Refering to @auselen's answer here: Using ARM NEON intrinsics to add alpha and permute, looks like armcc compiler is far more better than the gcc compiler for NEON optimizations. Is this really true? I haven't really tried armcc compiler. But I got pretty optimized code using the gcc compiler with -O3 optimization flag. But now I'm wondering if armcc is really that good? So which of the two compiler is better, considering all the factors?
Compilers are software as well, they tend to improve over time. Any generic claim like armcc is better than GCC on NEON (or better said as vectorization) can't hold true forever since one developer group can close the gap with enough attention. However initially it is logical to expect compilers developed by hardware companies to be superior because they need to demonstrate/market these features.
One recent example I saw was here on Stack Overflow about an answer for branch prediction. Quoting from last line of updated section "This goes to show that even mature modern compilers can vary wildly in their ability to optimize code...".
I am a big fan of GCC, but I wouldn't bet on quality of code produced by it against compilers from Intel or ARM. I expect any mainstream commercial compiler to produce code at least as good as GCC.
One empirical answer to this question could be to use hilbert-space's neon optimization example and see how different compilers optimize it.
This is armcc 5.01
This is GCC 4.4.3-4.7.1
Which looks extremely similar, so we have a draw. After seeing this I tried mentioned add alpha and permute again.
Compiling with gcc...
Compiling with armcc...
In this case armcc produces much better code. I think this justifies fgp's answer above. Most of the time GCC will produce good enough code, but you should keep an eye on critical parts or most importantly first you must measure / profile.
If you use NEON intrinsics, the compiler shouldn't matter that much. Most (if not all) NEON intrinsics translate to a single NEON instruction, so the only thing left to the compiler is register allocation and instruction scheduling. In my experience, both GCC 4.2 and Clang 3.1 do reasonably well at those tasks.
Note, however, that the NEON instructions are bit more expressive than the NEON instrinsics. For example, NEON load/store instructions have pre- and post-increment adressing modes which combine a load or store with an increment of the address register, thus saving you one instruction. The NEON intrinsics don't provide an explicit way to do that, but instead rely on the compiler to combine a reguler NEON load/store intrinsic and an address increment into a load/store instruction with post-increment. Similarly, some load/store instructions allow you to specify the alignment of the memory address, and execute faster if you specify stricter alignment guarantees. The NEON intrinsics, again, don't allow you to specify alignment explicitly, but instead rely on the compiler to deduce the correct alignment specifier. In theory, you use "align" attributes on your pointers to provide suitable hints to the compiler, but at least Clang seems to ignore those...
In my experience, neither Clang nor GCC are very bright when it comes to those kinds of optimizations. Fortunately, the additional performance benefit of these kinds of optimization usually isn't all that high - it's more like 10% than 100%.
Another area where those two compilers aren't particularly smart is avoidance of stack spilling. If you code uses more vector-valued variables than there are NEON registers, I've seem both compilers produce horrible code. Basically, what they seem to do is to schedule instructions based on the assumption that there are enough registers available. Register allocation seems to come afterwards, and seems to simply spill values to the stack once it runs of registers. So make sure you code has a working set of less than 16 128-bit vectors or 32 64-bit vectory at any time!
Overall, I've got pretty good results from both GCC and Clang, but I regularly had to reorganize the code a bit to avoid compiler Idiosyncrasies. My advice would be to stick with GCC or Clang, but check on the regularly with the dissassembler of your choice.
So, overall, I'd say sticking with GCC is fine. You might want to look at the dissassembly of the performance-critical parts, though, and check if it looks reasonable.