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# How is the result of this single-precision operation rounded? [Or why is this bit 1 and not 0?]

I'm working on a function optimization routine (a variant of the Nelder-Mead algorithm) which fails to converge in very specific conditions.

I've identified that a `float` variable, let's call it `a`, is being assigned the mean between `a` and another variable `b` that differs from it by a bit only.

More precisely, the values of each variables are as follows:

``````float a = 25.9735966f; // 41CFC9ED
float b = 25.9735947f; // 41CFC9EC
``````

And now I'm trying to assign to `a` the mean between `a` and `b`:

``````a = 0.5 * (a+b);
``````

When I write this code in a test program, I get the result I want, namely `25.9735947`. But in the debugger of my original library code I see that the value of a remains `25.9735966`. I'm pretty certain that I have the same compiler flags on both programs. Is there any reason why this single-precision calculation would yield different results?

UPDATE

As @PascalCuoq requested, here is what I think is the assembly for the line in question. The line is doing a few other things though and I'm not sure where the multiplication happens.

``````.loc 1 53 0 discriminator 2
movl    -60(%rbp), %eax
cltq
salq    \$3, %rax
movq    (%rax), %rax
movl    -44(%rbp), %edx
movslq  %edx, %rdx
salq    \$2, %rdx
leaq    (%rax,%rdx), %rcx
movl    -44(%rbp), %eax
cltq
salq    \$2, %rax
movl    -60(%rbp), %edx
movslq  %edx, %rdx
salq    \$3, %rdx
movq    (%rdx), %rdx
movl    -44(%rbp), %esi
movslq  %esi, %rsi
salq    \$2, %rsi
movss   (%rdx), %xmm1
movl    -52(%rbp), %edx
movslq  %edx, %rdx
salq    \$3, %rdx
movq    (%rdx), %rdx
movl    -44(%rbp), %esi
movslq  %esi, %rsi
salq    \$2, %rsi
movss   (%rdx), %xmm0
movss   .LC6(%rip), %xmm1
mulss   %xmm1, %xmm0
movss   %xmm0, (%rax)
movl    (%rax), %eax
movl    %eax, (%rcx)
``````

CLARIFICATION

My code is a ripoff variant of the Nelder-Mead code from Numerical Recipes. The offending line is this one:

``````p[i][j]=psum[j]=0.5*(p[i][j]+p[ilo][j]);
``````

In this line, `p[i][j] == 25.9735966f` and `p[ilo][j] == 25.9735947f`. The resulting value in `p[i][j]` is `25.9735966f`.

-
I do not have an explanation yet, but 25.9735947 is the correct rounded to nearest even result, as I think you don't need me to tell you. – Pascal Cuoq Oct 28 '11 at 20:07
Any chance to see the assembly for `a = 0.5 * (a+b);` from the original library code? No other library linked in that might "helpfully" set the rounding mode? – Pascal Cuoq Oct 28 '11 at 20:14
When you say "in the debugger," do you mean when you inspect the values using the debugger, or do you mean that using the debugger version of this library, when run otherwise normally, produces different results? – Scott Hunter Oct 28 '11 at 20:14
@Pascal that's what I understood too. And I'm only 99.9% sure that those values are the ones being processed in the library code. But it would be very difficult for me to ascertain that. – lindelof Oct 28 '11 at 20:14
The code for the assignment you are concerned with is around the `mulss` instruction. There is only one in the function, so there's no ambiguity. xmm0 and xmm1 are loaded with `a` and `b`, then added into xmm0 with `addss`. .LC6 should be a label where the constant 0.5 is stored, but it may be represented as an integer (1056964608). This completely excludes the possibility of some sort of double rounding: the instructions used are single-precision instructions from the SSE instruction set. – Pascal Cuoq Oct 28 '11 at 22:31

• round to nearest, and in case of equal distance: set the least significant bit to zero => `25.9735947f`
• round towards `+INF` => `25.9735966f`
• round towards `0` => `25.9735947f`
• round towards `-INF` => `25.9735947f`
What about broken things like `-ffast-math`? Or what if the intermediate result is being computed at higher/lower precision? – R.. Oct 29 '11 at 0:38