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Is it possible to detect the loss of precision, when you operate with floating-point numbers (of float, double, long double types)? Say:

template< typename F >
F const sum(F const & a, F const & b)
    F const sum_(a + b);
    // The loss of precision must be detected (here or one line above) if some fraction bit is lost due to rounding
    return sum_;

Especially intrested in case of when x87 FPU is present on target architecture, but without the intervention of the asm routines into the pure C++ code. C++11 or gnu++11 specific features also accepted if any.

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I think C++11 type traits for numerics do have something like that – Andy Prowl Jan 19 '13 at 20:49
maybe the is_exact value of the numeric_limits<T> type trait is what you're looking for – Andy Prowl Jan 19 '13 at 20:51
I think it is not possible statically, because of P bit in status word of x87 FPU should be checked only after the binary operation action has been performed. – Orient Jan 19 '13 at 20:53
check that sum-a==b and sum-b==a? Or try using fenv.h (not properly implemented by many compilers). – Marc Glisse Jan 19 '13 at 21:02
About x87 in particular, I am sure you'll find plenty of good discussions on the web (or even on SO). It complicates things because of double rounding at unpredictable times. gcc has flags to deal with it (some of which only work for C). Most portable is to write sum to a volatile variable and read it back (forces rounding). – Marc Glisse Jan 19 '13 at 21:28
up vote 4 down vote accepted

The C++ standard is very vague on the concept of floating point precision. There is no fully standard-conforming way to detect precision loss.

GNU provides an extension to enable floating-point exceptions. The exception you would want to trap is FE_INEXACT.

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It's not so much a GNU extension as GNU trying to be compliant with multiple standards. One is the language itself. Another is the IEC floating point standard, which is what dictates those floating point exceptions. – David Hammen Jan 19 '13 at 21:11
@DavidHammen good info. Interestingly (unlike C99) the C++ standard also doesn't promise IEC floats. It's a cloudy topic. – Drew Dormann Jan 19 '13 at 21:18
C99 advertises through __STDC_IEC_559__ and C++98 through std::numeric_limits<...>::is_iec559. – Marc Glisse Jan 19 '13 at 21:44

One thing that will help you is std::numeric_limits<double>::epsilon, which returns "the difference between 1 and the least value greater than 1 that is representable." In other words, it tells you the largest x>0 such that 1+x evaluates to 1.

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You may consider to use the interval arithmetic in boost library. It can guarantee the property that the error for an interval is always increasing during calculation: ∀ x ∈[a,b], f(x) ∈ f([a,b]).

In your case, you might consider to use the initial range [a-EPS,a+EPS] for the initial number a. After a series of operations, the abs(y-x) for the resulting interval [x,y] will be the (maximum) loss of precision you want to know.

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I havent really try that, but there should be a policy for you to always round it outward. It also mention the x87 floating-point unit, so I think it would be helpful for you – hwlau Jan 19 '13 at 21:20
Boost handles the rounding for you. Note that you can start from [a,a], and detect loss of precision when the interval is not a point anymore (i.e. do the operation once rounded up, once rounded down, and compare). – Marc Glisse Jan 19 '13 at 21:21

You can use something like the following:

#include <iostream>
#include <fenv.h>


template <typename F> F sum (const F a, const F b, F &error) {
    int round = fegetround();

    F c = a + b;

    F c_lo = a + b;

    F c_hi = a + b;

    error = std::max((c - c_lo), (c_hi - c));


    return c;

int main() {
    float a = 23.23528;
    float b = 4.234;
    float e;

    std::cout << sum(a, b, e) << std::endl;
    std::cout << e << std::endl;

A quick estimate of the maximum error amount is returned in the error argument. Bear in mind that switching the rounding mode flushes the floating-point unit (FPU) pipeline, so don't expect blazing fast speeds.

A better solution would be to try Interval Arithmetic (tends to give pessimistic error intervals, because variable correlations are not accounted for), or Affine Arithmetic (tracks variable correlations, and thus gives somewhat tighter error bounds).

Read here for a primer in these methods: http://citeseerx.ist.psu.edu/viewdoc/summary?doi=

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It safer to save FPU control word using fgetround before first call of fesetround then restore it at the end. – Orient Mar 16 at 18:49
It even better to use algebraic numbers, if you need true general precision. – Orient Mar 16 at 18:55
Answer has been updated. Do you mean symbolic variables? Yes, they're great - if the problem permits their use. – James Turner Mar 16 at 18:55
I mean similar to doc.cgal.org/latest/Algebraic_kernel_d/index.html implementations. – Orient Mar 17 at 1:37

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