# Divide a number by 3 without using *, /, +, -, % operators

How would you divide a number by 3 without using `*`, `/`, `+`, `-`, `%`, operators?

The number may be signed or unsigned.

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@AlexandreC. - those techniques are using addition (+) though. –  hatchet Jul 27 '12 at 19:40
This was oracle so what parts of oracle were you allowed to use? –  Hogan Jul 27 '12 at 19:45
The identified duplicate isn't a duplicate. Note that several answers here use neither bit shifting or addition since this question didn't restrict a solution to those operations. –  Michael Burr Jul 28 '12 at 0:37
...and here is how PL/SQL is born. –  ssg Jul 29 '12 at 13:28
BTW: The other question was about checking if a number is divisible by 3. This question is about dividing by 3. –  wildplasser Jul 30 '12 at 13:57

first:

``````x/3 = (x/4) / (1-1/4)
``````

then figure out how to solve x/(1 - y):

``````x/(1-1/y)
= x * (1+y) / (1-y^2)
= x * (1+y) * (1+y^2) / (1-y^4)
= ...
= x * (1+y) * (1+y^2) * (1+y^4) * ... * (1+y^(2^i)) / (1-y^(2^(i+i))
= x * (1+y) * (1+y^2) * (1+y^4) * ... * (1+y^(2^i))
``````

with y = 1/4:

``````int div3(int x) {
x <<= 6;    // need more precise
x += x>>2;  // x = x * (1+(1/2)^2)
x += x>>4;  // x = x * (1+(1/2)^4)
x += x>>8;  // x = x * (1+(1/2)^8)
x += x>>16; // x = x * (1+(1/2)^16)
return (x+1)>>8; // as (1-(1/2)^32) very near 1,
// we plus 1 instead of div (1-(1/2)^32)
}
``````

although it uses `+`, but somebody already implements add by bitwise op

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Okay I think we all agree that this isn't a real world problem. So just for fun, here's how to do it with Ada and multithreading:

``````with Ada.Text_IO;

procedure Divide_By_3 is

protected type Divisor_Type is
entry Poke;
entry Finish;
private
entry Release;
entry Stop_Emptying;
Emptying : Boolean := False;
end Divisor_Type;

protected type Collector_Type is
entry Poke;
entry Finish;
private
Emptying : Boolean := False;
end Collector_Type;

end Input;
end Output;

protected body Divisor_Type is
entry Poke when not Emptying and Stop_Emptying'Count = 0 is
begin
requeue Release;
end Poke;
entry Release when Release'Count >= 3 or Emptying is
New_Output : access Output;
begin
if not Emptying then
New_Output := new Output;
Emptying := True;
requeue Stop_Emptying;
end if;
end Release;
entry Stop_Emptying when Release'Count = 0 is
begin
Emptying := False;
end Stop_Emptying;
entry Finish when Poke'Count = 0 and Release'Count < 3 is
begin
Emptying := True;
requeue Stop_Emptying;
end Finish;
end Divisor_Type;

protected body Collector_Type is
entry Poke when Emptying is
begin
null;
end Poke;
entry Finish when True is
begin
Emptying := True;
end Finish;
end Collector_Type;

Collector : Collector_Type;
Divisor : Divisor_Type;

begin
Divisor.Poke;
end Input;

begin
Collector.Poke;
end Output;

Cur_Input : access Input;

-- Input value:
Number : Integer := 18;
begin
for I in 1 .. Number loop
Cur_Input := new Input;
end loop;
Divisor.Finish;
Collector.Finish;
end Divide_By_3;
``````
-

Quite amused none answered with a generic division:

``````/* For the given integer find the position of MSB */
int find_msb_loc(unsigned int n)
{
if (n == 0)
return 0;

int loc = sizeof(n)  * 8 - 1;
while (!(n & (1 << loc)))
loc--;
return loc;
}

/* Assume both a and b to be positive, return a/b */
int divide_bitwise(const unsigned int a, const unsigned int b)
{
int int_size = sizeof(unsigned int) * 8;
int b_msb_loc = find_msb_loc(b);

int d = 0; // dividend
int r = 0; // reminder
int t_a = a;
int t_a_msb_loc = find_msb_loc(t_a);
int t_b = b << (t_a_msb_loc - b_msb_loc);

int i;
for(i = t_a_msb_loc; i >= b_msb_loc; i--)  {
if (t_a > t_b) {
d = (d << 1) | 0x1;
t_a -= t_b; // Not a bitwise operatiion
t_b = t_b >> 1;
}
else if (t_a == t_b) {
d = (d << 1) | 0x1;
t_a = 0;
}
else { // t_a < t_b
d = d << 1;
t_b = t_b >> 1;
}
}

r = t_a;
printf("==> %d %d\n", d, r);
return d;
}
``````

-
``````#!/bin/ruby

def div_by_3(i)
i.div 3        # always return int http://www.ruby-doc.org/core-1.9.3/Numeric.html#method-i-div
end
``````
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I'm pretty sure you can wrap Ruby call as an external call from C with popen() –  A.B Jul 30 '12 at 15:05

All answers are probably not that what the interviewer liked to hear:

"I would never do that, who will me pay for such silly things. Nobody will have an advantage on that, its not faster, its only silly. Prozessor designers have to know that, but this must then work for all numbers, not only for division by 3"

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It seems no one mentioned the division criterion for 3 represented in binary - sum of even digits should equal the sum of odd digits (similar to criterion of 11 in decimal). There are solutions using this trick under Check if a number is divisible by 3.

I suppose that this is the possible duplicate that Michael Burr's edit mentioned.

-

Where InputValue is the number to divide by 3

``````SELECT AVG(NUM)
FROM (SELECT InputValue NUM from sys.dual
UNION ALL SELECT 0 from sys.dual
UNION ALL SELECT 0 from sys.dual) divby3
``````
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``````#include <stdio.h>

typedef struct { char a,b,c; } Triple;

unsigned long div3(Triple *v, char *r) {
if ((long)v <= 2)
return (unsigned long)r;
return div3(&v[-1], &r[1]);
}

int main() {
unsigned long v = 21;
int r = div3((Triple*)v, 0);
printf("%ld / 3 = %d\n", v, r);
return 0;
}
``````
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Why don't we just apply the definition studied at College? The result maybe inefficient but clear, as the multiplication is just a recursive subtraction and subtraction is an addition, then the addition can be performed by a recursive xor/and logic port combination.

``````#include <stdio.h>

int rc;
int carry;
rc = a ^ b;
carry = (a & b) << 1;
if (rc & carry)
else
return rc ^ carry;
}

int sub(int a, int b){
}

int div( int D, int Q )
{
/* lets do only positive and then
* add the sign at the end
* inversion needs to be performed only for +Q/-D or -Q/+D
*/
int result=0;
int sign=0;
if( D < 0 ) {
D=sub(0,D);
if( Q<0 )
Q=sub(0,Q);
else
sign=1;
} else {
if( Q<0 ) {
Q=sub(0,Q);
sign=1;
}
}
while(D>=Q) {
D = sub( D, Q );
result++;
}
/*
* Apply sign
*/
if( sign )
result = sub(0,result);
return result;
}

int main( int argc, char ** argv )
{
printf( "2 plus 3=%d\n", add(2,3) );
printf( "22 div 3=%d\n", div(22,3) );
printf( "-22 div 3=%d\n", div(-22,3) );
printf( "-22 div -3=%d\n", div(-22,-3) );
printf( "22 div 03=%d\n", div(22,-3) );
return 0;
}
``````

As someone says... first make this work. Note that algorithm should work for negative Q...

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Here it is in Python with, basically, string comparisons and a state machine.

``````def divide_by_3(input):
to_do = {}
enque_index = 0
zero_to_9 = (0, 1, 2, 3, 4, 5, 6, 7, 8, 9)
leave_over = 0
for left_over in (0, 1, 2):
for digit in zero_to_9:
# left_over, digit => enque, leave_over
to_do[(left_over, digit)] = (zero_to_9[enque_index], leave_over)
if leave_over == 0:
leave_over = 1
elif leave_over == 1:
leave_over = 2
elif leave_over == 2 and enque_index != 9:
leave_over = 0
enque_index = (1, 2, 3, 4, 5, 6, 7, 8, 9)[enque_index]
left_over = 0
digits = list(str(input))
if digits[0] == "-":
digits = digits[1:]
for digit in digits:
enque, left_over = to_do[(left_over, int(digit))]
``````
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Good 'ol `bc`:

``````\$ num=1337; printf "scale=5;\${num}\x2F3;\n" | bc
445.66666
``````
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if we consider `__div__` is not orthographically `/`

``````def divBy3(n):
return n.__div__(3)

print divBy3(9), 'or', 9//3
``````
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3 in base 2 is 11.

So just do long division (like in middle school) in base 2 by 11. It is even easier in base 2 than base 10.

For each bit position starting with most significant:

Decide if prefix is less than 11.

If it is output 0.

If it is not output 1, and then substitute prefix bits for appropriate change. There are only three cases:

`````` 11xxx ->    xxx    (ie 3 - 3 = 0)
100xxx ->   1xxx    (ie 4 - 3 = 1)
101xxx ->  10xxx    (ie 5 - 3 = 2)
``````

All other prefixes are unreachable.

Repeat until lowest bit position and you're done.

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Here's a method my Grandfather taught me when I was a child. It requires + and / operators but it makes calculations easy.

Add the individual digits together and then see if its a multiple of 3.

But this method works for numbers above 12.

Example: 36,

3+6=9 which is a multiple of 3.

42,

4+2=6 which is a multiple of 3.

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Well you could think of using a graph/tree like structure to solve the problem. Basically generate as many vertices as the number that is to be divided by 3. Then keep pairing each un-paired vertex with two other vertices.

Rough pseudocode:

``````function divide(int num)
while(num!=0)
Add a new vertice to vertiexList.
num--
quotient = 0
for each in vertexList(lets call this vertex A)
if vertexList not empty
Add an edge between A and another vertex(say B)
else
your Remainder is 1 and Quotient is quotient
if vertexList not empty
Add an edge between A and another vertex(say C)
else
your remainder is 2 and Quotient is quotient
quotient++
remove A, B, C from vertexList
Remainder is 0 and Quotient is quotient
``````

This can obviously be optimized and the complexity depends on how big you number is, but it shoud work providing you can do ++ and --. It's as good as counting only cooler.

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Using a Linux shell script:

``````#include <stdio.h>
int main()
{
int number = 30;
char command[25];
snprintf(command, 25, "echo \$((%d %c 3)) ", number, 47);
system( command );
return 0;
}
``````
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Generally, a solution to this would be:

`log(pow(exp(numerator),pow(denominator,-1)))`

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I would use this code to divide all positive, non float numbers. Basically you want to align the divisor bits to the left to match the dividend bits. For each segment of the dividend (size of divisor) you want to check to make sure if the the segment of dividend is greater than the divisor then you want to Shift Left and then OR in the first registrar. This concept was originally created in 2004 (standford I believe), Here is a C version which uses that concept. Note: (I modified it a bit)

``````int divide(int a, int b)
{
int c = 0, r = 32, i = 32, p = a + 1;
unsigned long int d = 0x80000000;

while ((b & d) == 0)
{
d >>= 1;
r--;
}

while (p > a)
{
c <<= 1;
p = (b >> i--) & ((1 << r) - 1);
if (p >= a)
c |= 1;
}
return c; //p is remainder (for modulus)
}
``````

Example Usage:

``````int n = divide( 3, 6); //outputs 2
``````
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Easy!

``````x /= 3;
``````

does not use the / operator. (/= is a different operator)

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