GP can't quickly solve novel problems that are beyond the knowledge of the person creating the fitness function. So, it can only currently be used to solve problems we already know how to solve, but are not ideal to fully solve, due to search space. Such as Traveling Salesman. Which can be more quickly solved with a GA.
The reason is actually pretty simple. To solve novel problems, the tools you give the GP need to be simple enough, or complete enough, that the GP search space becomes a true analogue to real genetics.
Genetic Programming, like real genetics, is subject to the same growth pattern that all platform-growth systems are. Which means that a GP will progress to a point where the core utilities included hit a platform, it levels off, and then takes a LONG time before it stumbles onto a new paradigm to build up to a new platform.
This pro-evolution video illustrates these platform-growth patterns.
It takes a long while to develop a new hand, and once it does, an additional hand becomes the new thing and quickly advances to an optimal example of more hands. (I should mention that this video is most-likely using a GA, not GP, but genetics are genetics)
This is all about the same logic that goes into Singularity Theory, BTW.
But what this means for GP is that it pretty-much is only good for research, not for practical application within a program. With a few simple exceptions where the requirements are slightly more in-depth than a GA can solve. Such as some scheduler programs. Where the programming search space is pretty small, and where the tools needed to solve it are well understood, and where there can be a well-defined fitness function.