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Will modern (2008/2010) incantations of Visual Studio or Visual C++ Express produce x86 MUL instructions (unsigned multiply) in the compiled code? I cannot seem to find or contrive an example where they appear in compiled code, even when using unsigned types.

If VS does not compile using MUL, is there a rationale why?

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What instruction(s) would it use otherwise? –  Jeff Mercado Oct 28 '10 at 2:53
@Jeff M I think perhaps the poster meant that IMUL is used instead in the compiled code. –  user166390 Oct 28 '10 at 2:54
@pst: I was just asking because I didn't have access to the compiler and couldn't see what instructions were actually used. I caved in and booted up my dev machine to figure it out. :) –  Jeff Mercado Oct 28 '10 at 3:04
@Jeff M I'm curios (but not that curious ;-) and was trying to prompt the poster to add clarification :p –  user166390 Oct 28 '10 at 3:09
Yes, VS seems to use IMUL. –  Spain Train Oct 28 '10 at 14:42

4 Answers 4

up vote 13 down vote accepted

imul is more powerful because it accepts using somewhat arbitrary operand registers, whereas mul necessarily uses eax as one of the inputs, and writes out the result into edx:eax. imul makes it easier for the compiler.

imul is nominally for signed integer types, but when multiplying two 32-bit values, the least significant 32 bits of the result are the same, whether you consider the values to be signed or unsigned. In other words, the difference between a signed and an unsigned multiply becomes apparent only if you look at the "upper" half of the result, which mul puts in edx and imul puts nowhere. In C, results of arithmetic operations have the same type than the operands (if you multiply two int together, you get an int, not a long long): the "upper half" is not retained. Hence, the C compiler only needs what imul provides, and since imul is easier to use than mul, the C compiler uses imul.

As a second step, since C compilers use imul and not mul, Intel and AMD invest more efforts into optimizing imul than mul, making the former faster in recent processors. This makes imul even more attractive.

mul is useful when implementing big number arithmetics. In C, in 32-bit mode, you should get some mul invocations by multiplying long long values together. But, depending on the compiler and OS, those mul opcodes may be hidden in some dedicated function, so you will not necessarily see them. In 64-bit mode, long long has only 64 bits, not 128, and the compiler will simply use imul.

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Are you certain of the causality of IMUL/MUL optimizations? Is it possible that VS prefers IMUL because it happens to already be faster (vice compilers prefering it, causing Intel/AMD to make it faster)? –  Spain Train Oct 28 '10 at 14:47
@Mike: on the 80386, mul and imul offer the same speed, and C compilers were already using imul because of the convenience of choosing the registers. So I think that compilers chose first, and processor vendors followed, not the other way round. –  Thomas Pornin Oct 28 '10 at 17:25
in 64-bit mode it'll use mul for __int128 –  Lưu Vĩnh Phúc Aug 12 at 17:54

There's three different types of multiply instructions on x86. The first is MUL reg, which does an unsigned multiply of EAX by reg and puts the (64-bit) result into EDX:EAX. The second is IMUL reg, which does the same with a signed multiply. The third type is either IMUL reg1, reg2 (multiplies reg1 with reg2 and stores the 32-bit result into reg1) or IMUL reg1, reg2, imm (multiplies reg2 by imm and stores the 32-bit result into reg1).

Since in C, multiplies of two 32-bit values produce 32-bit results, compilers normally use the third type (signedness doesn't matter, the low 32 bits agree between signed and unsigned 32x32 multiplies). VC++ will generate the "long multiply" versions of MUL/IMUL if you actually use the full 64-bit results, e.g. here:

unsigned long long prod(unsigned int a, unsigned int b)
  return (unsigned long long) a * b;

The 2-operand (and 3-operand) versions of IMUL are faster than the one-operand versions simply because they don't produce a full 64-bit result. Wide multipliers are large and slow; it's much easier to build a smaller multiplier and synthesize long multiplies using Microcode if necessary. Also, MUL/IMUL writes two registers, which again is usually resolved by breaking it into multiple instructions internally - it's much easier for the instruction reordering hardware to keep track of two dependent instructions that each write one register (most x86 instructions look like that internally) than it is to keep track of one instruction that writes two.

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My intuition tells me that the compiler chose IMUL arbitrarily (or whichever was faster of the two) since the bits will be the same whether it uses unsigned MUL or signed IMUL. Any 32-bit integer multiplication will be 64-bits spanning two registers, EDX:EAX. The overflow goes into EDX which is essentially ignored since we only care about the 32-bit result in EAX. Using IMUL will sign-extend into EDX as necessary but again, we don't care since we're only interested in the 32-bit result.

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According to http://gmplib.org/~tege/x86-timing.pdf, the IMUL instruction has a lower latency and higher throughput (if I'm reading the table correctly). Perhaps VS is simply using the faster instruction (that's assuming that IMUL and MUL always produce the same output).

I don't have Visual Studio handy, so I tried to get something else with GCC. I also always get some variation of IMUL.


unsigned int func(unsigned int a, unsigned int b)
    return a * b;

Assembles to this (with -O2):

        pushq   %rbp
        movq    %rsp, %rbp
        movl    %esi, %eax
        imull   %edi, %eax
        movzbl  %al, %eax
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