When I write the following program and use the GNU C++ compiler, the output is 1 which I think is due to the rotation operation performed by the compiler.

#include <iostream>

int main()
    int a = 1;
    std::cout << (a << 32) << std::endl;

    return 0;

But logically, as it's said that the bits are lost if they overflow the bit width, the output should be 0. What is happening?

The code is on ideone, http://ideone.com/VPTwj.

  • 1
    You might want to show exactly what command line (switches) you have used, what version of GCC and also on which platform. Sep 13, 2011 at 12:35
  • 3
    @xanatos How do you know that this is a "wrong" question?! Sep 13, 2011 at 12:36
  • 5
    @awoodland I too think so. According to latest draft: "The behavior is undefined if the right operand is negative, or greater than or equal to the length in bits of the promoted left operand." (5.8) N3291 Sep 13, 2011 at 12:38
  • 1
    The problem is that, as given by the OP, the question was illogical. He said "look here, it gives me 1", but the example he gave returned 0 :-)
    – xanatos
    Sep 13, 2011 at 12:38
  • 3
    @Arak Before speaking, at least follow the link and watch the history. His original message was: when i write the following program on GNU C++ compiler http://ideone.com/VPTwj it shows me an output of 1 then please follow the link and look at the upper left: language: C++ (gcc-4.3.4). I think it's as much clear as it can be.
    – xanatos
    Sep 13, 2011 at 12:47

10 Answers 10


This is caused due to a combination of an undefined behaviour in C and the fact that code generated for IA-32 processors has a 5 bit mask applied on the shift count. This means that on IA-32 processors, the range of a shift count is 0-31 only. 1

From The C programming language 2

The result is undefined if the right operand is negative, or greater than or equal to the number of bits in the left expression’s type.

From IA-32 Intel Architecture Software Developer’s Manual 3

The 8086 does not mask the shift count. However, all other IA-32 processors (starting with the Intel 286 processor) do mask the shift count to 5 bits, resulting in a maximum count of 31. This masking is done in all operating modes (including the virtual-8086 mode) to reduce the maximum execution time of the instructions.

1 http://codeyarns.com/2004/12/20/c-shift-operator-mayhem/

2 A7.8 Shift Operators, Appendix A. Reference Manual, The C Programming Language

3 SAL/SAR/SHL/SHR – Shift, Chapter 4. Instruction Set Reference, IA-32 Intel Architecture Software Developer’s Manual


In C++, shift is only well-defined if you shift a value less steps than the size of the type. If int is 32 bits, then only 0 to, and including, 31 steps is well-defined.

So, why is this?

If you take a look at the underlying hardware that performs the shift, if it only has to look at the lower five bits of a value (in the 32 bit case), it can be implemented using less logical gates than if it has to inspect every bit of the value.

Answer to question in comment

C and C++ are designed to run as fast as possible, on any available hardware. Today, the generated code is simply a ''shift'' instruction, regardless how the underlying hardware handles values outside the specified range. If the languages would have specified how shift should behave, the generated could would have to check that the shift count is in range before performing the shift. Typically, this would yield three instructions (compare, branch, shift). (Admittedly, in this case it would not be necessary as the shift count is known.)

  • But... why is this undefined behavior? Why couldn't the low-level code perform the subtraction, determine that it need consider only the lowest zero bits, and return 0 without inspecting the value at all?
    – Beta
    Sep 13, 2011 at 12:43
  • 5
    @Beta - it's undefined so as not to encumber implementations with the burden of emulating in software what was "the norm" in hardware at the point in time when the standard was conceived.
    – Flexo
    Sep 13, 2011 at 12:46
  • 2
    @Beta: interesting question ! Most of those undefined operations map directly to processor instructions. The behavior is generally undefined because doing otherwise would require checks prior to the operations that would not be implemented efficiently on most architectures. Typical safety/speed tradeof. Sep 13, 2011 at 12:49
  • 11
    @Beta: "Don't pay for what you don't need" principle. You can do the check, if your code needs it. But if the check was automatic, you could not not do it.
    – MSalters
    Sep 13, 2011 at 13:53
  • 1
    @Beta, Imagine the instruction for shift in a certain computer takes 5 bits. No matter what you do, you just can't shift a variable by 32! (Something like 01011 (shift) 010 (to register 2) 110 (from register 6) ????? (shift amount) (This is an imaginary but very possible instruction))
    – Shahbaz
    Oct 14, 2011 at 12:39

It's undefined behaviour according to the C++ standard:

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 × 2^E2, 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 E1×2^E2 is representable in the result type, then that is the resulting value; otherwise, the behavior is undefined.

  • 5
    that's some mighty quick standard searching!
    – Flexo
    Sep 13, 2011 at 12:39
  • 3
    @awoodland Yes, Google is seriously impressive! Sep 13, 2011 at 12:39
  • 2
    @AnkitSablok Undefined behavior means that any behavior can happen ;) check: stackoverflow.com/questions/2397984/… Sep 13, 2011 at 12:42
  • 3
    @Ankit The answer should not be 0. The answer is undefined. The answer could be anything. This is the essence of undefined behaviour. Sep 13, 2011 at 12:44
  • 2
    @AnkitSablok - it DOES justify the behaviour. The point is that when behaviour is undefined the compiler is allowed to do anything it pleases. At best guess the compiler has simply decided to do nothing (which is perfectly valid according to the standard)
    – V.S.
    Sep 13, 2011 at 12:45

The answers of Lindydancer and 6502 explain why (on some machines) it happens to be a 1 that is being printed (although the behavior of the operation is undefined). I am adding the details in case they aren't obvious.

I am assuming that (like me) you are running the program on an Intel processor. GCC generates these assembly instructions for the shift operation:

movl $32, %ecx
sall %cl, %eax

On the topic of sall and other shift operations, page 624 in the Instruction Set Reference Manual says:

The 8086 does not mask the shift count. However, all other Intel Architecture processors (starting with the Intel 286 processor) do mask the shift count to five bits, resulting in a maximum count of 31. This masking is done in all operating modes (including the virtual-8086 mode) to reduce the maximum execution time of the instructions.

Since the lower 5 bits of 32 are zero, then 1 << 32 is equivalent to 1 << 0, which is 1.

Experimenting with larger numbers, we would predict that

cout << (a << 32) << " " << (a << 33) << " " << (a << 34) << "\n";

would print 1 2 4, and indeed that is what is happening on my machine.


It doesn't work as expected because you're expecting too much.

In the case of x86 the hardware doesn't care about shift operations where the counter is bigger than the size of the register (see for example SHL instruction description on x86 reference documentation for an explanation).

The C++ standard didn't want to impose an extra cost by telling what to do in these cases because generated code would have been forced to add extra checks and logic for every parametric shift.

With this freedom implementers of compilers can generate just one assembly instruction without any test or branch.

A more "useful" and "logical" approach would have been for example to have (x << y) equivalent to (x >> -y) and also the handling of high counters with a logical and consistent behavior.

However this would have required a much slower handling for bit shifting so the choice was to do what the hardware does, leaving to the programmers the need to write their own functions for side cases.

Given that different hardware does different things in these cases what the standard says is basically "Whatever happens when you do strange things just don't blame C++, it's your fault" translated in legalese.

  • A bit more precisely, at least in the case of older versions of gcc, a<<b would be implemented as equivalent to a<<(b&31). I actually relied on this behavior once upon a time in a game, where a>>33 was faster and generated equivalent code to a>>1 (due to some implementation details of the 80486 CPU). Of course in retrospect I realize how foolish it was to do that, but I was young and inexperienced, and it DID give me a significant speed increase in an often-run inner loop.
    – fluffy
    Sep 13, 2011 at 17:11
  • @fluffy: It's not gcc, it's the processor. Given that the standard doesn't require any specific behavior what the guys from gcc did was just to use the assembler instruction for the shift not caring about what to do in case the counter was too big or negative. If you check the manual I pointed to you will see that indeed the x86 family uses the low 5 bits of the counter, ignoring the others... in their words "The count is masked to five bits, which limits the count range to 0 to 31". The standard wanted to leave this exact freedom, so that shift can become just one asm instruction.
    – 6502
    Sep 13, 2011 at 17:24
  • Yes, but in this case it's a matter of how the code is generated by the compiler. It was a case of shr eax vs. shr eax,1, and the fact that gcc had a design facet in which shr eax,33 would AND the immediate operand with 31 to ensure that it fit into the 5-bit parameter slot in the instruction. Immediate-mode shr has the shift amount encoded directly in the instruction, at least on x86 and most other CISC architectures. i.e. it's a matter of how the compiler is doing the masking TO SUPPORT THE CPU. It's a fine distinction but important.
    – fluffy
    Sep 13, 2011 at 22:18
  • @fluffy: The reason for which the standard doesn't mandate a behavior when counter is bigger than the bit size of the value is to avoid a performance penality in case of a parametric shift. In case of a constant shift (e.g. 33) a compiler could just simplify to a constant 0 without any performance penality. That gcc decided to keep uniform behavior to the parametric case is a reasonable choice but not the only one (I hope at least a warning was emitted tho). If you need control on the asm instruction generated just use asm... using a non-specified behavior is looking for trouble.
    – 6502
    Sep 14, 2011 at 6:03
  • At the time, gcc didn't emit a warning, but this was in the gcc 2.x days. Nowadays it does emit a warning, which is why I'd even remembered I was doing this terrible thing since I was dusting off old code for nostalgia's sake. :) And yes, I am fully aware that the behavior was unspecified and that to rely on it is a bad idea. I was just adding more to your answer about one of the particular ways it can behave that is different than the way you were stating. I should have been more precise that I was using immediate-mode >> rather than register-mode >> though.
    – fluffy
    Sep 14, 2011 at 15:47

Shifting a 32 bit variable by 32 or more bits is undefined behavior and may cause the compiler to make daemons fly out of your nose.

Seriously, most of the time the output will be 0 (if int is 32 bits or less) since you're shifting the 1 until it drops off again and nothing but 0 is left. But the compiler may optimize it to do whatever it likes.

See the excellent LLVM blog entry What Every C Programmer Should Know About Undefined Behavior, a must-read for every C developer.

  • 1
    IMO it's not the compiler in this case, it's the hardware that doesn't handle shifts bigger than registers. The standard simply didn't want to specify something that would require fatter and slower code for all parametric shifts on some CPUs.
    – 6502
    Sep 13, 2011 at 12:51

Since you are bit shifting an int by 32 bits; you'll get: warning C4293: '<<' : shift count negative or too big, undefined behavior in VS. This means that you're shifting beyond the integer and the answer could be ANYTHING, because it is undefined behavior.

  • It doesn't mean the answer could be 0 or 1, it means that absolutely anything could happen
    – Flexo
    Sep 13, 2011 at 12:48

You could try the following. This actually gives the output as 0 after 32 left shifts.


using namespace std;

int main()
  int a = 1;
  a <<= 31;
  cout << (a <<= 1);
  return 0;
  • 2
    This doesn't explain why there's a difference between a shift of 32 places, and two shifts that add up to 32 places. Aug 3, 2016 at 10:50

I had the same problem and this worked for me:

f = ((long long)1 << (i-1));

Where i can be any integer bigger than 32 bits. The 1 has to be a 64 bit integer for the shifting to work.


Try using 1LL << 60. Here LL is for long long. You can shift now to max of 61 bits.

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