# power of in x86 assembly

as a starter in ASM programming i am need to get the result of 2 to the power of 38 in Assembly , and i need your help in understanding why is my program doesn't produce the result i am need (it prints 4 decimal):

.386
.model flat, stdcall
option casemap:none

include \masm32\include\windows.inc
include \masm32\include\msvcrt.inc
includelib \masm32\lib\msvcrt.lib

.data

formatstr db "%d",0

.code
start:

mov eax , 2
mov ecx , 38
mov esi , eax
mov edx , 0

.while TRUE
mul esi
mov esi, edx
mov edx, 0
mov eax, 2
dec ecx
.break .if (!ecx)
.endw

end start


as you can see i am writing it using masm32 (if that has any matter in that case).

THX.

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What is "doesn't work?" –  GManNickG Oct 1 '12 at 20:10
@GManNickG edited –  Hanan N. Oct 1 '12 at 20:11
Think about how many digits will be needed to store 2^38 and how many bits have you result register. –  JohnTortugo Oct 1 '12 at 20:12
Note that 2^38 is too big for a (32 bit) int - your printf format string will need to be %lld, not %d, and the corresponding argument will need to be 64 bits. –  Paul R Oct 1 '12 at 20:12

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

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


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isn't the x1 loop should start at the dec ecx line ? –  Hanan N. Oct 1 '12 at 22:23
No. loop command decrements ecx and if ecx does not become zero, it jumps to the target address, in this case x1. loop x1 is practically equivalent to dec ecx; jnz x1. A conditional jump to dec ecx line would shift bits only 19 times instead of the needed 37 times. –  nrz Oct 1 '12 at 22:32

When you do a multiplication on an x86, edx will hold the top 32 bits of the result, and eax will hold the bottom 32 bits. When you do:

mul esi
mov esi, edx

The result is only going to be meaningful in the case that edx was 0 so the mov/add is basically doing mov esi, eax. If the top 32 bits are non-zero, you're going to end up with a fairly meaningless mish-mash of the upper and lower bits.