For `Int`

s, `x `div` 2`

is usually implemented as a single instruction. If you compile:

```
div2 :: Int -> Int
div2 x = x `div` 2
```

with `ghc -Wall -O2 -fforce-recomp -ddump-asm`

with GHC 9.6.4, you'll get the assembly below, to which I've added some annotations. Of the 23 or so instructions, the `(`div` 2)`

itself is implemented by a single instruction in the `.LcZw`

block.

```
sarq $1,%rax ;; *** SHIFT ARITHMETIC RIGHT BY ONE BIT ***
```

In the context of your `izq`

function -- again, assuming it's `izq :: Int -> Int`

-- the situation is similar. For the `even`

branch, the actual calculation of `(n-1) `div` 2`

is implemented in two assembly instructions:

```
decq %rax
sarq $1,%rax
```

while for the `odd`

branch, it takes three:

```
decq %rax
sarq $1,%rax
incq %rax
```

The cost of the `even`

/`odd`

check itself is rather expensive, apparently due to a bug in the `even`

implementation. Replace it with your own (e.g., `even' x = x `mod` 2 == 0`

), and you'll get better assembly.

```
;; even/odd check using `even` function (ick!)
leaq -1(%rax),%rbx
movq %rbx,%rcx
shrq $63,%rcx
movq %rbx,%rdx
addq %rcx,%rdx
andq $-2,%rdx
subq %rdx,%rbx
testq %rbx,%rbx
jne .Lc13I ;; jump if odd
;; even/odd check using: even' x = x `mod` 2 == 0
leaq -1(%rax),%rbx
andl $1,%ebx
testq %rbx,%rbx
jne .Lc15b
```

If `izq`

is inlined in a block of performant code, you can assume that the entire function will be boiled down to the 14 or so instructions listed above, and that the incremental cost of the `div`

will be one instructions.

But, a better way to think of it is that the cost of `div`

is almost nothing, and if you are trying to write some high performance code, you should do lots of profiling and look for improvements other than replacing `div`

.

The assembly generated by `div2`

:

```
.section .text
.align 8
.align 8
.quad 4294967301
.quad 0
.long 14
.long 0
.globl FastDiv.div2_info
.type FastDiv.div2_info, @function
FastDiv.div2_info:
.LcZm:
leaq -8(%rbp),%rax ;; check for sufficient stack space
cmpq %r15,%rax
jb .LcZt ;; ...if not, handle it
.LcZu:
movq $.Lblock_cZj_info,-8(%rbp) ;; push continuation for `div 2` operation on stack
movq %r14,%rbx
addq $-8,%rbp
testb $7,%bl ;; check if argument is evaluated
jne .LcZj ;; skip to continuation if it is
.LcZk:
jmp *(%rbx) ;; otherwise, evaluate argument
.align 8
.quad 0
.long 30
.long 0
.Lblock_cZj_info: ;; continuation for `div 2` starts here
.LcZj:
addq $16,%r12 ;; allocate 16 bytes on the heap
cmpq 856(%r13),%r12 ;; if not enough room...
ja .LcZx ;; ...do a garbage collection
.LcZw:
movq 7(%rbx),%rax ;; get the integer payload from the argument
sarq $1,%rax ;; *** SHIFT ARITHMETIC RIGHT BY ONE BIT ***
movq $GHC.Types.I#_con_info,-8(%r12) ;; add the constructor for boxed integers to the heap object
movq %rax,(%r12) ;; add the result of the shift to the heap object
leaq -7(%r12),%rbx ;; get a pointer to the heap object
addq $8,%rbp ;; clean up the stack
jmp *(%rbp) ;; call our continunation to pass the result along
.LcZx:
movq $16,904(%r13) ;; handle insufficient heap space
jmp stg_gc_unpt_r1
.LcZt:
leaq FastDiv.div2_closure(%rip),%rbx ;; handle insufficient stack space
jmp *-8(%r13)
.size FastDiv.div2_info, .-FastDiv.div2_info
```

`'div' 2`

might have a very different cost to`'div' x`

in general.`(`div` 2)`

is for postive numbers equivalent to`(`shiftR` 2)`

.`div`

operation? The function seems to do more than one other thing.