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I am trying to cast a SIMD integer variable into a double. But I can't see what the result of this operation will be. Example:

int arr[8]={12345678,12333333,12344444,12355555,12366666,12377777,12388888,12399999};
__m256i temp = _mm256_load_si256((__m256i *) arr);
__m256d temp2 = _mm256_castsi256_pd (temp);

as a result of this operation what are the members in my temp2?

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    Why are you using _mm256_load_si256, which may cause faults, instead of _mm256_loadu_si256? – MikeCAT Feb 27 '19 at 17:46
  • i didn't know that would cause faults, i will change to _mm256_loadu_si256 next time. – OgiciBumKacar Feb 27 '19 at 17:47
  • That might cause fault but modern compilers are smart and they align it. BTW, in order to avoid segmentation fault you can align your array to 32-byte boundary with searching align google for your platform including OS and Compiler. – Martin Mar 3 '19 at 22:55
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Short answer

The members in temp2 will be:

{4.014635e-305, 4.062922e-305, 4.111209e-305, 4.159495e-305}

How to obtain the values

Just write the SIMD data into an double array back and print it.

#include <stdio.h>
#include <immintrin.h>

int main(void) {
    int hoge[4]; /* hack that worked on tested environment to avoid Segmentation Fault */
    double result[4];
    int i;

    int arr[8]={12345678,12333333,12344444,12355555,12366666,12377777,12388888,12399999};
    __m256i temp = _mm256_load_si256((__m256i *) arr);
    __m256d temp2 = _mm256_castsi256_pd (temp);

    _mm256_storeu_pd(result, temp2);
    for (i = 0; i < 4; i++) printf("result[%d] = %.6e (%.15a)\n", i, result[i], result[i]);
    return 0;
}

I ran this code on Wandbox and got this output:

result[0] = 4.014635e-305 (0x1.c311500bc614e00p-1012)
result[1] = 4.062922e-305 (0x1.c87e300bc5c7c00p-1012)
result[2] = 4.111209e-305 (0x1.cdeb100bcb34a00p-1012)
result[3] = 4.159495e-305 (0x1.d357f00bd0a1800p-1012)

You can write the SIMD data to an double array via _mm256_storeu_pd().

An exception may be generated when address that is not 32-byte aligned is passed into _mm256_load_si256(), so you should do the alignment. Actually Segmentation Fault occurred on Wandbox, so I inserted the dummy array hoge to do the alignment.

Why the values were obtained

_mm256_castsi256_pd() is actually just copying the bytes and changing their interpretation.

Assuming little-endian is used and int is 4-byte long, the data in arr is like this in the byte-addressed memory:

data in arr[8]:
|   12345678|   12333333|   12344444|   12355555|   12366666|   12377777|   12388888|   12399999|
byte data in arr[8] (in little endian):
|4e 61 bc 00|15 31 bc 00|7c 5c bc 00|e3 87 bc 00|4a b3 bc 00|b1 de bc 00|18 0a bd 00|7f 35 bd 00|
data seen as 64-bit hex:
|     0x00bc311500bc614e|     0x00bc87e300bc5c7c|     0x00bcdeb100bcb34a|     0x00bd357f00bd0a18|

Then, assuming that 64-bit IEEE754 is used in double, the 64-bit data consists of 1-bit sign, 11-bit exponent and 52-bit significand.

Taking the first element 0x00bc311500bc614e as example, the sign bit is 0 (plus/zero), the exponent is 0x00b (11 - 1023 = -1012) and the significand is 0xc311500bc614e.

This matches with what is printed via %.15a in the sample code above. (two extra 0s are printed because printing 15 digits is specified while only data for 13 digits is reordered, so the remainder is padded with 0.) The other elements also matches like this.

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    You don't need a dead-reckoning hack, just alignas(32) double result[4]; if you want to use alignment-required store instead of storeu, to make sure you don't have a cache-line split. Sometimes gcc will choose to over-align arrays that are the target of an aligned store, but I guess not always. – Peter Cordes Feb 28 '19 at 5:23
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    And BTW, we're talking about x86 intrinsics, so yes int is 4 bytes, double is IEEE binary64, and everything is little endian. Intel's intrinsics API isn't careful about types, so it's only compatible with ABIs where this is true. (Which of course includes all existing x86 / x86-64 ABIs.) – Peter Cordes Feb 28 '19 at 5:25
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Operation _mm256_castsi256_pd does literally nothing, it is a reinterpretation - equivalent to:

  int v_i;
  double d_i = *((double*)(int*)&v_i).

Use __m256d _mm256_cvtepi32_pd (__m128i a) as it actually converts 4 integers to 4 doubles.

alignas(16) int arr[4]={12345678,12333333,12344444,12355555};
__m128i temp = _mm_load_si128((__m128i *) arr);
__m256d temp2 = _mm256_cvtepi32_pd(temp);

Note: the loading operations _mm_load_si128 and _mm256_load_si256 require the addresses to be properly aligned. Else use the unaligned versions _mm_loadu_si128 and _mm256_loadu_si256; thought the unaligned versions are slower.

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    Equivalent except without any undefined behaviour from violating strict aliasing. Also int and double aren't the same size on any x86 C++ implementation. memcpy from double to uint64_t would be a better example. – Peter Cordes Feb 27 '19 at 21:02
  • __m256d temp2 = _mm256_cvtepi32_pd(temp); Is there a way to fastly split an __m256i variable into 2 __m128i variables so that I can use it in this function? – OgiciBumKacar Feb 27 '19 at 21:31
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    @OgiciBumKacar: _mm256_extracti128_si256 for the high half (1 shuffle instruction), and _mm256_castsi256_si128 the low half (zero instructions). – Peter Cordes Feb 27 '19 at 22:33
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As a result of this operation, temp2 will contain garbage. For example, the first double lane will be 4.0146351468550722e-305.

This is by design. _mm256_castsi256_pd intrinsic doesn’t convert values, it only re-interprets bits in register as doubles.

If you want these double constants in the register, just use _mm256_setr_pd intrinsic:

// Set double values to the constants
__m256d temp2 = _mm256_setr_pd( 12345678, 12333333, 12344444, 12355555 );

Or if these values aren’t constant, use _mm256_cvtepi32_pd intrinsic, here's a complete example:

alignas( 32 ) int arr[ 8 ] = { 12345678, 12333333, 12344444, 12355555,
    12366666, 12377777, 12388888, 12399999 };
__m256i integers = _mm256_load_si256( ( const __m256i* ) &arr );
// Convert first 4 int32 values to doubles
__m256d lowDoubles = _mm256_cvtepi32_pd( _mm256_castsi256_si128( integers ) );
// Convert last 4 values to doubles
__m256d highDoubles = _mm256_cvtepi32_pd( _mm256_extracti128_si256( integers, 1 ) );

This will actually convert, not bit cast, the values.

AVX registers hold 256 bits of data. This is 8 int32 values in __m256i type, 8 float values in __m256 data type, but only 4 double values in __m256d type.

P.S. There’s also alignment bug in your code, best way to fix is add alignas(32) before int arr[8]

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  • __m256d temp2 = _mm256_cvtepi32_pd( temp ); when I run this I get the error error: cannot convert ‘__m256i {aka __vector(4) long long int}’ to ‘__m128i {aka __vector(2) long long int}’ for argument ‘1’ to ‘__m256d _mm256_cvtepi32_pd(__m128i)’ __m256d temp3 = _mm256_cvtepi32_pd( temp1 ); I think its because the function requires a __128i variable but temp1 is a __258i variable. Do you know a fast way to convert from __258i to __128i? So that I would only use the first 4 integers first and then the second 4 – OgiciBumKacar Feb 27 '19 at 21:42
  • thank you very much that worked. One last question. when I store the integers as double with these simd functions, my values change from 12345678 to 1.23456... even though my value is not above 2^52 ( which when I looked up was the highest integer a double can store). Is there a way I can fix this? – OgiciBumKacar Feb 27 '19 at 22:34
  • Maybe what if i explain what im trying to achieve it would make more sense. I am trying to do integer division in simd but since theres no function for it i am trying to first cast my integers to doubles and then do the divison and cast it back again. Is there a way I can do this? – OgiciBumKacar Feb 27 '19 at 22:35
  • @OgiciBumKacar See another update, I’ve verified the registers contain correct numbers. About division, the easy way is use Intel compiler, it has _mm256_div_epi32 function implemented in its runtime library. Yes, you can do with doubles if that’s what you need. – Soonts Feb 27 '19 at 23:08
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    Also, if you know divisors in advance and they’re same across all lanes, there’s better way, use godbolt.org then manually translate from assembly to vector intrinsics. E.g. this is how to divide by 12345678: godbolt.org/z/bmMO3S imul -> _mm256_mullo_epi32, sar -> _mm256_srai_epi32, shr -> _mm256_srli_epi32, add -> _mm256_add_epi32. – Soonts Feb 27 '19 at 23:09

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