Second question first:
div is a very slow instruction (more than 20 clock cycles). The sequence above consists of more instructions, but they're all relatively fast, so it's a net win in terms of speed.
The first five instructions (up to and including the
shrl) compute i/10 (I'll explain how in a minute).
The next few instructions multiply the result by 10 again, but avoiding the
imul instructions (whether this is a win or not depends on the exact processor you're targeting - newer x86s have very fast multipliers, but older ones don't).
movl %edx, %eax ; eax=i/10
sall $2, %eax ; eax=(i/10)*4
addl %edx, %eax ; eax=(i/10)*4 + (i/10) = (i/10)*5
addl %eax, %eax ; eax=(i/10)*5*2 = (i/10)*10
This is then subtracted from
i again to obtain
i - (i/10)*10 which is
i % 10 (for unsigned numbers).
Finally, on the computation of i/10: The basic idea is to replace division by 10 with multiplication by 1/10. The compiler does a fixed-point approximation of this by multiplying with (2**35 / 10 + 1) - that's the magic value loaded into
edx, though it's output as a signed value even though it's really unsigned - and right-shifting the result by 35. This turns out to give the right result for all 32-bit integers.
There's algorithms to determine this kind of approximation which guarantee that the error is less than 1 (which for integers means it's the right value) and GCC obviously uses one :)
Final remark: If you want to actually see GCC compute a modulo, make the divisor variable (e.g. a function parameter) so it can't do this kind of optimization. Anyway, on x86, you compute modulo using
div expects the 64-bit dividend in
edx:eax (high 32 bits in edx, low 32 bits in eax - clear edx to zero if you're working with a 32-bit number) and divides that by whatever operand you specify (e.g.
div ebx divides
ebx). It returns the quotient in
eax and the remainder in
idiv does the same for signed values.