. The gluons in ordinary hadrons like the proton are virtual, and virtual particles exist only in the mathematics of the model.

I never saw mention of it, but if so, that would mean the up quarks in a proton actively repel each other, would it not? The same for down quarks in neutrons, of course.

No. Like ACuriousMind said, quarks don't exist as free charged objects, they're confined, and occur only as constituents of bound states. IMHO to really grasp this you have to look to topological quantum field theory. See the blue trefoils at the top of this TQFT club page? They're there for a reason, and it's the worst-kept secret in physics. Have a rummage around and you soon find these pictures of a proton and a trefoil:

Put your finger on the trefoil at the bottom left, then go round it anticlockwise calling out the crossing-over directions: up, down up. Now where have you heard that before? LOL! The quarks are just parts of the bound state. They aren't point particles. If they were, you couldn't diffract protons, or neutrons, or buckyballs. Quarks are "partons", or parts, not things that can exist on their own.

In the article "The Anatomy of a Neutron" by Timothy Paul Smith, (available on line),the author said in Figure 3. that "In a quark model that includes spin, there is a repulson (repulsion?) between quarks with parallel spins, so the quarks will have slightly distorted orbits. In the proton, the effect on the charge radius is almost unnoticeable. However, in the neutron, it leads to a slightly negative surface and a slight positive center."