First of all, the exact behavior and accuracy of floating-point numbers is not defined by the C standard. If we assume IEEE-754 double-precision floating point numbers, then the following can be said:

`DBL_EPSILON`

(about 2.2e-16) is defined as the difference between 1 and the next greater representable number. This means that if you add at least `DBL_EPSILON / 2`

to 1.0, the result will be closer to `1.0 + DBL_EPSILON`

than to 1.0 so the result will not be 1.0. For your code, `c`

is less than `DBL_EPSILON / 2`

, so `1.0 + c`

gives `1.0`

.

(Note: I assume here that the rounding mode is to round to the nearest number, which is the default on most implementations. Other rounding modes can give different results).

When you go below a power of two (such as 1.0), the density of floating-point numbers doubles. This means that the effective value of epsilon drops to half its value. So `DBL_EPSILON / 4`

would be the minimum value that, when subtracted from 1.0, will give a different result. Since `c > DBL_EPSILON / 4`

, `1.0 - c`

gives a different result.

The result of this is that the first addition to `a`

will have no effect but the subtraction will change it, so it will end up with a value less than 1. `b`

will be affected by both operations and end up equal to 1.0.

This is verified by trying it out, giving:

a=0.99999999999999988898 b=1.00000000000000000000

`a`

is less than 1 and`b`

is equal to 1… – Arkku Dec 9 '19 at 14:16