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I have a doubt in Left Shift Operator

int i = 1;
i <<= (sizeof (int) *8);
cout << i;

It prints 1.

  1. i has been initialized to 1.
  2. And while moving the bits till the size of the integer, it fills the LSB with 0's and as 1 crosses the limit of integer, i was expecting the output to be 0.

How and Why it is 1?

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What if you <<8 separately sizeof (int) times? –  user166390 Feb 24 '12 at 10:41
1  
strange that compiler did not warn you –  triclosan Feb 24 '12 at 10:46
    
@triclosan: True. g++ warns even without any extra warn-level. You have to shut it up forcibly with -w to keep it from warning. –  bitmask Feb 24 '12 at 10:59
    
i = (int)((((unsigned int)i) << (sizeof(int)*4)) << (sizeof(int)*4)) works whenever sizeof(unsigned int) <= sizeof(int). But why not just write int i = 0; in the first place? –  Daniel Fischer Feb 24 '12 at 12:26

4 Answers 4

Let's say sizeof(int) is 4 on your platform. Then the expression becomes:

i = i << 32;

The standard says:

6.5.7-3

If the value of the right operand is negative or is greater than or equal to the width of the promoted left operand, the behavior is undefined.

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2  
try avoiding undefined behaviors!! –  Rohit Feb 24 '12 at 10:42
    
Which standard? The question is tagged c and c++. –  bitmask Feb 24 '12 at 10:42
    
@bitmask I was referring to the C99 standard. I guess my brain must have filtered out the C++ tag and the cout :-? –  cnicutar Feb 24 '12 at 10:43
    
Lets say sizeof (int) is 4 I redo the same operation as: i <<= 30; i <<= 1; i <<= 1; Due to statement 1, the value in bit becomes 0100 0000 ... (24 0's) Then by statement 2, it gets shifted left by 1 and turnes as negative number. And i expected the bit to be as 1000 0000 ... (24 0's) So as per the previous one, i was expecting the next statement to be 0 on left shifting by 1. –  SivaSu Feb 24 '12 at 11:03
1  
@bitmask, doesn't really matter, C++ (5.8/1 in C++2011) has the same constraint. –  AProgrammer Feb 24 '12 at 13:20

As cnicutar said, your example exhibits undefined behaviour. That means that the compiler is free to do whatever the vendor seems fit, including making demons fly out your nose or just doing nothing to the value at hand.

What you can do to convince yourself, that left shifting by the number of bits will produce 0 is this:

int i = 1;
i <<= (sizeof (int) *4);
i <<= (sizeof (int) *4);
cout << i;
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I'm not sure this is right, since i is signed. Consider this: If E1 has a signed type and nonnegative value and E1 x 2^E2 is representable in the result type, then that is the resulting value; otherwise, the behavior is undefined. Now your example clearly produces 2^32 which is not representable in an int. –  cnicutar Feb 24 '12 at 10:46
2  
@cnicutar: Yes, the output is undefined by the standard, just like the OP. However, while leaving the proper domain of C++, it will produce 0 on any implementation I know (although I hate "it works on my machine" arguments: ideone.com/tMDVl ... against my better judgement). –  bitmask Feb 24 '12 at 10:55
1  
One cause of problem is that if shifting change the sign bit (and historically, in some machines -- the one I can think of were sign and magnitude -- the sign bit doesn't take part of shift) you won't get E1 x 2^E2. My guess is that it is UB instead of just unspecified so that compilers don't have to protect against trap values -- something rare nowadays. –  AProgrammer Feb 24 '12 at 13:26

Expanding on the previous answer...

On the x86 platform your code would get compiled down to something like this:

; 32-bit ints:
mov cl, 32
shl dword ptr i, cl

The CPU will shift the dword in the variable i by the value contained in the cl register modulo 32. So, 32 modulo 32 yields 0. Hence, the shift doesn't really occur. And that's perfectly fine per the C standard. In fact, what the C standard says in 6.5.7-3 is because the aforementioned CPU behavior was quite common back in the day and influenced the standard.

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Are you sure about the 16-bit shift? –  Atom Feb 24 '12 at 11:08
    
@Atom: I've forgotten about it, you're right, it will shift a 16-bit word by up to 31 positions too. I'll remove the 16-bit case. –  Alexey Frunze Feb 24 '12 at 11:16
    
I tested what you mentioned as: i <<= 30; i <<= 2; It gives the expected output as 0. –  SivaSu Feb 24 '12 at 12:13

As already mentioned by others, according to C standard the behavior of the shift is undefined.

That said, the program prints 1. A low-level explanation of why it prints 1 is as follows:

When compiling without optimizations the compiler (GCC, clang) emits the SHL instruction:

...
mov    $32,%ecx
shll   %cl,0x1c(%esp)
...

The Intel documentation for SHL instruction says:

SAL/SAR/SHL/SHR—Shift

The count is masked to 5 bits (or 6 bits if in 64-bit mode and REX.W is used). The count range is limited to 0 to 31 (or 63 if 64-bit mode and REX.W is used).

Masking the shift count 32 (binary 00100000) to 5 bits yields 0 (binary 00000000). Therefore the shll %cl,0x1c(%esp) instruction isn't doing any shifting and leaves the value of i unchanged.

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Dup of my answer. :) –  Alexey Frunze Feb 24 '12 at 11:10
    
And one reason for the UB is that Intel did not say that for the 8086. That processor performed all the shifts you asked it to, and produced a zero for shifting more than the word size. –  Bo Persson Feb 24 '12 at 11:40

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