A. In an imperative programming language, statements are executed in sequence, and each statement may change the program's state. So analyzing translation units is inherently sequential.
An example: Check out how constant propagation might work -
a = 5;
b = a + 7;
c = a + b + 9;
You need to go through those statements sequentially before you figure out that the values assigned to
c are constants at compile time.
B. On top of this, different passes need to execute sequentially as well, and affect each other.
An example: Based on a schedule of instructions, you allocate registers, then you find that you need to spill a register to memory, so you need to generate new instructions. This changes the schedule again.
So you can't execute 'passes' like 'register allocation' and 'scheduling' in parallel either (actually, I think there are articles where computer scientists/mathematicians have tried to solve these two problems together, but lets not go into that).
So there is not much parallelism to be had at the level of 'within compilation of a C file'.
Moreover, GPUs especially don't fit because:
GPUs are good at floating point math. Something compilers don't need or use much (or at all?)
GPUs are good at SIMD. i.e. performing the same operation on multiple inputs. This is again, not something a compiler does.
Finally, parallelism is possible (and used) at a higher level.
GNU Make, for example, has the
-j=N argument. Which basically means: As long as it finds
N independent jobs (usually, compiling a bunch of files is what
GNU Make is used for anyway), it spawns
N processes (or
N instances of
gcc compiling different files in parallel).