Bits representation of negative numbers

This is a doubt regarding the representation of bits of signed integers. For example, when you want to represent -1, it is equivalent to 2's complement of (+1). So -1 is represented as 0xFFFFFFF. Now when I shift my number by 31 and print the result it is coming back as -1.

``````signed int a = -1;
printf(("The number is %d ",(a>>31));//this prints as -1
``````

So can anyone please explain to me how the bits are represented for negative numbers?

Thanks.

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Looking at it from another angle: think of any N-bit (sign-extending) right shift as dividing by 2^N, rounding DOWN (towards minus infinity, not towards 0.) Hence -1 shifted right (with sign extension) any number of times will keep on producing -1. –  vladr Nov 4 '12 at 6:34

When the top bit is zero, the number is positive. When it's 1, the number is negative.

Negative numbers shifted right keep shifting a "1" in as the topmost bit to keep the number negative. That's why you're getting that answer.

For more about two's complement, see this Stackoverflow question.

@Stobor points out that some C implementations could shift 0 into the high bit instead of 1. [Verified in Wikipedia.] In Java it's dependably an arithmetic shift.

But the output given by the questioner shows that his compiler is doing an arithmetic shift.

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But y shud it print as -1,it should print as 1 rite since the top most but is 1 which represents a negative number. –  Mjack Jul 24 '09 at 4:07
@Nosredna: you should also mention that the fill-with-sign-bit behaviour is implementation specific. –  Stobor Jul 24 '09 at 4:09
Since it represents a negative number, why would it print a positive number? –  Nosredna Jul 24 '09 at 4:09
@Stobor: Oh! Good point. I didn't know it was. Do you have a good reference on that? Does any compiler shift in zeros? Anyway, from his example I think his compiler is shifting in 1s. –  Nosredna Jul 24 '09 at 4:11
@Nosredna: the CPU registers don't know anything about signed vs unsigned - LSR does "what you'd expect" if you were interpreting the bits in the register as an unsigned number, ASR does "what you'd expect" if you were interpreting the bits as a signed number. –  Stobor Jul 24 '09 at 5:27

The C standard leaves it undefined whether the right shift of a negative (necessarily signed) integer shifts zeroes (logical shift right) or sign bits (arithmetic shift right) into the most significant bit. It is up to the implementation to choose.

Consequently, portable code ensures that it does not perform right shifts on negative numbers. Either it converts the value to the corresponding unsigned value before shifting (which is guaranteed to use a logical shift right, putting zeroes into the vacated bits), or it ensures that the value is positive, or it tolerates the variation in the output.

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Or it could "or" in the top bit (or bits) after the shift. –  Nosredna Jul 24 '09 at 4:26
Thanks a lot for all the answers.Guess i m not still cleared my doyubt yet.So is it compiler or hardware specific??? –  Mjack Jul 24 '09 at 4:34
@Maddy: it depends on the hardware and the compiler. For example, if a particular CPU only has logical shift right (LSR) and not arithmetic shift right (ASR), then the compilers for that machine will use the LSR and not the non-existent ASR. It also depends on the compiler; even if a machine has both ASR and LSR, a compiler writer might decide to use LSR for both signed and unsigned quantities, for any of a number of reasons. It might be quicker; it might be consistent with other platforms where the same compiler also runs; it might be that the person writing the compiler doesn't like ASR. –  Jonathan Leffler Jul 24 '09 at 4:42

This is an arithmetic shift operation which preserves the sign bit and shifts the mantissa part of a signed number.

cheers

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Basically there are two types of right shift. An unsigned right shift and a signed right shift. An unsigned right shift will shift the bits to the right, causing the least significant bit to be lost, and the most significant bit to be replaced with a 0. With a signed right shift, the bits are shifted to the right, causing the least significant bit be be lost, and the most significant bit to be preserved. A signed right shift divides the number by a power of two (corresponding to the number of places shifted), whereas an unsigned shift is a logical shifting operation.

The ">>" operator performs an unsigned right shift when the data type on which it operates is unsigned, and it performs a signed right shift when the data type on which it operates is signed. So, what you need to do is cast the object to an unsigned integer type before performing the bit manipulation to get the desired result.

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Not necessarily a 'signed shift' for signed integers (though it is very commonly done that way) - it depends on the compiler and/or hardware. –  Jonathan Leffler Jul 24 '09 at 4:31
Yeah. That's right. I've been programming for so long on well-behaved laptop / desktop / server machines running some variant of x86 and compiling with GCC, that it's often easy to forget the difference between what assumptions are reasonable for the current application and what the standard actually guarantees. –  Michael Aaron Safyan Jul 24 '09 at 19:30

Have a look at two's complement description. It should help.

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EDIT: When the below was written, the code in the question was written as:

``````unsigned int a = -1;
printf(("The number is %d ",(a>>31));//this prints as -1
``````

If unsigned int is at least 32 bits wide, then your compiler isn't really allowed to produce -1 as the output of that (with the small caveat that you should be casting the unsigned value to int before you pass it to printf).

Because a is an unsigned int, assigning -1 to it must give it the value of UINT_MAX (as the smallest non-negative value congruent to -1 modulo UINT_MAX+1). As long as unsigned int has at least 32 bits on your platform, the result of shifting that unsigned quantity right by 31 will be UINT_MAX divided by 2^31, which has to fit within int. (If unsigned int is 31 bits or shorter, it can produce whatever it likes because the result of the shift is unspecified).

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