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Suppose I have the number 'numb'=1025 [00000000 00000000 00000100 00000001] represented:

On Little-Endian Machine:

00000001 00000100 00000000 00000000

On Big-Endian Machine:

00000000 00000000 00000100 00000001

Now, if I apply Left Shift on 10 bits (i.e.: numb <<= 10), I should have:

[A] On Little-Endian Machine:

As I noticed in GDB, Little Endian does the Left Shift in 3 steps: [I have shown '3' Steps to better understand the processing only]

  1. Treat the no. in Big-Endian Convention:

    00000000        00000000        00000100    00000001
  2. Apply Left-Shift:

    00000000        00010000        00000100        00000000
  3. Represent the Result again in Little-Endian:

    00000000        00000100        00010000        00000000 

[B]. On Big-Endian Machine:

00000000        00010000        00000100        00000000

My Question is:

If I directly apply a Left Shift on the Little Endian Convention, it should give:


00000001 00000100 00000000 00000000

numb << 10:

00010000 00000000 00000000 00000000

But actually, it gives:

00000000        00000100        00010000        00000000 

To achieve the second result only, I have shown three hypothetical steps above.

Please explain me why the above two results are different: The actual outcome of numb << 10 is different than the expected outcome.

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up vote 94 down vote accepted

Endianness is the way values are stored in memory. When loaded into the processor, regardless of endianness, the bit shift instruction is operating on the value in the processor's register. Therefore, loading from memory to processor is the equivalent of converting to big endian, the shifting operation comes next and then the new value is stored back in memory, which is where the little endian byte order comes into effect again.

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Thanks for the explanation. Can you please suggest some reference where I can get a better understanding of such intricacies. – Sandeep Singh Aug 26 '11 at 1:10
The best thing for understanding endianness is to really use it on different architectures at an embedded level. However, I could refer you to these two articles: and… – Carl Sep 4 '11 at 23:39

No, bitshift, like any other part of C, is defined in terms of values, not representations. Left-shift by 1 is mutliplication by 2, right-shift is division. (As always when using bitwise operations, beware of signedness. Everything is most well-defined for unsigned integral types.)

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This is basically true for integer arithmetic, but C does provide plenty of cases of representation-dependent behaviour. – Edmund Aug 25 '11 at 3:44
@Edmund: Hm... most notably the implementation of signedness is not specified, and as a consequence the behaviour of bitwise operations (like right-shift) and of modulo and divide are implementation defined on negative integers. What other things have you in mind which are implementation-defined? – Kerrek SB Aug 25 '11 at 10:24
@KerrekSB unfortunately they're not implementation defined on negative integers. They are unspecified in C89 and undefined in C99+, which was a very bad idea. – Paolo Bonzini Jan 1 at 21:48
@PaoloBonzini: Yes, good point. Actually that's even better, since it reinforces the point that the shift operations are defined in terms of values, possibly being undefined when the result is not representable, and that speculating about the underlying representation doesn't help. – Kerrek SB Jan 1 at 21:56
@KerrekSB: the thing is that everyone actually needs left shift to be represented both as values and as representation, depending on the case. And using unsigned integers can cause other issues, for example x &= -1u << 20 will most likely be incorrect if x is 64-bit and int is 32-bit. For this reason, GCC promises to never treat signed shifts as undefined or even unspecified. – Paolo Bonzini Jan 7 at 15:10

Computers don't write numbers down the way we do. The value simply shifts. If you insist on looking at it byte-by-byte (even though that's not how the computer does it), you could say that on a little-endian machine, the first byte shifts left, the excess bits go into the second byte, and so on.

(By the way, little-endian makes more sense if you write the bytes vertically rather than horizontally, with higher addresses on top. Which happens to be how memory map diagrams are commonly drawn.)

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