Propagation of uncertainty is from the field of statistics and refers to how uncertainties in inputs affect mathematical functions of them. The analysis of errors that occur in computational arithmetic is numerical analysis.
FLT_EPSILON is not a measure of uncertainty or error in floating-point results. It is the distance between 1 and the next value representable in the
float type. Hence, it is the size of steps between representable numbers at the magnitude of 1.
When you convert a decimal numeral to floating-point, the rounding error that results may have a magnitude of up to ½ the step size when the common round-to-nearest mode is used. The reason the bound is ½ the step size is that for any number x (within the finite domain of the floating-point format), there is a representable value within ½ the step size (inclusive). This is because, if there is a representable number more than ½ the step size in one direction, there is a representable number less than ½ the step size in the other direction.
The step size varies with the magnitudes of the numbers. With binary floating-point, it doubles at 2, and again at 4, then 8, and so on. Below 1, it halves, and again at ½, ¼, and so on.
When you perform floating-point arithmetic operations, the rounding that occurs in the computation may compound or cancel previous errors. There is no general formula for the final error.
The two numerals use used in your sample code,
1.192092896e-7f, are so close together that they convert to the same
float value, 2−23. That is why there is no difference in your
There is a difference between
f2, but you did not print enough digits to display it.
You ask “Should not the
float value of
x + FLT_EPSILON and
x - FLT_EPSILON be the same?”, but your code does not contain
x - FLT_EPSILON.
Re: “My question is being
R the float value of
x, what is the
y value that
x + y ||
x - y equals the same
R float value?” This is trivially satisfied by
y = 0. Did you mean to ask what is the largest value of
y that satisfies the condition? That is a bit complicated.
The step size for a number x is called the ULP of x, which we may consider as a function ULP(x). ULP stands for Unit of Least Precision. It is the place value of the least digit in the floating-point representation of x. It is not a constant; it is a function of x.
For most values representable in a floating-point format, the largest
y that satisfies your condition is ½ ULP(x) of the least digit in the floating-point representation of x is even and, if the digit is odd, it is just under ½ ULP(x). This complication arises from the rule that the results of arithmetic are rounded to the nearest representable value and, in case of a tie, the value with the even low digit is chosen. Thus, adding ½ ULP(x) to x will yield a tie that will round to x if the low digit is even, but will not round to x if the low digit is odd.
However, for x that are on the boundary where the ULP changes, the largest
y that satisfies your condition is ¼ ULP(x). This is because, just below x (in magnitude), the step size changes, and the next number lower than x is half of x’s step size away instead of the usual full step size. So you can only go halfway toward that value before changing the result of the subtraction, so the most
y can be is ¼ ULP(x).