There's this related question: GCC: how is march different from mtune?

However, the existing answers don't go much further than the GCC manual itself. At most, we get:

If you use -mtune, then the compiler will generate code that works on any of them, but will favour instruction sequences that run fastest on the specific CPU you indicated.


The -mtune=Y option tunes the generated code to run faster on Y than on other CPUs it might run on.

But exactly how does GCC favor one specific architecture, when bulding, while still being capable of running the build on other (usually older) architectures, albeit slower?

I only know of one thing (but I'm no computer scientist) which would be capable of such, and that's a CPU dispatcher. However, it doesn't seem (for me) that mtune is generating a dispatcher behind the scenes, and instead some other mechanism is probably in effect.

I feel that way for two reasons:

  1. Searching "gcc mtune cpu dispatcher" doesn't find anything relevant; and
  2. If it was based on dispatcher, I think it could be smarter (even if by some option other than mtune) and test for cpuid to detect supported instructions at runtime, instead of relying on a named architecture which is provided at build time.

So how does it work really?

  • 3
    @yugr it is definitely not a dupe. The question you linked, as well as the question the OP himself linked deal with understanding march vs mtune. While those questions show what mtune promises, this question specifically asks what the compiler can do to fulfill those promises. – bolov Jun 12 '17 at 14:11

-mtune doesn't create a dispatcher, it doesn't need one: we are already telling the compiler what architecture we are targeting.

From the GCC docs:


        Tune to cpu-type everything applicable about the generated code, except for the ABI and the
        set of available instructions.

This means that GCC won't use instructions available only on cpu-type 1 but it will generate code that run optimally on cpu-type.

To understand this last statement is necessary to understand the difference between architecture and micro-architecture.
The architecture implies an ISA (Instruction Set Architecture) and that's not influenced by the -mtune.
The micro-architecture is how the architecture is implemented in hardware. For an equal instruction set (read: architecture), a code sequence may run optimally on a CPU (read micro-architecture) but not on another due to the internal details of the implementation. This can go as far as having a code sequence being optimal only on one micro-architecture.

When generating the machine code often GCC has a degree of freedom in choosing how to order the instructions and what variant to use.
It will use a heuristic to generate a sequence of instructions that run fast on the most common CPUs, sometime it will sacrifice a 100% optimal solution for CPU x if that will penalise CPUs y, z and w.

When we use -mtune=x we are fine tuning the output of GCC for CPU x thereby producing a code that is 100% optimal (from the GCC perspective) on that CPU.

As a concrete example consider how this code is compiled:

float bar(float a[4], float b[4])
    for (int i = 0; i < 4; i++)
        a[i] += b[i];

    float r=0;

    for (int i = 0; i < 4; i++)
        r += a[i];

    return r;

The a[i] += b[i]; is vectorised (if the vectors don't overlap) differently when targeting a Skylake or a Core2:


    movups  xmm0, XMMWORD PTR [rsi]
    movups  xmm2, XMMWORD PTR [rdi]
    addps   xmm0, xmm2
    movups  XMMWORD PTR [rdi], xmm0
    movss   xmm0, DWORD PTR [rdi] 


    pxor    xmm0, xmm0
    pxor    xmm1, xmm1
    movlps  xmm0, QWORD PTR [rdi]
    movlps  xmm1, QWORD PTR [rsi]
    movhps  xmm1, QWORD PTR [rsi+8]
    movhps  xmm0, QWORD PTR [rdi+8]
    addps   xmm0, xmm1
    movlps  QWORD PTR [rdi], xmm0
    movhps  QWORD PTR [rdi+8], xmm0
    movss   xmm0, DWORD PTR [rdi]

The main difference is how an xmm register is loaded, on a Core2 it is loaded with two loads using movlps and movhps instead of using a single movups.
The two loads approach is better on a Core2 micro-architecture, if you take a look at the Agner Fog's instructions tables you'll see that movups is decoded into 4 uops and has a latency of 2 cycles while each movXps is 1 uop and 1 cycle of latency.
This is probably due to the fact that 128-bit accesses were split into two 64-bit accesses at the time.
On Skylake the opposite is true: movups performs better than two movXps.

So we have to pick up one.
In general, GCC picks up the first variant because Core2 is an old micro-architecture, but we can override this with -mtune.

1 Instruction set is selected with other switches.

  • 4
    This shows how important are programmers with experience on this site. The explanation is spot on and your example is worth a thousand words. I don't usually leave +1 comments, but this truly deserves a "Great job!". Thank you! – bolov Jun 12 '17 at 14:07
  • 2
    @Marc.2377, it's not about instruction exclusivity, you can have 2 micro-architectures support the same ISA, but have them optimized differently, so for example a simple scalar addition would best be achieved with an add instruction on one, but a lea on the other (ignoring side effects for a second). The compiler would therefore pick the actual instruction based on the optimization target requested by -mtune. P.S. - great answer indeed! – Leeor Jun 12 '17 at 20:21
  • 1
    @Marc.2377 - more or less, but mtune doesn't actually preclude the use of a dispatcher. They are more or less orthogonal. As Margaret explains, mtune=X means "use the machine model for X to make optimization decisions", but still create code that runs based on the march argument. You can kind of imagine that mtune and march always have some value: even if they aren't specified on the command line, they take a default. So some compilers (uncommon) and libraries (common) like to use dispatch-based code, and can still occur if you specify mtune. – BeeOnRope Jun 18 '17 at 19:03
  • 2
    gcc should use movsd instead of pxor + movlps to load the 64-bit low half and zero the upper half. Silly compiler :( Nice choice of example, though. Unaligned loads becoming cheap in more recent CPUs (and free when the data happen to be aligned) is an interesting thing. But Core2 doesn't just split 128 accesses. movaps is 1 uop. It's just that unaligned loads didn't have as much hardware support, so they always used multiple uops and couldn't be efficient in case the data did happen to be aligned at runtime. With more load-port hardware, they can be 1 uop in NHM and later. – Peter Cordes Jul 10 '17 at 1:53
  • 2
    @PeterCordes, great point, I added aligned_float and restrict which greatly cleans up the assembly and shows both solutions for core2 godbolt.org/z/DvvAg_ – Z boson Nov 1 '18 at 8:32

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