# How do I implement multiplication and division in MIPS assembly without using the built in instructions?

Ok, here is the problem. I had to write a MIPS program that got 2 input numbers from the user. Then, I had to write a code that would output the product, quotient and remainder for the 2 numbers entered by the user.

Now, that was pretty straight forward. However, I didnt realize that we could NOT use the multiply and divide operands in the program. Now I dont know what to do because I am confused on how to do it without the multiply and division operands. I only used it twice in the whole program, it works fine but my professor wont accept it and now im getting sad. Any help would be appreciated. Thank you

Here is my code

``````# Given positive integers a and b, output a/b and a%b.
.data
str1: .asciiz "Enter a: "
str2: .asciiz "Enter b: "
str3: .asciiz "a/b = "
str4: .asciiz "a%b = "
str5: .asciiz "a*b = "
newline: .asciiz "\n"
.text

main: li   \$v0, 4            # system call code for print_string
la   \$a0, str1         # address of str1
syscall                # print str1

#get the first number from user, put it into \$s0

li   \$v0, 5            # system call code for read_int
syscall                # read an integer into \$v0 from console
add  \$s0, \$v0, \$zero   # copy \$v0 into \$s0 (a)

li   \$v0, 4            # system call code for print_string
la   \$a0, str2         # address of str1
syscall                # print str1

# get second number from user, put it into \$t1
syscall         #make the syscall
move \$s1, \$v0       #move the number read into \$s1(b)

#DO THE CALCULATIONS................................................
div \$s0, \$s1        #diving \$s0 by \$s1
mflo    \$t0         #storing value of lo(quotient) in
#register \$t0
mfhi    \$t1         #storing value of hi(remainder) in
#register \$t1

mult \$s0, \$s1
mflo \$t2

li \$v0,1
move \$a0, \$t2
syscall

li \$v0,4
la \$a0, str5
syscall

li   \$v0, 4            # system call code for print_string
la   \$a0, str3         # address of str1
syscall                # print str1

#print a/b
li  \$v0, 1      #load syscall print_int into \$v0
move \$a0, \$t0      #move the number to print into \$t2
syscall
# read print string for str4
li \$v0, 4
la \$a0, str4
syscall
# print remainder
li \$v0, 1
move \$a0, \$t1
syscall

#end of program
li  \$v0, 10     #system call code for exit
syscall
``````
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you need to ask yourself: "what is multiplication? what is division?" the wikipedia entry on multiplication might help (I'm serious) –  mfrankli Mar 21 '12 at 5:04
i did, honestly.......i understand the concept that if you shift the binary over to the left, it divides......if you shift it over to the right, it multiplies......................i just dont know how to put that into mips –  John Doe Mar 21 '12 at 5:08
oh man I hadn't even thought of doing it that way; it might be possible, but definitely tricky –  mfrankli Mar 21 '12 at 5:11

What you're looking for is bitwise multiplication/division.

I'm not sure I can summarize it succinctly, but here I go with an example:

### To Multiply

Let's say you wish to multiply the number 6 by the number 5.
If a = number 6, then (in simplified 8-bit) this is:
`a=00000110`

If b = the number 5, then (in simplified 8-bit) this is:
`b=00000101`

To multiply these numbers, you need to shift by the nearest multiple of two below the nummber, then add.

For example, the nearest multiple of 2 below 5 is 4, that is to say it's 2^2;
So we bitwise shift left `a` (the number 6) 2 times:
`a << 2`
Which now makes it `00011000`

This means we've now multiplied by 4; to now make this multiplied by 5, we simply add `a` again:

``````     00011000
+00000110
=00011110
=30 (base 10)
``````

Which is 6*5.

Let's try this again with 12*11 The nearest multiple of 2 below 11 is 8 (2^3). This means we'll need to bitwise shift the number 12 3 times, then add it to itself another 3 times.

``````    00001100 = 12
//Let's bitshift by 3
01100000 = 96
01100000
+00001100
=01101100 = 108
+00001100
=01111000 = 120
+00001100
=10000100 = 132 = 12*11
``````

### To Divide

To divide 12 by 11, you go the other way; subtract 12 from 132, 3 times, then bitshift to the right 3 times (to divide by 8)

### Relevant Resource(s)

That's the best I can do right at this moment; if you want more, with relevant algorithms in C, take a look at http://www.programmersheaven.com/mb/CandCPP/295363/295363/bitwise-multiplication--division/

If you want any of this answer expanded, comment below;

P.S. I've shown you two examples with prime numbers (nasty) but what if you get a number like 12? Logically, based on what I've said, the nearest multiple of 2 is 8 (2^3), so you'd have to bitshift left 3, then add 12 to the number 4 times.

But if you do the maths, you'd find that 12 is actually = (2^3 + 2^2)... which means you can get (12 << 3) (that's 12 bitshift-left 3 times), then add it to (12 << 2) (that's 12 bitshift left 2 times)... magic!

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I note that mfrankli's answer above for multiplication would work acceptably well, but wouldn't be quite so useful for division, alas –  jonodlo Mar 21 '12 at 5:24
I think multiplication:addition::division:subtraction? –  mfrankli Mar 21 '12 at 5:25
Oh lord, I'm not even thinking right now; you're quite right - if you wanted to divide a by b, you could just keep subtracting b from a until you have an amount leftover that's smaller than b (which makes up your remainder) –  jonodlo Mar 21 '12 at 5:27
The java makes sense....it is just that I dont know how to convert that into MIPS –  John Doe Mar 21 '12 at 12:27

Try this for multiplication algorithm: This is MIPS implementation of Boothe's algorithm: http://code.google.com/p/mips-booth-multiplication/source/browse/trunk/booth.asm?r=9

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From the Wikipedia entry on Multiplication:

"Because the result of scaling by whole numbers can be thought of as consisting of some number of copies of the original, whole-number products greater than 1 can be computed by repeated addition"

In other words, to multiply a * b you add a together b times.

The strategy you mention in your comment (bitshifting) is interesting - probably more efficient, but definitely MUCH more complicated.

An analogous strategy will work for division/remainder.

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