People keep talking about how computer representations cannot perfectly represent real numbers, and how computer operations on floating point numbers cannot be perfectly precise.

This is true, but the same is true of the real world.

Real measurements are approximations to some degree of precision. Operations on real measurements result in approximations to some degree of precision.

If I count 17 bowling balls, I have 17 bowling balls. If I remove 16 bowling balls, I have one bowling ball.

But if I have a stick that is 17 inches long, what I really have is a stick that is about 17 inches long. If I cut off 16 inches, I'm really cutting off is about 16 inches, and what I'm left with is about 1 inch.

You have to keep track of the accuracy of your measurements, and the precision of your results. If I have 17.0, accurate to three significant digits, and subtract 16.0, also accurate to three significant digits, the result is 1.0, accurate to two significant digits. And that's what you got. Your mistake was in assuming that the extra precision provided by your results, beyond the accuracy you were given, was meaningful. It's not. It's meaningless noise.

This isn't something specific to computer floating point numbers, you have the same issue whether using a calculator or working out the problems by hand.

Keep track of your significant digits, and format your answers to suppress precision beyond what is significant.