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I have a double value d and would like a way to nudge it very slightly larger (or smaller) to get a new value that will be as close as possible to the original but still strictly greater than (or less than) the original.

It doesn't have to be close down to the last bit—it's more important that whatever change I make is guaranteed to produce a different value and not round back to the original.

(This question has been asked and answered for C, C++)

The reason I need this, is that I'm mapping from Double to (something), and I may have multiple items with the save double 'value', but they all need to go individually into the map.

My current code (which does the job) looks like this:

private void putUniqueScoreIntoMap(TreeMap map, Double score,
            A entry) {

        int exponent = 15;
        while (map.containsKey(score)) {
            Double newScore = score;
            while (newScore.equals(score) && exponent != 0) {
                newScore = score + (1.0d / (10 * exponent));
            if (exponent == 0) {
                throw new IllegalArgumentException("Failed to find unique new double value");
            score = newScore;
        map.put(score, entry);

share|improve this question
Why do you use a double type for your need? A long "modificationId" would be much easier to implement. – Benoit Courtine Sep 7 '10 at 11:25
This is pretty hacky. Why not use a map of lists? – Joeri Hendrickx Sep 7 '10 at 12:30
What @Joeri said. If you need multiple values for a key in a map, just store a list of values for each key instead. – Christoffer Hammarström Sep 7 '10 at 14:01
up vote 18 down vote accepted

Use Double.doubleToRawLongBits and Double.longBitsToDouble:

double d = // your existing value;
long bits = Double.doubleToLongBits(d);
d = Double.longBitsToDouble(bits);

The way IEEE-754 works, that will give you exactly the next viable double, i.e. the smallest amount greater than the existing value.

(Eventually it'll hit NaN and probably stay there, but it should work for sensible values.)

share|improve this answer
Is that going to be reliable on both endian-nesses? – Donal Fellows Sep 7 '10 at 11:38
That's exactly what I was looking for, thanks. – barryred Sep 7 '10 at 11:39
@Jon Skeet - Why is this a better answer than using Double.MIN_VALUE? – Erick Robertson Sep 7 '10 at 11:54
@Erick: Because that wouldn't work :) See my comments on Richard's answer. – Jon Skeet Sep 7 '10 at 12:11
Jon, and what will happen if mantis is all 1-s ? is it fine if carry will go to exponent? exponent will be incremented, so 1.11111...1eX will become 10.0000eX => 1.00000eX+1 . i have a feeling that it can break normalization at some point. is not it safer to leave FP operations to FPU? – Andrey Sep 7 '10 at 13:02

In Java 1.6 and later, the Math.nextAfter(double, double) method is the cleanest way to get the next double value after a given double value.

The second parameter is the direction that you want. Alternatively you can use Math.nextUp(double) (Java 1.6 and later) to get the next larger number and since Java 1.8 you can also use Math.nextDown(double) to get the next smaller number. These two methods are equivalent to using nextAfter with Positive or Negative infinity as the direction double.

Specifically, Math.nextAfter(score, Double.MAX_VALUE) will give you the answer in this case.

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It might be helpful to note that the second parameter is the direction to move in. – Ax. Sep 7 '10 at 13:57
Nice - didn't know about that. – Jon Skeet Sep 7 '10 at 14:11
@Ax. I'd like to think that it is not necessary to do that. All that you need to know is in the javadocs. – Stephen C Aug 25 '13 at 0:33
Java 8 added Math.nextUp(double) and Math.nextDown(double) as well so that the direction is implicit – Eben Sep 19 '14 at 4:00
@Eben: Math.nextUp(double) is available since Java 1.6. Math.nextDown(double) was added in Java 1.8. – Andreas Mayer May 7 '15 at 9:56

Have you considered using a data structure which would allow multiple values stored under the same key (e.g. a binary tree) instead of trying to hack the key value?

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What about using Double.MIN_VALUE?

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d += Double.MIN_VALUE

(or -= if you want to take away)

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Given how small MIN_VALUE is, this will often result in d not changing. – AakashM Sep 7 '10 at 11:26
not correct. if number is big then after addition and normalization Double.MIN_VALUE will evaporate and numer will not change – Andrey Sep 7 '10 at 11:29

Use Double.MIN_VALUE.

The javadoc for it:

A constant holding the smallest positive nonzero value of type double, 2-1074. It is equal to the hexadecimal floating-point literal 0x0.0000000000001P-1022 and also equal to Double.longBitsToDouble(0x1L).

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And what happens when you add that to a reasonably large value? – Jon Skeet Sep 7 '10 at 11:37
It might overflow, or it might make no difference at all, but, it is a legitimate answer to his question, as it is the smallest possible value for a double that is positive. – Richard J. Ross III Sep 7 '10 at 11:55
@Richard: Making no difference at all means it isn't a legitimate answer to the question: "It doesn't have to be close down to the last bit—it's more important that whatever change I make is guaranteed to produce a different value and not round back to the original." You've got to create a different value. Adding Double.MIN_VALUE won't always do that. – Jon Skeet Sep 7 '10 at 12:11
@Jon Skeet: I'm not quite understanding how the two answers are different. The JavaDocs say that Double.MIN_VALUE is the same as Double.logBitsToDouble(0x1L) which seems the same as "long bits = Double.doubleToLongBits(d); bits++;". Is there any more you can clarify? " – Kelly S. French Sep 7 '10 at 13:54
@Kelly: There's a difference between adding Double.MIN_VALUE to a double value, and incrementing the bit pattern representing a double. They're entirely different operations, due to the way that floating point numbers are stored. If you try to add a very little number to a very big number, the difference may well be so small that the closest result is the same as the original. Adding 1 to the current bit pattern, however, will always change the corresponding floating point value, by the smallest possible value which is visible at that scale. – Jon Skeet Sep 7 '10 at 14:10

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