I am not aware of such a thing, I believe this is far too abstract and complicated for a feasible P to exist.
I believe any useful F would effectively be a description of translations between a common intermediate language and the individual CPU instruction set (even if that language is declarative rather than a traditional compiler). Have a look at LLVM's TableGen, which is used to declare a lot of information about backends. AFAIK it's still not sufficient for describing architectures in their entirety, and apparently quite complicated to work with.
I do not see how P would know anything about L, but it would need that knowledge to create a compiler C[i]. Unless of course you create P specifically to know about L, at which point P becomes specific to a single L, and is effectively a traditional compiler front end, which is nothing new. The only difference is that you're writing a program for emitting the compiler, but I do not see how this saves you anything over just writing
C'' like someone wrote
C' beforehand. (Parsing is a much simpler and smaller problem, hence successful advances, in parser generation. Despite this, parser generators are at best competitive with hand-written-by-experts parsers both in implementation effort and quality.) Alternatively, make P an AI and teach it compiler construction, but that's not possible with the current state of AI, and then you gotta find a way to teach P the languages (read: still no free compilers for you).
Apart from that, a compiler has to know a lot more than just CPU instructions. OS services, ABIs, and executable formats are just three of many nontrivial problems they face. I have similar doubts about applying a similar solution to those issues. The good old "decouple front end and back end" trick is almost as efficient in terms of effort, obviously much more possible, and makes much more sense to me.