Consider the following C function prototype, where num_t is a data type declared using typedef:

void store_prod(num_t *dest, unsigned x, num_t y) {
 *dest = x*y;

gcc generates the following assembly code implementing the body of the computation: What data type is num_t?

The correct answer is that num_t is unsigned long long but I really don't understand why, any help will be greatly appreciated!!

# dest  at %ebp +8, x at %ebp +12, y at %ebp +16
movl  12(%ebp), %eax
movl  20(%ebp), %ecx
imull %eax, %ecx
mull  16(%ebp)
leal  (%ecx,%edx), %edx
movl  8(%ebp), %ecx
movl  %eax, (%ecx)
movl  %edx, 4(%ecx)
  • Was mull 6(%ebp) supposed to be 16? Otherwise the code makes no sense, because a dword load from 6(%ebp) would partially overlap the dword at 8(%ebp). – Peter Cordes Jan 13 at 18:14
  • yess, i wrote it wrong, so sorry x) it's fixed – grekuliPuli Jan 13 at 18:19
  • The convention is to return values that don't fit into a single register (AX) via the DX:AX register pair. [but it is compiler/platform-dependedent]. Also x86 multiplications put the most significant part ofthe result into DX. – wildplasser Jan 13 at 18:22
  • @wildplasser: gcc is computing the value in edx:eax, but the function stores the value to memory. The C return type is void. Perhaps this is un-optimized code; gcc -O0 seems to treat it almost like a GNU C statement-expression and does reliably make the last assignment work as a return value. Probably because of some quirk of gcc's internal design. – Peter Cordes Jan 13 at 18:25
  • 1
    @wildplasser: No, instructions don't run faster on EDX:EAX, but the output of widening mul is implicitly edx:eax. Only multi-operand forms of imul give you a choice. The compiler had no choice without using extra mov instructions (except it used LEA to give itself a choice where to put the upper half, for no reason) . mul and cdq are why the calling convention made that choice. (Are you using Go asm notation, where AX actually means EAX or RAX? This is a 32-bit question using AT&T syntax, so just say EDX:EAX.) – Peter Cordes Jan 13 at 20:02

We can tell from the use of (%ebp) addressing modes that this is 32-bit code, not x86-64.

In 32-bit mode, unsigned long long is the only 64-bit unsigned integer type, in any of the common ABIs. (e.g. the i386 System V ABI, used on Linux). long is 32-bit.

We can tell that num_t is a 64-bit integer type because it's stored in two 32-bit halves from the result of integer multiply and addition.

We can tell that it's an unsigned integer type because gcc used mul instead of imul between the x and the low half of y. (2-operand imul %eax, %ecx to multiply x with the upper half of y is the same binary operation for signed or unsigned: only full-multiply (N x N => 2N bits) cares about signedness.)

IDK why gcc would use leal (%ecx,%edx), %edx instead of add %ecx, %edx. Maybe you compiled with -mtune=atom or something? Preserving flags isn't necessary.

Anyway, it's an ordinary 64 x 32 => 64 bit extended-precision multiplication.

This is C, not C++, so a class wrapping a 64-bit integer with an overloaded * operator can be ruled out, too.

We can rule out FP types because that would have used an FP multiply.

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