## Initial Question:

A group of us (electronic engineering students - UK) have recently been getting to grips, in our own time, with programming the PIC16F84A microcontroller. The need has arisen to multiply two 8-bit numbers together, with no known min/max for each. A fellow student presented the following idea.

```
multiply_numbers:
; Takes numbers in Num1 and Num2, and returns product in OutH:OutL
clrf OutH ; clear all non-input variables
clrf OutL
mult_loop
bcf STATUS,c ; clear carry bit
movfw Num2
addwf OutL ; add Num2 to OutL
btfsc STATUS,c ; check carry bit
incf OutH ; if set, increment OutH
decfsz Num1 ; decrement Num1
goto mult_loop ; if Num1 is not zero, repeat loop
return ; else return
```

I felt that this, although quite short in terms of lines of code, could take a relatively long time to execute for larger numbers. I did a bit of thinking myself and started along a route of shifting one number to the right, the other to the left, and adding the left-shifted number a certain amount of times, along the way, to the output to arrive at the final answer. I wasn't quite doing it right, but then stumbled across this question on SO which gave me the idea of expressing one of the input numbers as:

N = a_0 + a_1*2 + a_2*2^2 + a_3*2^3 + ... + a_7*2^7

From that starting point, I came up with this method for multiplying two 8-bit numbers to get a 16-bit output (stored in two 8-bit registers).

```
multiply_numbers:
; Takes numbers in Num1 and Num2L, and returns product in OutH:OutL
clrf Num2H ; clear all non-input variables
clrf OutL
clrf OutH
mult_loop
btfsc Num1,0 ; test LSB of Num1
call add_num16 ; if set, add Num2H:Num2L to OutH:OutL
call shift_left ; shift Num2H:Num2L left (multiply by 2)
rrf Num1,f ; shift Num1 right
clrw ; clear working register (0x00)
bcf STATUS,z ; clear zero bit (3) of the STATUS register
addwf Num1,w ; add 0x00 to Num1
btfss STATUS,z ; if Num1 is zero, then exit loop
goto mult_loop ; else, continue with another iteration
return
add_num16
movfw Num2H
addwf OutH,f ; add Num2H to OutH
bcf STATUS,c ; clear carry bit (0) of the STATUS register
movfw Num2L
addwf OutL,f ; add Num2L to OutL
btfsc STATUS,c ; check carry bit
incf OutH,f ; increment OutH if set (OutL overflowed)
return
shift_left
bcf STATUS,c ; clear carry bit
rlf Num2L,f ; rotate Num2L left (carry -> LSB, MSB -> carry)
rlf Num2H,f ; rotate Num2H left, using carry bit from Num2L
return
```

I think this second example is quicker in most cases, simply because the loop will only repeat up to 8 times instead of up to 256 times.

Am I correct in my assumption of their relative speed/efficiency? And does the second block of code actually function as I intend it to (are there any potential problems with it that I've missed)? Lastly, can this multiplication be further optimized using techniques not already employed?

Thank you in advance.

*P.S. All variables/registers have been properly defined with their own address. The extensive code commenting is because we are trying to compile a set of routines that we can refer back to in the future and still know at a glance what is going on and why.*

*P.P.S. This question is related to personal/hobby interest in programming this pic and has nothing to do with any current coursework, etc. Just to allay any suspicions you might have had!*

Microcontroller: PIC16F84A

Development environment: MPLABX IDE v1.10

Compiler: mpasm (v5.43)

## Edit #1:

- Instead of testing the LSB of Num1 and adding a left-shifted Num2H:Num2L to OutH:OutL, test the MSB of Num1 and add Num2 to a left-shifted OutH:OutL.
- Make 'shift_left' inline rather than a called sub-function.
- Unroll 'mult_loop' to optimize the 8th iteration.

Method 2 improved:

```
multiply_numbers:
; Takes numbers in Num1 and Num2, and returns product in OutH:OutL
clrf OutL ; clear all non-input variables
clrf OutH
; 1st iteration
btfsc Num1,7 ; test MSB of Num1
call add_num8 ; if set, add Num2 to OutH:OutL
bcf STATUS,c ; clear carry bit
rlf OutL,f ; rotate OutL left (carry -> LSB, MSB -> carry)
rlf OutH,f ; rotate OutH left, using carry bit from OutL
rlf Num1,f ; shift Num1 left
; 2nd iteration
btfsc Num1,7
call add_num8
bcf STATUS,c
rlf OutL,f
rlf OutH,f
rlf Num1,f
; 3rd iteration
btfsc Num1,7
call add_num8
bcf STATUS,c
rlf OutL,f
rlf OutH,f
rlf Num1,f
; 4th iteration
btfsc Num1,7
call add_num8
bcf STATUS,c
rlf OutL,f
rlf OutH,f
rlf Num1,f
; 5th iteration
btfsc Num1,7
call add_num8
bcf STATUS,c
rlf OutL,f
rlf OutH,f
rlf Num1,f
; 6th iteration
btfsc Num1,7
call add_num8
bcf STATUS,c
rlf OutL,f
rlf OutH,f
rlf Num1,f
; 7th iteration
btfsc Num1,7
call add_num8
bcf STATUS,c
rlf OutL,f
rlf OutH,f
rlf Num1,f
; 8th iteration
btfss Num1,7 ; test MSB of Num1
return ; if not set, then return. else...
add_num8
bcf STATUS,c ; clear carry bit (0) of the STATUS register
movfw Num2
addwf OutL,f ; add Num2L to OutL
btfsc STATUS,c ; check carry bit
incf OutH,f ; increment OutH if set (OutL overflowed)
return
```