# Find the combinations of 2 1's in a binary number

We have a binary number and we need to generate combination of 2 1's from the given number. If given such a combination of 2 1's we should be able to produce the next combination.

Example:-

``````Given vector   : 10101111 Given combination : 10100000 output       : 10001000
Given vector   : 10101111 Given combination : 10001000 output       : 10000100
Given vector   : 10101111 Given combination : 10000010 output       : 10000001
Given vector   : 10101111 Given combination : 10000001 output       : 00101000
Given vector   : 10101111 Given combination : 00101000 output       : 00100100
``````

Edit: Once the 2nd 1 reaches the last 1 in the given binary number, the 1st 1 is incremented(set to next '1' in the binary number and the 2nd '1' is made the '1' that comes after the 1st '1'(as in eg 4))

This is to be done in hardware so it should not be computationally complex. How can we design this module in VHDL.

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your example don't make much sense. given that `10000010` and `10000001` are nearly identical, how they can produce vastly different `100000001` and `00101000` as outputs? – Marc B Mar 4 '14 at 19:11
What should `10101111` and `00000011` give as output? – Joachim Isaksson Mar 4 '14 at 19:13
@JoachimIsaksson :The given condition is the final case. This case can be ignored ( The system will not be given the final combination as input) – Maximus Mar 4 '14 at 19:18
@MarcB: All the outputs are the next combination 2 1's from the given binary number. So increment the 1st '1' when the 2nd '1' is the last 1 in the binary number – Maximus Mar 4 '14 at 19:20

Here is some asynchronous code that will do the job:

``````library IEEE;
use IEEE.STD_LOGIC_1164.ALL;

entity nex2ones is
Port ( vector : in   STD_LOGIC_VECTOR (1 to 8);
combo1 : in   STD_LOGIC_VECTOR (1 to 8);
combo2 : out  STD_LOGIC_VECTOR (1 to 8);
error  : out  STD_LOGIC);
end nex2ones;

architecture Behavioral of nex2ones is

type int_array_8 is array (1 to 8) of integer range 0 to 8;

begin

process (vector,combo1)

variable ones_ixs        : int_array_8;
variable first_combo1_ix : integer range 0 to 8 := 0;
variable second_combo1_ix: integer range 0 to 8 := 0;
variable first_combo1_k  : integer range 0 to 9 := 0;
variable second_combo1_k : integer range 0 to 9 := 0;
variable k               : integer range 1 to 9;

begin

ones_ixs := (others => 0); -- indices of 1s in vector
combo2   <= (others => '0');
k := 1;
first_combo1_ix  := 0;
second_combo1_ix := 0;
first_combo1_k   := 0;  -- corresponding ptr to ones_ixs
second_combo1_k  := 0;
error            <= '0';

for j in 1 to 8 loop

if combo1(j) = '1' then
if first_combo1_ix = 0 then
first_combo1_ix := j;
first_combo1_k := k;
else
second_combo1_ix := j;
second_combo1_k := k;
end if;
end if;

if vector(j) = '1' then
ones_ixs(k) := j;
k := k + 1;
end if;

end loop;

if k > 1 then k := k - 1; end if; -- point to last nonzero index

if (first_combo1_ix = 0 or second_combo1_ix = 0)
--or (first_combo1_ix = ones_ixs(k-1) and second_combo1_ix = ones_ixs(k))
or (k < 2) then
error <= '1';
else -- no error proceed
if second_combo1_ix = ones_ixs(k) then              -- can't slide 2nd anymore
if (second_combo1_k - first_combo1_k) > 1 then    -- is 1st movable
combo2(ones_ixs(first_combo1_k + 1)) <= '1';    -- move 1st
if (second_combo1_k - first_combo1_k) > 2 then  -- is 2nd movable
combo2(ones_ixs(first_combo1_k + 2)) <= '1'; -- move 2nd
else
combo2(ones_ixs(second_combo1_k)) <= '1';     -- leave 2nd be
end if;
else
error <= '1'; -- no mas
end if;
else
combo2(ones_ixs(first_combo1_k)) <= '1';      -- leave 1st be
combo2(ones_ixs(second_combo1_k + 1)) <= '1'; -- next
end if;
end if;

end process;

end Behavioral;
``````

Testbench output:

``````   ps       vector   combo1   combo2
error
0     00000000 00000000 00000000 1
100000     10101111 10100000 10001000 0
200000     10101111 10001000 10000100 0
300000     10101111 10000010 10000001 0
400000     10101111 10000001 00101000 0
500000     10101111 00101000 00100100 0
600000     10101111 00100100 00100010 0
700000     10101111 00000011 00000000 1
800000     11001110 00000110 00000000 1
900000     10001110 00001010 00000110 0
1000000     11001110 00001010 00000110 0
``````
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