`2^38`

obviously does not fit in one 32-bit register such as `eax`

.

To store the value `2^38`

(`274877906944`

) you need 39 bits. In 32-bit code you can use eg. two 32-bit registers such as `edx:eax`

. However, in 32-bit code `mul`

only accepts 32-bit **factors** (eg. registers, other of them is always `eax`

), so using 32-bit `mul`

in a loop won't work, because you cannot store your intermediate results in a 32-bit register to be multiplied **again**, even if `mul`

stores the 64-bit **result** in `edx:eax`

.

But you can use `rcl`

to compute eg. `2^38`

in 32-bit code:

```
xor edx,edx
mov eax,2 ; now you have 2 in edx:eax
mov ecx,38 ; 2^n, in this case 2^38 (any value x, 1 <= x <= 63, is valid).
x1: dec ecx ; decrease ecx by 1
jz ready ; if it's 2^1, we are ready.
shl eax,1 ; shift eax left through carry flag (CF) (overflow makes edx:eax zero)
rcl edx,1 ; rotate edx through carry flag (CF) left
jmp x1
ready: ; edx:eax contains now 2^38.
```

**Edit:** a non-loop implementation inspired by @Jagged O'Neill's answer. This one is without jumps for exponent >= 32, one jump for exponent < 32, works also for `ecx`

0, for `ecx`

greater than 63 sets `edx:eax`

to `0`

.

```
mov ecx,38 ; input (exponent) in ecx. 2^n, in this case 2^38.
; (any value x, 0 <= x <= 63, is valid).
; the code begins here.
xor eax,eax
xor edx,edx ; edx:eax is now prepared.
cmp cl,64 ; if (cl >= 64),
setb al ; then set eax to 0, else set eax to 1.
jae ready ; this is to handle cl >= 64.
; now we have 0 <= cl <= 63
sub ecx,1
setnc al ; if (count == 0) then eax = 0, else eax = 1.
lea eax,[eax+1] ; eax = eax + 1. does not modify any flags.
jna ready ; 2^0 is 1, 2^1 = 2, those are ready now.
mov ebx,ecx ; copy ecx to ebx
cmp cl,32 ; if (cl >= 32)
jb low_5_bits
mov cl,31 ; then shift first 31 bits to the left.
shld edx,eax,cl
shl eax,cl ; now shifted 31 bits to the left.
lea ecx,[ebx-31] ; cl = bl - 31
low_5_bits:
shld edx,eax,cl
shl eax,cl
ready:
```