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Assume I have two vectors represented by two arrays of type `double`, each of size 2. I'd like to add corresponding positions. So assume vectors `i0` and `i1`, I'd like to add `i0[0] + i1[0]` and `i0[1] + i1[1]` together.

Since the type is `double`, I would need two registers. The trick would be to put `i0[0]` and `i1[0]` , and `i0[1]` and `i1[1]` in another and just add the register with itself.

My question is, if I call `_mm_load_ps(i0[0])` and then `_mm_load_ps(i1[0])`, will that place them in the lower and upper 64-bits separately, or will it replace the register with the second `load`? How would I place both doubles in the same register, so I can call `add_ps` after?

Thanks,

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I think what you want is this:

``````double i0[2];
double i1[2];

// do whatever you want to with "sum" now
``````

When you do a `_mm_load_pd`, it puts the first double into the lower 64 bits of the register and the second into the upper 16 bits. So, after the loads above, `x1` holds the two `double` values `i0[0]` and `i0[1]` (and similar for `x2`). The call to `_mm_add_pd` vertically adds the corresponding elements in `x1` and `x2`, so after the addition, `sum` holds `i0[0] + i1[0]` in its lower 64 bits and `i0[1] + i1[1]` in its upper 64 bits.

Edit: I should point out that there is no benefit to using `_mm_load_pd` instead of `_mm_load_ps`. As the function names indicate, the `pd` variety explicitly loads two packed doubles and the `ps` version loads four packed single-precision floats. Since these are purely bit-for-bit memory moves and they both use the SSE floating-point unit, there is no penalty to using `_mm_load_ps` to load in `double` data. And, there is a benefit to `_mm_load_ps`: its instruction encoding is one byte shorter than `_mm_load_pd`, so it is more efficient from an instruction cache sense (and potentially instruction decoding; I'm not an expert on all of the intricacies of modern x86 processors). The above code using `_mm_load_ps` would look like:

``````double i0[2];
double i1[2];

__m128d x1 = (__m128d) _mm_load_ps((float *) i0);
__m128d x2 = (__m128d) _mm_load_ps((float *) i1);
// do whatever you want to with "sum" now
``````

There is no function implied by the casts; it simply makes the compiler reinterpret the SSE register's contents as holding doubles instead of floats so that it can be passed into the double-precision arithmetic function `_mm_add_pd`.

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You can certainly use `_mm_load_ps`, but you risk slower performance on a hypothetical future processor which is designed in such a fashion that there is a domain-bypass penalty between single- and double-precision floating point operations. I know of no plans for such a processor, but that's not to say that one won't ever be implemented; that's why there are distinct load operations. It's a remote possibility, admittedly, but why risk it? – Stephen Canon Feb 13 '12 at 15:32
I agree that there is a risk of performance deterioration on a future processor. I would suggest that one consider (i.e. measure) any performance benefit to be obtained by using `MOVPS` instead of `MOVPD` on an application-specific basis. If there's a benefit to using it today, and there is no indication of a looming architecture that would have a penalty for doing so, I would do it. Loads like these could easily be abstracted in tandem to allow automatic switch to a different implementation in the future. – Jason R Feb 13 '12 at 16:41

The `_ps` prefix is an abbreviation for "packed single", meaning it is for use with single-precision floating point, not double-precision.

Instead, you want `_mm_load_pd()`. This function takes a 16-byte aligned pointer to the first member of an array of two `double`s, and load them both. So you would use this like so:

``````__m128d v0 = _mm_load_pd(i0);
`_mm_load_ps` can in fact be used with double-precision values (and there are benefits to doing so); see my answer. – Jason R Feb 13 '12 at 15:27