# Can floating point error cause 'a/(double)b >= a/b' to fail?

Can `result` ever be false because `4 / 2.0` may return something like `1.99999999`? More generally than the title:

``````int a = // any valid int
int b = // any valid int
boolean result = (a/(double)b) >= a/b;
``````

If this is possible, can anyone provide an example of `a` and `b`? If this isn't possible, is there any java or floating point specification which proves this?

I wrote this logic a few minutes ago, and suddenly worried about it breaking. I have been unable to break it, but I'm wondering if it's guaranteed across all JVMs.

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If `a` and `b` are positive `int` values, then `a/(double)b >= a/b`.

I use the following premises, along with understood semantics, such as that the `int` value of `a/b` will be converted to `double` for the comparison with the other operand of `>=`.

Premises:

• The range of `int` is [-2,147,483,648, 2,147,483,648).
• `double` is IEEE 754 64-bit binary.
• The rounding mode is round-to-nearest.
• All floating-point operations, particularly division, conform to IEEE 754.
• The integer `a/b` truncates toward zero.

Notation:

• a is the mathematical value of `a`.
• b is the mathematical value of `b`.
• Mathematical expressions, such as a/b, are exact, as distinct from computed expressions such as `a/b`.
• Let L be the value produced for `a/(double)b`.
• Let R be the value produced for `a/b`.

Proof:

• All `int` values are representable in `double`, so IEEE 754 requires that converting `int` to `double` be exact.
• Therefore, `(double) a` and `(double) b` produce a and b exactly, and `a/(double)b` produces a/b correctly rounded to the nearest `double`.
• Since R is a/b truncated toward zero, and a/b is positive, R is floor(a/b).
• The greatest a/b can be is 2,147,483,647/1 = 2,147,483,647. Each integer at this magnitude and below is exactly representable as a `double`.
• L is the `double` nearest a/b. If L is reduced by rounding, it is reduced to the next lower `double`. Since all integers at this magnitude are representable, floor(a/b) is representable, so L is at least floor(a/b).
• Therefore LR.
• The conversion of R to `double` is exact, so the comparison of L to R with `>=` produces the same result as the mathematical LR.
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Thanks for the great and thorough response! –  Cory Kendall Mar 12 '13 at 6:29

For negative numbers, it fails for a = -10, b = 3.

For positive inputs only, I think you are safe.

Let x be the real number result of dividing a by b.

First consider the case where x is representable as an int. It is also representable as a double, and both calculations return x.

Now suppose x is not an int. The question is whether the absolute value of the rounding error difference between x and a/(double b) can ever exceed the truncation error for a/b. It cannot.

The truncation error t = x - a/b must be at least 1/b. x cannot be bigger than Integer.MAX_VALUE/b, so t/x is at least 1/Integer.MAX_VALUE. That is much greater than the maximum rounding error on a correctly rounded double calculation.

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`4 / 2.0` must return `2.0` because floating-point division is exact.
Negative numbers may cause your comparison to fail, though. Note that `-1/2 = 0` while `-1.0/2.0 = -0.5`.
Also because those are binary digits, no? `4 / 2.0` is `4 * 2^(-1)` which, IIRC, is how floats are stored. –  WChargin Mar 12 '13 at 0:48
Can you expand on the definition of "exact"? I assume that calculating `1/3` will lead to something like "0.33333..." to some amount of precision, but will never equal the true "exact" mathematical value of `1/3`. –  Cory Kendall Mar 12 '13 at 0:48