so, lets say I have a signed integer (couple of examples):

-1101363339 = 10111110 01011010 10000111 01110101 in binary.
-2147463094 = 10000000 00000000 01010000 01001010 in binary.
-20552      = 11111111 11111111 10101111 10111000 in binary.

now: -1101363339 >> 31 for example, should equal 1 right? but on my computer, I am getting -1. Regardless of what negative integer I pick if x = negative number, x >> 31 = -1. why? clearly in binary it should be 1.

  • 1
    Pretty sure this is still undefined behavior in C. Which is to say, there's no hard rule about what'll happen on other systems.
    – cHao
    Commented Jun 21, 2013 at 0:16
  • @cHao I remember hearing that it is up to the implementation wether to make the shift arithmetic, however most choose to do so
    – aaronman
    Commented Jun 21, 2013 at 0:17
  • 1
    @aaronman: Yeah, apparently the standard (or my copy of the draft, at least) says it's implementation-defined. Oops. :)
    – cHao
    Commented Jun 21, 2013 at 0:21
  • If you're trying to use this as a test for branch-optimization or something, just mask it afterwards: (x >> 31) & 1. Or even better, treat it as unsigned: (unsigned)x >> 31.
    – paddy
    Commented Jun 21, 2013 at 0:27
  • 1
    @paddy: Or use (x < 0).
    – jxh
    Commented Jun 21, 2013 at 0:41

4 Answers 4


Per C99 6.5.7 Bitwise shift operators:

If E1 has a signed type and a negative value, the resulting value is implementation-defined.

where E1 is the left-hand side of the shift expression. So it depends on your compiler what you'll get.

  • 9
    @aaronman: cause his answer is the only correct one.
    – liori
    Commented Jun 21, 2013 at 0:23
  • 2
    @liori actually his isn't even an answer to the OP
    – aaronman
    Commented Jun 21, 2013 at 0:24
  • 2
    @aaronman: This is the only correct answer as far as the C language is concerned...
    – Kerrek SB
    Commented Jun 21, 2013 at 0:29
  • 3
    @dgamma3 it's implementation defined, so the OP's implementation defined it to be an arithmetic shift
    – aaronman
    Commented Jun 21, 2013 at 0:34
  • 3
    @dgamma3: If you were to implement signed arithmetic with sign-magnitude or one's-complement representations, what would such a shift mean? The fact that there's "no natural best choice" is the reason why it's explicitly implementation-defined. An implementation can pick whichever methods suits it best (e.g. corresponds most closely to the hardware).
    – Kerrek SB
    Commented Jun 21, 2013 at 0:39

In most languages when you shift to the right it does an arithmetic shift, meaning it preserves the most significant bit. Therefore in your case you have all 1's in binary, which is -1 in decimal. If you use an unsigned int you will get the result you are looking for.

Per C 2011 6.5.7 Bitwise shift operators:

The result of E1 >> E2 is E1 right-shifted E2 bit positions. If E1 has an unsigned type or if E1 has a signed type and a nonnegative value, the value of the result is the integral part of the quotient of E1/ 2E2. If E1 has a signed type and a negative value, the resulting value is implementation-defined.

Basically, the right-shift of a negative signed integer is implementation defined but most implementations choose to do it as an arithmetic shift.

  • +1 For suggesting unsigned int as a solution Commented Jun 21, 2013 at 0:27
  • @Code-Guru thanks, I honestly don't understand why your answer and the other one got downvoted when the answer being upvoted isn't even an answer
    – aaronman
    Commented Jun 21, 2013 at 0:29
  • Yes, the answer by @JeffWalden doesn't really explain why the OP sees this particular behavior. Commented Jun 21, 2013 at 0:36
  • 1
    @dgamma3 An unsigned int can't be negative. So there is no "binary interpretation of a negative value" Commented Jun 21, 2013 at 1:00
  • 8
    @aaronman: +1, but you should stop whining about the plight of your answer. If you are answering questions, your answer will often not get picked (even if you think it is better).
    – jxh
    Commented Jun 21, 2013 at 1:01

The behavior you are seeing is called an arithmetic shift which is when right shifting extends the sign bit. This means that the MSBs will carry the same value as the original sign bit. In other words, a negative number will always be negative after a left shift operation.

Note that this behavior is implementation defined and cannot be guaranteed with a different compiler.

  • 5
    Nope, in C right shifting a negative value is implementation-defined behavior. Also, in C the >>> operator doesn't exist. Commented Jun 21, 2013 at 0:18
  • @jxh The other bits come from what is in the previous bit, which is the definition of a left shift. Obviously the OP doesn't know about the rules for the MSB. Commented Jun 21, 2013 at 0:19
  • I don't think they have >>> in c unfortunately
    – aaronman
    Commented Jun 21, 2013 at 0:21
  • @jxh "This means that the MSB will always be the same no matter how many bits you shift to the left" This statement is only guaranteed for the MSB. I can easily imagine an example where x >>= 1 changes every bit of x except the MSB. Commented Jun 21, 2013 at 0:21
  • @aaronman Looks like you are right. Java has it, but not C. Commented Jun 21, 2013 at 0:23

What you are seeing is an arithmetic shift, in contrast to the bitwise shift you were expecting; i.e., the compiler, instead of "brutally" shifting the bits, is propagating the sign bit, thus dividing by 2N.

When talking about unsigned ints and positive ints, a right shift is a very simple operation - the bits are shifted to the right by one place (inserting 0 on the left), regardless of their meaning. In such cases, the operation is equivalent to dividing by 2N (and actually the C standard defines it like that).

The distinction comes up when talking about negative numbers. Several negative numbers representation exist, although currently for integers most commonly 2's complement representation is used.

The problem of a "brutal" bitwise shift here is, for starters, that one of the bits is used in some way to express the sign; thus, shifting the binary digits regardless of the negative integers representation can give unexpected results.

For example, commonly in 2's representation the most significant bit is 1 for negative numbers, 0 for positive numbers; applying a bitwise shift (with zeroes inserted to the left) to a negative number would (between other things) make it positive, not resulting in the (usually expected) division by 2N

So, arithmetic shift is introduced; negative numbers represented in 2's complement have an interesting property: the division by 2N behavior of the shift is preserved if, instead of inserting zeroes from the left, you insert bits that have the same value of the original sign bit.

In this way, signed divisions by 2N can be performed with just a bit of extra logic in the shift, without having to resort to a fully-fledged division routine.

Now, is arithmetic shift guaranteed for signed integers? In some languages yes1, but in C it's not like that - the behavior of the shift operators when dealing with negative integers is left as an implementation-defined detail.

As often happens, this is due to different hardware support for the operation; C is used on vastly different platforms, and, especially in the past, there was quite a difference in the "cost" of operations depending on the platform.

For example, if the processor does not provide an arithmetic right shift instruction, the compiler would be mandated to emit a much slower DIV instruction of some kind, which could be a problem in an inner loop on slower processors. For these reasons, the C standard leaves it up to the implementor to do the most appropriate thing for the current platform.

In your case, your implementation probably chose arithmetic shift because you are running on an x86 processor, that uses 2's complement arithmetic and provides both bitwise and arithmetic shift as single CPU instructions.

  1. Actually, languages like Java even have separated arithmetic and bitwise shift operators - this is mainly due to the fact that they do not have unsigned types to e.g. store bitfields.

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