# How does this 128 bit integer multiplication work in assembly (x86-64)?

I'm reading Computer Systems: A Programmer's Perspective and the homework was to describe how this algorithm works.

C function:

``````void store_prod(__int128 *dest, int64_t x, int64_t y) {
*dest = x * (__int128)y;
}
``````

Assembly:

``````movq %rdx, %rax
cqto
movq  %rsi, %rcx
sarq  \$63,  %rcx
imulq %rax, %rcx
imulq %rsi, %rdx
mulq  %rsi
movq  %rax, (%rdi)
movq  %rdx, 8(%rdi)
ret
``````

I don't know why it performs: `xh * yl + yh * xl = value which we add after unsigned multiplication`

• Both of the operands to the multiplication must be of the same type. To that end, `x` is promoted to type `__int128`, because `y` is of this type after the cast, and the integer promotion rank of `__int128` is higher than that of `int64_t`. One of the conversions is done by `cqto`, but that only works on `rax`, so the other is converted by `sarq`.
– EOF
Nov 18, 2015 at 20:02
• You don't multiply with `1` or `-1`, you multiply with `0` or `-1`. The arithmetic right shift does exactly what the `cqto` does: sign-extend to a whole register (`%rcx` for the `sarq`, `%rdx` for `cqto`).
– EOF
Nov 18, 2015 at 20:09
• Since `imul` already provides a 64x64->128 bit multiply, I don't see the point of this. You can still explain how it works, of course :) Probably the usual case of disabled optimization, otherwise the compiler is clever enough to use a single `imul`. Nov 18, 2015 at 20:21
• @EOF no need, as I said, at least gcc and clang is clever enough to turn that exact C code into a single `imul`. icc, for some reason, isn't. Nov 18, 2015 at 20:33
• It sounds to me like you want to ask a more general question. Such as if your processor only can do 32*32 to 64 or 64*64 to 64 how to do 128-bit multiplication? That's a much more interesting question. You don't want to do `xh * yl + yh * xl`. You can do that but then you have to figure out overflow. There is a way to do the multiplication without worrying about overflow. Nov 24, 2015 at 13:29

As always, compiler options matter. That source code with `gcc -Og` (optimize for debugging) produces very similar asm to your listing (the cast sign-extends both operands to 128-bit before doing a full 128x128 => 128-bit multiply). This is a naive implementation of exactly what the C standard says should happen (integer precedence rules for converting both operands to the same type).

If you're going to talk about compiler output, you should always say which version of which compiler with what options. Or just post a link to it on godbolt, like the one above. (Edit: oops, source and asm were from a book that didn't give that info. And if that's the global edition of CS:APP 3e, beware that the practice problems are filled with errors in the global edition.)

With `gcc -O3` or `-O2`, GCC takes advantage of the fact that both operands are still really only 64bit, so a single `imul` is enough. (This still produces the same result for every input, and thus still implements the C logic, per the as-if rule. C doesn't have widening operations so you're forced to write the source in an "inefficient" way that depends on the compiler to transform it into efficient asm.)

The `sar \$63, %rcx` is part of sign-extending `rsi` into `rcx:rsi`, just like `cqto` sign-extends `rax` into `rdx:rax`. It replaces every bit of RCX with a copy of the original sign bit.

Most of this answer was already given by other people in comments, but I don't think anyone else noticed that `gcc -Og` / `-O1` gives almost exactly that asm output.

• thanks for the answer. As I said, it's the homework written in the book, so I don't know which compiler was used and with which optimization level flags. Nov 19, 2015 at 8:26
• @TomZych: thanks for the tidy up. Minor improvement, but definitely an improvement. :) Nov 19, 2015 at 9:20
• De rien - almost have my Copy Editor badge :) Nov 19, 2015 at 9:21
• Thanks for the answer. I upvoted. A minor, language-lawyer remark here: the upward conversion to 128 bits should not be called an integer promotion, to be precise. An integer promotion specifically refers to the conversion up to `int` or `unsigned int`. For reference, see the Integer promotions section in en.cppreference.com/w/c/language/conversion Jul 27, 2021 at 9:44
• @aafulei: thanks for catching that terminology mistake from this old answer before I knew better :) Jul 27, 2021 at 10:12

What GCC is doing is using the property that signed multiplication can be done using the following formula.

``````(hi,lo) = unsigned(x*y)
hi -= ((x<0) ? y : 0)  + ((y<0) ? x : 0)
``````

Despite the fact that there is no need to do this since in this case the x86-64 instruction set has a signed 64-bit*64-bit to 128-bit instruction (`imul` with one operand) this formula is useful in other cases. For example for implementing signed 128-bit multiplication with SSE2/AVX2/AVX512 or for implementing 256-bit multiplication when the instruction set only does 128-bit multiplication (such as with x86-64).

GCC implemented this formula a bit differently though. If we take the sign bit and extend it to the whole word, call this function `sign_ext`, then the function returns `-1` or `0`. Then what GCC did is:

``````hi += sign_ext(x)*y + sign_ext(y)*x
``````

for example `sign_ext(x)*y` in pseudo-instructions for 64-bit words is

``````sarq  \$63, x    ; sign_ext(x)
imulq   y, x    ; sign_ext(x)*y
``````

Why is this formula true?

That's a good qeustion. I asked this same question as well and njuffa wrote

@Zboson: It follows directly from two's complement complement representation. E.g. 32-bit integers `-n` and `-m` are represented as unsigned numbers `x=2**32-n, y=2**32-m`. If you multiply those you have `x*y = 2**64 - 2**32*n - 2**32*m + n*m`. The middle terms indicate the necessary corrections to the upper half of the product. Working through a simple example using -1*-1 should prove very instructive.

In order to understand why do we do this operations, try to interpret int128_t as: 2^64 * xh + xl

so if we want to multiply two int128_t integers, we will do the following:

x = 2^64 * xh + xl

y = 2^64 * yh + yl

so x * y = (2^128 * xh * yh) + (2^64 * xh * yl) + (2^64 * yh * xl) + (yl * xl)

And this is exactly, what the assembly code does:

yh = %rdx yl = %rax

xh = %rcx xl = %rsi

2^64 * xh * yl: is `imulq %rax, %rcx` 2^64 indicates, that we need to add this to the high order bits

2^64 * yh * xl: is `imulq %rsi, %rdx` 2^64 indicates, that we need to add this to the high order bits

2^128 * xh * yh: This operation is not needed, since `2^128 * xh * yh` won't fit in 128 bit integer. It represents only sign bit information and may be ignored.

xl * yl: is `mulq %rsi`

I hope this clears things up!