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I'm currently reading through the excellent Library for Double-Double and Quad-Double Arithmetic paper, and in the first few lines I notice they perform a sum in the following way:

std::pair<double, double> TwoSum(double a, double b)
    double s = a + b;
    double v = s - a;
    double e = (a - (s - v)) + (b - v);
    return std::make_pair(s, e);

The calculation of the error, e, relies on the fact that the calculation follows that order of operations exactly because of the non-associative properties of IEEE-754 floating point math.

If I compile this within a modern optimizing C++ compiler (e.g. MSVC or gcc), can I be ensured that the compiler won't optimize out the way this calculation is done?

Secondly, is this guaranteed anywhere within the C++ standard?

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This ain't Javascript. If something as simple as that weren't well-defined by the spec, C++ programmers would scream bloody murder. But since compilers and their optimizers are written by humans (for the moment), I'd do calculations a few isomorphic ways and ensure it came out the same before feeding the output to a neurosurgery robot. For most other purposes, just assume it will behave predictably. –  HostileFork Oct 5 '11 at 2:36
@HostileFork: Well thankfully this won't be used in any critical applications such as that :) I'm reading through this for my own learning. –  Mike Bantegui Oct 5 '11 at 2:39
I'm going to test that code using different compiler optimization settings and see. :) But my bet is that the results will be the same regardless. –  user898058 Oct 5 '11 at 3:26

9 Answers 9

up vote 3 down vote accepted

Yes, that is safe (at least in this case). You only use two "operators" there, the primary expression (something) and the binary something +/- something (additive).

Section 1.9 Program execution (of C++0x N3092) states:

Operators can be regrouped according to the usual mathematical rules only where the operators really are associative or commutative.

In terms of the grouping, 5.1 Primary expressions states:

A parenthesized expression is a primary expression whose type and value are identical to those of the enclosed expression. ... The parenthesized expression can be used in exactly the same contexts as those where the enclosed expression can be used, and with the same meaning, except as otherwise indicated.

I believe the use of the word "identical" in that quote requires a conforming implementation to guarantee that it will be executed in the specified order unless another order can give the exact same results.

And for adding and subtracting, section 5.7 Additive operators has:

The additive operators + and - group left-to-right.

So the standard dictates the results. If the compiler can ascertain that the same results can be obtained with different ordering of the operations then it may re-arrange them. But whether this happens or not, you will not be able to discern a difference.

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Unfortunately, I've seen many times different compiler behavior w.r.t. floating-point code optimization and I would not want to rely on bugs or absence of thereof in the compiler implementation. And I'm not sure we have a single widely spread compiler that fully conforms to the standard. Standards are good. Bugs are bad. –  Alexey Frunze Oct 5 '11 at 3:14
"So the standard dictates the results." If so, then gcc does not provides any option to turn on standard behaviour. –  curiousguy Oct 5 '11 at 3:18
Pretty sure that's wrong. The compiler is allowed to generate any code that yields within +/- 1 LSB of the correct result, IIRC. –  Ben Voigt Oct 5 '11 at 3:23
@Ben, if you can find a citation for that, I'd accept it. I have quoted the standard and believe that to be the definitive reference. –  paxdiablo Oct 5 '11 at 4:11
@BenVoigt "+/- 1 LSB of the correct result" Not sure what this means. Is what are the allowed results of ((1.+double_epsilon/2)-1.)? –  curiousguy Oct 5 '11 at 4:12

You might like to look at the g++ manual page:

Particularly -fassociative-math, -ffast-math and -ffloat-store

According to the g++ manual it will not reorder your expression unless you specifically request it.

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I do not see any compiler option that guaranties consistent FP behaviour. –  curiousguy Oct 5 '11 at 3:16
"The following options control compiler behavior regarding floating point arithmetic. These options trade off between speed and correctness. All must be specifically enabled." –  teambob Oct 5 '11 at 3:22
@teambob: Only true for gcc. The Intel C++ compiler defaults to -fp-model fast=1. –  Ben Voigt Oct 5 '11 at 3:26
@BenVoigt What is "true of gcc"? –  curiousguy Oct 5 '11 at 3:30
@BenVoigt: Yes, the information was specifically for gcc/g++. Thanks for the interesting information about ICC. –  teambob Oct 5 '11 at 3:52

This is a very valid concern, because Intel's C++ compiler, which is very widely used, defaults to performing optimizations that can change the result.


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reason for downvote? –  Ben Voigt Oct 5 '11 at 4:59

I would be quite surprised if any compiler wrongly assumed associativity of arithmetic operators with default optimising options.

But be wary of extended precision of FP registers.

Consult compiler documentation on how to ensure that FP values do not have extended precision.

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In general, you should be able to -- the optimizer should be aware of the properties of the real operations.

That said, I'd test the hell out of the compiler I was using.

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The x86 compiler is also aware that doing a store/load of every intermediate FP result is costly. –  curiousguy Oct 5 '11 at 2:58

Yes. The compiler will not change the order of your calculations within a block like that.

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Where is it guarantied? –  curiousguy Oct 5 '11 at 2:46
In the specifications for the compiler. If you write x = (1 + 2) * 3; The result will be 9 on any worthy compiler. Period. To build on the OP's question. If you have a block of statements and one is a = b * c; d = a * e; The compiler will do them in that order. What if a wasn't initialized and it tried to compile the second statement first? –  user898058 Oct 5 '11 at 2:49
@ephaitch: But what about x = 1 + 1e25 - 1e25; What do you expect from your "any worthy compiler"? –  Ben Voigt Oct 5 '11 at 2:53
@ephaitch: No, this question is, in fact, precisely about the behavior of decimal precision in arithmetic. –  GManNickG Oct 5 '11 at 3:02
Well, then I'm confused, so I'll stay out of this conversation. Because in re-reading the OP's post, he is asking if he can be assured that "the calculation follows that order of operations" once compiled. –  user898058 Oct 5 '11 at 3:06

Between compiler optimizations and out-of-order execution on the processor, it is almost a guarantee that things will not happen exactly as you ordered them.

HOWEVER, it is also guaranteed that this will NEVER change the result. C++ follows standard order of operations and all optimizations preserve this behavior.

Bottom line: Don't worry about it. Write your C++ code to be mathematically correct and trust the compiler. If anything goes wrong, the problem was almost certainly not the compiler.

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Actually, because of the extended precision of the registers of the fp unit (notably on x86), compiler would have to store intermediate results in memory to get correctly rounded fp results. Many don't! –  curiousguy Oct 5 '11 at 2:45
@curiosguy, can you elaborate? I've always been under the assumption that all FP operations simply use the guard bit when shifting the operands in order to reduce rounding error (as is specified in the IEEE standard), but the extra information in the guard bit is discarded after the final rounding. –  Stargazer712 Oct 5 '11 at 2:48
@Stargazer712, there are many examples of programs that give different results depending on whether their intermediate results were kept in an 80-bit floating point register or if they were stored to a 64-bit double. See… for one example. –  Mark Ransom Oct 5 '11 at 2:53
@curiousguy, Stargazer712: The extra precision of the FPU does reduce rounding error. And it will not be what is called out by the IEEE-754 spec. But that does not make it "incorrect", because the C++ spec does not require exact IEEE-754 results. Instead it refers to ISO/IEC 10967. –  Ben Voigt Oct 5 '11 at 3:02
"Does any of this change for a specific compiler if you change the optimization level?" I don't know any compiler that is not broken by default on x86. –  curiousguy Oct 5 '11 at 3:11

As per the other answers you should be able to rely on the compiler doing the right thing -- most compilers allow you to compile and inspect the assembler (use -S for gcc) -- you may want to do that to make sure you get the order of operation you expect.

Different optimization levels (in gcc, -O _O2 etc) allows code to be re-arranged (however sequential code like this is unlikely to be affected) -- but I would suggest you should then isolate that particular part of code into a separate file, so that you can control the optimization level for just the calculation.

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"As per the other answers you should be able to rely on the compiler doing the right thing" As per the other comments, you should not. –  curiousguy Oct 5 '11 at 3:23

The short answer is: the compiler will probably change the order of your calculations, but it will never change the behavior of your program (unless your code makes use of expression with undefined behavior:

However, you can still influence this behavior by deactivating all compiler optimizations (option "-O0" with gcc). If you still needs the compiler to optimize the rest of your code, you may put this function in a separate ".c" which you can compile with "-O0". Additionally, you can use some hacks. For instance, if you interleaves your code with extern function calls the compiler may consider that it is unsafe to re-order your code as the function may have unknown side-effect. Calling "printf" to print the value of your intermediate results will conduct to similar behavior.

Anyway, unless you have any very good reason (e.g. debugging) you typically don't want to care about that, and you should trust the compiler.

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"it will never change the behavior of your program" This is false. FP behaviour is not consistent on most compiler by default. And apparently GCC does not even provide a standard conformant mode! –  curiousguy Oct 5 '11 at 3:21

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