BTW, your code doesn't actually work: `mov ebx, 2`

clobbers ebx, but you don't save/restore it. So you've stepped on a register that is call-preserved in all the usual ABIs / calling conventions. See the x86 tag wiki.

Also, I think `ret 12`

should be `ret 8`

, since you take two 4 byte args. (See below).

Here's an interesting idea: branchless by always adding two elements. For an odd-length array, it's the same two elements. For an even-length array, it's the middle-round-down and middle-round-up.

If your code actually has the same array length repeatedly, so a branch will predict well, a conditional branch will probably be better (on `test ecx, 1`

/ `jnz odd`

, or `jc`

after shift). Esp. if odd lengths are the common case. *Sometimes* it's worth doing something unconditionally, even if it's not always needed.

```
; Untested
GetMedian PROC
;; return in eax. clobbers: ecx, edx (which don't need to be saved/restored)
mov ecx, [esp+8] ; ecx = unsigned len
mov edx, [esp+4] ; edx = int *arr
shr ecx ; ecx = len/2. CF = the bit shifted out. 0 means even, 1 means odd
mov eax, [edx + ecx*4] ; eax = arr[len/2]
sbb ecx, -1 ; ecx += 1 - CF.
add eax, [edx + ecx*4] ; eax += arr[len/2 + len&1]
shr eax, 1 ; eax /= 2 (or sar for arithmetic shift)
ret 12 ;;; Probably a bug
GetMedian ENDP
;; 5 instructions, plus loading args from the stack, and the ret.
```

I left off the instructions to make a stack frame, because this is a leaf function with no need for any local storage. Using `ebp`

doesn't make anything easier or help with backtraces, and is a waste of instructions.

For most conditions, you have to use `setcc`

to get a 0 or 1 in a register based on the flag. But `CF`

is special. add-with-carry and sub-with-borrow use it (which I take advantage of here), and so do the rotate-through-carry instructions. It's more common to `adc reg, 0`

, but I needed the inverse, and came up with `sbb reg, -1`

to add 0 or 1 depending on CF.

**Are you sure **`ret 12`

is right? Your 2 args are only 8 bytes. `ret imm16`

adds the immediate to `esp`

*after* popping the return address, so the count is the total change to the stack pointer due to the `call`

/`ret`

pair.

Also, I assume that adding two elements won't wrap (carry or overflow), even when it's the middle element of an odd-length array.

Or, another branchless approach which is probably worse

```
; Untested
; using cmov on two loads, instead of sbb to make the 2nd load address dependent on CF
GetMedian PROC
mov ecx, [esp+8] ; ecx = unsigned len
mov edx, [esp+4] ; edx = int *arr
shr ecx, 1 ; ecx = len/2. CF = the bit shifted out. 0 means even, 1 means odd
mov eax, [edx + ecx*4] ; eax = arr[len/2]
mov edx, [edx + ecx*4 + 4] ; edx = arr[len/2+1] (reads past the end if len=0, and potentially touches a different cache line than len/2)
cmovc edx, eax ; CF still set from shr. edx = odd ? arr[len/2] : edx
add eax, edx
shr eax, 1 ; eax /= 2 (or sar for arithmetic shift)
ret 8
GetMedian ENDP
```

## Branching implementation:

This is probably more like what you'd get from a C compiler, but some compiler might not be smart enough to branch on CF as set by the shift. I wouldn't be surprised either way, though; I think I've seen gcc or clang branch on flags set by shifts.

```
; Untested
GetMedian PROC
;; return in eax. clobbers: ecx, edx (which don't need to be saved/restored)
mov ecx, [esp+8] ; ecx = unsigned len
mov edx, [esp+4] ; edx = int *arr
shr ecx ; ecx = len/2. CF = the bit shifted out. 0 means even, 1 means odd
mov eax, [edx + ecx*4] ; eax = arr[len/2]
jc @@odd ; conditionally skip the add and shift
add eax, [edx + ecx*4 + 4] ; eax += arr[len/2 + 1]
shr eax, 1 ; eax /= 2 (or sar for arithmetic shift)
@@odd: ;; MASM local label, doesn't show up in the object file
ret 8
GetMedian ENDP
```

Alternatively:

```
jnc @@even
ret 8 ; fast-path for the odd case
@@even: ;; MASM local label, doesn't show up in the object file
add eax, [edx + ecx*4 + 4] ; eax += arr[len/2 + len&1]
shr eax, 1 ; eax /= 2 (or sar for arithmetic shift)
ret 8 ; duplicate whole epilogue here: any pop or whatever
```

## Play with the scale factor instead of shifting:

Mask off the low bit of `len`

, and then use `arr[len/2] = [edx + (len/2)*4] = [edx + len*2]`

This shortens the dependency chain from `len`

to result by one `shr`

, but it means the first load has to come after the branch. (And without tail-duplication (separate `ret`

s), we'd need an unconditional branch somewhere to implement the `if(odd){}else{}`

structure instead of the simpler `load; if(even){}; ret`

structure.)

```
; Untested
GetMedian PROC
;; return in eax. clobbers: ecx, edx (which don't need to be saved/restored)
mov ecx, [esp+8] ; ecx = unsigned len
mov edx, [esp+4] ; edx = int *arr
test ecx, 1
jz @@even
mov eax, [edx + ecx*2 - 2] ; odd
ret 8
@@even:
mov eax, [edx + ecx*2]
add eax, [edx + ecx*2 + 4]
shr eax, 1
ret 8
GetMedian ENDP
```

`-S`

. If you don't have either of those compiers, take a visit to gcc.godbolt.org. – EOF May 14 '16 at 15:49