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If I want to move 2 unsigned bytes from memory into a 32-bit register, can I do that with a MOV instruction and no mode switch?

I notice that you CAN do that with the MOVSE and MOVZE instructions. For example, with MOVSE the encoding 0F B7 moves 16 bits to a 32 bit register. It is a 3 cycle instruction, though.

Alternatively I guess I could move 4 bytes into the register and then somehow CMP just two of them somehow.

What is the fastest strategy for retrieving and comparing 16-bit data on 32-bit x86? Note that I am mostly doing 32-bit operations so I can't switch to 16-bit mode and stay there.


FYI to the uninitiated: the issue here is that 32-bit Intel x86 processors can MOV 8-bit data and 16-bit OR 32-bit data depending on what mode they are in. This mode is called the "D-bit" setting. You can use special prefixes 0x66 and 0x67 to use a non-default mode. For example, if you are in 32-bit mode, and you prefix the instruction with 0x66 this will cause the operand to be treated as 16-bit. The only problem is that doing this causes a big performance hit.

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So that's on a P1 or PMMX then, right? The specific microarchitecture is quite important for questions like this. – harold Oct 26 '12 at 19:11
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If you restrict your question to trying to optimize below 3 cycles, you're unlikely to do better than MOVSE/ZE. You might do better to describe what you want to do with the 16 bit quantity; it is more likely one can optimize the block of code containing the MOVZE/SE than the instruction itself, especially if that block has to touch the data "next to" the 16 bit quantity for other reasons. – Ira Baxter Oct 26 '12 at 19:47
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Your cycle timings are not accurate. For an Atom, movsx reg,r/m16 cost 1/1 cyce. LCP stalls are heavily architecture dependent. The Intel advice is to load 32 bits and only use the 16-bit register. – Hans Passant Oct 26 '12 at 19:53
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The operand size prefix isn't length-changing if you use it on an instruction that has no immediate operand (in some cases the 16bit version is then still somewhat slower, but it won't stall the decoders, unless there is a 16byte boundary between the opcode and the modr/m byte). What are you comparing with? If it's a constant, consider putting it in a register. Also, movzx is fast on anything after PMMX, so you could just use that. – harold Oct 27 '12 at 8:36
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Seriously, just use movzx or movsx as appropriate. They are fast on anything made in the last decade. – Stephen Canon Jan 2 '13 at 16:15

stick to 32 bit mode and use 16 bit instructions

mov eax, 0         ; clear the register
mov ax, 10-binary  ; do 16 bit stuff

Alternatively I guess I could move 4 bytes into the register and then somehow CMP just two of them

mov eax, xxxx ; 32 bit num loaded
mov ebx, xxxx
cmp ax, bx    ; 16 bit cmp performed in 32 bit mode
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Doing this causes a prefixed instruction (mode exception). If you actually assemble this code you will see a 0x66 prefix is added to the CMP opcode. This causes a processor stall and huge performance hit. – Tyler Durden May 2 '13 at 15:00
    
The operand-size prefix only causes a performance hit on Intel CPUs when used on an instruction with an imm16 immediate operand (not imm8), because then it changes the length of the rest of the instruction, like add ax, 0x1234. cmp ax,bx is fast, and so is movzx eax, word [mem]. (On Intel SnB-family, mov ax, 0x1234 doesn't have an LCP stall. The decoders handle 16bit mov specially.) – Peter Cordes Apr 10 at 18:05
    
Does not always work. If your address is not 4 byte aligned you pay a penalty, and this code can crash (due to the ignored bytes being off the end of the page and the next page not mapped). – Joshua Apr 11 at 18:20

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