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I'm trying to do a kind of left shift that would add zeros at the beginning instead of ones. For example, if I left shift 0xff, I get this:

0xff << 3 = 11111000

However, if I right shift it, I get this:

0xff >> 3 = 11111111

Is there any operation I could use to get the equivalent of a left shift? i.e. I would like to get this:


Any suggestion?


To answer the comments, here is the code I'm using:

int number = ~0;
number = number << 4;   
std::cout << std::hex << number << std::endl;

number = ~0;
number = number >> 4;
std::cout << std::hex << number << std::endl;



Since it seems that in general it should work, I'm interested as to why this specific code doesn't. Any idea?

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This question doesn't make sense. You should not get the result you describe on a C compiler. Please post the actual code. –  Lundin Jan 18 '13 at 10:40
@Lundin: Not true! If the value is signed, this is actually a correct behaviour under the C standard (effectively, the sign bit is preserved.) It's an implementation-specific case. –  Jonathan Grynspan Jan 18 '13 at 10:53
@JonathanGrynspan No... the literals in the question will be of type signed integer but they will be positive. No sign bits are set, nothing is negative. The C standard is only concerned about whether the integer is negative or not. C11 6.5.7/4 (left shift) "If E1 has a signed type and nonnegative value..." "...otherwise, the behavior is undefined." C11 6.5.7/5 (right shift) "If E1 has a signed type and a negative value, the resulting value is implementation-defined." –  Lundin Jan 18 '13 at 11:02
@JonathanGrynspan: the reason it's not implementation-defined is that INT_MAX is guaranteed to be at least 2^16-1. So 0xff is a positive value of type int, and it can be shifted left by 3 without exceeding INT_MAX. What the questioner describes is not conforming behavior, so either it's not what his code really did or else his compiler's broken. –  Steve Jessop Jan 18 '13 at 11:15
Hrm, you guys are right. I was thinking (at 5somethingAM) that 0xff would be a signed char but obviously that's wrong. I retract my previous statement. Coffee, then bit shifting. –  Jonathan Grynspan Jan 18 '13 at 11:23

4 Answers 4

up vote 10 down vote accepted

This is how C and binary arithmetic both work:

If you left shift 0xff << 3, you get binary: 00000000 11111111 << 3 = 00000111 11111000

If you right shift 0xff >> 3, you get binary: 00000000 11111111 >> 3 = 00000000 00011111

0xff is a (signed) int with the positive value 255. Since it is positive, the outcome of shifting it is well-defined behavior in both C and C++. It will not do any arithmetic shifts nor any kind or poorly-defined behavior.

#include <stdio.h>

int main()

  printf("%.4X %d\n", 0xff << 3, 0xff << 3);
  printf("%.4X %d\n", 0xff >> 3, 0xff >> 3);



07F8 2040
001F 31

So you are doing something strange in your program because it doesn't work as expected. Perhaps you are using char variables or C++ character literals.

Source: ISO 9899:2011 6.5.7.

EDIT after question update

int number = ~0; gives you a negative number equivalent to -1, assuming two's complement.

number = number << 4; invokes undefined behavior, since you left shift a negative number. The program implements undefined behavior correctly, since it either does something or nothing at all. It may print fffffff0 or it may print a pink elephant, or it may format the hard drive.

number = number >> 4; invokes implementation-defined behavior. In your case, your compiler preserves the sign bit. This is known as arithmetic shift, and arithmetic right shift works in such a way that the MSB is filled with whatever bit value it had before the shift. So if you have a negative number, you will experience that the program is "shifting in ones".

In 99% of all real world cases, it doesn't make sense to use bitwise operators on signed numbers. Therefore, always ensure that you are using unsigned numbers, and that none of the dangerous implicit conversion rules in C/C++ transforms them into signed numbers (for more info about dangerous conversions, see "the integer promotion rules" and "the usual arithmetic conversions", plenty of good info about those on SO).

EDIT 2, some info from the C99 standard's rationale document V5.10:

6.5.7 Bitwise shift operators

The description of shift operators in K&R suggests that shifting by a long count should force the left operand to be widened to long before being shifted. A more intuitive practice, endorsed by the C89 Committee, is that the type of the shift count has no bearing on the type of the result.


Shifting by a long count no longer coerces the shifted operand to long. The C89 Committee affirmed the freedom in implementation granted by K&R in not requiring the signed right shift operation to sign extend, since such a requirement might slow down fast code and since the usefulness of sign extended shifts is marginal. (Shifting a negative two’s complement integer arithmetically right one place is not the same as dividing by two!)

share|improve this answer
+1 for the call of sanity! –  Matthieu M. Jan 18 '13 at 12:30
@Lundin, Yes, the lang says so. But why? a. Why are they UB/ID? and b. Why are they not both UB / ID? What is it about signed numbers with nagative values? –  Chethan Jan 22 '13 at 9:28
@Chethan I can just speculate, but it is likely because of the underlying hardware instructions on assembler level. Right shift on a negative number will default to the assembler instruction for arithmetic right shift. This can be executed as expected, because it only makes the number smaller. The data loss is expected and predicted. But if you left shift, the assembler instruction for arithmetic left shift will "shift out" bits into a carry bit in a CPU register, which you can't reach from C. –  Lundin Jan 22 '13 at 9:35
@Chethan So the C compiler could either just discard this carry bit, or it could do something fancy with it. What the programmer expects isn't obvious. On two's complement systems, the number would change into something completely different, data would get shifted into the sign bit, it just doesn't make any sense. –  Lundin Jan 22 '13 at 9:36
@Chethan I found a bit of info from the standard's rationale document, post updated above. I know too little of the initial K&R de facto standard to comment it, however. Perhaps someone else reading it could enlighten us both. –  Lundin Jan 22 '13 at 9:47

If you explicitilhy shift 0xff it works as you expected

cout << (0xff >> 3) << endl; // 31

It should be possible only if 0xff is in type of signed width 8 (char and signed char on popular platforms).

So, in common case:

You need use unsigned ints

(unsigned type)0xff

right shift works as division by 2(with rounding down, if I understand correctly).

So when you have 1 as first bit, you have negative value and after division it's negative again.

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I upvoted, but really just put a little more text. like why it make the difference. –  UmNyobe Jan 18 '13 at 10:29
0xffu works instead of the cast. –  Pubby Jan 18 '13 at 10:29
I don't understand this answer at all. 0xff is equivalent to writing (signed int)255. There is nothing in the original post setting any sign bits. 0xFF >> 3 is 0x1F, the positive number 31. –  Lundin Jan 18 '13 at 10:39
Right shift does not work as division! The rounding is different. –  Pubby Jan 18 '13 at 10:39
Note that you only have to do this for values of 0xff only if it's in a signed char type - otherwise 0xff has a non-negative value (255). I think this should be explicitly noted because I've seen people confused by thinking that 0xff has a negative value in contexts where it doesn't. –  Michael Burr Jan 18 '13 at 10:41

The two kinds of right shift you're talking about are called Logical Shift and Arithmetic Shift. C and C++ use logical shift for unsigned integers and most compilers will use arithmetic shift for a signed integer but this is not guaranteed by the standard meaning that the value of right shifting a negative signed int is implementation defined.

Since you want a logical shift you need to switch to using an unsigned integer. You can do this by replacing your constant with 0xffU.

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No, C and C++ invokes implementation-defined behavior when you right shift a negative number. There are no guarantees that the result makes any sense or that it can be represented as a correctly formatted negative number. If you left shift a negative number, you invoke undefined behavior. –  Lundin Jan 18 '13 at 10:42
Checks standard. Yes, you're correct, the type of shift is implementation defined. It's just usually an arithmetic shift. I've updated my answer. –  Jack Aidley Jan 18 '13 at 10:51
@Lundin - could you elaborate or point to std. –  Chethan Jan 18 '13 at 10:52
@Chethan Yes, I've posted an answer of my own. As a rule of thumb, when you use bit-wise operators, C does not know or care of the programmer's intended representation of the contents. It just manipulates the bits. For example, whether the result of right shift of a signed number happens to end up in a way that makes sense or not, depends on the compiler. –  Lundin Jan 18 '13 at 10:58

To explain your real code you just need the C++ versions of the quotes from the C standard that Lundin gave in comments:

int number = ~0;
number = number << 4;

Undefined behavior. [expr.shift] says

The value of E1 << E2 is E1 left-shifted E2 bit positions; vacated bits are zero-filled. If E1 has an unsigned type, the value of the result is E1 × 2E2, reduced modulo one more than the maximum value representable in the result type. Otherwise, if E1 has a signed type and non-negative value, and E1×2E2 is representable in the result type, then that is the resulting value; otherwise, the behavior is undefined.

number = ~0;
number = number >> 4;

Implementation-defined result, in this case your implementation gave you an arithmetic shift:

The value 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 non-negative 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

You should use an unsigned type:

unsigned int number = -1;
number = number >> 4;
std::cout << std::hex << number << std::endl;


share|improve this answer
The C11 and C++11 standards seem 100% identical in their description of the shift operators. –  Lundin Jan 18 '13 at 15:41
@Lundin: yes, I didn't mean to imply the rules (or even the text) are different. It's just that the questioner has since explained in a comment that they're using C++, previously it was unclear. –  Steve Jessop Jan 18 '13 at 15:51

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