The title says it all. I want to know whether an x86 instruction that reads data from memory, translates its bytes or its bits to the Little-Endian order. For example if we have the following data at address 0 (in binary) (written here in RAW format, sequential):

00110010 01010100

And we read it the following way:

mov ax, word [0]

What will AX contain - "01010100 00110010" or "00101010 01001100"? Or translated into unsigned integer in decimal - "21554" or "10828"?
I suppose that the x86 integer instructions will interpret the register sequential binary data as a Big-Endian binary number, the same endianness as Arabic numbers are written.

  • endianness is generally at the multi-byte level. you shouldn't have to worry about bit-ordering in a single byte.
    – Marc B
    Sep 19, 2014 at 16:45
  • 2
    The processor both reads and writes those bits, the order never matters. While they could never agree about which side of the egg matters most, programmers do universally write the most significant bit on the left. Sep 19, 2014 at 19:08
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    -1 for zero research effort shown
    – xmojmr
    Sep 20, 2014 at 6:32
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    @xmojmr - I think its a fair question for someone less experienced. As far as I know, he would only see the effects of endian-ness if he was viewing both registers and memory. He may not know how to do it.
    – jww
    Sep 20, 2014 at 18:55
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    @jww I think the question shows zero research effort (though it can be useful). Google: "x86 endian" gives me as 1st link Wikipedia: Endianness which says "...The Intel x86 and x86-64 series of processors use the little-endian format, and for this reason, the little-endian format is also known as the Intel convention...". Showing a research effort (also by someone less experienced) is listed as 1st point ("Search, and research") in Help Center > How do I ask a good question?
    – xmojmr
    Sep 20, 2014 at 19:18

3 Answers 3


1.3.1 Bit and Byte Order x86 is little-endian. In illustrations of data structures in memory, smaller addresses appear toward the bottom of the figure; addresses increase toward the top. Bit positions are numbered from right to left. The numerical value of a set bit is equal to two raised to the power of the bit position. IA-32 processors are “little endian” machines; this means the bytes of a word are numbered starting from the least significant byte. Figure 1-1 illustrates these conventions.

enter image description here

The terms endian and endianness refer to the convention used to interpret the bytes making up a data word when those bytes are stored in computer memory. In computing, memory commonly stores binary data by organizing it into 8-bit units called bytes. When reading or writing a data word consisting of multiple such units, the order of the bytes stored in memory determines the interpretation of the data word.

Each byte of data in memory has its own address. Big-endian systems store the most significant byte of a word in the smallest address and the least significant byte is stored in the largest address (also see Most significant bit). Little-endian systems, in contrast, store the least significant byte in the smallest address.

The illustration to the right shows an example using the data word "0A 0B 0C 0D" (a set of 4 bytes written out using left-to-right positional, hexadecimal notation) and the four memory locations with addresses a, a+1, a+2 and a+3; then, in big-endian systems, byte 0A is stored in a, 0B in a+1, 0C in a+2 and 0D in a+3. In little-endian systems, the order is reversed with 0D stored in memory address a, 0C in a+1, 0B in a+2, and 0A in a+3.

enter image description here enter image description here

So, as you can see endianness is always about bytes order not bits.

  • Its a nice graphic but you did not answer his question. Here it is again: "Is Little-Endian a byte or bit order in x86 architecture?".
    – jww
    Sep 20, 2014 at 9:00

AFAIK, endianness is never a bit order, it is always a byte order, no matter for which processor.

The lowest bit is always considered to be at the "right" side and the highest at the "left" side of an integral value (be it a 1, 2, 4, or 8 byte value), so shifts or rotations to the "right" always go toward the lowest bit and to the "left" always toward the highest bit. This is independent of endianness.

The x86 is little endian, meaning that the lowest byte comes first (i.e. at the lowest address). This means that the bytes 0x01, 0x02, 0x03 and 0x04, in that order, can just as well be seen as the 32 bit value 0x04030201, two 16 bit values of 0x0201 and 0x0403 or 4 single bytes (assuming that bytes are octets, i.e. 8 bit values -- there are systems where bytes have other bit sizes, but not the x86).

  • 3
    Related: vector byte-shifts (pslldq) and element indexing (pshufd/shufps/pblend...) treat vector registers the same way as bit-shifts treat the bits in an integer register. So in comments, it's better (but harder to type) to keep track of which elements are where with notation like // [ d c b a ]. This is why _mm_set_epi32(d, c, b, a); takes its args in the opposite order from int arr = {a, b, c, d}; Mar 29, 2016 at 11:39
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    Incidentally, bit order endianness does matter sometimes but x86 arch doesn't have the hardware that would let you observe it because it doesn't have any buses narrower than a byte.
    – Joshua
    Apr 12, 2016 at 16:01
  • There is no bit order endianness, AFAIK. At least not at the software level. I know of no processor where a bit shifted left will turn up in a "lower" position or a bit shifted right in a "higher" position. Apr 13, 2016 at 12:20
  • PPC numbers the bits backwards (or at least they used to), so a left shift moves a bit from position 1 to position 0. 8051 is a bit-addressable architecture, and its endianness is defined down to the bit level (and it's little-endian even at the bit level).
    – sh1
    Jul 7, 2016 at 16:05
  • So 1 << 3 would not result in 8? I wouldn't want to write software in which that isn't true. After all, left and right are just arbitrary conventions, and I would consider "left" as "towards the higher bit", regardless of the underlying hardware. Jul 7, 2016 at 19:05

Binary is a bit tedious, so I translated it to hex; hope that's okay.

The answer to your question, in this case, is that you will get 21,554 (in decimal).

Here is how you can ascertain this on your own...

First, place those two bytes in memory somewhere, with the Equ $

Some_16_Bit_Value   Equ         $
                    Db          032h
                    Db          054h

Okay, now with that in your .Data segment, put something like this in your .Code segment..

        Mov         Ax, Word Ptr [Some_16_Bit_Value]        ;See what you get

The assembler will generate a complete instruction for you, like this...

        mov         ax,word ptr [Some_16_Bit_Value (13FE9A002h)] 

Open a debug window and view that memory location (i.e., 13FE9A002h)

There you will see the first two bytes are: 32 54 (Those are hex, which is what just about everybody uses)

Step into that mov instruction

You will see that AX will then contain 5432 (in hex, which is your decimal 21,554)

  • Its a nice answer but you did not answer his question. Here it is again: "Is Little-Endian a byte or bit order in x86 architecture?".
    – jww
    Sep 20, 2014 at 9:02
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    @jww "...you did not answer his question. Here it is again:..." I'll have to get better, as this is what I read in the original post, "...What will 'ax' contain ...in decimal - "21554" or "10828"?..."
    – User.1
    Sep 20, 2014 at 21:12

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