Floating point numbers are represented internally as a binary number, almost always in IEEE format You can see how numbers are represented here:
For instance, 0.25 in binary is 0.01b and is represented as +1.00000000000000000000000 * 2-2.
This is stored internally with 1 bit for the sign, eight bits for the exponent (representing a value between -127 and +128, and 23 bits for the value (the leading 1. is not stored). In fact, the bits are:
Whereas 0.2 in binary has no exact representation, just like 1/3 has no exact representation in decimal.
Here the problem is that just as 1/2 can be represented exactly in decimal format as 0.5, but 1/3 can only be approximated to 0.3333333333, 0.25 can be represented exactly as a binary fraction, but 0.2 cannot. In binary it is 0.0010011001100110011001100....b where the last four digits repeat.
To be stored on a computer it is roudned to 0.0010011001100110011001101b. Which is really, really close, so if you're calculating coordinates or anything else where absolute values matter, it's fine.
Unfortunately, if you add that value to itself five times, you will get 1.00000000000000000000001b. (Or, if you had rounded 0.2 down to 0.0010011001100110011001100b instead, you would get 0.11111111111111111111100b)
Either way, if your loop condition is 1.00000000000000000000001b==1.00000000000000000000000b it will not terminate. If you use <= instead, it's possible it will run one extra time if the value is just under the last value, but it will stop.
It would be possible to make a format that can accurately represent small decimal values (like any value with only two decimal places). They are used in financial calculations, etc. But normal floating point values do work like that: they trade the ability to represent some small "easy" numbers like 0.2 for the ability to represent a wide range in a consistent fashion.
It's common to avoid using a float as a loop counter for that exact reason, common solutions would be:
- If one extra iteration doesn't matter, use <=
- If it does matter, make the condition <=1.0001 instead, or some other value smaller than your increment, so off-by-0.0000000000000000000001 errors don't matter
- Use an integer and divide it by something during the loop
- Use a class specially made to represent fractional values exactly
It would be possible for a compiler to optimise a float "=" loop to turn it into what you mean to happen, but I don't know if that's permitted by the standard or ever happens in practice.