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I want to know why int, double etc have 1 more negative value than positive value.

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Probably a good read. –  chris Jan 12 '13 at 7:23
Because the simplest and most mathematically convenient representation of signed integers works that way. –  Louis Wasserman Jan 12 '13 at 7:24
double generally does not have 1 more negative value than positive value. It usually has the exact same number of positive values as negative values. –  Benjamin Lindley Jan 12 '13 at 7:29
This depends on language and implementation. –  stefan Jan 12 '13 at 7:34
@stefan: For Java, it doesn't depend on the implementation. And for C and C++, can you name an implementation that didn't use two's complement? I'd be surprised if one existed, other than someone doing it as a hobby in their basement, not to be used by anyone in production. –  Benjamin Lindley Jan 12 '13 at 7:48

3 Answers 3

up vote 18 down vote accepted

In a nutshell: 0 has to fit somewhere, it is in the positives, which makes them have one less than the negatives.

Example: 5 slots for negatives and 5 for positives, negatives get -1 to -5, positives get 0 to 4

  • don't forget to read @chris link :)

As @WhozCraig pointed out, this is only valid for architectures that use two's complement representation of signed binary numbers.

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+1 this is a well-put answer for something that all-too-often comp engineers forget about two's-comp. (at least for int-twos-comps). The simple phrase "0 has to fit somewhere." is catch-phrase memorable. –  WhozCraig Jan 12 '13 at 7:37
@WhozCraig If I knew English I would have said the same thing –  Alter Mann Jan 12 '13 at 7:54
@DavidRF Yeah, I probably would have clarified in his answer that this is with respect to numbers that store signed-ness using a two-complement format, which is really what this answer is all about, but that single phrase was worth the upvote for me. If the author doesn't edit it, I just might to clarify that point. –  WhozCraig Jan 12 '13 at 7:58
@Arnaud caught me mid-edit, but you summed it up. Good for me. Still like that phrase. –  WhozCraig Jan 12 '13 at 8:15
And having 0 on the positive side is good, since it allows positive signed and unsigned to have the same representation. –  zch Jan 12 '13 at 14:26

Assume that you have an integer datatype that uses 4 bits. You can represent 16 possible signed integers with them. Positive integer values are assigned to the first half of the range:

0000b = 0
0001b = 1
0010b = 2
0011b = 3
0100b = 4
0101b = 5
0110b = 6
0111b = 7

For the second half, there are two choices:

  1. Map the 8 positions to integers -1 to -7 and the special value -0. This is used by one's complement and sign-and-magnitude representation of numbers.
  2. Map the 8 positions to integers -1 to -8. This is used by two's complement representation which most programmers are familiar with (and the one you're talking about).

The negative numbers are mapped like this:

1000b = -8
1001b = -7
1010b = -6
1011b = -5
1100b = -4
1101b = -3
1110b = -2
1111b = -1

While this might not make sense, this mapping makes it easy to perform arithmetic operations.

This does not apply to floats; they are represented differently. Most floating point representations have equal range on either side of +0/-0.

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For C, it's not guaranteed that you'll be running on a machine with two's complement arithmetic hardware (one more negative than positive). In reality, it'll probably be that way though.

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It's effectively guaranteed. I'm not aware of any significant architectures designed in the last 30+ years which don't use two's complement. –  duskwuff Jan 12 '13 at 7:41
Of course there are also non-significant architectures, not designed in the last 30 years, that still have C compilers. See Exotic architecture the standard committee cares about –  Bo Persson Jan 12 '13 at 11:35

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