Properly testing two floating-point numbers for equality is something that a lot of people, including me, don't fully understand. Today, however, I thought about how some standard containers define equality in terms of operator<. I always see people with problems surrounding equality, but never with the other relational comparisons. There are even silent versions of them to use, which include everything except for equality and inequality.

Assuming operator< works "properly", unlike operator==, why couldn't we do this:

bool floateq(float a, float b) {
    //check NaN
    return !(a < b) && !(b < a);

In fact, I did run a test with an additional overload for doubles, as seen here, and it seems to have the same pitfalls as comparing them with operator==:

std::cout << "float->double vs double: " 
          << floateq(static_cast<double>(0.7f), 0.7) << " " 
          << (static_cast<double>(0.7f) == 0.7) << "\n";


float->double vs double: 0 0

Am I to worry about using all comparison operators, or is there some other aspect of comparing floating-point numbers that I'm not understanding correctly?

  • 3
    There's nothing wrong with equality-comparing floating point values per se. The problem is that the result may not behave as expected. – Kerrek SB Jul 15 '13 at 20:52

The ==, <, >, <=, >=, and != operators work just fine with floating-point numbers.

You seem to have the premise that some reasonable implementation of < ought to compare (double)0.7f equal to 0.7. This is not the case. If you cast 0.7f to a double, you get 0x1.666666p-1. However, 0.7 is equal to 0x1.6666666666666p-1. These are not numerically equal; in fact, (double)0.7f is considerably smaller than 0.7 --- it would be ridiculous for them to compare equal.

When working with floating-point numbers, it is important to remember that they are floating-point numbers, rather than real numbers or rational numbers or any other such thing. You have to take into account their properties and not the properties everyone wants them to have. Do this and you automatically avoid most of the commonly-cited "pitfalls" of working with floating-point numbers.

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  • I think this is exactly what I needed. It didn't click that casting the float leaves the extra precision part different from a double that had it originally. Thus, one has to be less than the other, and therefore not equal. It's such a shame, too, because it would have made my life so much easier if this had worked :p – chris Jul 15 '13 at 21:23
  • Great question and also great answer. For anyone writing software dealing with money, I use the comparison if( abs(a-b) < 0.001 ). Normally, financial systems only go to one-half cent or at the most to one-tenth. Definitely is important to clarify carefully. – Chris K Sep 11 '13 at 6:21
  • It's very risky to do financial calculations with floating point numbers. Generally it's done with either an integer number of pennies, or with a decimal representation. Either way, you still need to exercise great care. – Phil Perry Jul 9 '14 at 16:38
  • @PhilPerry: People who have never done financial calculations really love saying that. I don't understand why. Using floating-point for money, as long as you pay attention to what you're doing, is an excellent idea if speed is paramount. – tmyklebu Jul 9 '14 at 17:03
  • @tmyklebu, it's riskier to do financial in floating point because of all the numerical processing gotchas that can bite you, compared to integer or decimal. If you really pay attention, and know all the shortcomings of floating point and how to get around them, then you might just be able to pull it off. – Phil Perry Jul 9 '14 at 19:18

When using floating-point numbers, the relational operators have meanings, but their meanings don't necessarily align with how actual numbers behave.

If floating-point values are used to represent actual numbers (their normal purpose), the operators tend to behave as follows:

  • x > y and x >= y both imply that the numeric quantity which x is supposed to represent is likely greater than y, and at worst probably not much less than y.

  • x < y and x <= y both imply that the numeric quantity which x is supposed to represent is likely less than than y, and is at worst probably not much greater than y.

  • x == y implies that the numeric quantities which x and y represent are indistinguishable from each other

Note that if x is of type float, and y is of type double, the above meanings will be achieved if the double argument is cast to float. In the absence of a specific cast, however, C and C++ (and also many other languages) will convert a float operand to double before performing a comparison. Such conversion will greatly reduce the likelihood that the operands will be reported "indistinguishable", but will greatly increase the likelihood that the comparison will yield a result contrary to what the intended numbers actually indicate. Consider, for example,

float f = 16777217;
double d = 16777216.5;

If both operands are cast to float, the comparison will indicate that the values are indistinguishable. If they are cast to double, the comparison will indicate that d is larger even though the value f is supposed to represent is slightly bigger. As a more extreme example:

float f = 1E20f;
float f2 = f*f;
double d = 1E150;
double d2 = d*d;

Float f2 contains the best float representation of 1E40. Double d2 contains the best double representation of 1E400. The numerical quantity represented by d2 is hundreds of orders of magnitude greater than that represented byf2, but(double)f2 > d2. By contrast, converting both operands to float would yieldf2 == (float)d2`, correctly reporting that the values are indistinguishable.

PS--I am well aware that IEEE standards require that calculations be performed as though floating-point values represent precise power-of-two fractions, but few people seeing the code float f2 = f1 / 10.0; as being "Set f2 to the representable power-of-two fraction which is closest to being one tenth of the one in f1". The purpose of the code is to make f2 be a tenth of f1. Because of imprecision, the code cannot fulfill that purpose perfectly, but in most cases it's more helpful to regard floating-point numbers as representing actual numerical quantities than to regard them as power-of-two fractions.

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The following code (which I changed so it compiles: Specifically the call to floateq was changed to floatcmp) prints out float->double vs double: 1 0 , not 0 0 (as one would expect when comparing those two values as floats).

#include <iostream>

bool floatcmp(float a, float b) {
    //check NaN
    return !(a < b) && !(b < a);

int main()
    std::cout << "float->double vs double: "
              << floatcmp(static_cast<double>(0.7f), 0.7) << " "
              << (static_cast<double>(0.7f) == 0.7) << "\n";

However what matters for the standard library is that operator< defines a strict weak ordering, which it in fact does for floating point types.

The problem with equality is that two values may look the same when rounded to say 4 or 6 places but are in fact totally different and compare as not equal.

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  • Sorry, the code sample I posted was mainly taken from my test, which was linked to. That has an overload for two floats and an overload for two doubles. I touched up the question to better reflect that and keep the name consistent. – chris Jul 15 '13 at 20:54
  • Regarding the actual answer, shouldn't that bit of fluff however many decimal places in be accommodated for by operator<? – chris Jul 15 '13 at 20:58
  • operator< is not a strict weak ordering for floating-point types, though, because !(1 < NaN) and !(2 < NaN) but 1 < 2. Transitivity of equality fails. – tmyklebu Jul 15 '13 at 21:10
  • @tmyklebu, Is it a strict weak ordering when NaN is not a possibility, though? – chris Jul 15 '13 at 21:12
  • @chris: Indeed it is. – tmyklebu Jul 15 '13 at 21:17

Float and double are both in the binary equivalent of scientific notation, with a fixed number of significant bits. If the infinite precision result of a calculation is not exactly representable, the actual result is the closest one that is exactly representable.

There are two big pitfalls with this.

  1. Many simple, short decimal expansions, such as 0.1, are not exactly representable in float or double.
  2. Two results that would be equal in real number arithmetic can be different in floating point arithmetic. For example, floating point arithmetic is not associative - (a + b) + c is not necessarily the same as a + (b + c)

You need to pick a tolerance for comparisons that is larger than the expected rounding error, but small enough that it is acceptable in your program to treat numbers that are within the tolerance as being equal.

If there is no such tolerance, it means you are using the wrong floating point type, or should not be using floating point at all. 32-bit IEEE 754 has such limited precision that it can be really challenging to find an appropriate tolerance. Usually, 64-bit is a much better choice.

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Generally all comparison operations on floating point numbers should be done within a specified precision limit. Otherwise, you may be bitten by accumulated rounding error which is not seen at low precision, but will be taken into account by comparison operators. It just often doesn't matter much for sorting.

Another code sample which does show that your comparison doesn't work (http://ideone.com/mI4S76).

#include <iostream>

bool floatcmp(float a, float b) {
    //check NaN
    return !(a < b) && !(b < a);

int main() {
    using namespace std;

    float a = 0.1;
    float b = 0.1;

    // Introducing rounding error:
    b += 1;
    // Just to be sure change is not inlined
    cout << "B after increase = " << b << endl;
    b -= 1;
    cout << "B after decrease = " << b << endl;

    cout << "A " << (floatcmp(a, b) ? "equals" : "is not equal to") << "B" << endl;


B after increase = 1.1
B after decrease = 0.1
A is not equal toB
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  • Where is the random past-preicision part of a float stored? I only see a sign bit, an exponent, and a significand. – tmyklebu Jul 15 '13 at 21:07
  • Well, I have to agree that the wording I used is kind of frustrating. Updated. – Artem Tokmakov Jul 15 '13 at 21:45
  • 2
    The trouble with your updated answer is that you have to pick that tolerance somehow. It can't be too big, or you'll falsely say that two different things are equal, and it can't be too small, or you'll falsely say that two "equal" things are different. Picking the tolerance, when it can be done at all, usually requires a careful analysis of the input and the roundoff arising from the computation that you do on that input, by which point it's probably obvious to you that you will need to compare within a tolerance. – tmyklebu Jul 15 '13 at 21:48

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