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I'm working with integers and SSE and have become very confused about how endianness affects moving data in and out of registers.

My initial, wrong, understanding

Initially my understanding was as follows. If I have an array of 4 byte integers the memory would be laid out as follows since x86 architectures are little endian:

0D 0C 0B 0A 1D 1C 1B 1A 2D 2C 2B 2A .... nD nC nB nA

Where the letters A, B, C and D index the bytes within an integer element, and numbers index the element.

In an XMM register, my understanding is that four integers would be laid out as follows:

0A 0B 0C 0D 1A 1B 1C 1D 2A 2B 2C 2D 3A 3B 3C 3D

However, I'm pretty sure this picture is wrong for several reasons. The first is the documentation for the mm_load_si128 intrinsic, which is supposed to work for any integer data, but in the above picture should only work for one word size. Similarly there is this thread: Finally I see people writing code like the following:

__declspec(align(16)) int32_t A[N];
__m128i* As = (__m128i*)A;

A potentially correct picture

The Wikipedia article on endianness says I should think of memory addresses increasing right to left. How about the following picture for memory then?

nA nB nC nD ... 2A 2B 2C 2D 1A 1B 1C 1D 0A 0B 0C 0D

And then in a register:

3A 3B 3C 3D 2A 2B 2C 2D 1A 1B 1C 1D 0A 0B 0C 0D
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The easiest way to think about this is that the byte ordering of the whole XMM register is little endian. So the least significant byte of the whole 16 bytes is byte 0. Individual elements are also little endian. Note also that we only care about endianness with SIMD when doing any horizontal operations, such as packing or unpacking - the rest of the time it makes no difference. – Paul R Jun 5 '14 at 7:57
@PaulR, if you have four 32-bit integers or eight 16-bit shorts what is the least significant byte? I would have expected for 32-bit ints the 128-bit register is 0A0B0C0D 1A1B1C1D 2A2B2C2D 3A3B3C3D (or 3A3B3C3D...0A0B0C0D). But the OP makes a good point that since the way to load integers values (8-bit, 16-bit, 32-bit, or 64-bit) is with one instruction which does not depend on the size of the integer then it must fill them the same way independent of the integer size. So how is it represented in the register? – Z boson Jun 5 '14 at 8:27
If you think of little endian byte ordering as always starting at the lowest address, which corresponds to byte 0 in the XMM register, then for 32 bits ints the first int is as 0..3, the second int at 4..7, etc. For 16 bits shorts the first short is at 0..1, the second short is at 2..3, etc. So the ordering of the vector, and the ordering of the elements is the same - the least significant byte is at the lowest index within the element/vector. If I can find the time I will draw some diagrams and post it as an answer. – Paul R Jun 5 '14 at 8:32
I don't see how it's possible for mm_load_si128 to translate from memory to 0..3 4..7 or 0..1 2..3 unless it knows the size of the integers that it's loading. If there was a separate instruction for each possible integer size (like there is for float and double) this would make sense but there's only one instruction. – Z boson Jun 5 '14 at 9:53
Think about the layout in memory - if the whole vector is little endian and each element is little endian then everything "just works". The first byte is byte 0 of the vector and also byte 0 of the first element. For 4x32 bit ints (call them a..d) you have: a0 a1 a2 a3 b0 b1 b2 b3 c0 c1 c2 c3 d0 d2 d2 d3 where a0 is the LS byte of the first int, a. Similarly for 8 x 16 bit shorts, a..h, you have: a0 a1 b0 b1 c0 c1 d0 d1 e0 e1 f0 f1 g0 g1 h0 h1`. – Paul R Jun 5 '14 at 12:16
up vote 2 down vote accepted

It's just a question of interpretation. We read/write digits of a number from left to right and highest digit to lowest digit. So for a 32-bit number with the highest byte A then B then C and lowest byte D we would read/write ABCD. We do the same notating a 128-bit integer.

3A3B3C3D 2A2B2C2D 1A1B1C1D 0A0B0C0D

But in a little endian system it reads and writes digits from the lowest address to the highest like this

0D0C0B0A 1D1C1B1A 2D2C2B2A 3D3C3B3A

For 16-bit integers it's the same logic. We could read/write it as

7A7B 6A6B 5A5B 4A4B 3A3B 2A2B 1A1B 0A0B

and the little endian computer read/stores it from lowest to highest address as

0B0A 1B1A 2B2A 3B3A 4B4A 5B5A 6A6B 7B7A

That's why there is only one instruction to read/write 32-bit, 16-bit and 8-byte integers int a 128-bit register: namely movdqa and movaps (or the unaligned variants movdqu and movups).

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