There's more to compiling than CPU speed and number of cores available: disk bandwidth and memory bandwith matter a lot too.
In your case, I imagine that each CPU HT sibling is getting roughly 4 processes to execute. As it starts one, it blocks on disk IO and moves onto the next process. The second one tries to open a second file, blocks on disk IO, and the sibling moves onto the next process. Starting four compilers before the first disk IO is ready wouldn't surprise me.
So when the first one finally read in the program source, the compiler must start hunting through directories to find the #included files. Each one requires some open() calls followed by read() calls, all of which can block, and all of which will relinquish the sibling for other processes to run.
Now multiply that by eight siblings -- each HT core will run until it blocks on memory access, at which point it'll swap over to the other sibling, and run for a while. Once the memory of the first sibling has been fetched into the cache, it is probably time for the second sibling to stall while waiting for memory.
There is an upper limit on how much faster you can get your compiles to run by using
make -j, but twice-number-of-cpus has been a good starting point for me in the past.