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I am trying to extract 4 bytes out of a 128 bit register in efficient way. The problem is that each value is in a sperate 32bit {120,0,0,0,55,0,0,0,42,0,0,0,120,0,0,0}. I want to transform the 128 bit to 32 bit it the form {120,55,42,120}.

The "raw" code looks like the following:

__m128i byte_result_vec={120,0,0,0,55,0,0,0,42,0,0,0,120,0,0,0};
unsigned char * byte_result_array=(unsigned char*)&byte_result_vec;
result_array[x]=byte_result_array[0];
result_array[x+1]=byte_result_array[4];
result_array[x+2]=byte_result_array[8];
result_array[x+3]=byte_result_array[12];  

My SSSE3 code is:

unsigned int * byte_result_array=...;
__m128i byte_result_vec={120,0,0,0,55,0,0,0,42,0,0,0,120,0,0,0};
const __m128i eight_bit_shuffle_mask=_mm_set_epi8(1,1,1,1,1,1,1,1,1,1,1,1,0,4,8,12);    
byte_result_vec=_mm_shuffle_epi8(byte_result_vec,eight_bit_shuffle_mask);
unsigned int * byte_result_array=(unsigned int*)&byte_result_vec;
result_array[x]=byte_result_array[0];

How can I do this efficiently with SSE2. Is there a better version with SSSE3 or SSE4?

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1 Answer 1

up vote 7 down vote accepted

You can look at a previous answer of mine for some solutions to this and the reverse operation.

In particular in SSE2 you can do it by first packing the 32-bit integers into signed 16-bit integers and saturating:

byte_result_vec = _mm_packs_epi32(byte_result_vec, byte_result_vec);

Then we pack those 16-bit values into unsigned 8-bit values using unsigned saturation:

byte_result_vec = _mm_packus_epi16(byte_result_vec, byte_result_vec);

We can then finally take our values from the lower 32-bits of the register:

int int_result = _mm_cvtsi128_si32(byte_result_vec);
unsigned char* byte_result_array = (unsigned char*)&int_result;
result_array[x]   = byte_result_array[0];
result_array[x+1] = byte_result_array[1];
result_array[x+2] = byte_result_array[2];
result_array[x+3] = byte_result_array[3];

EDIT: The above assumes that the 8-bit words are initially in the low bytes of their respective 32-bit words and the rest is filled with 0s, since otherwise their will get clamped during the saturating packing process. Thus the operations are the following:

             byte   15                               0
                    0 0 0 D  0 0 0 C  0 0 0 B  0 0 0 A

_mm_packs_epi32 ->  0 D 0 C  0 B 0 A  0 D 0 C  0 B 0 A

_mm_packus_epi16 -> D C B A  D C B A  D C B A  D C B A
                                               ^^^^^^^

_mm_cvtsi128_si32 -> int DCBA, laid out in x86 memory as bytes A B C D

-> reinterpreted as unsigned char array { A, B, C, D }

If the uninterresting bytes are not filled with 0s initially, you have to mask them away beforehand:

byte_result_vec = _mm_and_si128(byte_result_vec, _mm_set1_epi32(0x000000FF));

Or if the interresting bytes are initially in the high bytes, you have to shift them into the low bytes beforehand:

byte_result_vec = _mm_srli_epi32(byte_result_vec, 24);

Or, if you actually want { D, C, B, A } (which is not completely clear to me from your question), well, then this amounts to just switching the array index in the assignments (or alternively perfoming a 32-bit shuffle (_mm_shuffle_epi32) on the initial SSE register beforehand).

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this is a perfect answer. How can I upvote it twice? :) this helped me a lot. Do you happen to know a better way with SSE4? –  martin s Nov 20 '12 at 16:17
    
@martins: with SSSE3 and greater, you just want a PSHUFB (which is what your existing code should compile to). –  Stephen Canon Nov 20 '12 at 16:25
    
@martins I'm not that well versed in SSE > 2, maybe I'll try to look into it. –  Christian Rau Nov 20 '12 at 16:26

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