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There already is a question on this, but it was closed as "ambiguous" so I'm opening a new one - I've found the answer, maybe it will help others too.

The question is: how do you write a sequence of assembly code to initialize an XMM register with a 128-bit immediate (constant) value?

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5 Answers 5

up vote 9 down vote accepted

Just wanted to add that one can read about generating various constants using assembly in Agner Fog's manual Optimizing subroutines in assembly language, Generating constants, section 13.4, page 121.

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+1 for Agner Fog –  Paul R Jul 11 '11 at 18:01
    
Thanks, forgot about that one :). Btw, the book suggests SHUFPD which works, but in this case I think my proposal with MOVLHPS is better (shorter, at least) –  Virgil Jul 11 '11 at 18:15
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You can do it like this, with just one movaps instruction:

        .align 4      ; note: some versions of gcc toolchain require .align 16

LC0:
        .long   1082130432
        .long   1077936128
        .long   1073741824
        .long   1065353216

foo:
        movaps  LC0(%rip), %xmm0
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True, but I was generating the code dynamically, it was simpler to add code than to add a memory section :) (and btw, your example should use .align 16, right?) –  Virgil Jul 11 '11 at 18:13
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@Virgil: different versions of the gcc toolchain are a little inconsistent on this, but usually the .align directive takes a power of 2 argument, so .align 4 means align to a multiple of 2^4 = 16 bytes. –  Paul R Jul 11 '11 at 18:20
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How would you do this on x86-32? I can't figure out how to translate the pc-relative addressing. –  Janus Troelsen Nov 10 '11 at 10:58
    
I use align 16 and it works as expected (i.e. Virgil is correct.) I do not know whether that changed, but .align 4 would potential crash with an alignment exception. –  Alexis Wilke Jan 20 '13 at 0:11
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@JanusTroelsen did you try (%eip) -- with 'e' instead of 'r'. –  Alexis Wilke Jan 20 '13 at 0:12
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As one of the 10000 ways to do it, use pinsertq

mov rax, first half

pinsertq xmm0, rax, 0  

mov rax, second half

pinsertq xmm0, rax, 1
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Where is pinsertq documented? I couldn't find that instruction in any of the intel instruction manuals. –  Sergey L. Oct 14 '13 at 11:15
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The best solution (especially if you want to stick to SSE2 - i.e. to avoid using AVX) to initialize two registers (say, xmm0 and xmm1) with the two 64-bit halves of your immediate value, do MOVLHPS xmm0,xmm1 In order to initialize a 64-bit value, the easiest solution is to use a general-purpose register (say, AX), and then use MOVQ to transfer its value to the XMM register. So the sequence would be something like this:

MOV RAX, <first_half>
MOVQ XMM0, RAX
MOV RAX, <second_half>
MOVQ XMM1, RAX
MOVLHPS XMM0,XMM1
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The part about SSE2 and AVX is rather a non sequitur - perhaps you mean SSE3/SSSE3/SSE4 rather than AVX ? –  Paul R Jul 11 '11 at 18:01
    
I meant the CPID feature flag. SSE3/4 doesn't help you much. I think I found a simpler way to do it with AVX instructions, but I ignored it since CPUs supporting it aren't widespread. –  Virgil Jul 11 '11 at 18:21
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There are multiple ways of embedding constants in the instruction stream:

  1. by using immediate operands
  2. by loading from PC-relative addresses

So while there is no way to do an immediate load into a XMM register, it's possible to do a PC-relative load (in 64bit) from a value stored "right next" to where the code executes. That creates something like:

.align 4
.val:
    .long   0x12345678
    .long   0x9abcdef0
    .long   0xfedbca98
    .long   0x76543210
func:
     movdqa .val(%rip), %xmm0

When you disassemble:

0000000000000000 :
   0:   78 56 34 12 f0 de bc 9a
   8:   98 ca db fe 10 32 54 76

0000000000000010 :
  10:   66 0f 6f 05 e8 ff ff    movdqa -0x18(%rip),%xmm0        # 0 

which is utterly compact, 23 Bytes.

Other options are to construct the value on the stack and again load it from there. In 32bit x86, where you don't have %rip-relative memory access, one can still do that in 24 Bytes (assuming the stackpointer is aligned on entry; else, unaligned load required):

00000000 :
   0:   68 78 56 34 12          push   $0x12345678
   5:   68 f0 de bc 9a          push   $0x9abcdef0
   a:   68 98 ca db fe          push   $0xfedbca98
   f:   68 10 32 54 76          push   $0x76543210
  14:   66 0f 6f 04 24          movdqa (%esp),%xmm0

While in 64bit (stackpointer alignment at function entry is guaranteed there by the ABI) that'd take 27 Bytes:

0000000000000000 :
   0:   48 b8 f0 de bc 9a 78 56 34 12   movabs $0x123456789abcdef0,%rax
   a:   50                              push   %rax
   b:   48 b8 10 32 54 76 98 ba dc fe   movabs $0xfedcba9876543210,%rax
  15:   50                              push   %rax
  16:   66 0f 6f 04 24                  movdqa (%rsp),%xmm0

If you compare any of these with the MOVLHPS version, you'll notice it's the longest:

0000000000000000 :
   0:   48 b8 f0 de bc 9a 78 56 34 12   movabs $0x123456789abcdef0,%rax
   a:   66 48 0f 6e c0                  movq   %rax,%xmm0
   f:   48 b8 10 32 54 76 98 ba dc fe   movabs $0xfedcba9876543210,%rax
  19:   66 48 0f 6e c8                  movq   %rax,%xmm1
  1e:   0f 16 c1                        movlhps %xmm1,%xmm0

at 33 Bytes.

The other advantage of loading directly from instruction memory is that the movdqa doesn't depend on anything previous. Most likely, the first version, as given by @Paul R, is the fastest you can get.

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Good job at presenting every single possibility and showing which one is the shortest. Personally, I prefer the IP relative, it's clear and very short. On the other hand, its one possibly "expensive" hit to memory (opposed to the code that should always be in the cache.) –  Alexis Wilke Jan 20 '13 at 0:17
    
Wrt. to caching, by loading the constant from an address within the same cacheline as the code loading it, you have a good chance of it being cache-hot - since the executing code must've been fetched by the time it runs, and at least L2 is unified, it's likely to get no worse than L2 cache hit overhead for the load of the constant. –  FrankH. Jan 21 '13 at 10:07
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