If newDisplayWidth is less than 1125899906842624 and the other integers are positive and do not exceed 53 bits, then `newSelectionWidth`

equals `newDisplayWidth`

. A proof follows.

Notation:

- I will use the term
`double`

to name the floating-point type being used, IEEE-754 64-bit binary.
- Text in
`code`

style represents computed values, while plain text represents mathematical values. Thus 1/3 is exactly one-third, while `1./3.`

is the result of dividing 1 by 3 in floating-point arithmetic.

I assume:

- The widths are positive integers not wider than the
`double`

significand (53 bits).
- The divisions
`oldDisplayImageWidth / realImageWidth`

and `newDisplayImageWidth / realImageWidth`

are performed in `double`

arithmetic with the operands converted to `double`

.

The limits on the integers assures that conversion to `double`

is exact and that overflow and underflow are not encountered during the operations used in this problem.

Consider `oldScale`

, which is a `double`

set to `oldDisplayImageWidth / realImageWidth`

. The maximum error in a single floating-point operation in round-to-nearest mode is half an ULP (because every mathematical number is no farther than half an ULP from a representable number). Thus, `oldScale`

equals oldDisplayImageWidth / realImageWidth • (1+e_{0}), where e_{0} represents the relative error and is at most half a `double`

epsilon. (The `double`

epsilon is 2^{-52}, so |e_{0}| ≤ 2^{-53}.)

Similarly, `newScale`

is newDisplayImageWidth / realImageWidth • (1+e_{1}), where e_{1} is some error that is at most 2^{-53}.

Then `oldSelectionWidth / oldScale`

is oldSelectionWidth / `oldScale`

• (1+e_{2}), again for some e_{2} ≤ 2^{-53}, and `oldSelectionWidth / oldScale * newScale`

is oldSelectionWidth / `oldScale`

• (1+e_{2}) • `newScale`

• (1+oldSelectionWidth / `oldScale`

• (1+e_{3}). Note that this is the argument passed to `round`

.

Now substitute the expressions we have for `oldScale`

and `newScale`

. This yields oldSelectionWidth / (oldDisplayImageWidth / realImageWidth • (1+e_{0})) • (1+e_{2}) • (newDisplayImageWidth / realImageWidth • (1+e_{1})) • (1+e_{3}). The realImageWidth terms cancel, and we can rearrange the others to produce oldSelectionWidth • newDisplayImageWidth / oldDisplayImageWidth • (1+e_{1}) • (1+e_{2}) • (1+e_{3}) / (1+e_{0}).

We are given that oldSelectionWidth equals oldDisplayImageWidth, so those cancel, and the argument to `round`

is exactly: newDisplayImageWidth • (1+e_{1}) • (1+e_{2}) • (1+e_{3}) / (1+e_{0}).

Consider the combined error terms minus one (this is the relative error in the final value): (1+e_{1}) • (1+e_{2}) • (1+e_{3}) / (1+e_{0}) – 1. This expression has greatest magnitude when e_{0} is –2^{-53} and the others are +2^{-53}. Then it is slightly greater than 2 ULP (at most 324518553658426753804753784799233 / 730750818665451377972204001751459814038961127424). If newDisplayImageWidth is less than 1125899906842624, then newDisplayImageWidth times this relative error is less than ½. Therefore, newDisplayImageWidth • (1+e_{1}) • (1+e_{2}) • (1+e_{3}) / (1+e_{0}) would be within ½ of newDisplayImageWidth.

Since newDisplayImageWidth is an integer, if the argument to `round`

is within ½ of newDisplayWidth, then the result is newDisplayWidth.

Therefore, if newDisplayWidth is less than 1125899906842624, then `newSelectionWidth`

equals `newDisplayWidth`

.

(The above proves that 1125899906842624 is a sufficient limit, but it may not be necessary. A more involved analysis may be able to prove that certain combinations of errors are impossible, so the maximum combined error is less than used above. This would relax the limit, allowing larger values of newDisplayWidth.)