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I'm experimenting with an i.MX53 board with linux ubuntu. I'm working over ssh with a cross compiler (arm-linux-gnueabihf) on my host system.

For a benchmark with floating-point operations on the processor (ARM Cortex-A8), I created the following two different programs, which both contain a simple loop. In the first program, the loop contains a single multiplication, in the second one the same multiplication with an extra addition.

I compiled the two programs with the following compiler call:

arm-linux-gnueabihf-g++-4.8 -O3 -ffast-math -Ofast -Wall -fmessage-length=0 -Wno-multichar -Wno-unknown-pragmas -std=c++11 -mcpu=cortex-a8 -mfpu=neon -mfloat-abi=hard -save-temps loopMul.cpp -o loopMul

Now my question: Why outputs the compiler such different assembly code for the loop part? (see assembly code)

I recognised that in the first program, the compiler generates NEON instructions for the multiplication, and in the second one only the slower VFP instructions.

first program (loopMul.cpp):

#include <iostream>
#include <ctime>

using namespace std;

int main(int argc, char **argv)
{
    size_t length = 10E7;
    float test = 1;

    clock_t start = clock();    

    for(size_t i=1; i<length; i++)
    {
        test *= i;
    }

    clock_t elapsed = clock() - start;

    cout << test << endl;

    float elapsed_seconds = float(elapsed) / float(CLOCKS_PER_SEC);
    cout << "loop took " << elapsed_seconds <<  "seconds" << endl;

    return 0;
}

second program (loopMulAdd):

#include <iostream>
#include <ctime>

using namespace std;

int main(int argc, char **argv)
{
    size_t length = 10E7;
    float test = 1;

    clock_t start = clock();    

    for(size_t i=1; i<length; i++)
    {
        test *= i;
        test += 1;
    }

    clock_t elapsed = clock() - start;

    cout << test << endl;

    float elapsed_seconds = float(elapsed) / float(CLOCKS_PER_SEC);
    cout << "loop took " << elapsed_seconds <<  "seconds" << endl;

    return 0;
}

assembly output of first programm (loopMul.s):

    .syntax unified
    .cpu cortex-a8
    .eabi_attribute 27, 3
    .eabi_attribute 28, 1
    .fpu neon
    .eabi_attribute 23, 1
    .eabi_attribute 24, 1
    .eabi_attribute 25, 1
    .eabi_attribute 26, 2
    .eabi_attribute 30, 2
    .eabi_attribute 34, 1
    .eabi_attribute 18, 4
    .thumb
    .file   "loopMul.cpp"
    .section    .text.startup,"ax",%progbits
    .align  2
    .global main
    .thumb
    .thumb_func
    .type   main, %function
main:
    .fnstart
.LFB1265:
    @ args = 0, pretend = 0, frame = 0
    @ frame_needed = 0, uses_anonymous_args = 0
    push    {r4, lr}
    .save {r4, lr}
    fstmfdd sp!, {d8, d9, d10, d11}
    .vsave {d8, d9, d10, d11}
    bl  clock
    vmov.i32    q11, #4  @ v4si
    vmov.f32    q9, #1.0e+0  @ v4sf
    movw    r2, #30783
    movt    r2, 381
    movs    r3, #0
    vldr    d16, .L8
    vldr    d17, .L8+8
    mov r4, r0
.L3:
    vcvt.f32.s32    q10, q8
    adds    r3, r3, #1
    cmp r3, r2
    vadd.i32    q8, q8, q11
    vmul.f32    q9, q9, q10
    bne .L3
    vmov.i32    q8, #0  @ v16qi
    vext.8  q4, q9, q8, #8
    vmul.f32    q4, q4, q9
    vext.8  q5, q4, q8, #4
    bl  clock
    flds    s15, .L8+16
    vmul.f32    q4, q5, q4
    vmov.32 r3, d8[0]
    fmsr    s0, r3
    fmuls   s0, s0, s15
    fcvtds  d0, s0
    subs    r4, r0, r4
    movw    r0, #:lower16:_ZSt4cout
    movt    r0, #:upper16:_ZSt4cout
    bl  _ZNSo9_M_insertIdEERSoT_
    bl  _ZSt4endlIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_
    movw    r0, #:lower16:_ZSt4cout
    movw    r1, #:lower16:.LC0
    movt    r0, #:upper16:_ZSt4cout
    movt    r1, #:upper16:.LC0
    bl  _ZStlsISt11char_traitsIcEERSt13basic_ostreamIcT_ES5_PKc
    fmsr    s15, r4 @ int
    fsitos  s0, s15
    flds    s15, .L8+20
    fmuls   s0, s0, s15
    fcvtds  d0, s0
    bl  _ZNSo9_M_insertIdEERSoT_
    movw    r1, #:lower16:.LC1
    movt    r1, #:upper16:.LC1
    bl  _ZStlsISt11char_traitsIcEERSt13basic_ostreamIcT_ES5_PKc
    bl  _ZSt4endlIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_
    fldmfdd sp!, {d8-d11}
    movs    r0, #0
    pop {r4, pc}
.L9:
    .align  3
.L8:
    .word   1
    .word   2
    .word   3
    .word   4
    .word   1733542428
    .word   897988541
    .fnend
    .size   main, .-main
    .align  2
    .thumb
    .thumb_func
    .type   _GLOBAL__sub_I_main, %function
_GLOBAL__sub_I_main:
    .fnstart
.LFB1422:
    @ args = 0, pretend = 0, frame = 0
    @ frame_needed = 0, uses_anonymous_args = 0
    push    {r4, lr}
    movw    r4, #:lower16:.LANCHOR0
    movt    r4, #:upper16:.LANCHOR0
    mov r0, r4
    bl  _ZNSt8ios_base4InitC1Ev
    mov r0, r4
    movw    r1, #:lower16:_ZNSt8ios_base4InitD1Ev
    movw    r2, #:lower16:__dso_handle
    movt    r1, #:upper16:_ZNSt8ios_base4InitD1Ev
    movt    r2, #:upper16:__dso_handle
    pop {r4, lr}
    b   __aeabi_atexit
    .cantunwind
    .fnend
    .size   _GLOBAL__sub_I_main, .-_GLOBAL__sub_I_main
    .section    .init_array,"aw",%init_array
    .align  2
    .word   _GLOBAL__sub_I_main(target1)
    .section    .rodata.str1.4,"aMS",%progbits,1
    .align  2
.LC0:
    .ascii  "loop took \000"
    .space  1
.LC1:
    .ascii  "seconds\000"
    .bss
    .align  2
.LANCHOR0 = . + 0
    .type   _ZStL8__ioinit, %object
    .size   _ZStL8__ioinit, 1
_ZStL8__ioinit:
    .space  1
    .hidden __dso_handle
    .ident  "GCC: (Ubuntu/Linaro 4.8.1-10ubuntu7) 4.8.1"
    .section    .note.GNU-stack,"",%progbits

Assembly output of the second programm(loopMulAdd.s):

    .syntax unified
    .cpu cortex-a8
    .eabi_attribute 27, 3
    .eabi_attribute 28, 1
    .fpu neon
    .eabi_attribute 23, 1
    .eabi_attribute 24, 1
    .eabi_attribute 25, 1
    .eabi_attribute 26, 2
    .eabi_attribute 30, 2
    .eabi_attribute 34, 1
    .eabi_attribute 18, 4
    .thumb
    .file   "loopMulAdd.cpp"
    .section    .text.startup,"ax",%progbits
    .align  2
    .global main
    .thumb
    .thumb_func
    .type   main, %function
main:
    .fnstart
.LFB1265:
    @ args = 0, pretend = 0, frame = 0
    @ frame_needed = 0, uses_anonymous_args = 0
    push    {r4, lr}
    .save {r4, lr}
    fstmfdd sp!, {d8}
    .vsave {d8}
    bl  clock
    fconsts s16, #112
    mov r2, #57600
    movt    r2, 1525
    movs    r3, #1
    fcpys   s14, s16
    mov r4, r0
.L3:
    fmsr    s13, r3 @ int
    adds    r3, r3, #1
    cmp r3, r2
    fsitos  s15, s13
    fcpys   s13, s14
    fmacs   s13, s16, s15
    fcpys   s16, s13
    bne .L3
    bl  clock
    fcvtds  d0, s16
    subs    r4, r0, r4
    movw    r0, #:lower16:_ZSt4cout
    movt    r0, #:upper16:_ZSt4cout
    bl  _ZNSo9_M_insertIdEERSoT_
    bl  _ZSt4endlIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_
    movw    r0, #:lower16:_ZSt4cout
    movw    r1, #:lower16:.LC0
    movt    r0, #:upper16:_ZSt4cout
    movt    r1, #:upper16:.LC0
    bl  _ZStlsISt11char_traitsIcEERSt13basic_ostreamIcT_ES5_PKc
    fmsr    s15, r4 @ int
    fsitos  s0, s15
    flds    s15, .L7
    fmuls   s0, s0, s15
    fcvtds  d0, s0
    bl  _ZNSo9_M_insertIdEERSoT_
    movw    r1, #:lower16:.LC1
    movt    r1, #:upper16:.LC1
    bl  _ZStlsISt11char_traitsIcEERSt13basic_ostreamIcT_ES5_PKc
    bl  _ZSt4endlIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_
    fldmfdd sp!, {d8}
    movs    r0, #0
    pop {r4, pc}
.L8:
    .align  2
.L7:
    .word   897988541
    .fnend
    .size   main, .-main
    .align  2
    .thumb
    .thumb_func
    .type   _GLOBAL__sub_I_main, %function
_GLOBAL__sub_I_main:
    .fnstart
.LFB1422:
    @ args = 0, pretend = 0, frame = 0
    @ frame_needed = 0, uses_anonymous_args = 0
    push    {r4, lr}
    movw    r4, #:lower16:.LANCHOR0
    movt    r4, #:upper16:.LANCHOR0
    mov r0, r4
    bl  _ZNSt8ios_base4InitC1Ev
    mov r0, r4
    movw    r1, #:lower16:_ZNSt8ios_base4InitD1Ev
    movw    r2, #:lower16:__dso_handle
    movt    r1, #:upper16:_ZNSt8ios_base4InitD1Ev
    movt    r2, #:upper16:__dso_handle
    pop {r4, lr}
    b   __aeabi_atexit
    .cantunwind
    .fnend
    .size   _GLOBAL__sub_I_main, .-_GLOBAL__sub_I_main
    .section    .init_array,"aw",%init_array
    .align  2
    .word   _GLOBAL__sub_I_main(target1)
    .section    .rodata.str1.4,"aMS",%progbits,1
    .align  2
.LC0:
    .ascii  "loop took \000"
    .space  1
.LC1:
    .ascii  "seconds\000"
    .bss
    .align  2
.LANCHOR0 = . + 0
    .type   _ZStL8__ioinit, %object
    .size   _ZStL8__ioinit, 1
_ZStL8__ioinit:
    .space  1
    .hidden __dso_handle
    .ident  "GCC: (Ubuntu/Linaro 4.8.1-10ubuntu7) 4.8.1"
    .section    .note.GNU-stack,"",%progbits
share|improve this question
    
Can you try with -funsafe-math-optimizations flag? Normally I would have expected a vmla but may be it is due to floating point correctness. –  auselen Jan 10 '14 at 13:37
    
I tried '-funsafe-math-optimizations' already but nothing changes on the assambly output. –  user3181003 Jan 10 '14 at 13:48

1 Answer 1

Q: Why outputs the compiler such different assembly code for the loop part?

The reason is quite simple.

In the first case (multiplication loop) the compiler was able to auto-vectorize the loop and used the SIMD capabilities of the NEON unit.

In the second case the compiler was not so smart. It did not found a way to vectorize the loop and therefore didn't used the NEON but the vfp instruction set.

As far as I remember you can force the compiler to use NEON instead of the FPU using a option. If this increases the performance or not depend highly on the nature of your floating point code though.

share|improve this answer
    
I also thought about auto-vectorization, but in the example loop, every iteration depends on the one befor. So I thougth there is no way to vectorize this loop. I would realy like to understand the mechanism when the compiler choose to use NEON instructions and when it uses VFP instructions. –  user3181003 Jan 10 '14 at 13:55
1  
float test = 1; for(size_t i=1; i<length; i++) test *= i; runs through a process called loop induction. Apparently the not so smart compiler is passing a turing test; it appears to be as smart as at least one human :) I think people who criticize compilers have never written one. Both loops can be auto-vectorized, but the compiler seems to give up in the 2nd case. There are many options with gcc to tune how far to look for these cases. People also complain if a compiler runs long. Optimization too much and you have no code. –  artless noise Jan 10 '14 at 16:52
    
+1 for recognizing the condition. Here is a recent gcc paper on induction, which says that the induction has some address short coming on ARM. The paper should help you understand the mechanism. See gcc optimization and look for loop, tree, vect; these may help you. –  artless noise Jan 10 '14 at 17:02
    
thanks a lot for this specific help! Unfortunately I'm not that familiar with compiler architecture, but I will try to follow your advice to understand this particular problem. In fact my main goal is to write some audio algorithms like iir-filter and fir-filter on an arm cortex-a8. I recognized that they work unproportionaly faster on intel-processor then on arm-processor. So I start to add compiler-flags(for gcc) to optimize the code for the arm-processor. But even with all flags that I found, the code don't get faster. Is there maybe an better compiler for floating point jobs on an arm? –  user3181003 Jan 12 '14 at 11:12

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