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I am at the moment trying to code a titration curve simulator. But I am running into some trouble with comparing two values.

I have created a small working example that perfectly replicates the bug that I encounter:

#include <iostream>
#include <math.h>

using namespace std;

int main()
    double a, b;
    a = 5;
    b = 0;
    for(double i = 0; i<=(2*a); i+=0.1){
        b = i;
        cout << "a=" << a << "; b="<<b;
            cout << "Equal!" << endl;
            cout << endl;
    return 0;

The output at the relevant section is

a=5; b=5

However, if I change the iteration increment from i+=0.1 to i+=1 or i+=0.5 I get an output of

a=5; b=5Equal!

as you would expect.

I am compiling with g++ on linux using no further flags and I am frankly at a loss how to solve this problem. Any pointers (or even a full-blown solution to my problem) are very appreciated.

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Click me. –  Maroun Maroun Jan 5 '14 at 21:31
Don't use floating points in loop conditions... –  Vallentin Jan 5 '14 at 21:31
1.0 and 0.5 can be represented as finite, exact numbers, using floating point numbers. 0.1 on the other hand can only be represented by an infinite floating point number, which exposes a rounding error when stored in a finite floating point number. –  IInspectable Jan 5 '14 at 21:33
This: floating-point-gui.de –  Daniel Frey Jan 5 '14 at 21:34
@OliCharlesworth From the front page of floating-point-gui.de: "Maybe you asked for help on some forum and got pointed to a long article with lots of formulas that didn’t seem to help with your problem." - guess where that link points to ;) –  Daniel Frey Jan 5 '14 at 21:49

3 Answers 3

up vote 2 down vote accepted

Unlike integers, multiplying floats/doubles and adding them up doesn't produce exactly the same results.

So the best practice is find if the abs of their difference is small enough.

If you have some idea on the size of the numbers, you can use a constant:

if (fabs(a - b) < EPS) // equal

If you don't (much slower!):

float a1 = fabs(a), b1 = fabs(b);
float mn = min(a1,b1), mx = max(a1,b1);
if (mn / mx > (1- EPS)) // equal

Note: In your code, you can use std::abs instead. Same for std::min/max. The code is clearer/shorter when using the C functions.

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Why not use std::abs? It's overloaded for floating point types in C++. –  Mark Jan 5 '14 at 21:59
std::abs is also fine. Code was a little shorter in the answer with fabs - just for readability. –  egur Jan 5 '14 at 22:08

I would recommend restructuring your loop to iterate using integers and then converting the integers into doubles, like this:

double step = 0.1;

for(int i = 0; i*step<=2*a; ++i){
    b = i*step;
    cout << "a=" << a << "; b="<<b;
        cout << "Equal!" << endl;
        cout << endl;

This still isn't perfect. You possibly have some loss of precision in the multiplication; however, the floating point errors don't accumulate like they do when iterating using floating point values.

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Floating point arithmetic is... interesting. Testing equality is annoying with floats/doubles in most languages because it is impossible to accurately represent many numbers in IEEE floating point math. Basically, where you might compute an expression to be 5.0, the compiler might compute it to be 4.9999999, because it's the closest representable number in the IEEE standard.

Because these numbers are slightly different, you end up with an inequality. Because it's unmaintainble to try and predict which number you will see at compile time, you can't/shouldn't attempt to hard code either one of them into your source to test equality with. As a hard rule, avoid directly checking equality of floating point numbers.

Instead, test that they are extremely close to being equal with something like the following:

template<typename T>
bool floatEqual(const T& a, const T& b) {
  auto delta = a * 0.03;
  auto minAccepted = a - delta;
  auto maxAccepted = a + delta;
  return b > minAccepted && b < maxAccepted;

This checks whether b is within a range of + or - 3% of the value of a.

share|improve this answer
Not good if a is zero... –  egur Jan 5 '14 at 21:44
IEEE 754 floating point arithmetic is well defined, and is predictable on all implementations that implement the standard (most C++ compilers do). –  IInspectable Jan 5 '14 at 21:44
@IInspectable - intriguing. Thanks! I'm more interested in the result than the reason, but I've updated the post all the same. –  Mark Jan 5 '14 at 21:54
Bad example: 5.0 is representable in IEEE 754. 4.9999999 is not. The question contains another non-representable number, 0.1. –  MSalters Jan 6 '14 at 9:38

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